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UPTEC-ES12011
Examensarbete 30 hpApril 2012
Wind Power and Its Impact on the Moldovan Electrical System
Joel ErikssonSimon Gozdz Englund
Teknisk- naturvetenskaplig fakultet UTH-enheten Besöksadress: Ångströmlaboratoriet Lägerhyddsvägen 1 Hus 4, Plan 0 Postadress: Box 536 751 21 Uppsala Telefon: 018 – 471 30 03 Telefax: 018 – 471 30 00 Hemsida: http://www.teknat.uu.se/student
Abstract
Wind Power and Its Impact on the MoldovanElectrical System
Joel Eriksson & Simon Gozdz Englund
The master thesis project has been executed with the cooperation of BorlängeEnergi, with the aim of reducing the high electric energy dependency which Moldovahas on Ukraine, Transnistria and Russia.
The project examines what reduction that would be possible by wind powerinstallations on the existing electrical grid of Moldova. The installations should notsurpass the capacity of the transmission lines or the voltage levels according toregulation. The southern regions of Moldova proved to have the best wind conditionsand the locations of Besarabeasca, Zarnesti, Leovo, Ciadyr and Cimislia in thesouthern region were chosen for wind power installations.
For the analysis a model over the Moldovan electrical system is constructed. Each ofthe five chosen locations is modelled with a generator symbolizing the wind powerinstallation. The power flow software PSS/E is used to construct the model. Toexamine possible wind power installations different scenarios are created. Thescenarios are executed with the southern regions 110 kV system as a focus area. Allscenarios are analysed with a contingency analysis, where transmission lines in thefocus region are tripped. The contingency analysis and the scenarios are automatedusing the programming language Python.
An economic analysis shows payback periods for wind power investments in Moldova,the analysis also shows the sensitivity of the electricity price and discount rates.
The project concludes that wind power installations are possible with the Moldovanelectric grid as it looks today. The installations would result in reducing the highdependency of imported electrical energy.
Sponsor: ÅForsk SidaISSN: 1650-8300, UPTEC ES** ***Examinator: Kjell PernestålÄmnesgranskare: Mikael BergkvistHandledare: Ronny Arnberg
i
I Förord (in Swedish)
Bakgrunden till detta spännande examensarbete är att författarna på egen hand sökte en utmaning
vad gäller uppbyggnad och utformning av framtida elektriska kraftnät. Deras frågeställning var vad
händer i ett kraftnät vid en massiv utbyggnad av t.ex. vindkraft, karakteriserad av stora variationer i
effekt? Frågeställningen är höggradigt intressant i länder med lite tillgång på vattenkraft och ur
perspektivet av utfasning av fossila bränslen. Ur den synvinkeln var det svenska kraftnätet mindre
intressant. Efter kontakter med Ronny Arnberg, Borlänge Energi, kom projektet att fokusera på
elförsörjningen i Moldavien vars kraftnät blev modell för studien. Målet är inte att lösa Moldaviens
energiförsörjningsproblem.
De ambitioner som författarna hade inledningsvis har sedan modererats på ett förtjänstfullt sätt av
ämnesgranskaren Mikael Bergkvist att bättre passa tillgänglighet, tid och resurser. Ronny Arnberg har
bistått med mängder med kontakter i Moldavien som öppnat dörrar för författarna. Resultatet på
författarnas initiala fråga har kanske inte blivit besvarad men väl gett stora insikter i de utmaningar
som väntar.
2012-03-16
Kjell Pernestål
Examinator
Unv.lekt.
Uppsala Universitet
ii
II Acknowledgments
This Master Thesis Project has been financed by a MFS scholarship and a ÅForsk scholarship without
which the project could not have been executed.
Technical support was provided by the Technical University of Moldova, Anatolie Boscneanu Main
Specialist at the National Agency for Energy Regulation and Lise Toll Project Developer at E.ON
Climate & Renewables. Technical support was also provided along with and guidance in times of
need throughout the project by our supervisors at Uppsala University; Mikael Bergkvist and Kjell
Pernestål.
Special thanks should be directed to Professor Arion Valentin and PhD student Victor Gropa at the
Technical University of Moldova who took us in with the true spirit of the Moldovan people; with
helping hands wanting nothing in return. Thank you
This project could not have been written without the help of Borläng energi and its enthusiast Ronny
Arnberg who provided contacts and a workplace in Moldova.
We would also like to take the chance to express our gratitude for the opportunity to experience
Moldova and its truly great people, out of which we now call many friends and whom we will never
forget.
iii
III Populärvetenskaplig beskrivning (in Swedish)
Moldavien är ett av de fattigare länderna i Europa. Det finns ett starkt engagemang och en stor vilja
för sammarbeten med västländer för att lämna fattigdomen och närma sig Västeuropa. Ett viktigt
steg i detta är att bli av med det starka energiberoende gentemot Ukraina och Ryssland som finns
idag. Moldaviens interna politiska situation är svår. En del av Moldavien, Transnistrien, existerar idag
som en autonom republik och har en långdragen konflikt bakom sig som ännu inte är löst.
Transnistrien och situationen där är viktig ur en energisituation då den största kraftanläggningen i
hela regionen ligger där.
Moldavien importerar idag mellan 94 och 98 % av sin totala energikonsumtion där de stora
importprodukterna är naturgas från Ryssland och el från Ukraina och Transnistrien. Av sin
elkonsumtion har Moldavien idag endast möjlighet att producera ca 26 % nationellt, resten
importeras från Ukraina och Transnistrien.
I examensarbetet utreds möjligheterna att minska detta starka beroende genom att öka intern
elproduktion genom vindkraft. Fokus ligger på elnätet, alltså hur mycket vindkraft som kan installeras
till dagens existerande elnät utan att elledningarna blir överbelastade eller att spänningar i elnätet
ökar eller sjunker utanför gällande gränsvärden.
Vindpotentialen har undersökts via tidigare studier och den visar på att potentialen är störst i den
södra delen av Moldavien. Dessa vindkraftskarteringar är utförda utifrån vindmätningar på
meterologiska stationer, ofta på 10 till 12 meters höjd. Genom simuleringsprogram har man sedan
kunnat uppskatta vindhastigheter för olika områden och höjd.
Fem platser med bra vindpotential valdes ut för vidare studier över hur mycket vindkraft som kan
installeras ur nätets perspektiv. Dessa platser i närheten av städerna; Besarabeasca, Zarnesti, Leovo,
Ciadyr och Cimislia ligger alla i södra delen av Moldavien. Den begränsade faktorn för hur mycket
vindkraft som kan byggas är elnätet.
För att undersöka effekterna från vindkraftsinstallationerna på elnätet var det nödvändigt att bygga
upp en modell i datorprogrammet PSS/E, designat för att beräkna effektflöden i elnät. Datorn kan
sedan utföra de komplexa beräkningar som krävs för att räkna ut effekter och spänningar i systemet.
Det räcker dock inte att endast se på systemet som det faktiskt ser ut, man måste också undersöka
vad som skulle händer då en elledning i systemet kopplas bort i en så kallad n-1 analys. Att en lina
kopplas bort kan bero på behov av underhåll eller rena fel som kan uppstå vid till exempel olyckor.
Platserna undersöktes i den färdiga modellen bland annat en och en men även i ett scenario där det
på alla platser samtidigt installeras vindkraft. Vindkraftparkerna symboliseras i modellen som
generatorer som genererar aktiv effekt.
Resultaten visar att den maximalt möjliga installerade effekten varierar mycket beroende på plats.
Cimislia visar sig ha möjlighet för 100 MW, innan överföringskapaciteten blir begränsande. De övriga
platserna begränsas på grund av att spänningsnivåer stiger eller sjunker utanför riktlinjerna. Då
installation sker på alla platser samtidigt finns det möjlighet att installera omkring 260 MW, även här
är höga spänningar en begränsande faktor för ytterligare installation.
iv
Den reaktiva effekten i elnätet har en stark koppling till spänningsnivåer och därav upprepas
scenariona då vindkraftparkerna även har möjlighet att producera eller konsumera reaktiv effekt. Då
vindkraftparkerna på detta sätt har möjlighet att kompensera med reaktiv effekt hålls spänningen
konstant på basspänningsnivån.
De nya resultaten visar att detta ger en möjlighet att öka vindkraftinstallationen per plats. De platser
i tidigare scenariot som tidigt fick spänningsproblem begränsas nu, precis som Cimislia, endast av
överföringskapaciteten. Installation vid Cimislia minskar dock något då reaktiv effekt även den ”tar
upp plats” på elnätet. Maximal produktion är dock fortfarande störst i Cimislia med ca 100 MW. Då
vindkraft installeras på alla platser samtidigt ges en ökning till 355 MW, alltså en tydlig ökning av
möjlig vindkraftsinstallation.
För att räkna ut den totala minskningen av importerad el bör man ta hänsyn till att en vindkraftpark
med installerad effekt med t.ex. 260 MW inte kommer leverera 260 MW hela tiden på grund av att
vinden inte blåser hela tiden. För att ta hänsyn till detta används två olika utnyttjandefaktorer för
vindkraftparkerna, 0,1 och 0,3 där 0,1 är en relativt låg utnyttjandefaktor och 0,3 är en relativt hög
utnyttjandefaktor. Resultaten visar att vindkraftverk som endast levererar aktiv effekt kan minska
elimporten med mellan 7 % till 20 % beroende på utnyttjandefaktorerna. Då vindkraftparken har
möjligheten att konsumera reaktiv effekt kan elimporten minska med mellan 8 % till 25 %.
I rapporten utförs även en ekonomisk analys där återbetalningstiden för ett vindkraftsprojekt tas
fram. Återbetalningstiden beräknas med nettonuvärdesmetoden och återbetalningstiden tas fram
för några olika räntesatser. Återbetalningstiden för vindkraftsprojekten varierar från 3 år till att aldrig
betala tillbaka sig vid de olika ekonomiska scenarierna.
Slutsatsen är att Moldaviens starka beroende av importerad elektricitet kraftigt kan minskas med en
utbyggnad av vindkraft i södra delen av landet.
v
IV Executive summary
The Moldovan electrical energy imports can be reduced by as much as 25 %. This reduction is
possible by wind power installations at the suitable locations of Besarabeasca, Zarnesti, Leovo, Ciadyr
and Cimislia.
Assuming a possible good wind resource with a capability factor of 0,3 wind power installations of
355 MW would reduce the electrical energy imports by 25 % according to the model created for the
project. The model has not been verified with other models, which is of priority for future work.
For a total installation of 355 MW the installed power needs to be allocated as shown below:
Besarabasca 56 MW
Zarnesti 68 MW
Leovo 68 MW
Ciadyr 91 MW
Cimislia 72 MW
The strongest site for wind power production, one site at a time, is Cimislia with a total installed
power of 102 MW possible. With all sites together the maximum installed power is 260 MW without
reactive power compensation and 355 MW with reactive power compensation.
Economic calculations include a sensitivity analysis with different the electricity price and discount
rates. The economic analyses shows that the payback time vary from 3 years to never being paid
back and conclusions are drawn that further investigations needs to be made.
vi
V List of Acronyms and Abbreviations
ANRE National Agency for Energy Regulation
AVR Automatic Voltage Regulation
CDM Clean Development Mechanism
CER Certified Emission Reduction credits
CHP Combined Heat and Power
DSA Dynamic Security Assessment
EBRD European Banc of Reconstruction and Development
ENTSO-E European Network of Transmission System Operators for Electricity
FACTS Flexible Alternating Current Transmission Systems
HAWT Horizontal Axis Wind Turbine
HPP Hydro Power Plant
IPS Integrated Power System
MAWS Mean Annual Wind Speed
MSSR Moldovan Soviet Socialist Republic
PSS/E Power System Simulator for Engineering
p.u Per Unit
SNC Second National Communication
SSA Static Security Assessment
TUM Technical University of Moldova
UNFCCC United Nations Framework Commission of Climate Change
VAWT Vertical Axis Wind Turbine
WAsP Wind Atlas Analysis and Application Program
Table of Contents
I Förord (in Swedish) ______________________________________________________ i
II Acknowledgments _______________________________________________________ ii
III Populärvetenskaplig beskrivning (in Swedish)________________________________ iii
IV Executive summary ______________________________________________________ v
V List of Acronyms and Abbreviations ________________________________________ vi
Chapter 1 Introduction ____________________________________________________ 1
1.2 Borlänge Energi ___________________________________________________________ 1
1.3 Moldova – Background _____________________________________________________ 1
1.3.1 Grid History _____________________________________________________________________ 2
1.3.2 Energy _________________________________________________________________________ 2
1.3.3 Bio Energy Potential ______________________________________________________________ 3
1.3.4 Solar Energy Potential _____________________________________________________________ 3
1.3.5 Wind Energy Potential ____________________________________________________________ 4
1.1.1 Environmental Goals ______________________________________________________________ 4
1.4 Aim and Goals ____________________________________________________________ 5
Chapter 2 Background _____________________________________________________ 6
2.1 Grid – Theory ____________________________________________________________ 6
2.1.1 Active and Reactive Power _________________________________________________________ 6
2.1.2 Introduction to the Electrical Power System ___________________________________________ 8
2.1.3 Components in the Electrical Power System __________________________________________ 11
2.1.4 Per-Unit System _________________________________________________________________ 15
2.1.5 Equivalents in Electrical Power Systems ______________________________________________ 15
2.1.6 Static Modelling _________________________________________________________________ 16
2.2 Wind Power ____________________________________________________________ 19
2.2.1 Moldova´s Wind Resource ________________________________________________________ 22
2.2.2 Economy ______________________________________________________________________ 23
2.3 Method ________________________________________________________________ 24
2.3.1 PSS/E _________________________________________________________________________ 24
2.3.2 Building the Model ______________________________________________________________ 24
2.3.3 Scenarios ______________________________________________________________________ 29
2.3.4 Economy ______________________________________________________________________ 30
Chapter 3 Results ________________________________________________________ 32
3.1 Base Case_______________________________________________________________ 32
3.2 Scenario I _______________________________________________________________ 33
3.2.1 Scenario I, With Reactive Power Compensation _______________________________________ 33
3.3 Scenario II ______________________________________________________________ 34
3.3.1 Scenario II, With Reactive Power Compensation _______________________________________ 35
1.1 Reduction of Imported Electric Energy _______________________________________ 36
3.3.2 Scenario I ______________________________________________________________________ 36
3.3.3 Scenario II _____________________________________________________________________ 37
3.4 Economy _______________________________________________________________ 37
Chapter 4 Discussion _____________________________________________________ 40
4.1 Scenarios _______________________________________________________________ 40
4.1.1 Scenario I ______________________________________________________________________ 40
4.1.2 Scenario II _____________________________________________________________________ 41
4.1.3 Economy ______________________________________________________________________ 42
Chapter 5 Conclusion _____________________________________________________ 43
Chapter 6 Future Work ___________________________________________________ 44
Appendix A Map of the Moldovan electrical system ___________________________ A-1
Appendix B Map over the wind potential in Moldova _________________________ B-1
Appendix C Description of WAsP __________________________________________ C-1
Appendix D Line diagram and data over the equivalent 330 kV circuit ____________ D-1
Appendix E Transmission Line Data ________________________________________ E-1
Appendix F Line diagram and data over the complete model ___________________ F-1
Appendix G General Python Script – executing the contingency analysis __________ G-1
Appendix H Python Script – Scenario I ______________________________________ H-1
Appendix I Python Script – Scenario II, Monte Carlo Simulation____________________ I-1
Appendix J Base Case - Contingency Loading Report _____________________________ J-1
Appendix K Base Case – Line Diagram with Line Capacities _____________________ K-1
Appendix L Scenario I – Overload Report _____________________________________ L-1
Appendix M Scenario I Reactive Power Compensation – Overload Report_________ M-1
Appendix N Scenario II - Overload Report ___________________________________ N-2
Appendix O Scenario II Reactive Power Compensation – Overload Report _________ O-2
Appendix P Scenario II – Contingency Loading Report _________________________ P-1
Appendix Q Scenario II – Line Diagram for Line Capacities ______________________ Q-1
Appendix R Scenario II All Generators – Results ______________________________ R-1
Appendix S The Contingency and Automation Process in PSS/E _________________ S-1
Appendix T Sub, Mon and Con files for the contingency analysis ________________ T-1
Appendix U Division of the Work Between the Authors ________________________ U-1
Table of Figures and Tables
Figure 1.1 Regional gropes of ENTSO-E and the IPS electrical systems [8] 2
Figure 2.1 The total power aka. the apparent power, active power and reactive power [18] 7
Figure 2.2 Real power and reactive power plotted against the load angle and voltage [20] 8
Figure 2.3 Structure of an electrical power system [20] 9
Figure 2.4 Showing the basic schematics of an on-load tap changer [20] 12
Figure 2.5 Transmission line equivalent 13
Figure 2.6 The magnetic field H between two conductors 14
Figure 2.7 Electric field E between two conductors 14
Figure 2.8 Busses connected in star and delta with line impedance Z [20] 16
Figure 2.9 An equivalent circuit of a short transmission line 17
Figure 2.10 An equivalent circuit of a medium transmission line 18
Figure 2.11 Schematic scheme over a contingency plan [23] 19
Figure 2.12 A typical arrangement for a HAWT [20] 20
Figure 2.13 A typical Cp/λ curve for a wind turbine [20] 20
Figure 2.14 Turbine power as a function of the wind speed [20] 21
Figure 2.15 An investment and payback curve for a nonspecific project [25] 23
Figure 2.16 One line diagram over the PSS/E model 25
Figure 2.17 Load and generation in Moldova, rectangles represent generation and circles loads 28
Figure 2.18 The algorithm for the contingency analysis where generator G is increased 30
Figure 3.1 The dispersion of voltage levels for the base case contingency analysis 32
Figure 3.2 A histogram of the dispersion of voltage levels with a contingency analysis 34
Figure 3.3 A histogram of the dispersion of voltages levels with a contingency analysis 35
Figure 3.4 Payback time with a capability factor of 0,3 37
Figure 3.5 Payback time with a capability factor of 0,1 38
Figure 3.6 Payback time including CER:s with a capability factor of 0,3 38
Figure 3.7 Payback time including CER:s with a capability factor of 0,1 39
Figure A-1 Map over the Moldovan electrical system [31] A-1
Figure B-1 Wind Potential in Moldova at the height of 70 meters [14] B-1
Figure D-1 Line diagram from PSS/E for the equivalent circuit over the Moldovan electrical system D-1
Figure F-1 Line diagram for the equivalent circuit over the Moldovan electrical system F-1
Figure K-1 One line diagram with line capacities K-1
Figure Q-1 One line diagram with line capacities Q-1
Figure R-1 Shows the iterations with all generators in scenario I. R-1
Figure R-2 Histogram over the maximum generation without reactive power compensation R-2
Figure R-3 Results from the second iteration with a narrow interval for each generator R-2
Figure R-4 F Histogram over the maximum generation with reactive power compensation R-2
Figure S-1 Shows the recorder function within PSS/E S-2
Figure T-1 Contingency file created for the contingency analysis T-1
Figure T-2 Monitor file created for the contingency analysis T-1
Figure T-3 Subsystem file created for the contingency analysis T-1
Table 1.1 Existing transmission lines in Moldova 3
Table 2.1 Load values for the active generation and consumption 28
Table 2.2 Model load values for the active generation and consumption 28
Table 3.1 Maximum generation before violation in the contingency report 33
Table 3.2 Maximum values regarding only line capacities 33
Table 3.3 Extended generation potential until line capacity is reached 33
Table 3.4 Possible generation capacity with reactive power compensation 33
Table 3.5 Maximum generation for each location giving maximum total generation for the region 34
Table 3.6 Maximum generation for each location giving maximum total generation for the region 35
Table 3.7 Imported electrical energy reduction due to wind power installations 36
Table 3.8 Imported electrical energy reduction with reactive power compensation 36
Table 3.9 Imported electrical energy reduction due to wind power installations 37
Table D-1 Bus data for equivalent circuit over the Moldovan electrical system D-2
Table D-2 Plant data for equivalent circuit over the Moldovan electrical system D-2
Table D-3 Machine data for equivalent circuit over the Moldovan electrical system D-2
Table D-4 Load data for equivalent circuit over the Moldovan electrical system D-2
Table D-5 Branch data for equivalent circuit over the Moldovan electrical system D-2
Table E-1 Data over transmission line types E-1
Table E-2 Impedance values for the lines in the 110 kV system E-1
Table E-3 Base impedance values E-1
Table E-4 Per Unit values for the lines in the 110 kV system E-1
Table F-1 Bus Data F-2
Table F-2 Branch Data F-2
Table F-3 Machine Data F-3
Table F-4 Plant Data F-3
Table F-5 Load Data F-3
Table F-6 Switched Shunt Data F-3
Table F-7 Three Winding Data F-3
Table F-8 Winding Data, MGRAS F-4
Table F-9 Winding Data, Vulcanesti F-4
Table F-10 Winding Data, Hancesti-Straseni F-4
Table F-11 Winding Data, Chisinau F-4
Table J-1 The busses with maximum and minimum voltage levels from the loading report J-8
1
Chapter 1 Introduction The introduction starts by giving a description of the company that the project has been executed in
cooperation with. Thereafter follows a short background of Moldova with its electrical system,
energy and renewable energy potential. The introduction ends with the aim and the goals of the
project.
1.2 Borlänge Energi AB Borlänge Energi is owned by the municipality of Borlänge. Borlänge Energi provides a wide range
of services such as electricity, electricity grid, district heating, water, sewage, storm water and waste
handling. In addition to these commitments Borlänge Energi also handles the municipality’s streets
and parks [1].
Borlänge Energi has had international collaborations since the 1990th, with a primary focus on the
environment. In 1998 the local authorities in Borlänge and the Swedish embassy in Bucharest
initiated a project to establish links between the Swedish and the Romanian municipalities. This led
to collaboration between Borlänge and the Romanian city of Pietsi. In Pietsi Ronny Arnberg from
Borlänge Energi and the mayor of Borlänge Nils Persson met with representatives from Chisinau city
hall and from APA Canal, the water and wastewater company in Chisinau. This was the start for the
cooperation between Borlänge Energi and Moldova with focus on the capital, Chisinau. [2].
The municipality of Chisinau has an interest in understanding “the Swedish way” of thinking. From
the cooperation with the municipality of Borlänge they will try to study different ways of spreading
information to the society, working with youth and sustainable development. From the start of the
cooperation in the year 2009 several projects regarding the environment have been conducted [3].
With the cooperation as a base many master thesis projects have been written together with
Borlänge Energi in Chisinau.
1.3 Moldova – Background The Republic of Moldova is a small country situated in the south-eastern part of Europe with a total
area of 33 800 m2 and 3,6 million inhabitants. Bordering countries to the north, south and east is
Ukraine and to the west Romania. The capital is Chisinau with a population of around 600 000
inhabitants, other important cities are Tiraspol (located in Transnistria, see below) and Baltsi. Around
41 % of the inhabitants live in cities. Moldova became an independent state 1991 with the
dissolution of the Soviet Union [4]. With a GDP of 1500 US dollars per capita Moldova is the poorest
country of Europe [5].
The population consists of different ethnical groups with the biggest being the Moldavians but there
are also large groups of Ukrainians and Russians. The different ethnic groups have contributed to the
violent history of the country. In connection with the dissolution of the Soviet Union an armed
conflict broke out in the eastern part of Moldova called Transnistria. The majority of the population
in Transnistria consists of Russians and Ukrainians who wanted to establish a breakaway republic of
Transnistria. The breakaway republic never gained international recognition and the armed conflict
ended in 1992. Negotiations between Moldova and Transnistria with help from Russia have ended in
a greater sense of autonomy for Transnistria, to this date the conflict is not yet solved. [6]
2
1.3.1 Grid History Before the dissolution of the Soviet Union the electrical grid and power plants were laid out to jointly
optimize the market in the south-western Soviet Union and the other countries in the region e.g.
Romania. With the fall of the Soviet Union these countries had to redesign their electrical systems.
Moldova and Ukraine stayed with the Eastern European system IPS (Interconnected Power Systems)
together with Russia while Romania chose to connect with the Western European system ENTSO-E
(European Network of Transmission System Operators for Electricity). ENTSO-E operates at the same
frequency as IPS but the two systems do not operate synchronized with each other. [7]
Figure 1.1 Regional gropes of ENTSO-E and the IPS electrical systems [8]
The ENTSO-E is the joint European transmission system operator, in Figure 1.1; all marked zones
except IPS are part of the ENTSO-E network and thus operate synchronously.
1.3.2 Energy Moldova imports 94 % to 98 % [9] of its consumed energy from Russia, Ukraine and Transnistria. The
country thus is very dependent on the eastern countries for energy supply. Striving to align itself with
the western part of Europe the energy security is an important issue. The main possibility for
improving the energy security is with new power supply within the country.
Today the electric power generation in Moldova and Transnistria consists of three CHP (Combined
Heat and Power) plants, two HPP (Hydropower Plants); MGRAS, the biggest power plant in the
region, fired with gas, and situated in Transnistria; and other minor power plants. The total capacity
in Moldova, incl. Transnistria, is 3008 MW but around 2570 MW is generated by MGRAS and is thus
not controlled by the Moldovan government. This means that Moldova only has around 438 MW of
generation capacity. This is not enough to supply the demand of baseload in Moldova [10]. The total
consumed electric energy in Moldova year 2010 was 4102 GWh out of which 1064 GWh was
produced domestically and 3038 GWh was imported i.e. Moldova imported 74 % of all electrical
energy consumed within the country. Due to the complex situation with Transnistria electrical energy
imports have mainly come from Ukraine, but recently imports from Transnistria have increased and
are now dominating. [11]
Moldova
3
The transmission grid in Moldova is interconnected with the neighbouring countries; six 330 kV
overhead power lines to the Ukrainian power system, the connections to Romania consists of four
110 kV lines and one 400 kV line with which Moldova also gets connection with the Bulgarian power
system see Appendix A. Because of the connections to the ENTSO-E system i.e. with a different
synchronization than Moldova in Romania and Bulgaria, the transmission lines can only operate in
island mode on the Moldavian side, or by using back to back frequency converters. [12]
The backbone in the Moldovan electrical system is the 330 kV line going from north to south, it is the
main connection to both Transnistria and Ukraine. Well integrated together with the 330 kV system
is the mesh of the 110 kV system which is spread out throughout Moldova. Table 1.1 shows the
existing overhead line voltages and the total length of these. [13]
Table 1.1 Existing transmission lines in Moldova
Voltage level [kV] Length of the overhead transmission lines [km]
400 214
330 532,4
110 5231,1
Total: 5977,5
1.3.3 Bio Energy Potential Moldova has no experience of large scale applications of bio energy even though it’s an agricultural
country. It has some experience in small scale applications in the rural area. Moldova’s biomass
suitable for energy use comes from forestry, agriculture, food industry and waste from households,
where agricultural waste has the biggest potential as an energy source. At present Moldova biomass
is inefficiently used as many outdated and simple technologies are used to convert the biomass into
energy e.g. domestic fires and stoves efficiency rating rarely exceeds 50 %. There is also a lot of
biomass that today cannot be used because the lack of new, today already existing, technologies
needed for the conversion of biomass into energy. [14]
The technical potential of biomass in Moldova is 5,4TWh, where 2,1TWh comes from agricultural
waste, 1,2TWh comes from fuel wood, 1,3TWh comes from wood processing waste and 0,8TWh
comes from biogas. The potential for bio fuels is another 0,6TWh, meaning that the total potential of
bio energy in Moldova is 6TWh. [15]
Bio energy has the biggest energy potential in Moldova; both in theoretical values and in the
potential to include it in today’s already existing social infrastructure and energy system
development programs. [14]
1.3.4 Solar Energy Potential There has been research about solar energy utilization in Moldova. The research where performed by
the institute of Energy of the academy of Sciences of RSSM (Moldovan Soviet Socialist Republic) in
the late 1950s. The research resulted in a greenhouse with solar installations and heat storage in the
ground. Because of the low prices for fossil fuel and lack of politic incitements for renewable energy
the project was terminated. In the 1980s the work for implementing solar installations where
restarted. [14]
4
Solar energy is received on the earth’s surface all the time, though the amount of energy received on
the earth’s surface depends on several different factors. The most important factors are the suns
brightness, duration and height above the horizon. In Moldova the theoretical duration of the sun,
when it’s shining unimpeded, is 4445-4452 hours per year [14] but the real duration is 2100-2300
hours per year because of clouds concealing the sun. The amount of solar energy received on the
surface of Moldova differs from 2300 kWh/ m2 year in south to 2100 kWh/m2 year in the north [14].
Other sources estimate the solar radiation in Chisinau to be 1300 kWh/m2 year. [15]
The solar energy in Moldova is primarily used for heating water using solar panels, secondarily used
to dry fruit, vegetables and medicinal plants and tertiary for converting solar energy into electricity
via photovoltaic conversion.
1.3.5 Wind Energy Potential Historically, the area that today is called the Republic of Moldova has been appreciated as favourable
wind zone for wind energy development. Statistical data from 1901, before the development of
steam engines and internal combustion engines, shows that a total of 6208 windmills were
registered in the Moldova area and its surroundings. Some of these windmills were even used during
the interwar period. During the 1950s even 350 windmills where built, exclusively to pump water for
agricultural purposes. These where later replaced by cheaper and more easy to handle electrical
systems. The electrification that occurred in Moldova during the 1950s as well as the low prices for
electrical energy where factors that wind power could not compete with at the time. Today Moldova
doesn’t have any wind power.
At present day Moldova has no wind power installed; however there are plans to install wind power
plants in a near future. The south of Moldova is often mentioned as a preferable area to build wind
power. The opinions of Moldova’s wind potential differ e.g. the organisation 3tier concluded MAWS
(Mean Annual Wind Speed) of 4-6 m/s at the height of 80 m [15] while a feasibility study written by
the UNDP Moldova concluded MAWS of 4,5-8,5 m/s at a height of 70 m [14]. Moldova’s technical
potential for wind power is up to 1 GW installed power providing approximately 1,1TWh of electrical
energy [15]. This correlates to a capability factor of 13 %, which is very low.
1.1.1 Environmental Goals Renewable energy in Moldova would go in accordance with the goals set up in their SNC (Second
National Communication) directed to the UNFCCC (United Nations Framework Commission of
Climate Change). The national priorities to reach the goals of greenhouse gas reductions include
wider use of CDM (Clean Development Mechanism) projects, implementing a more aggressive policy
on transfer of the green technologies, intensifying the process of international cooperation. An
analysis on the possibilities to construct a wind power plant in Moldova in regards of the wind
potential and the stability of the electrical grid would facilitate and work for the Moldavian national
goals. The SNC also identifies relevant policies for the energy sector where two out of five directly
would be coherence with the intended study, “…assuring energy security of the country by improving
the interconnection capacity with the neighbouring countries and construction of new local sources
of power generation based of the most recent and advanced environment friendly technologies.”
and “…increasing the share of renewable sources of energy in the energy balance of the country”.
[16]
5
1.4 Aim and Goals Moldova has a high dependency of imported electrical energy from Ukraine and Transnistria. To rid
this huge dependency Moldova could look to its national resources for domestic production. The
national goals in Moldova are angled towards sustainable development with more renewable energy.
This project will investigate how much the dependency of electrical imports could be reduced by
wind power installations in the Moldovan electrical system as it looks today.
The goals of the project:
The project will conclude in how much wind power installations would be possible in
Moldova considering limiting factors of the electrical system.
The project will show how much the electrical imports can be reduced by wind power
installations in Moldova.
The project will also conclude in potential sites for wind power installation
An economic analysis will show whether it would be profitable to construct wind power in
Moldova
6
Chapter 2 Background The background describes the grid theory important for the project, a section with wind power
potential and finally the method with the creation of the model. This is followed with the scenarios
used to examine the model.
2.1 Grid – Theory To understand transmission networks active and reactive power are important concepts described
below, also described are definitions of terms and components in the electrical system. The section
ends with a description of approximations needed for computerize model calculations.
2.1.1 Active and Reactive Power Power is the rate of change of energy with respect to time [17]. It is the amount of energy being
absorbed by a load during a time interval. Reactive power cannot be expressed in the same way, it
cannot be seen as a constant flow of energy from one point to another, the reactive power is flowing
back and forth in the system and when completing a cycle just as much energy that was flowing away
has flowed back. The average reactive power in any system is always equal to zero. The reactive
power is thus not measured by its average value, being zero, but by its amplitude, its maximum
value. This gives a measurement of how much reactive power that is actually flowing through the
system. [17]
In an RLC circuit, with inductance L and capacitance C, the voltage before and after the load will have
a small angular difference described by the load angle , the current will be shifted from the voltage
with the current angle . The difference between and is the power factor angle .
With a purely inductive load the current lags the voltage by and in a purely capacitive load the
current leads the voltage with . In the following equations the load angle is equal to zero.
Equation 1
Equation 2
With these expressions for voltage and current the instantaneous power can be expressed by:
Equation 3
This expression combined with trigonometric identities gives Equation 2.4.
Equation 2.4
Equation 2.4 consists of one real and one imaginary part; the real power is defined as the average
value of the real part.
Equation 2.5
The average value of reactive part, as can be seen below in the Figure 2.1, is always zero; this is the
definition of reactive power. Instead the reactive power is measured by its amplitude value, this
gives us: [18]
Equation 2.6
7
Figure 2.1 The total power aka. the apparent power, active power and reactive power [18]
P is expressed in Watts and Q in VAr (Volt Ampere reactive) both describing the same quantity but
with different units to distinguish them. The power factor angle in the cosine term in Equation 2.5
and Equation 2.6 called the power factor. For inductive loads where the current lags the voltage the
load consumes reactive power. With capacitive loads the current leads the voltage and the load
creates reactive power. [17]
According to [19] the active and reactive power in a RLC four terminal electric circuit can be
described by Equation 2.7 and Equation 2.8 if the resistance R is neglected and assuming that the
load angle is small.
| || |
Equation 2.7
and
| |
| | | | Equation 2.8
Equation 2.7 describes the dependence the active power has on the differences between the phase
voltages and the angle between these. The phase voltages in the power system may not differ much
between busses and thus the active power is highly dependent on the load angle which
is the angular difference between and . This gives us the characteristics that the active power is
strongly dependent on the load. [20]
According to Equation 2.8 even a small change in voltage causes a large change in reactive power. If
the reactive power is plotted against the voltage it corresponds to an inverted parabola, the
dependency on the reactance gives us that the smaller the reactance the steeper will the parabola
be, this means that with a low reactance small changes in voltages causes very large changes to the
reactive power. The relationship can be seen in Figure 2.2 together with the sinusoidal characteristics
of . [20]
Po
wer
Time
8
Figure 2.2 Real power and reactive power plotted against the load angle and voltage [20]
In the three phase system the power is increased by a factor of √ as seen in the equations below.
[17]
Equation 2.9
Equation 2.10
2.1.2 Introduction to the Electrical Power System The modern society requires energy for use in the industry, agriculture, commerce, transportation,
communications, domestic households etc. The total energy required during one year is called total
annual energy demand. About 85 % [21] of the total energy demand in the world is today supplied by
fossil fuels like coal, oil, and natural gas. A large part of these fuels contribute to the electric energy
production. Today the world is switching from these fossil fuels and more electrical energy is
produced by renewable sources like wind power, solar power, hydro power, biogas, bio energy and
geothermal energy. One of the major reasons for the increase in renewable energy is the global
warming. In the future it’s likely that the share of the energy market taken by renewables will
increase to high levels and play a more dominant role on the design of electrical power systems. [20]
2.1.2.1 Structure of the Electrical Power System The electrical power system can be divided into three different parts; generation, transmission and
distribution.
The transmission network is normally the network with the highest voltage, from 300 kV and above.
Transmission networks have the highest transferring capacities and are mostly built as meshed
networks to increase the security of the system. To the transmission network only very large
electrical energy consumers and producers are connected. The transmission network can also be
used as connecting lines to other systems for example tying different countries together. [20]
The sub transmission network is a part of the transmission network. It consists of a high or medium
voltage network, with the voltage levels ranging between 100 kV to 300 kV. Unlike the transmission
network the sub transmission network is built as a radial network or a weakly coupled network. To
the sub transmission network medium producers and consumers can be connected. [20]
9
Figure 2.3 Structure of an electrical power system [20]
Distribution networks are networks with medium voltages, in the range of 1 kV to 100 kV. The
distribution network is often radial built networks. To the distribution network small generation and
medium sized customers are connected. Wind power plants are often connected to the distribution
network. The classification of the different parts of the system is not a strict classification and can
vary depending on who is classifying it. [20]
2.1.2.2 Reliability of Supply One of the most important features of the electrical power system is that electrical energy cannot
easily be stored in large quantities. At any instant in time the energy demand has to be met by the
corresponding electricity generation. Fortunately the combined load pattern is pretty predictable
whilst individual loads may vary quite much. This predictable system demand can thus quite easily be
planned allowing scheduling the daily generation to be controlled in a predetermined manor. [17]
The electrical system is designed to operate within certain operational limits governed by grid codes.
These operational limits ensure that you avoid major interruption of supply that can lead to life-
threatening situations for the normal consumer, and for the industrial consumer may pose severe
technical and production problems and thus loss of income. This is why high reliability of supply is of
fundamental importance for the electrical system. High reliability can be ensured by: [17]
High quality of installed elements
The provision of reserve generation
Employing large interconnected power systems capable of supplying each consumer via
Alternative routes
A high level of system security [17]
10
2.1.2.3 Stability and Security of the Power System The stability of the power system is defined as the ability of the power system to regain equilibrium
after being subjected to a change. The most common changes that affect the stability of the system
are the variables described in the chapter on Active and Reactive Power i.e. the nodal voltage
magnitudes, which affect the reactive power, and the nodal load angles, connected with the active
power. This gives us the new terms of power angle stability, and voltage stability. [17]
The security of the power system refers to the ability of the power system to survive certain
contingencies without affecting the quality of electrical supply to the customers. The stability of the
power grid is part of the security but the concept of security is wider and also deals with other issues.
The assessment of the power system can be divided into the SSA (Static Security Assessment) and the
DSA (Dynamic Security Assessment). The DSA deals with the stability and quality of electrical supply
during a change in the system where as the SSA only considers before and after scenario and
assumes that there was no breach in stability along the way. [17]
It is in the interest of the TSO to perform the SSA in order to first evaluate the pre contingency state
i.e. determine available transfer capability of transmission links and identify network congestions.
Secondly to evaluate the post contingency states i.e. verify the bus voltages and power flow limits.
Being responsible for the grid security the TSO needs to find ways of controlling the system so that it
does not break down. Having no direct control over the generating units the only way to affect
power outputs or control settings of the power plants are the grid codes or commercial agreements.
[17]
As stated above the DSA deals with problems regarding the system stability and quality of electrical
supply, the analysis in this report strictly deals with SSA and will thus not describe the problems
regarding the dynamic simulations. A short description of some of the problems that occur follows in
the next chapter. [17]
2.1.2.4 Quality of the Electrical Supply It is not just important that there is a high reliability to the system, there also has to be a high quality
of the electrical supply. Electrical energy of high quality is provided by:
Regulated and defined voltage levels with low fluctuations
A regulated and defined value of the frequency with low fluctuations
Low harmonic content
Low content of transients and flicker
To ensure the quality of the electrical supply two basic methods can be used. Firstly the proper uses
of automatic voltage control i.e. shunt elements, tap transformers, frequency control methods and
AVR (Automatic Voltage Regulation) within the generating units. Secondly by employing large
interconnected systems because larger systems are naturally affected by load variations as well as
other disturbances. To ensure the quality of electrical supply the TSO set codes that the grid should
operate within. A common standard is that the frequency should not deviate from the base value
with more than ± 0,1 Hz and the nodal voltages should stay within ± 10 % of its normal value. These
regulations vary depending on voltage level but also depending of fault scenario. [17]
11
2.1.3 Components in the Electrical Power System The most important components of the electrical power system are generating units, transformers,
shunt elements and transmission lines. These are described below.
2.1.3.1 Generating Units Generating units are the elements in the electrical power system that produces electrical energy.
There are several different types of generators with different properties. Examples of different
generators are the synchronous generator and induction generator. The generators are converting
kinetic energy into electrical energy. Electrical energy is produced by a generator driven by a kinetic
energy source, often a turbine or diesel engine. The turbine is equipped with a turbine governor
which controls either the speed or the power output according to a pre-set power-frequency
characteristic. The generated power is then fed to the electrical power system. [17]
Traditionally the electrical power system has been operated with relatively few large power plants
connected to the transmission network. These large plants are usually either thermal or hydro based.
Concerns about global warming and sustainability have increased the interest for renewable
generation like thermal power plants which uses bio fuels, wind power and solar. This requires major
changes in the electrical power system as the generation will increasingly be based on large amount
of small producers often with the generation situated close to the energy source. Renewable energy
has lower energy density than non-renewable energy sources and therefore the renewable power
plants tend to be smaller, around hundreds of kilowatts to a few megawatts. Plants of this small size
are often connected to the distribution level of the power system, rather than the transmission level
because of the lower costs for the connection. These plants are called distributed generation. [17]
Wind turbines are a typical example of distributed generation power source. Wind turbines often use
induction generators with either fixed speed or doubly fed generators to convert the power in wind
into electrical energy. It is important to know that the rotating magnetic field in the induction
machine is produced by a magnetizing current, whether it is operating as a generator or a motor. The
magnetizing current is always supplied from an outside power source, often from the electrical
power system. This means that the induction machine always consumes reactive power and
therefore always must be connected to a power system that can provide the induction machine with
reactive power for it to function properly. The reactive power can either be provided directly from
the electrical power system or via reactive power compensation units installed together with the
wind turbine. [17]
2.1.3.2 Transformers Transformers are needed to connect parts of the power system with different voltage levels.
Generator step-up transformers are used when connecting generators to the grid. Tap transformers
are used when there is a need for voltage regulation. Transformers can also be used for reduction of
voltage to suit the low voltages needed by the consumers. This is done with distribution
transformers. Connection of different parts of the electrical network with different voltage levels is
done with transmission transformers. [20]
12
Transformers are built up by a magnetic core with windings wrapped around the core. For two
winding transformer there are two sets of windings and with the three winding transformer there are
three sets of windings. The three winding transformer can thus transform one voltage level into two
different to suit several needs at once. The relation between the phasor voltage and the number of
turns at each winding is shown in Equation 2.11. [17]
Equation 2.11
Thus the change in number of turns for the windings will affect the voltage levels proportionally.
Transformers that can control voltage levels by changing the number of turns of the windings are
known as tap changing transformers. The tap changers can operate ether as off load or on load. The
off-load tap changers have a regulation rate of generally ± 5 % of voltage levels. The off load tap
changers are operated manually and change is normally made to accommodate the seasons. The on-
load tap changers have a general operational range of maximum ± 20 % of voltage levels and change
is controlled by a regulator and can thus respond directly to disturbances such as a load change. A
basic principle of a tap changer is shown in Figure 2.4 where the selectors S1 and S2 can move
between the windings to cause small changes to the voltage. [20]
Figure 2.4 Showing the basic schematics of an on-load tap changer [20]
2.1.3.3 Shunt Elements Due to the fact that reactive power causes losses and uses the capacity in electrical lines the optimal
operation is reached if reactive power is compensated for close to the point of consumption and not
produced at the generation sources far from the consumption. One way to compensate for the
reactive power is with shunt compensation i.e. by installation of capacitors or inductors close to the
point of interest. Shunt compensation can also be used to stabilize voltage levels and thus
strengthening the stability of the electrical power system. [20]
Transmission lines are generally consuming reactive power but if the load is very low the production
of reactive power can exceed the consumption. This may lead to very high reactive power levels
which in turn may lead to very high voltage levels due to the strong correlation between reactive
power and voltages seen in Equation 2.8. Compensation for this effect is generally done for lines
longer than 200 km by installation of shunt reactors. In a loaded line, shunt capacitors may be used
to produce reactive power and compensate for voltage drops, more commonly series capacitors are
connected in series with the conductors to compensate for the reactive power consumed by the line.
[20]
13
Shunt compensation can also be supplied by a synchronous motor or generator running at no load
called synchronous compensation. Being rather expensive switched shunt capacitor banks and
reactors are often used in addition to the synchronous compensation at substations. Small such
compensators, of several MVA, are often used on the tertiary winding of transmission transformers
while larger compensation, of up to hundreds MVA, are connected to by individual step-up
transformers to high-voltage substations. [20]
2.1.3.4 Transmission Lines There are both overhead and underground transmission lines though the overhead transmission
lines are the most common. An overhead transmission line consists of three main components,
conductors, insulators and support structures. Transmission lines often also have shield wires placed
above the conductor to protect it from lightning.
2.1.3.4.1 Important Parameters The design of the transmission line determines these parameters e.g. conductor type, the space
between conductors and the size determines the series impedance and shunt admittance where the
series impedance affects the ohmic losses, line-voltage drops and the stability limits. The shunt
admittance, which is primarily capacitive, affects the line charging currents. The line charging
currents are the currents which increases reactive power in the power system. In light loaded power
systems shunt reactors often are installed to absorb this reactive power and thus reducing over
voltages. [17]
A transmission line can be described with the equivalent seen in Figure 2.5 where R is the resistance,
L is the inductance, G is the conductance and C is the capacitance.
Figure 2.5 Transmission line equivalent
2.1.3.4.2 Resistance in Transmission Lines The DC resistance in the conductors depends on the length, cross sectional area and the conductivity
of the conductor. The conductivity also depends on the temperature. The DC resistance is described
below:
Equation 2.12
where is the conductivity at temperature T, is the length of the conductor and A is the cross
sectional area. The conductivity depends on the material and common materials for conductors are
copper and aluminium. Temperature and current magnitude also affect the resistance in conductors
with AC current. The resistance is frequency dependent due to the “skin effect” which is the
phenomenon that the current distribution tends to be denser at the surface of the conductor. This
14
causes a conductor loss, the effect only occurs with AC currents. The higher the frequency the higher
is the real power losses due to the “skin effect”. losses is always bigger than losses
[17].
| |
Equation 2.13
2.1.3.4.3 Conductance in Transmission Lines The conductance can be modelled as the shunt admittance in overhead lines. The conductance
occurs because of the leaking currents due to the corona effect, damaged insulators and dirt, salt and
other contaminants. The corona effect occurs when the electrical field strength at the conductor
surface causes the surrounding air to ionize and thereby conduct. The losses from the conductance
are much lower than the ohmic losses in the conductor, and are thus normally
neglected. [17]
2.1.3.4.4 Inductance in Transmission Lines The inductance in conductors comes from the current flowing in the transmission line.
Figure 2.6 The magnetic field H between two conductors
The inductance depends on the magnetic field intensity H, the magnetic flux density B, the flux
linkages , and inductance from flux linkages per ampere
as can be seen in Figure 2.6. [17]
2.1.3.4.5 Capacitance in Transmission Lines An electric field is created between two conductors because of the difference in potential between
the conductors, represented by ΔV in Figure 2.7.
Figure 2.7 Electric field E between two conductors
The capacitance is defined by the charge divided by the voltage
. The charge is dependent on
the electrical field and the flux. In an ideal solid cylindrical conductor the flux and electrical field is
equal to the area integral of the electric field strength and the electric flux density over the surface
area of the conductor. [17]
15
2.1.4 Per-Unit System Working with electrical systems with different voltages the per-unit system is often introduced.
Basically it reduces the risk of making calculation error when going from one voltage level to another.
If values are expressed in per-unit there can be a direct comparison from one side of a transformer to
another. The expression for calculating the per-unit value is shown in Equation 2.14.
Equation 2.14
The resistance and reactance base values are calculated using the base value of the impedance
and the base values for the conductance and susceptance is calculated with the base value for the
admittance . The connection between the two base values can be seen in Equation 2.15. [17]
Equation 2.15
2.1.5 Equivalents in Electrical Power Systems Electrical systems are generally very large with a lot of components, modelling this as a complete
system including all components is often an impossible task if even a desired one. One method of
creating an equivalent of parts in an electrical system is called model reduction methods. This
method consists first of physical reductions, where suitable models for the system are chosen
depending on how influential the system elements are to a disturbance. A component far from a
disturbance is not as affected by a disturbance and can thus be modelled more simply. Secondly
there is topological reduction where busses can be reduced to limit the size of the equivalent
network and number of components in it.
The topological reduction can be achieved by many techniques using matrix operation. The reduction
can be done with Gauss-Rutishauser elimination, also called Ward equivalent, which use the
admittance matrix as a starting point, se 2.1.6.1 for how to create the bus admittance matrix.
Reduction can also be done looking at one specific bus, a typical such reduction is reduction of a
centre bus in a star bus system creating a delta connected bus system. Equation 2.16 is describes the
new admittance derived from old admittances in the system, k here describing the centre bus in the
star system. [20]
Equation 2.16
The directly connected busses i.e. its neighbours will be affected in such a way that the admittance
needs to be changed between these busses. Busses in the system not directly connected to the bus
being removed will not be affected by the removal. With the star – delta equivalent, a change of
impedance needs to be regarded in lines AB, AC and BC. [20]
16
Figure 2.8 Busses connected in star and delta with line impedance Z [20]
In the case with the star connected bus Equation 2.16 can be written as seen in Equation 2.17. When
taking into consideration that the admittance is the inverse of the impedance the equation can be
rewritten as seen in Equation 2.18. [20]
Equation 2.17
Equation 2.18
Considering a circuit which consists of only three busses connected in serial Equation 2.18 is
simplified and is expressed by Equation 2.19.
Equation 2.19
2.1.6 Static Modelling
2.1.6.1 Bus Based Equations For computing the power flow in an electrical system it is necessary to compute voltage magnitudes
and phase angles at each bus in the system. The input data for these calculations are the voltage
magnitudes V, the load angle δ, the net real power P and the reactive power Q. Two of these
parameters are always input data at each bus in the system and two are calculated by the power
flow program. The bus categorization is as follows: [17]
Swing bus, also known as slack bus
o The electrical model can only contain one swing bus being the reference bus for
other busses in the system. Input data are the voltage and the load angle, normally
as 1 p.u. and 0 . The swing bus is not a real bus. It is only a way to help model the
system and perform numerical calculations.
Load bus
o Normally the most common bus in a power system where P and Q are input data and
V and δ are calculated.
Voltage controlled bus, also known as generator bus
o Normally the bus to which a generator is connected. P and V are input data and Q
and δ are calculated. With this bus there are also some extra input data, one can
here also decide for example which interval a generator can operate between i.e.
QMAX and QMIN. A bus to which a tap-changing transformer is connected to should
also be designed this bus type.
17
Computer programs calculating power flows in electrical system use the bus admittance matrix
which forms Equation 2.20 together with the voltage and current. The bus admittance matrix is built
up on the diagonal by the sum of admittances connected to the specific bus in question and all off
diagonal elements are the negative sum of all admittances between the specific bus and other busses
in the system. [17]
Equation 2.20
Equation 2.20 is combined of the bus admittance matrix Y, the column vector of the bus voltages V
and the vector of current sources I. The system admittance and the bus connections can be input
data for the computations which result in the bus admittance vector. With the bus admittance vector
and the current at each bus the bus voltage can be determined. [17]
For one line these calculations can be made manually but for a system with many components this
builds up to complex matrix calculations best suited for computer computation. There are many
different programs for computing power flow problems e.g. PSS/E, PSCAD, Power World Simulator,
Aristo, etc. The solution type used to solve can also vary but the most common is the Newton-
Raphson method. [17]
Since power flow bus data consist of the real and reactive power for load busses, and real power and
voltages for generator busses. Equation 2.20 has to be rewritten while using Newton-Raphson
methods of solving matrix equations, but it is still the base for the calculations. [17]
2.1.6.2 Line Approximations Transmission lines characteristics can be modelled for calculations and depend on the length of the
transmission line. A short transmission line, while having a 50 Hz system, shorter than 100 km can be
represented as Figure 2.9 i.e. only with series resistance and inductance. The subscript S and R stands
for the sending end and receiving end voltage and current and is the length of the line.
Figure 2.9 An equivalent circuit of a short transmission line
For a medium length transmission line the admittance, Y, cannot be neglected, and is represented by
the admittance making the equivalent circuit change to a Π-circuit with the admittance connected in
parallel with half at each end of the circuit, as seen in Figure 2.10. It is the same equivalent seen in
Figure 2.5 but here with the admittance divided between the sending and receiving end. Medium-
length lines ranges from 100 to 300 km.
18
Figure 2.10 An equivalent circuit of a medium transmission line
The admittance is dependent on the conductance and the capacitance by:
Equation 2.21
The conductance is normally small enough to be neglected in transmission line calculations making
the admittance in Figure 2.10 and the equations below only dependent on the capacitance.
Equation 2.22 shows the relation between the sending and receiving currents and voltages for the
circuits where the parameters A, B, C and D depends on the constants R, L and C and thus changes
depending on the different length of the transmission lines.
Equation 2.22
The equation can be written in matrix format:
[
] [
] [
] Equation 2.23
For the short line equivalent circuit the A, B, C, D matrix is as shown below:
[
] [
] Equation 2.24
Equation 2.25 shows the relations for a medium length line where the more complex matrix also
includes the admittance Y.
[
] [
] Equation 2.25
The expressions above are as stated approximations where the impedance and admittance is seen as
lumped together. In reality these characteristics of the lines are uniformly distributed along the line.
To account for this one can study line section of length Δx which changes the relations. The relations
do not change for the short transmission lines but for medium lines with the admittance connected
in parallel we get a new A, B, C, D matrix, shown in Equation 2.26. The equation together with
Equation 2.23 makes it possible to solve for voltage and currents from one bus to another. [17]
[
] [
] Equation 2.26
19
2.1.6.3 Contingency Analysis Contingency analyses are introduced to make sure that the system maintains a certain system
security i.e. with static operation that means; operation without overloads and voltage levels within
grid code levels. The contingency refers to changes in the system that might weaken the electrical
power system and is thus one way to determine weak points in the power system in need of
upgrades. There are different types of contingency analyses from the most basic only considering the
outage of a single transmission line to more complex analyses considering multiple line outages
or/and loss or change of generators/loads in the system. Even open lines i.e. unused, can be closed in
a contingency analysis. [22]
Figure 2.11 Schematic scheme over a contingency plan [23]
The most basic contingency can be described as an N-1 contingency analysis where one component
from the model is disconnected; in the electrical system this can either be on purpose, for
maintenance, upgrades etc. or by an accident or fault. [23]
2.2 Wind Power There are several ways to extract the power of the wind but there are mainly two different types of
wind turbines are used; HAWT (Horizontal Axis Wind Turbine) and VAWT (Vertical Axis Wind
Turbines). Today the three bladed HAWT is the most common wind turbine. Three blades are
generally favoured because it has lower power pulsations, as the blade passes the tower, than a
HAWT with fewer blades. Moreover a three bladed wind turbine is more aesthetically appealing than
a wind turbine with fewer blades than three, whilst the turbines are rotating. Any number of blades
can be used on HAWT, although if too many blades are used they tend to interfere with each other
aerodynamically. Figure 2.12 shows a typical arrangement for a HAWT where Gen stands for
generator G/B for gear box and T for transformer. [20]
N-1 Contingency
Report/Fix Violations?
Final Report
N-0 Base Case
Report/Fix Violations? Yes
Yes
No
No
20
Figure 2.12 A typical arrangement for a HAWT [20]
The power of the wind is extracted by aerodynamically designed blades that produce a lift force
along the length of the blade. This aerodynamic force integrated along the length of the blade
produces the torque on the turbine shaft. The turbine shaft is connected to the gearbox which
increases the shaft speed. The gearbox and generator is placed in the nacelle at the top of the tower.
The generator is connected to the electrical power system via a transformer. [20]
The power in the wind varies with the cube of the wind speed and is described with the following
equation.
Equation 2.27
where is the power that can be extracted from the wind, is the air density, is the swept area of
the blade, is the coefficient of performance for the turbine and is the wind speed. For the wind
turbine to be able to absorb all the kinetic energy in the wind, the wind speed after the turbine has
to be zero. This is impossible because the airflow has to be continuous. The theoretical maximum of
energy that can be absorbed by the wind turbine is called the Betz limit and defined when Cp is equal
to 16/27. The Betz limit is derived from an infinitely thin rotor, which represents the turbine, and a
fluid flowing at a certain speed. In reality the coefficient of performance Cp for a wind turbine is
lower, because also varies with the tip speed ratio λ. A typical value for Cp is around 0,4. [20]
Figure 2.13 A typical Cp/λ curve for a wind turbine [20]
21
A
curve, as seen in Figure 2.13, for a specific wind turbine helps determent at what tip speed ratio
the wind turbine extracts the maximum amount of power in the wind. This is a powerful tool when
designing wind turbines. [20]
Figure 2.14 Turbine power as a function of the wind speed [20]
Figure 2.14 shows the wind turbine power as a function of the wind speed. In order for the wind
turbine to produce power the wind speed need to be greater than vw1, which is called the cut in
speed and lies typically around 3-4 m/s. If the wind speed is lower than the cut in speed the power in
the wind is not high enough for the generator to produce energy. With increasing wind speed the
turbine produces more power until it reaches point A. At point A the generator produces its
maximum power which happens at wind speed which is the rated wind speed, more specifically
the wind speed the turbine is designed for. For higher wind speeds than the rated wind speed the
turbine is regulated with either pitch regulation or stall regulation to extract the right amount of
power from the wind preventing the wind turbine from accelerating. The power output remains
constant until the wind speed reaches , typically around 25 m/s, which is called shut down wind
speed; where the wind turbine shuts down to prevent it from breaking. [20]
The wind is the most important aspect for wind power. Therefore the wind is measured at a desired
location for building a wind power plant over at least one year. Another important aspect of wind
power is the capability factor CF that is defined as seen in Equation 2.28 for a period of one year.
Equation 2.28
CF is the ratio between actual energy production and the maximum amount of energy that could
have been produced if the plant had operated at full capacity over the designated time period. It can
be used to see how efficiently a wind power plant has been operating over one year, a typical value is
around 0,2. [20]
22
2.2.1 Moldova´s Wind Resource In order to decide the wind potential for a specific location, a large amount of data for that specific
area is needed. This can be done with a variety of measuring instruments such as anemometers and
direction sensors. Especially important to investigate is the wind velocity probabilistic distribution,
daily and seasonal variations and prevalent wind directions. These are all important aspects for the
efficiency or inefficiency for utilization of the wind power. Another important aspect to account for is
the capability factor.
As described in Equation 2.27 the energy in the wind is proportional to the cube of the wind speed.
This relation is fundamental in all wind power. Statistical data with a high level of credibility is hard to
obtain because it requires systematic observations during a long period of time, at least for one year
but preferable longer, and at hub height of the wind turbine. These measurements is often
performed by companies who are specialized in determining the wind power potential, this data is
very expensive to retrieve. However there are ways to determine the wind power potential with data
measured at the lower heights, which means that data from meteorological weather stations, often
10-12 meters above ground level, can be used to determine the wind power potential. These
measurements are often influenced by the surroundings such as trees and houses.
Two different methods are mainly used to determine the wind power potential for a certain location.
One model is developed in Europe and one in USA. The American model is developed by NASA
together with the U.S.A Air Force and is based on the dynamic climate theory which means that the
model doesn’t require a lot of meteorological data, but instead requires more computing processing
power. The European model is called WAsP (Wind Atlas Analysis and Application Program) and has
been used when drawing the European wind atlas. Several European countries such as Austria,
Croatia, Slovenia and Czech Republic etc. have used WAsP when drawing their wind atlases. Moldova
has several meteorological stations which has recorded the wind direction and the wind velocity
every three hours during a period of more than 10 years and have therefore chosen to use WAsP to
draw their wind atlas.
From the calculations given by the WAsP program and with the data from weather stations, a wind
atlas can be derived. The wind atlas main goal is to present the wind energy resource in the area of
the weather station, thus estimate the wind energy potential in the region and with this information
you can identify the best locations for building a wind turbine or a wind power park. A wind atlas
produced over Moldova can be seen in Appendix B [14]
The wind atlas is not very accurate and cannot be used as reference when deciding exact locations
for wind power plants, further investigations must be made. The wind atlas only gives a hint of the
wind conditions. According to the wind atlas the southern region is best suited for wind power
installations.
There are other publications of the wind potential in Moldova from the beginning of the 1990th;
these predictions give a negative picture of the wind power potential in Moldova. However these
investigations where based on wind data from the meteorological station in Chisinau, which is
located in the centre of Chisinau and is surrounded by a variety of obstacles and cannot be
considered as a good reference station. [14]
23
2.2.2 Economy The payback method is used for determining the time it takes for an investment to repay the sum of
the original investment. It’s a useful tool when investigating if an investment is profitable in a
reasonable timeframe, or when comparing different investment proposals trying to determine which
one is the most profitable. Originally the payback method doesn’t account for other factors such as
inflation or discount rate but there is a discounted payback method where these factors are taken
into account. It’s described with the following equation:
∑
Equation 2.29
where is the net cash flow; which is the cash inflow minus outflow, is the discount rate and is
the time. [24]
Figure 2.15 An investment and payback curve for a nonspecific project [25]
Figure 2.15 shows a typical investment and payback curve. At the start of the project money is
invested in the project, this called the investment period. Until the project reaches the self-funding
point the project just costs money. Typical cost during the investment period for wind installations
can be wind measurements, calculations of wind potential, project management and off course costs
for building the wind power plant. At the self-funding point, the investment is starting to earn money
and the investors are getting the invested money back. At the breakeven point the investor has got
all the invested money back and beyond this point all the money earned is pure profit.
24
2.3 Method Five potential locations were chosen for wind power installations. To simulate the effects new
generation would have on the electrical power system of Moldova a model for power flow
simulations is constructed. In the model different scenarios is simulated to show installation
capacities for each location separately and for all sites at the same time.
2.3.1 PSS/E Power flow simulations are done by computer programs, with approximations of transmission lines,
transformers and other components of the electrical power system. There are a number of different
programs on the market, for this project PSS/E (Power System Simulator for Engineering) is used. The
software has efficient tools for simulating static power flows, contingency analysis, and it also has the
possibility to automate these processes. The automation process in PSS/E can be executed in three
different ways, in this project Python programing was used to simulate the different scenarios
described later in chapter 2.3.3 . A description over how a contingency analysis can be executed in
PSS/E together with the creation of important files needed for the process can be seen in Appendix S.
The appendix also describes in more detail the different ways to automat in PSS/E.
2.3.2 Building the Model There were no existing models over the Moldovan electrical power systems that could be used in the
project. A model was created with the help of the Technical University of Moldova (TUM), situated in
Chisinau, specific for this project. TUM provided an equivalent circuit over the Moldovan electrical
power system. The equivalent circuit describes a 330 kV electrical power system, partially seen as the
green line in Appendix A, stretching from big cities in Moldova such as Chisinau, Baltsi and Tiraspol in
Transnistria, going in to Ukraine and finally back to Moldova again completing a full circle. The
equivalent circuit can also be seen as the green part in Figure 2.16. The model is a 7 bus system, out
of which 3 busses are situated in Ukraine, it includes 5 branches, 3 generators and 5 loads divided
between the two areas; Moldova and Ukraine. The complete model along with its specified data,
Table D-1 to Table D-5, can be seen in Appendix D.
Detailed data of the southern parts of Moldovan electrical power system was also provided, the data
was provided in the form of schematics over the grid also stating length and type of the transmission
lines. The properties of the specific lines are given in Table E-1. With this given data the initial model
was extended by 17 busses located in the southern region of Moldova. The line diagram over the
complete equivalent model is shown in Figure 2.16, detailed data over the model can be seen in
Appendix F.
25
Figure 2.16 One line diagram over the PSS/E model
The extended part is the main focus of the report and describes mainly a 110 kV system with the only
exception being one 400 kV line, the blue and yellow part in Figure 2.16. The system is connected to
the initial equivalent circuit, green in the model, at three locations. The different voltage levels also
introduces 4 three winding transformers to the system. Not all busses and thus also not all branches
are modelled but all power flow paths in the southern regions 110 kV system are accounted for.
All values in the model are expressed in per-unit values, the voltage values uses respective base
voltage value as base value i.e. 110 kV, 330 kV and 400 kV. The impedance values are expressed with
the base impedance values given for each voltage levels see Table E-3 in Appendix E. The 400 kV line
is also long enough so the admittance needs to be regarded, the relation between base impedance
and base admittance can be seen in Equation 2.15. [26]
Reactive Power Flow
400 kV Line
330 kV Line
110 kV Line
Active Power Flow
Load
Generator
Three winding
transformer
Switched shunt
Line Offline
26
2.3.2.1 Busses The model consists of 24 busses, the initial 7 have 330 kV as their base voltage, 11 busses are
connected within the 110 kV grid and 2 busses are situated on the 400 kV line between Vulcanesti
and MGRAS, in Transnistria. There are also 4 busses in the 35 kV system, each connected to a three
winding transformer, these busses have no meaning except for modelling the transformer i.e. they
have no load or generation connected to them and can thus be seen as a part of the three winding
transformer not contributing to any system losses by themselves.
The swing bus is the MGRAS bus, situated in Transnistria and is chosen as such because of the high
electrical energy imports from Transnistria. It is also an appropriate swing bus because of the
excessive generation capacity of MGRAS. The swing bus input voltage is increased a bit from
standard 1 p.u. to 1,0455 to increase the system overall voltages. Also the two generators in Ukraine
has an increased voltage to 1,0455 for the same reason.
2.3.2.2 Branches All branches in the 110 kV system are relatively short, the longest is still less than 50 km and as
described in section 2.1.6.2 the admittance is thus neglected. The 400 kV line is of medium length
type and thus also needs to take into consideration the admittance, this value can be located in Table
F-2, under the heading charging, in Appendix F
There is a branch between Tarecklia and Ciadyr that is marked in the model but it is not in use as can
be seen in Figure F-1 and Table F-2. The line is an existing one but for reasons unknown to this
project is not in use at the moment.
The extended southern system do not account for all transmission lines but all power flows paths are
accounted for, thus only transmission lines connected in series are removed. The impedance in these
lines has been accounted for by the method of Equation 2.19. Line data can be seen in Appendix
EThe total impedance values for the lines are given in Table E-2 and recalculated using Table E-3 and
Equation 2.14, the resulting impedance values can be seen in Table E-4. The used rating for the
equivalent lines is the thermal level, rate A in PSS/E, and the rating for each equivalent line is the
rating of the connected lines with the lowest individual rating
2.3.2.3 Shunt Elements There are two switched shunts connected to the grid, these do not operate on a daily basis, were one
is only used during the night, and were thus neglected. This because the fact that the model
simulates maximum load flows and shunt compensation should only be included if it is connected for
use whenever needed which not is the case here. [26]
2.3.2.4 Transformers The four transformers connected to the system are tap transformers and are simulated to operate as
voltage control step transformers with a 15 step interval within plus minus 10 % of base voltage. At
each transformer position there are two three winding transformers, due to constraints in the free
university edition of PSS/E the model is built up by one transformer at each transformer point.
Equivalent values representing two transformers in one were provided by TUM [26] and the ratings
were multiplied by two due to the doubled capacity; the transformers at each point are identical.
27
Three winding transformers in PSS/E are modelled as three two winding transformer connected
together in a star bus, this star bus is not visible by the user. The nominal voltage specified for each
winding is the base voltage for respective bus each winding is connected to. The nominal voltages for
each winding is by default zero and is interpreted by PSS/E as the base voltage for the bus to which
the transformer is connected [27]. The tap transformers operate with voltage control for the busses
in the models extended system i.e. not for busses in the 330 kV equivalent system provided by TUM.
2.3.2.5 Loads and Generation Loads and generation in the model are based on maximum load data for 2011 [26], they can be seen
allocated to important busses for the model in the sketch in Figure 2.17.
Baltsi is the northern metropolitan in Moldova, both in the aspect population and electrical network.
In the model all loads in northern Moldova are allocated to Baltsi. The third CHP, CHP 3, in Moldova
is located within Baltsi and constitute together with a small HPP, located close to Baltsi at the border
to Romania, the generation connected to Baltsi in the model.
Moldova has a small export of energy to Romania made possible by back to back converters. The
export is included in the load located at Chisinau. The generation in Chisinau consists of CHP1 and
CHP 2.
Straseni is a big electrical hub located just north of Chisinau in the centre of Moldova, as can be seen
in Figure A-1 in Appendix A. All loads in central Moldova are allocated to Straseni.
To the MGRAS bus is apart from the huge gas fired electrical complex located in Transnistria also the
HPP on the river Nistru allocated. The loads in eastern and southeaster Moldova are allocated to the
MGRAS in the model.
The generation and export/import to Ukraine can be seen as divided in two. To the south there is an
export of electricity to the Odessa region in Ukraine, the Ubolgr bus in the model, see Figure F-1 in
Appendix F. To the north the Ukrainian busses connected to the 330 kV system is represented.
28
Figure 2.17 Load and generation in Moldova, rectangles represent generation and circles loads
There are some differences between stated values and values in the model as can be seen in Table
2.1 and Table 2.2. The difference is due in order minimize the difference between power flows in this
model and more complex models used at TUM.
Table 2.1 Load values for the active generation and consumption
Values Baltsi Straseni Chisinau MGRAS Ukraine
Generation (MW) 34 0 231 703 425
Load (MW) 170 87 382 129 438
Table 2.2 Model load values for the active generation and consumption
Model Values Baltsi Straseni Chisinau MGRAS Ukraine
Generation (MW) 34 0 234 703 428
Load (MW) 171 87 391 220 444
The reactive power compensation for all generators in the system has a maximum production of
reactive power, the maximum is calculated with the power factor equal to 0,8 using Equation 2.5 and
Equation 2.6. The biggest source of generation in Ukraine comes from UDSGEC81, which is a HPP.
This source gives a lot of reactive power compensation possibilities; positive and negative. The
second Ukrainian generator, ULDTEC81, takes into account the balancing capacity of Ukraine and has
possibilities to compensate enough reactive power necessary to keep its fixed voltage point.
29
Five generators were added to the southern region in the model each one representing a connection
point for a wind power plant. The exact locations are good from a wind potential perspective as well
as from a grid stability perspective [26]. The locations are Besarabeasca, Zarnesti, Leovo, Ciadyr and
Cimislia and can be seen marked on the wind potential map in Figure B-1 in Appendix A.
2.3.3 Scenarios A contingency analysis is first performed on the model as it is, symbolizing the Moldovan electrical
system as it looks today with a maximum load scenario. This base case scenario is later used for
comparison to analyse changes in the system when installing wind power.
Two scenarios were developed to examine the wind power potential in the southern region of the
Moldovan electrical system. The scenarios were executed with the help of different Python scripts
making it possible to automate some processes. One part of the Python script used to automate the
contingency analysis in the base case and the scenarios was re-used in all scenarios, se the script in
Appendix G.
The contingency analysis takes into account two parameters as limiting factors:
Transmission line capacities
Voltage level grid codes within ± 10 % of base voltage
The generation at each location is purely active i.e. the reactive power is limited to operate only at 0
MW. As stated under 2.1.6.1 generator busses are designed to keep voltage levels at a specific level,
normally at 1 p.u. Designing the generators to have 0 MW output or input of reactive power makes
the generator bus operate as a load bus with negative active power output and with varying voltages.
The two scenarios are also tested where the generators have the possibility to consume or produce
reactive power, thus operating as a “true” generator bus. The reactive power consumption or
production occurs to keep the voltage levels at 1 p.u. making generator acting towards stabilizing the
system.
There is a natural limit for what is possible to install given by the lines connected to each point of
connection. As shown in the figure at Appendix Fone can see that each installation point has exactly
two lines connected to it. This means that, with the contingency analysis, the generators can never
have a higher installed power than the lowest transfer capacity of any of the two transmission lines
connected to the bus i.e. after regards are taken to the loads connected to each bus and the losses in
the lines. This gives a definite maximum for the installed power for each of the five sites. A
description of each scenario follows below.
2.3.3.1 Scenario I The five points of installation i.e. Besarabeasca, Zarnesti, Leovo, Ciadyr and Cimislia, are tested
separately. Installation is increased using a specific Python script for scenario I, see Appendix H, it
increases the generation values with one MW at a time. In between each increase the script calls
upon the main script to perform the contingency analysis. A separate text file is created containing all
values which did not lead to violations in the contingency analysis. The value then needs to be read
manually. The script operates according to Figure 2.18 where the generation at generator G is
increased as long as no violation is reached in the contingency analysis.
30
Figure 2.18 The algorithm for the contingency analysis where generator G is increased
2.3.3.2 Scenario II The second scenario intends to find the total maximum production possible in the southern region of
Moldova. The situation is an optimization problem where the different sites generation is the
variable parameters and line capacities and voltage levels are limiting factors. Finding the maximum
total potential of generation is highly difficult only testing manually; that is to which level of
generation the different generators should operate with in order to find a maximum total
generation. There are too many parameters to easily optimize this problem; the level of
unpredictability is too high. To optimize this problem a Monte Carlo simulation was used. The
concept of the Monte Carlo simulation is working with random numbers, in this case using the built
in random generator of Python. A new script was written to give each generator a random number
from 0 to maximum value, given by line capacities, the results are then saved in text files for further
processing in Excel. The algorithm is basically the same as in Figure 2.18 if a random generator
replaces the plus 1 MW and working with all five generators at the same time. The script can be seen
in Appendix I
To find a maximum value a high amount of iterations needs to be made, the script is run with 100000
iterations. The solution1 is then tested and if increase is possible a new simulation is made with ±5
MW of given maximum value. The solution provides a maximum; it cannot be proved to be the
absolute maximum. The maximum is tested by increasing each generator one by one by one MW
separately.
2.3.4 Economy The payback method is used to determine the payback time for wind power plant installation in
Moldova. This was done by plotting the capital value in relation to time and determining at what
year the capital value reached the breakeven point. The capital value is determined with Equation
2.29. Assumptions made are as follows. The investment cost for a wind power plant used in this
report is 1,1 million €/MW installed capacity, this number also include costs for maintenance during
a lifespan of a wind power plant. This cost can differ around 1,0 to 1,5 million €/MW depending on
the location for the wind power plant, type of wind power plant, reactive power compensation
Violation
Stop Simulation
No violation
G
Grid
N-1
+ 1 MW
31
devices, etc. [28]. A life time for a wind power plant is ca. 20 years. Two different capacity factors,
and were used, this because the capacity factor of a wind power plant differs from
location to location and year. The different capacity factors give an interval of the payback time
instead of one definite value. In this report three different discount rates of 6, 8 and 10 % were used
in the analysis. The electricity price used was 0,11 €/kWh [29] with the sensitivity analysis of ± 20 %.
The payback time is also compared between including and excluding income from CERs. The cost for
CER:s which was used in the calculations was 4 €/tonne CO2 [30].
32
Chapter 3 Results The results from the different scenarios are described in this chapter. The Base case, Scenario I and
Scenario II are described in detail. After follows the reduced electrical imports possible from the
results in Scenario I and Scenario II. The chapter ends with the economic results.
3.1 Base Case Running a contingency with the Base Case scenario does not give any violations in the systems i.e.
the voltage levels are kept within voltage limits and the lines supply sufficient capacity to transfer the
power. One can also note that the lines are not used close to rated values i.e. there is a lot of
potential for new generation in the system, see Appendix Jfor a loading table report for the
contingency which show the usage of lines in comparison to capacity and voltage reports for each
bus at all contingencies and the line diagram in Appendix Kwhich also show how much each line is
loaded.
Table J-1 in Appendix J shows the highest and lowest values for the loading report for the base case.
It shows that the highest voltage is at the Vulcanesti bus, throughout the entire contingency analysis.
For low voltages with a contingency the Ciadyr bus and the Comrat bus are dominating; where they
represent the lowest voltage in the system. The Zarnesti and Cimislia busses have the lowest voltages
at one contingency each. The overall lowest voltage can be found at the Ciadyr bus with 0,933 p.u.
when the line between Ciadyr and Vulcanesti is tripped.
A histogram is created showing the dispersion for the voltage levels throughout the contingency
analysis; it can be seen in Figure 3.1. All voltage levels at all busses in the focus area, the 110 kV
system, are sampled and then stored in the bins making up the frequency in the histogram. The
histogram shows that the majority of voltage levels lie close to one p.u.
Figure 3.1 The dispersion of voltage levels for the base case contingency analysis
0
5
10
15
20
25
30
35
40
45
0,93 0,94 0,95 0,96 0,97 0,98 0,99 1 1,01 1,02 1,03
Fre
qu
en
cy
Voltage [per unit]
Base Case
33
3.2 Scenario I The results from scenario I where the generation at each location is increased separately are shown
in Table 3.1.
Table 3.1 Maximum generation before violation in the contingency report
Besarabeasca Zarnesti Leovo Ciadyr Cimislia
Maximum Generation [MW] 60 25 30 84 102
If generation is increased by 1 MW at each location the contingency analysis results in violations.
These violations can be seen in the contingency report in Appendix L. The report shows that for
Besarabeasca, Zarnesti, Leovo the limiting factor is high voltage levels and for Ciadyr the limiting
factor is low voltage levels. For Cimislia the limiting factor is the capacity on the transmission lines.
The violations are spread out; no contingency of any single line causes violations for more than one
location and no contingency causes the same violation. Comparing the generated values with the
maximum generation possible before the line capacity is reached, Table 3.2, we get the extra
generation potential in Table 3.3 i.e. if voltage faults were to be compensated for.
The maximum generation at each point due to capacities of the transmission lines is shown in Table
3.2.
Table 3.2 Maximum values regarding only line capacities
Besarabeasca Zarnesti Leovo Ciadyr Cimislia
Values in MW 84 87 83 96 102
If no regard is taken to the voltage limits i.e. when the only limiting factor is the capacity of the
transmission lines, the extended generation potential is increased and can be seen in the table
below.
Table 3.3 Extended generation potential until line capacity is reached
Besarabeasca Zarnesti Leovo Ciadyr Cimislia
Generation potential [MW] 24 62 53 12 0
3.2.1 Scenario I, With Reactive Power Compensation For the scenario using one generator at the time with reactive power compensation gives us results
shown in Table 3.4.
Table 3.4 Possible generation capacity with reactive power compensation
Besarabeasca Zarnesti Leovo Ciadyr Cimislia
New Generation [MW] 74 78 74 91 98
Produced Reactive Power [MVAr] -19,7 -19,3 -22,8 -16,8 -19,6
Increased Generation [MW] 14 53 44 7 -3
34
When generation, as in scenario I, is increased by 1 MW the resulting overload report can be seen in
Appendix M. According to the report the only limiting factor for further generation is the line
capacity; faults occur only at lines directly connected to the busses that is generating and only when
the other line directly connected to the bus is tripped. One exception can be seen in Besarabeasca
where only the tripping of the line going to Chisinau results in breach of capacity for the other line
connected to Besarabeasca. The extra generation does not reach values given by Table 3.4 because
the reactive power produced also uses line capacity.
3.3 Scenario II The first iteration process with 100000 iteration can be seen visualized in Appendix R, it shows a line
diagram with all outcomes that did not reach violation, Figure R-2 in the appendix shows a histogram
over the outcome for the simulation. The first Iteration method was followed by an iteration method
with an interval close to values given for maximum generation in the first step. The second iteration
was then followed by a ±5 MW iteration, se Figure R-3, giving the results shown in Table 3.5.
Table 3.5 Maximum generation for each location giving maximum total generation for the region
Besarabeasca Zarnesti Leovo Ciadyr Cimislia
Maximum Generation [MW] 29 14 31 84 102
Total Maximum Generation [MW] 260
An increase of 1 MW for each generator separately results in voltage violations for all points except
for Cimislia, where the capacity once again is the limiting factor. The violations can be seen in
Appendix Lwhere voltage violations occur with the contingency analysis when lines represented by
single 7 and 11 are removed; single 7 is the line between Zarnesti and Vulcanesti and single 11 is the
line between Comrat and Cimislia. In total there are violations at five occasions caused by high
voltage, out of these five; one is at the Zarnesti bus, three at the Ciadyr bus and one at the
Besarabeasca bus. A histogram showing the dispersion for the voltage levels throughout the
contingency and can be seen in Figure 3.2.The histogram shows that voltage levels, compared to the
base case as seen in histogram in Figure 3.1, has increased and several voltage levels are almost as
high as 1,1 p.u. which is the maximum voltage limit according to grid codes.
Figure 3.2 A histogram of the dispersion of voltage levels with a contingency analysis
0
5
10
15
20
25
30
35
40
0,9
3
0,9
4
0,9
5
0,9
6
0,9
7
0,9
8
0,9
9 1
1,0
1
1,0
2
1,0
3
1,0
4
1,0
5
1,0
6
1,0
7
1,0
8
1,0
9
1,1
1,1
1
Fre
qu
en
cy
Voltage [per unit]
Scenario II
35
3.3.1 Scenario II, With Reactive Power Compensation To derive the results using generator busses with variable reactive power output the iterations from
earlier have to be repeated. Due to the Monte Carlo method the values derived cannot be used for
direct comparison but rather a general view that there is a high increase of the total production.
Histograms showing the two different cases in scenario II can be seen in Appendix R
Table 3.6 Maximum generation for each location giving maximum total generation for the region
Besarabeasca Zarnesti Leovo Ciadyr Cimislia
Maximum Generation [MW] 56 68 68 91 72
Produced Reactive Power [MVAr] -8,3 -9,7 -14,7 -6,1 -6,5
Increased Generation [MW] 27 54 37 7 -30
Increased Total Generation [MW] 95
The overload reports in Appendix O for the contingency analysis where each generators generation is
increased by one MW separately shows that the voltage values is a problem only at one location and
only when one line is tripped. The voltage levels sink below grid code values for the Tarecklia bus
when the line between Chisinau and Cimislia is tripped. This occur no matter which generators
generation is increased by 1 MW. The bus voltage levels through a contingency analysis are shown
below.
Figure 3.3 A histogram of the dispersion of voltages levels with a contingency analysis
Comparing the results with Figure 3.1 and Figure 3.2 one can see a decrease in voltage levels with
some values lying close to 0,9 which is the lowest value allowed according to grid codes. Overall
voltage levels are close to 1 p.u. showing a stable system.
The line capacity is also a limiting factor when the Ciadyr generation is increased; line capacity is
surpassed on the line between Ciadyr and Vulcanesti as well as for the line between Comrat and
Ciadyr. As can be seen in Appendix Kthe loading of the lines has increased by much from the base
case.
0
20
40
60
80
100
0,9
0,9
1
0,9
2
0,9
3
0,9
4
0,9
5
0,9
6
0,9
7
0,9
8
0,9
9 1
1,0
1
1,0
2
1,0
3
1,0
4
1,0
5
1,0
6
1,0
7
1,0
8
1,0
9
1,1
1,1
1
Fre
qu
en
cy
Voltage [per unit]
Scenario II - Reactiv Power Compensation
36
1.1 Reduction of Imported Electric Energy The reduction of electric energy depends on the capability factor of the wind power park. Reduction
will be reduced from the imported electrical energy in Moldova as it was in 2010 i.e. 3038 GWh
which stood for 74 % of the total consumed electrical energy. The reduced imports are not equal to
the generated power from the wind power plants but rather the reduced production from the swing
buss in MGRAS.
3.3.2 Scenario I The first scenario gives two different reduction possibilities; one with the generators producing a net
zero reactive power contribution, Table 3.7, and one where the generators can compensate with
reactive power, Table 3.8.
Table 3.7 Imported electrical energy reduction due to wind power installations
Besarabeasca Zarnesti Leovo Ciadyr Cimislia
Installed Power [MW]: 60 25 30 84 102 Reduced Power at MGRAS [MW] 57 25 30 77 95 Capability factor 0,1 Reduced Production at MGRAS [GWh] 50 22 26 67 83 Reduced Electrical Imports [%] 1,6 0,7 0,9 2,2 2,7 Capability factor 0,3 Reduced Production at MGRAS [GWh] 57 25 30 77 95 Reduced Electrical Imports [%] 4,9 2,2 2,6 6,6 8,2
Without the possibility to produce or consume reactive power the reduced electrical energy imports
vary depending on location between 1 to 8 % of total imported electrical energy. The reduction is
highly dependent on the specific location of installation where installations in Cimislia give the
highest reduction.
Table 3.8 Imported electrical energy reduction with reactive power compensation
Besarabeasca Zarnesti Leovo Ciadyr Cimislia
Installed Power [MW]: 74 78 74 91 98 Reduced Power at MGRAS [MW] 66 67 55 79 90 Capability factor 0,1 Reduced Production at MGRAS [GWh] 58 59 48 69 79 Reduced Electrical Imports [%] 1,9 1,9 1,6 2,3 2,6 Capability factor 0,3 Reduced Production at MGRAS [GWh] 173 176 144 207 236 Reduced Electrical Imports [%] 5,7 5,8 4,7 6,8 7,8
In the case where the generators are able to consume or produce reactive power the reductions
increase to between 2 to 8 % of total imported electrical energy. The location with reactive power
compensation the location does not matter as much as without reactive power compensation.
37
3.3.3 Scenario II Scenario II gives as scenario I two different electrical energy reduction possibilities both seen in Table
3.9.
Table 3.9 Imported electrical energy reduction due to wind power installations
All generators without reactive power compensation
All Generators with reactive power compensation
Installed Power [MW] 260 355 Reduced Power at MGRAS [MW] 234 293 Capability factor 0,1 Produced Electricity at MGRAS [GWh] 204 256 Reduced Electrical Imports [%] 6,7 8,4 Capability factor 0,3 Produced Electricity [GWh] 613 768 Reduced Electrical Imports [%] 20,2 25,3
The electrical reduction without voltage production or consumption can reduce the electrical energy
imports for Moldova by between 7 to 20 % depending on the capability factor of the wind power
park. With the possibility to produce or consume reactive power this value increases to between 8 to
25 %.
3.4 Economy This section contains an economic analysis of the economic potential for building wind power plants
in Moldova. The payback time is determined for two different capability factors and is compared with
three different prices of electricity and three different discount rates. The results are presented
below. EP stands for electricity price.
Figure 3.4 Payback time with a capability factor of 0,3
-1500000
-1000000
-500000
0
500000
1000000
1500000
2000000
0 1 2 3 4 5 6 7 8 9 10
Euro
Years
Payback time, capability factor = 0,3
EP=0,09€/kWh, r=6%
EP=0,09€/kWh, r=8%
EP=0,09€/kWh, r=10%
EP=0,11€/kWh, r=6%
EP=0,11€/kWh, r=8%
EP=0,11€/kWh, r=10%
EP=0,13€/kWh, r=6%
EP=0,13€/kWh, r=8%
EP=0,13€/kWh, r=10%
38
In Figure 3.4 the payback time when the wind power plant has a capability factor of 0,3 is shown. The
payback time varies from ca. 3 to 7 years depending on the electricity price and interest. The graph
also shows that the price of electricity has bigger impact on the payback time than the interest.
Figure 3.5 Payback time with a capability factor of 0,1
In Figure 3.5 the payback time when the wind power plant has a capability factor of 0,1 is shown. The
payback time varies from 14 years to never. In this case there is no significant difference on who has
the biggest impact on the payback time. However with high electricity price the investment reaches
the breakeven point with all the three different interests while with low electricity price only reaches
the breakeven point in one case. The lifespan of a wind power plant is usually around twenty years
and in this case only three scenarios pays back before twenty years.
Figure 3.6 Payback time including CER:s with a capability factor of 0,3
-1200000
-1000000
-800000
-600000
-400000
-200000
0
200000
400000
600000
800000
0 2 4 6 8 10 12 14 16 18 20 22 24 26 28 30 32 34 36 38 40
Euro
Years
Payback time, capability factor = 0,1
EP=0,09€/kWh, r=6%
EP=0,09€/kWh, r=8%
EP=0,09€/kWh, r=10%
EP=0,11€/kWh, r=6%
EP=0,11€/kWh, r=8%
EP=0,11€/kWh, r=10%
EP=0,13€/kWh, r=6%
EP=0,13€/kWh, r=8%
EP=0,13€/kWh, r=10%
-1500000
-1000000
-500000
0
500000
1000000
1500000
2000000
0 1 2 3 4 5 6 7 8 9 10
Euro
Years
Paybacktime including CER, capability factor = 0,3
EP=0,09€/kWh, r=6%
EP=0,09€/kWh, r=8%
EP=0,09€/kWh, r=10%
EP=0,11€/kWh, r=6%
EP=0,11€/kWh, r=8%
EP=0,11€/kWh, r=10%
EP=0,13€/kWh, r=6%
EP=0,13€/kWh, r=8%
EP=0,13€/kWh, r=10%
39
In Figure 3.6 the payback time when the wind power plant has a capability factor of 0,3 and including
income from CERs is shown. In this graph the payback time is reduced from 3 to 7 years to 3 to 6
years. It’s also shown that the electricity price has bigger impact on the payback time than the
interest.
Figure 3.7 Payback time including CER:s with a capability factor of 0,1
In Figure 3.7 the payback time when the wind power plant has a capability factor of 0,3 and including
income from CERs is shown. In this graph the payback time is reduced from 14 years to never to 13
years to never. Still there is no significant difference on which parameter that has the biggest impact
on the payback time.
-1200000
-1000000
-800000
-600000
-400000
-200000
0
200000
400000
600000
800000
0 2 4 6 8 10121416182022242628303234363840
Euro
Years
Paybacktime including CER, capability factor = 0,1
EP=0,09€/kWh, r=6%
EP=0,09€/kWh, r=8%
EP=0,09€/kWh, r=10%
EP=0,11€/kWh, r=6%
EP=0,11€/kWh, r=8%
EP=0,11€/kWh, r=10%
EP=0,13€/kWh, r=6%
EP=0,13€/kWh, r=8%
EP=0,13€/kWh, r=10%
40
Chapter 4 Discussion Throughout the project many assumptions have been made, this affects the validity of the model.
The results derived in this project have the model as base i.e. the results are true for this model but
before the model has been verified with other models the results cannot be seen as true for the
Moldovan electrical system. Because the model has been designed with real data over the Moldovan
electrical system the results can give us a good indication of what possibilities and problems exists
with wind power installations in the southern region of Moldova.
4.1 Scenarios All results are based on the model created in the project and all results thus have the same accuracy
as data used to construct the model. The model does not have exact data and is much generalized
with many parts as equivalents. Loads and generation are not exact and sometimes allocated to
locations in the model far from actual locations. This means that the results do not have exact
relevance but merely gives the possibilities for a general overview over possibilities regarding new
installations in the southern region in Moldova.
The scenarios consider installations of power for one specific location or at all locations at once.
Some sites could be optimized to have more power but this is not investigated in the project.
The scenarios are based on the model with maximum load flows and contingencies on the 110 kV
lines only, it does thus not consider the low load scenario or changes that might occur with loads and
generators within the system. These changes are likely to affect the maximum values possible to
install.
All Scenarios are designed to stay within ± 10 % of base voltage. Using ±10 % of base voltage levels as
limiting factors might seem high and it is true that for normal operations the grid code for the
Moldovan electrical system states that the voltage levels should lie within ±5 % of base voltage
levels, but extreme cases such as for a contingency where lines are tripped is here seen as extreme
scenarios where ±10 % of base voltage levels are used [26].
4.1.1 Scenario I To upgrade the generation capacity for Besarabeasca one would have to build new transmission lines
to upgrade the capacity, for the other locations cheaper solution could be found with the installation
of shunt elements to consume reactive power in order to decrease the voltage levels in the busses. It
would make most sense to upgrade the grid with such installations where most potential exists
before line capacity is reached. According to Table 3.3 the locations of Zarnesti and Leovo would be
best suited for such installations, regarding voltage stability.
The results in Table 3.4 shows that generation potential is highly increased at some busses when the
generators are given the potential to produce or consume reactive power. The results are built on
the fact that the voltage levels are kept at 1 p.u, this proves to be effective in increasing generation
potential at some busses and also makes the specific bus a strong point regarding voltage in the
region. For Besarabeasca the fact that the voltage is kept at 1 p.u. result in decreasing the generation
capacity; the apparent power increases even though the active power decreases i.e. the
Besarabeasca bus becomes very stable out of a voltage but on the other hand reduces possible active
power output.
41
4.1.2 Scenario II The introduction of generation and the effect it has on voltage and capacity levels can be seen as
stochastic but is not, it just depends on many factors that make it very difficult to predict what
generation would be optimal at each location to generate a total maximum production for the
region. To try to introduce generation at all five locations at the same time raises many questions
about reliability. Our method of finding a maximum generation cannot be proven to give the
absolute maximum, but a value close to maximum.
The result does thus only give a guiding value of how much new generation that would be possible in
the southern region of Moldova. It also shows quite clear that some sites are more sensible for
change and would thus suit better out of a grid upgrade perspective. Cimislia is already limited by the
capacities of the lines connected to the bus; upgrades to increase generation in Cimislia would be
dependent on constructing new transmission lines. Ciadyr, Zarnesti and Besarabeasca are the
weakest points in the grid according to voltage limits where Ciadyr would not benefit much from grid
upgrades in form of voltage compensators being very close to its maximum value. Ciadyr and
Zarnesti are far from maximum generation and would thus benefit most from reactive power
compensation.
The results from looking at where violations are given by increasing each generators generation with
one MW shows that Zarnesti Besarabeasca and Ciadyr are the weakest point according to high
voltage violations where upgrades are likely to give a high value of further generation possibilities.
Looking at the histograms in Figure 3.1 and Figure 3.2 we can quite clearly see that the general
voltage levels are increased and several busses in Scenario II are very close to the maximum value.
This shows that if reactive power compensation would be used, it would support the system by
consuming reactive power and thus decreasing the voltage levels. This is proven to be a correct
assumption when generators can vary in reactive power because maximum generation is increased
from 260 MW to 355 MW. This is good for wind power installations because wind generators usually
consume reactive power and in this case some of the reactive power can be fed from the grid. In this
case where generators can produce or consume reactive power Tarecklia is clearly the limiting factor
for further installation of wind power. This due to low voltage levels, but line capacities are likely to
become a big problem if generation were to be increased further, meaning that the whole 110 kV
system would be in need of upgrades to increase line capacity’s. Looking at the histogram in Figure
3.3 most voltage levels lay close to 1 p.u. i.e. the system is relatively stable, but some voltage levels
are very low. The problem with low voltage levels lie at the Tarecklia bus and even though reactive
power compensation would not increase possible wind power installations by much it would increase
the stability of the system.
Alternatively constructing new lines connecting the wind plants directly to the 330 kV system that is
likely to have a higher capacity for new generation, this would of course bring forth new questions of
economic aspects in constructing long new lines.
42
4.1.3 Economy Moldova’s has a difficult economic situation, being one of the poorest countries in Europe with
inflation rates that are very high. We believe that the most likely scenario is that big wind power
plants would not be constructed without investors from other countries; here the CDM projects
could play a major roll.
The economical calculations made in this project can only be seen as vague approximation without
secure data. We can see in the economical results that the payback time for investments vary by
much, strongly influenced by the capability factor and discount rates. The curves in the economic
analysis are only accurate until the brake-even point.
With Moldova’s economic situation the inflation is high; this tends to increase the discount rates if a
loan for the investment is taken within the country.
Generally concerning wind power a capability factor as low as 10 % is not realistic and payback times
for the investment will become extremely long if even possible making investments unrealistic; with
such a low capability factor a new location should be found examined. For wind turbine investments
the payback time should not exceed 20 years which is the general life expectancy of a wind turbine, it
should rather be some years below 20 to make the investment profitable. Setting the limit to 15
years all scenarios are possible with capability factor of 0,3 but with the capability factor of 0,1 only
one scenario would be possible i.e. with high electricity price and low discount rates at 6 %.
Predictions of a future electricity price tend to lean towards higher electricity prices rather than
lower prices thus making investment of wind power plants more profitable.
Incentives for renewable energy projects such as CDM are helpful for wind power investments but in
our scenarios it does not have as strong influence as the capability factor, discount rates and the
electricity price.
43
Chapter 5 Conclusion The conclusions drawn by this report are based on the model constructed in the report where wind
power installations are made in the southern region of Moldova where wind conditions are
satisfying.
The Moldovan electrical system in the southern region is constructed with high amounts of unused
transmission line capacity, giving the southern region in Moldova a high potential for wind power
installations.
With wind power installations at only one location the report conclude that Cimislia has the highest
potential for wind power installations with 102 MW. This would reduce the electrical energy imports
by 8 %.
With wind power installations at all sites generation can reach 260 MW of installed power if the wind
power plant does not produce or consume reactive power. If the plants are able to consume reactive
power a further 95 MW can be installed.
The electrical energy imports can be highly reduced by wind power installation at busses;
Besarabeasca, Zarnesti, Leovo, Ciadyr, Cimislia at the same time. Total potential electrical energy can
be reduced by as much 8 % to 25 % depending on the capability factor of the wind power plants.
The economic results suggest that payback periods for wind power installations in Moldova stretches
from 3 years to never reaching the breakeven point. Further studies are necessary.
44
Chapter 6 Future Work
The Model should be extended to regard a low flow scenario as well as contingency analysis
where generators, loads and transformers are tripped.
Wind potential, wind data should be sampled over the period, at specified locations, of at
least one year at planned hub height of the wind.
Further investigations of suggested wind power plant locations from environmental aspects
as well as NiMBY (Not in My Back Yard) aspects.
More specific aspects for the needed investments; such as site-specific costs, inflation,
electricity price, CER:s and future renewable energy incentives.
Aspects regarding balancing the wind power output within Moldova should be considered
The project does not consider power quality and the project should be extended to include
such considerations.
45
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A-1
Appendix A Map of the Moldovan electrical system
Figure A-1 Map over the Moldovan electrical system [31]
B-1
Appendix B Map over the wind potential in Moldova
Figure B-1 Wind Potential in Moldova at the height of 70 meters [14]
C-1
Appendix C Description of WAsP
WAsP is a computer program used for predicting wind climates, wind resources and power
productions from wind turbines and wind power parks. The predictions are based on wind data from
meteorological stations. WAsP uses bi-dimensional extrapolation of the wind measured parameters
and also accounts for the obstacles in the neighbourhood of the data collecting point, in this case a
meteorological station. WAsP is developed by the Wind Energy Division at the technical university of
Denmark at Risö. The program WAsP contains four basic computing modules. [32]
Analysis of ”raw” measured data
Elaborating wind atlas
Wind climatological estimation
Estimation of wind potential
Analysis of raw measured data can be used as a separate tool and with it is possible to investigate
the statics of the collected wind data. For example the module can provide a wind rose diagram and
the Weibull distribution curve from data for a specific meteorological station or from data for several
meteorological stations.
The elaborating wind atlas modulus creates a wind atlas. From the data given by the meteorological
stations the WAsP program can calculate the new values, for the analysis, desired parameters and
thereby create a data set. This can be done for the desired height. This data set represents the wind
atlas from which an analysis of the wind conditions in the area can be made.
The wind climatological estimation modulus can estimate the wind value in any far-off emplacement,
thus underlining possible emplacements. In other words the modulus permits the estimation of the
real wind parameters on the interesting emplacement for a wind turbine or a wind power park.
The estimation of wind potential modulus calculates the wind energy potential from the annual
average wind speed at the right height and also the annual energy production for a wind turbine or a
wind power park. This modulus also can estimate the annual energy production for different types of
wind turbines.
D-1
Appendix D Line diagram and data over the equivalent 330 kV circuit
Figure D-1 Line diagram from PSS/E for the equivalent circuit over the Moldovan electrical system
Load
Generator
D-2
Table D-1 Bus data for equivalent circuit over the Moldovan electrical system
Bus Number Bus Name Base kV Area Number/Name Code Voltage (kV) Angle (deg)
1 UDSGEC81 330 2 UKRAINA 2 350,10 -4,27
2 BALTSI 330 1 MOLDOVA 1 331,46 -8,74
3 STRASENI 330 1 MOLDOVA 1 319,50 -11,15
4 KISHINAU 330 1 MOLDOVA 1 318,18 -11,01
5 UKOTOVSK 330 2 UKRAINA 1 336,92 -7,34
6 MGRAS 330 1 MOLDOVA 2 323,14 -8,98
7 ULDTEC81 330 2 UKRAINA 3 363,00 0,00
Table D-2 Plant data for equivalent circuit over the Moldovan electrical system
Bus Number Bus Name Code PGen QGen QMax QMin VSched (kV) Voltage (kV)
1 UDSGEC81 330,00 2 97,60 103,70 103,70 103,70 363,00 350,10
6 MGRAS 330,00 2 147,80 -5,20 -5,20 -5,20 330,00 323,14
7 ULDTEC81 330,00 3 622,30 293,70 9999,00 -9999,00 363,00 363,00
Table D-3 Machine data for equivalent circuit over the Moldovan electrical system
Bus Number Bus Name Code VSched (pu) Pgen (MW)
Pmax
(MW)
Pmin
(MW)
Qgen
(Mvar)
Qmax
(Mvar)
Qmin
(Mvar)
Mbase
(MVA)
1 UDSGEC81 330,00 2 363,0 97,6 0,0 0,0 103,7 103,7 103,7 100
6 MGRAS 330,00 2 330,0 147,8 0,0 0,0 -5,2 -5,2 -5,2 100
7 ULDTEC81 330,00 3 363,0 622,3 9999,0 -9999,0 293,7 9999,0 -9999,0 100
Table D-4 Load data for equivalent circuit over the Moldovan electrical system
Bus Number Bus Name Area Number/Name Pload (MW) Qload (Mvar)
2 BALTSI 330,00 1 MOLDOVA 115,0 31,9
3 STRASENI 330,00 1 MOLDOVA 151,1 51,4
4 KISHINAU 330,00 1 MOLDOVA 209,4 94,4
5 UKOTOVSK 330,00 2 UKRAINA 374,7 76,3
Table D-5 Branch data for equivalent circuit over the Moldovan electrical system
From Bus Number From Bus Name To Bus Number To Bus Name Line R (ohms) Line X (ohms)
1 UDSGEC81 330,00 2 BALTSI 330,00 4,5411 37,6903
1 UDSGEC81 330,00 7 ULDTEC81 330,00 7,6775 61,4087
2 BALTSI 330,00 3 STRASENI 330,00 5,5539 35,6974
3 STRASENI 330,00 4 KISHINAU 330,00 2,2107 14,2332
4 KISHINAU 330,00 6 MGRAS 330,00 2,0038 16,9666
5 UKOTOVSK 330,00 6 MGRAS 330,00 8,0042 49,2990
5 UKOTOVSK 330,00 7 ULDTEC81 330,00 4,4976 36,1984
E-1
Appendix E Transmission Line Data
Table E-1 Data over transmission line types
AS Conductor nr: r0(Ohm\100km) x0(Ohm\100km) r0(Ohm\km) x0(Ohm\km)
35 77,23 0 0,77 0
50 59,20 0 0,59 0
70 42,00 41,00 0,42 0,41
95 31,40 42,90 0,31 0,43
120 24,90 42,30 0,25 0,42
150 19,50 41,60 0,12 0,42
185 15,60 40,90 0,16 0,41
240 12,00 40,10 0,12 0,40
Table E-2 Impedance values for the lines in the 110 kV system
Line ID kV R (1 phase) X (1phase) R (3 phase) X (3 phase)
1 110 17,5578 40,8323 52,6734 122,4969
2 110 6,4896 17,0144 19,4688 51,0432
3 110 5,382 11,4816 16,146 34,4448
4 110 7,9929 13,5783 23,9787 40,7349
5 110 5,772 15,133 17,316 45,399
6 110 19,0734 32,4018 57,2202 97,2054
7 110 8,8395 15,0165 26,5185 45,0495
8 110 13,3575 28,496 40,0725 85,488
9 110 10,9746 23,8011 32,9238 71,4033
10 110 18,55125 35,94048 55,65375 107,82144
111 110 9,048 19,3024 27,144 57,9072
12 110 13,104 27,9552 39,312 83,8656
13 110 6,006 12,8128 18,018 38,4384
14 110 17,28405 32,65825 51,85215 97,97475
15 400 0 0 3,5 46,99
Table E-3 Base impedance values
ZBase 110 kV ZBase 330 kV ZBase 400 kV
121 1089 1600
Table E-4 Per Unit values for the lines in the 110 kV system
Line ID R (3 phase) p.u X (3 phase) p.u
1 0,435317355 1,012371074
2 0,160899174 0,421844628
3 0,133438017 0,284667769
4 0,198171074 0,336652066
5 0,143107438 0,375198347
6 0,472894215 0,803350413
7 0,219161157 0,372309917
8 0,331177686 0,706512397
9 0,272097521 0,590109917
10 0,459948347 0,891086281
11 0,224330579 0,478571901
12 0,324892562 0,693104132
13 0,148909091 0,317672727
14 0,428530165 0,809708678
15 0,0021875 0,02936875
1 Line 11 is out of use
2 1 stands for load bus, 2 for generator bus and 3 is the swing bus
F-1
Appendix F Line diagram and data over the complete model
Figure F-1 Line diagram for the equivalent circuit over the Moldovan electrical system
Reactive Power Flow
400 kV Line
330 kV Line
110 kV Line
Active Power Flow
Load
Generator
Three winding
transformer
Switched shunt
Line Offline
F-2
Table F-1 Bus Data
Bus Number Bus Name Base kV Area Number/Name Code 2 Voltage (pu) Angle (deg)
1 35 1 MOLDOVA 1 0,9990 -1,51
30100 MGRAS 330 1 MOLDOVA 3 1,0455 0
30120 MGRAS 400 1 MOLDOVA 1 1,0390 -1,2
30195 MGRAS 35 1 MOLDOVA 1 1,0423 -0,57
32049 BALTSI 330 1 MOLDOVA 2 1,0079 -0,34
34057 CHISINAU 110 1 MOLDOVA 2 1,0115 1,64
34060 HANCESTI 110 1 MOLDOVA 1 0,9990 -1,5
34061 CHISINAU 330 1 MOLDOVA 1 1,0045 -1,55
34062 STRASENI 330 1 MOLDOVA 1 1,0004 -1,6
34112 CHISINAU 35 1 MOLDOVA 1 1,0107 1,64
36005 BESARABEASCA 110 1 MOLDOVA 2 0,9831 -3,81
36012 ZARNESTI 110 1 MOLDOVA 1 0,9911 -6,89
36023 COMRAT 110 1 MOLDOVA 1 0,9809 -4,94
36025 LEOVO 110 1 MOLDOVA 1 0,9785 -4,29
36028 TARECKLIA 110 1 MOLDOVA 1 1,0065 -5,34
36031 CIADYR 110 1 MOLDOVA 2 0,9808 -6,42
36032 CIMISLIA 110 1 MOLDOVA 2 0,9910 -2,05
36038 VULCANESTI 110 1 MOLDOVA 1 1,0180 -5,36
36046 VULCANESTI 400 1 MOLDOVA 1 1,0294 -2,8
36110 VULCANESTI 35 1 MOLDOVA 1 1,0184 -5,36
70530 UKOTOVSK 330 2 UKRAINE 1 0,9966 -3,79
70544 UBOLGR 110 2 UKRAINE 1 1,0180 -5,36
70805 UDSGEC81 330 2 UKRAINE 2 1,0455 3,39
70822 ULDTEC81 330 2 UKRAINE 2 1,0455 -0,11
Table F-2 Branch Data
From
Bus
Number From Bus Name
To Bus
Number To Bus Name Id Line R (pu) Line X (pu) Charging (pu)
In
Service3
Rate A (I as
MVA)
30100 MGRAS 330,00 34061 CHISINAU 330,00 1 0,0018 0,0156 0,000 1 0
30100 MGRAS 330,00 70530 UKOTOVSK 330,00 1 0,0074 0,0453 0,000 1 0
30120 MGRAS 400,00 36046 VULCANESTI 400,00 15 0,0022 0,0294 0,011 1 1964
32049 BALTSI 330,00 34062 STRASENI 330,00 1 0,0051 0,0328 0,000 1 0
32049 BALTSI 330,00 70805 UDSGEC81 330,00 1 0,0042 0,0346 0,000 1 0
34057 CHISINAU 110,00 34060 HANCESTI 110,00 3 0,1334 0,2847 0,000 1 84,8
34057 CHISINAU 110,00 36005 BESARABEASCA110,00 1 0,4353 1,0124 0,000 1 84,8
34057 CHISINAU 110,00 36032 CIMISLIA 110,00 2 0,1609 0,4218 0,000 1 97,2
34060 HANCESTI 110,00 36025 LEOVO 110,00 6 0,4729 0,8034 0,000 1 72,4
34061 CHISINAU 330,00 34062 STRASENI 330,00 1 0,0020 0,0131 0,000 1 0
36005 BESARABEASCA110,00 36023 COMRAT 110,00 4 0,1982 0,3367 0,000 1 72,4
36012 ZARNESTI 110,00 36023 COMRAT 110,00 10 0,4599 0,8911 0,000 1 72,4
36012 ZARNESTI 110,00 36038 VULCANESTI 110,00 14 0,4285 0,8097 0,000 1 72,4
36023 COMRAT 110,00 36025 LEOVO 110,00 7 0,2192 0,3723 0,000 1 72,4
36023 COMRAT 110,00 36028 TARECKLIA 110,00 9 0,2721 0,5901 0,000 1 85,8
36023 COMRAT 110,00 36031 CIADYR 110,00 8 0,3312 0,7065 0,000 1 84,8
36023 COMRAT 110,00 36032 CIMISLIA 110,00 5 0,1431 0,3752 0,000 1 97,2
36028 TARECKLIA 110,00 36031 CIADYR 110,00 11 0,2243 0,4786 0,000 0 84,8
36028 TARECKLIA 110,00 36038 VULCANESTI 110,00 13 0,1489 0,3177 0,000 1 84,8
36031 CIADYR 110,00 36038 VULCANESTI 110,00 12 0,3249 0,6896 0,000 1 84,8
36038 VULCANESTI 110,00 70544 UBOLGR 110,00 1 0,0000 0,0001 0,000 1 0
70530 UKOTOVSK 330,00 70822 ULDTEC81 330,00 1 0,0041 0,0332 0,000 1 0
70805 UDSGEC81 330,00 70822 ULDTEC81 330,00 1 0,0071 0,0564 0,000 1 0
2 1 stands for load bus, 2 for generator bus and 3 is the swing bus
3 1 states in service and 0 out of service
F-3
Table F-3 Machine Data
Bus Number Bus Name Id Code VSched (pu) Pgen (MW)
Pmax
(MW)
Pmin
(MW) Qgen (Mvar)
Qmax
(Mvar)
Qmin
(Mvar)
Mbase
(MVA)
30100 MGRAS 330,00 1 3 1,0455 703,054 2520 0 442,6036 2000 50 100
32049 BALTSI 330,00 1 2 1 34 40 0 5 50 5 100
34057 CHISINAU 110,00 1 2 1 234 240 0 20 180 20 100
36005 BESARABEASCA110,00 1 2 1 0 9999 -9999 0 0 0 100
36012 ZARNESTI 110,00 1 1 1 0 9999 -9999 0 0 0 100
36025 LEOVO 110,00 1 1 1 0 9999 -9999 0 0 0 100
36031 CIADYR 110,00 1 2 1 0 9999 -9999 0 0 0 100
36032 CIMISLIA 110,00 1 2 1 0 9999 -9999 0 0 0 100
70805 UDSGEC81 330,00 1 2 1,0455 326 0 0 83,6194 200 -200 100
70822 ULDTEC81 330,00 1 2 1,0455 102 9999 -9999 151,1422 9999 -9999 100
Table F-4 Plant Data
Bus Number Bus Name Code PGen QGen QMax QMin VSched (pu) Voltage (pu) RMPCT
30100 MGRAS 330,00 3 703,1 442,6 2000 50 1,0455 1,0455 100
32049 BALTSI 330,00 2 34 5 50 5 1 1,0079 100
34057 CHISINAU 110,00 2 234 20 180 20 1 1,0115 100
36005 BESARABEASCA110,00 2 0 0 0 0 1 0,9831 100
36012 ZARNESTI 110,00 1 0 0 0 0 1 0,9911 100
36025 LEOVO 110,00 1 0 0 0 0 1 0,9785 100
36031 CIADYR 110,00 2 0 0 0 0 1 0,9808 100
36032 CIMISLIA 110,00 2 0 0 0 0 1 0,991 100
70805 UDSGEC81 330,00 2 326 83,6 200 -200 1,0455 1,0455 100
70822 ULDTEC81 330,00 2 102 151,1 9999 -9999 1,0455 1,0455 100
Table F-5 Load Data
Bus Number Bus Name Id Area Number/Name Pload (MW) Qload (Mvar)
30100 MGRAS 330,00 1 1 MOLDOVA 220 70
32049 BALTSI 330,00 1 1 MOLDOVA 171 70
34060 HANCESTI 110,00 1 1 MOLDOVA 6 0,6
34061 CHISINAU 330,00 1 1 MOLDOVA 391 220
34062 STRASENI 330,00 1 1 MOLDOVA 87 36
36005 BESARABEASCA110,00 1 1 MOLDOVA 4,2 0,5
36012 ZARNESTI 110,00 1 1 MOLDOVA 6,4 -1,3
36023 COMRAT 110,00 1 1 MOLDOVA 13,8 1,5
36025 LEOVO 110,00 1 1 MOLDOVA 3,5 0,9
36028 TARECKLIA 110,00 1 1 MOLDOVA 0,6 -1
36031 CIADYR 110,00 1 1 MOLDOVA 7,1 1,9
36032 CIMISLIA 110,00 1 1 MOLDOVA 2,4 0,4
36038 VULCANESTI 110,00 1 1 MOLDOVA 29,2 -12,4
70530 UKOTOVSK 330,00 1 2 UKRAINE 380 189
70544 UBOLGR 110,00 1 1 UKRAINE 64 24,2
Table F-6 Switched Shunt Data
Bus Number Bus Name
In Service Control Mode
Adjustment Method Vhi (pu) Vlo (pu)
Contributed Vars (%) VSC Name
Blk 1 Steps
Blk 1 Bstep (Mvar)
30195 MGRAS 35,000 0
Discrete, cntr voltage (1)
Sequential input order (0) 1,1 0,95 100 None 6 -30
36046 VULCANESTI 400,00 0
Discrete, cntr voltage (1)
Sequential input order (0) 1,1 0,95 100 None 3 -55
Table F-7 Three Winding Data
From
Bus
Numbe
r
From Bus
Name
To Bus
Numbe
r
To Bus
Name
Last Bus
Numbe
r
Last Bus
Name
W1-2
R (pu)
W1-2
X (pu)
W2-3
R (pu)
W2-3
X (pu)
W3-1
R (pu)
W3-1
X (pu)
Magnetizin
g G (pu or
watts)
Magnetizin
g B (pu)
F-4
30120
MGRAS
400,00 30100
MGRAS
330,00 30195
MGRAS
35,000
0,000
4
0,022
2
0,000
1
0,039
4
0,000
1
0,040
3 0,0003 -0,0030
36038
VULCANEST
I 110,00 36110
VULCANEST
I 35,000 36046
VULCANEST
I 400,00
0,000
8
0,036
9
0,001
3
0,082
5
0,001
3
0,045
7 0,0010 -0,0050
34060
HANCESTI
110,00 34062
STRASENI
330,00 1 35
0,000
8
0,029
7
0,001
5
0,093
9
0,001
5
0,064
3 0,0010 -0,0050
34057
CHISINAU
110,00 34061
CHISINAU
330,00 34112
CHISINAU
35,000
0,000
8
0,029
7
0,001
5
0,093
9
0,001
5
0,064
3 0,0010 -0,0050
Table F-8 Winding Data, MGRAS
Bus
Number Bus Name Winding
Rate A
(MVA)
Control
Mode
Auto
Adjust
Rmax (ratio
or angle)
Rmin (ratio
or angle)
Vmax (pu, kV
MW, or Mvar)
Vmin (pu, kV
MW, or Mvar)
Tap
Positions
30120 MGRAS 400,00 1 420 Voltage 1 1,1 0,9 1,05 0,95 15
30100 MGRAS 330,00 2 420 Voltage 1 1,1 0,9 1,05 0,95 15
30195 MGRAS 35,000 3 420 Voltage 1 1,1 0,9 1,05 0,95 15
Table F-9 Winding Data, Vulcanesti
Bus
Number Bus Name Winding
Rate A
(MVA)
Control
Mode
Auto
Adjust
Rmax (ratio
or angle)
Rmin (ratio
or angle)
Vmax (pu, kV
MW, or Mvar)
Vmin (pu, kV
MW, or Mvar)
Tap
Positions
36038 VULCANESTI 110,00 1 500 Voltage 1 1,1 0,9 1,05 0,95 15
36110 VULCANESTI 35,000 2 500 Voltage 1 1,1 0,9 1,05 0,95 15
36046 VULCANESTI 400,00 3 500 Voltage 1 1,1 0,9 1,05 0,95 15
Table F-10 Winding Data, Hancesti-Straseni
Bus
Number Bus Name Winding
Rate A
(MVA)
Control
Mode
Auto
Adjust
Rmax (ratio
or angle)
Rmin (ratio
or angle)
Vmax (pu, kV
MW, or Mvar)
Vmin (pu, kV
MW, or Mvar)
Tap
Positions
34060 HANCESTI 110,00 1 400 Voltage 1 1,1 0,9 1,05 0,95 15
34062 STRASENI 330,00 2 400 Voltage 1 1,1 0,9 1,05 0,95 15
1 35 3 400 Voltage 1 1,1 0,9 1,05 0,95 15
Table F-11 Winding Data, Chisinau
Bus
Number Bus Name Winding
Rate A
(MVA)
Control
Mode
Auto
Adjust
Rmax (ratio
or angle)
Rmin (ratio
or angle)
Vmax (pu, kV
MW, or Mvar)
Vmin (pu, kV
MW, or Mvar)
Tap
Positions
34057 CHISINAU 110,00 1 400 Voltage 1 1,1 0,9 1,05 0,95 15
34061 CHISINAU 330,00 2 400 Voltage 1 1,1 0,9 1,05 0,95 15
34112 CHISINAU 35,000 3 400 Voltage 1 1,1 0,9 1,05 0,95 15
G-1
Appendix G General Python Script – executing the contingency analysis
#mainScript takes five inputs; each representing a generator output in MW. mainScript also returns a value #stating if violations have
occurred
def mainScript(genA, genB, genC, genD, genE):
#Generator names and power outputs
windBusA = 36005
windBusB = 36012
windBusC = 36025
windBusD = 36031
windBusE = 36032
runNum=('#',genA,' & ', genB, ' [MW] at Wind Generators ', windBusA, windBusB)
outNum = str(runNum) #outNum is the output text defineing the increase
#Changing the wind generator output (MW)
id = "1" #Machine identifier
intgar = [] #Owner number, array of 4 elements i.e. 4 different
#owner (no input)
realarA = genA #Array of 16 elements where the first element is the
#machine active power output
realarB = genB
realarC = genC
realarD = genD
realarE = genE
ierr = psspy.machine_data(windBusA,id,intgar,realarA)
ierr = psspy.machine_data(windBusB,id,intgar,realarB)
ierr = psspy.machine_data(windBusC,id,intgar,realarC)
ierr = psspy.machine_data(windBusD,id,intgar,realarD)
ierr = psspy.machine_data(windBusE,id,intgar,realarE)
#Creating a file to store the ac-reports
islct = 2 #Virtual devic selector; 1-standard destination, 2,3,4,5-
#output to file, printer, progress device, report device, 6-
#no output
filarg = "reportTemp.txt" #Report file name (output)
options = []
options.append(0) #1: 0-open with carriage control format and overwrite
#existing files, 1-open with list format, 2-open file for
#append
options.append(0) #2: 0-printer option only, number of copies
ierr = psspy.report_output(islct, filarg, options)
if ierr>0:
f = open('testIerr.txt','a')
out = 'Error with creating the the temporary report file with generator
levels: ',genA, genB, genC, genD, genE, ' error num: ', ierr
f.write(str(out))
f.write('\n')
f.close()
a=2
return a
#Solution for the new base case
options = []
options.append(1) #1: Tap adjustment; 0-disabled, 1-enable, 2-direct adjustment
options.append(0) #2: Area interchange adjustment; 0-disabled, 1-enabled using tie line flows, 2- enabled using tie line flows and loads
options.append(0) #3: Phase shift adjustment; 0-disabled, 1-enable
options.append(1) #4: Dc tap adjustment; 0-disabled, 1-enable
options.append(0) #5: Switched shunt adjustment; 0-disabled, 1-enable
options.append(1) #6: Flat start; 0-no flat start, 1-flat start
G-2
options.append(0) #7: Var limit; 0-apply var limits immediatly, >0-apply var limits on iteration n, -1-ignor var limits
options.append(0) #8: Non-divergent solution; 0-disable, 1-enable
ierr = psspy.fnsl(options)
if ierr>0:
f = open('testIerr.txt','a')
out = 'Error with solving the new base case at generator levels: ',genA, genB, genC, genD, genE, ' error num: ', ierr
f.write(str(out))
f.write('\n')
f.close()
a=2
return a
#Creates a .dfx output file based on existing .sub, .mon and .con files
ierr = psspy.dfax(1, 'Sub', 'Mon', 'Cont', 'Dfx')
if ierr>0:
f = open('testIerr.txt','a')
out = 'Error with creating the .dfx file at generator levels: ',genA, genB, genC, genD, genE, ' error num: ', ierr
f.write(str(out))
f.write('\n')
f.close()
a=2
return a
#Executes a accc Contingency analys with the output file Accc.acc
tol = None # Mismatch tolerance TOLN by default
options = [] # Seven array element for specifying solution options
options.append(0) #1: Tap adjustment; 0-disable, 1-enable, 2-direct adjustment
options.append(0) #2: Area interchange adjustment; 0-disabled, 1-enabled using tie line flows, 2- enabled using tie line flows and loads
options.append(0) #3: Phase shift adjustment; 0-disabled, 1-enable
options.append(0) #4: Dc tap adjustment; 0-disabled, 1-enable
options.append(0) #5: Switched shunt adjustment; 0-disabled, 1-enable, 2-enable continuous mode, disable discrete mode
options.append(1) #6: Solution method; 0-FDNS, 1-FNSL, 2-optimized FDNS
options.append(1) #7: Non-divergent solution; 0-disable, 1-enable
dfxfile = 'Dfx' # Imports .dfx file
accfile = 'Accc' # Output file
ierr = psspy.accc(tol,options,dfxfile,accfile)
if ierr>0:
f = open('testIerr.txt','a')
out = 'Error with the contingency solution at generator levels: ',genA, genB, genC, genD, genE, ' error num: ', ierr
f.write(str(out))
f.write('\n')
f.close()
a=2
return a
#Executes the ac-report based on the contingency and stores it in the report file
STATUS=[]
STATUS.append(0) #1: Report form; 0-spreadsheet overload report, 1-spreadsheet loading table, 2-avaiable capacity table, 4,5
#and 6-non-spreadsheet reports
STATUS.append(1) #2: Base case rating; 1-rate A, 2-rate B, 3-rate C
STATUS.append(1) #3: Contingency case rating; 1-rate A, 2-rate B, 3-rate C
STATUS.append(0) #4: Exclude interfaces from report; 0-no, 1-yes
STATUS.append(1) #5: Run voltage limit check; 0-no, 1-yes
STATUS.append(0) #6: Only if #1 = 0 or 3; 0-no, 1-yes
STATUS.append(0) #7: Only if #1 = 0 or 3; 0-no, 1-yes
STATUS.append(0) #8: Exclude cases with no overloads from non-spreadsheet reports; only if #1 = 3,4,5 or 6; 0-no, 1-yes
STATUS.append(0) #9: Report post-tripping action solutions; 0-no, 1-yes
interval=[] # Filtering criterias
interval.append(0) #1: Number of low voltage range violations
interval.append(0) #2: Number of high voltage range violations
interval.append(0) #3: Number of voltage deviation violations
interval.append(0) #4: Number of buses in the largest disconnected island
G-3
realval=[]
realval.append(0.5) #1: Bus mismatch converged tolerance (MW or MVA)
realval.append(0.5) #2: Ssystem mismatch converged tolerandce (MVA)
realval.append(100) #3: % of flow rating, use only when STATUS#1 is 0,3 or 4
realval.append(0) #4: Minimum contingency case flow change
realval.append(0) #5: Minimum contingency case percent loading increas
realval.append(0) #6: Minimum contingency case voltage change
acccOutFile='Accc.acc'
ierr = psspy.accc_single_run_report_2(STATUS,interval, realval,acccOutFile)
if ierr>0:
f = open('testIerr.txt','a')
out = 'Error with writing the report file for contingency solution at generator levels: ',genA, genB, genC, genD, genE, '
error num: ', ierr
f.write(str(out))
f.write('\n')
f.close()
a=2
return a
#Checking violations and returning true or false
f = open('reportTemp.txt','r')
data_list = f.readlines()
a = len(data_list[27])
b = len(data_list[30])
f.close()
if a==1 and b==1:
return a
else:
a=2
return a
H-1
Appendix H Python Script – Scenario I
#oneByOne increases one specific generator's output and
#stores values not generating violation in a report file
def oneByOne():
file = open('Run1GenA.txt','w') #Change file name to get separate reports for different generators
genA = 0
genB = 0
genC = 0
genD = 0
genE = 0
generators = [genA, genB, genC, genD, genE]
for i in range (0,103,1):
violation = mainScript(genA, genB, genC, genD, genE)
if violation == 1:
genA = i #Change to other generators to check their maximum value
else:
break
violation = mainScript(genA, genB, genC, genD, genE)
file.write('Violation with generators set at: \n\n')
out = 'genA = ',genA,' genB = ',genB,' genC = ',genC,' genD = ',genD,' genE = ',genE
file.write(str(out))
file.write('\n')
fTemp = open('reportTemp.txt','r')
flag = False
fTemp.close()
fTemp = open('reportTemp.txt','r')
for line in fTemp:
if "MULTI-SECTION LINE" in line:
file.write('\n')
file.write(line)
flag = True
elif flag:
file.write(line.strip())
file.write('\n')
if "CONTINGENCY LEGEND" in line:
flag = False
fTemp.close()
file.close()
I-1
Appendix I Python Script – Scenario II, Monte Carlo Simulation
def allTogether():
#f = open('Run1Random.txt','w')
#f2 = open('Run1Max.txt','w')
#fA = open('Run1MaxGenA.txt','w')
#fB = open('Run1MaxGenB.txt','w')
#fC = open('Run1MaxGenC.txt','w')
#fD = open('Run1MaxGenD.txt','w')
#fE = open('Run1MaxGenE.txt','w')
n = open('testall.txt','w')
n1 = open('testallA.txt','w')
n2 = open('testallB.txt','w')
n3 = open('testallC.txt','w')
n4 = open('testallD.txt','w')
n5 = open('testallE.txt','w')
maxGen=0
for i in range (1,1000):
count = open('testRaknare.txt','w') #counter to folow the iterations
count.write(str(i))
count.write('\n')
count.close
genA = 28+random.randrange(0,5) #The random generator,
genB = 10+random.randrange(0,5) #values needs to be changed
genC = 28+random.randrange(0,5) #to use different intervals.
genD = 83+random.randrange(0,5)
genE = 98+random.randrange(0,5)
violation = mainScript(genA, genB, genC, genD, genE)
if violation == 1: #if=1 there is no violation
maxGen = genA+genB+genC+genD+genE
out = 'genA = ',genA,' genB = ',genB,' genC = ',genC,' genD = ',genD,' genE =
',genE
n.write(str(maxGen))
n.write('\n')
n1.write(str(genA))
n1.write('\n')
n2.write(str(genB))
n2.write('\n')
n3.write(str(genC))
n3.write('\n')
n4.write(str(genD))
n4.write('\n')
n5.write(str(genE))
n5.write('\n')
J-1
Appendix J Base Case - Contingency Loading Report
ACCC LOADING REPORT: MONITORED BRANCHES AND INTERFACES USING RATING SET A % LOADING VALUES ARE % MVA FOR TRANSFORMERS AND % CURRENT FOR NON-TRANSFORMER BRANCHES INCLUDES VOLTAGE REPORT AC CONTINGENCY RESULTS FILE: C:\Users\Joel\Desktop\Testfiler\CONTINGENCYBACECASE.acc DISTRIBUTION FACTOR FILE: C:\Users\Joel\Desktop\Testfiler\Dfx.dfx SUBSYSTEM DESCRIPTION FILE: C:\Users\Joel\Desktop\Testfiler\Sub.sub MONITORED ELEMENT FILE: C:\Users\Joel\Desktop\Testfiler\Mon.mon CONTINGENCY DESCRIPTION FILE: C:\Users\Joel\Desktop\Testfiler\Cont.con **PERCENT LOADING UNITS** %MVA FOR TRANSFORMERS % I FOR NON-TRANSFORMER BRANCHES **OPTIONS USED IN CONTINGENCY ANALYSIS** Solution engine: Full Newton-Raphson (FNSL) Solution options Tap adjustment: Stepping Area interchange control: Disable Phase shift adjustment: Disable Dc tap adjustment: Enable Switch shunt adjustment: Enable all Non diverge: Disable Mismatch tolerance (MW ): 0.5 Dispatch mode: Disable <---------------- MULTI-SECTION LINE ----------------> <----------------- MONITORED BRANCH -----------------> CONTINGENCY RATING FLOW % 34057*CHISINAU 110.00 34060 HANCESTI 110.00 3 BASE CASE 84.8 18.2 21.1 34057*CHISINAU 110.00 36005 BESARABEASCA110.00 1 BASE CASE 84.8 9.1 10.5 34057*CHISINAU 110.00 36032 CIMISLIA 110.00 2 BASE CASE 97.2 15.1 15.4 34060*HANCESTI 110.00 36025 LEOVO 110.00 6 BASE CASE 72.4 5.9 8.1 36005*BESARABEASCA110.00 36023 COMRAT 110.00 4 BASE CASE 72.4 4.9 6.9 36012*ZARNESTI 110.00 36023 COMRAT 110.00 10 BASE CASE 72.4 3.5 4.8 36012 ZARNESTI 110.00 36038*VULCANESTI 110.00 14 BASE CASE 72.4 4.1 5.6 36023 COMRAT 110.00 36025*LEOVO 110.00 7 BASE CASE 72.4 2.5 3.5 36023 COMRAT 110.00 36028*TARECKLIA 110.00 9 BASE CASE 85.8 3.9 4.5 36023*COMRAT 110.00 36031 CIADYR 110.00 8 BASE CASE 84.8 3.2 3.9 36023 COMRAT 110.00 36032*CIMISLIA 110.00 5 BASE CASE 97.2 12.5 12.9 36028 TARECKLIA 110.00 36038*VULCANESTI 110.00 13 BASE CASE 84.8 3.1 3.6 36031 CIADYR 110.00 36038*VULCANESTI 110.00 12 BASE CASE 84.8 5.4 6.3 34057*CHISINAU 110.00 34060 HANCESTI 110.00 3 SINGLE 1 84.8 0.0 0.0 34057*CHISINAU 110.00 36005 BESARABEASCA110.00 1 SINGLE 1 84.8 9.3 10.8 34057*CHISINAU 110.00 36032 CIMISLIA 110.00 2 SINGLE 1 97.2 15.5 15.8 34060*HANCESTI 110.00 36025 LEOVO 110.00 6 SINGLE 1 72.4 5.6 7.6 36005*BESARABEASCA110.00 36023 COMRAT 110.00 4 SINGLE 1 72.4 5.2 7.2 36012*ZARNESTI 110.00 36023 COMRAT 110.00 10 SINGLE 1 72.4 3.5 4.9 36012 ZARNESTI 110.00 36038*VULCANESTI 110.00 14 SINGLE 1 72.4 4.1 5.6 36023 COMRAT 110.00 36025*LEOVO 110.00 7 SINGLE 1 72.4 2.0 2.8 36023 COMRAT 110.00 36028*TARECKLIA 110.00 9 SINGLE 1 85.8 4.0 4.6 36023*COMRAT 110.00 36031 CIADYR 110.00 8 SINGLE 1 84.8 3.3 3.9 36023 COMRAT 110.00 36032*CIMISLIA 110.00 5 SINGLE 1 97.2 12.9 13.4 36028 TARECKLIA 110.00 36038*VULCANESTI 110.00 13 SINGLE 1 84.8 3.2 3.7 36031 CIADYR 110.00 36038*VULCANESTI 110.00 12 SINGLE 1 84.8 5.4 6.3
J-2
34057*CHISINAU 110.00 34060 HANCESTI 110.00 3 SINGLE 2 84.8 18.8 21.9 34057*CHISINAU 110.00 36005 BESARABEASCA110.00 1 SINGLE 2 84.8 0.0 0.0 34057*CHISINAU 110.00 36032 CIMISLIA 110.00 2 SINGLE 2 97.2 18.1 18.4 34060*HANCESTI 110.00 36025 LEOVO 110.00 6 SINGLE 2 72.4 7.6 10.4 36005 BESARABEASCA110.00 36023*COMRAT 110.00 4 SINGLE 2 72.4 4.0 5.7 36012*ZARNESTI 110.00 36023 COMRAT 110.00 10 SINGLE 2 72.4 2.7 3.7 36012 ZARNESTI 110.00 36038*VULCANESTI 110.00 14 SINGLE 2 72.4 5.1 6.9 36023 COMRAT 110.00 36025*LEOVO 110.00 7 SINGLE 2 72.4 4.2 5.9 36023 COMRAT 110.00 36028*TARECKLIA 110.00 9 SINGLE 2 85.8 4.4 5.1 36023 COMRAT 110.00 36031*CIADYR 110.00 8 SINGLE 2 84.8 2.0 2.4 36023 COMRAT 110.00 36032*CIMISLIA 110.00 5 SINGLE 2 97.2 15.3 15.9 36028 TARECKLIA 110.00 36038*VULCANESTI 110.00 13 SINGLE 2 84.8 4.1 4.8 36031 CIADYR 110.00 36038*VULCANESTI 110.00 12 SINGLE 2 84.8 6.4 7.4 34057*CHISINAU 110.00 34060 HANCESTI 110.00 3 SINGLE 3 84.8 19.5 22.7 34057*CHISINAU 110.00 36005 BESARABEASCA110.00 1 SINGLE 3 84.8 12.4 14.5 34057*CHISINAU 110.00 36032 CIMISLIA 110.00 2 SINGLE 3 97.2 0.0 0.0 34060*HANCESTI 110.00 36025 LEOVO 110.00 6 SINGLE 3 72.4 9.4 12.8 36005*BESARABEASCA110.00 36023 COMRAT 110.00 4 SINGLE 3 72.4 8.0 11.4 36012*ZARNESTI 110.00 36023 COMRAT 110.00 10 SINGLE 3 72.4 2.2 3.1 36012 ZARNESTI 110.00 36038*VULCANESTI 110.00 14 SINGLE 3 72.4 6.1 8.3 36023 COMRAT 110.00 36025*LEOVO 110.00 7 SINGLE 3 72.4 5.7 8.2 36023 COMRAT 110.00 36028*TARECKLIA 110.00 9 SINGLE 3 85.8 5.8 6.8 36023 COMRAT 110.00 36031*CIADYR 110.00 8 SINGLE 3 84.8 1.2 1.4 36023*COMRAT 110.00 36032 CIMISLIA 110.00 5 SINGLE 3 97.2 2.4 2.6 36028 TARECKLIA 110.00 36038*VULCANESTI 110.00 13 SINGLE 3 84.8 5.9 6.8 36031 CIADYR 110.00 36038*VULCANESTI 110.00 12 SINGLE 3 84.8 7.6 8.8 34057*CHISINAU 110.00 34060 HANCESTI 110.00 3 SINGLE 4 84.8 17.3 20.1 34057*CHISINAU 110.00 36005 BESARABEASCA110.00 1 SINGLE 4 84.8 10.1 11.8 34057*CHISINAU 110.00 36032 CIMISLIA 110.00 2 SINGLE 4 97.2 17.0 17.3 34060*HANCESTI 110.00 36025 LEOVO 110.00 6 SINGLE 4 72.4 0.0 0.0 36005*BESARABEASCA110.00 36023 COMRAT 110.00 4 SINGLE 4 72.4 5.9 8.3 36012*ZARNESTI 110.00 36023 COMRAT 110.00 10 SINGLE 4 72.4 2.9 4.1 36012 ZARNESTI 110.00 36038*VULCANESTI 110.00 14 SINGLE 4 72.4 4.8 6.6 36023*COMRAT 110.00 36025 LEOVO 110.00 7 SINGLE 4 72.4 3.5 4.9 36023 COMRAT 110.00 36028*TARECKLIA 110.00 9 SINGLE 4 85.8 4.3 5.0 36023 COMRAT 110.00 36031*CIADYR 110.00 8 SINGLE 4 84.8 2.4 2.9 36023 COMRAT 110.00 36032*CIMISLIA 110.00 5 SINGLE 4 97.2 14.2 14.8 36028 TARECKLIA 110.00 36038*VULCANESTI 110.00 13 SINGLE 4 84.8 3.9 4.5 36031 CIADYR 110.00 36038*VULCANESTI 110.00 12 SINGLE 4 84.8 6.2 7.1 34057*CHISINAU 110.00 34060 HANCESTI 110.00 3 SINGLE 5 84.8 18.5 21.6 34057*CHISINAU 110.00 36005 BESARABEASCA110.00 1 SINGLE 5 84.8 4.2 4.9 34057*CHISINAU 110.00 36032 CIMISLIA 110.00 2 SINGLE 5 97.2 16.7 17.0 34060*HANCESTI 110.00 36025 LEOVO 110.00 6 SINGLE 5 72.4 6.8 9.3
J-3
36005*BESARABEASCA110.00 36023 COMRAT 110.00 4 SINGLE 5 72.4 0.0 0.0 36012*ZARNESTI 110.00 36023 COMRAT 110.00 10 SINGLE 5 72.4 2.9 4.1 36012 ZARNESTI 110.00 36038*VULCANESTI 110.00 14 SINGLE 5 72.4 4.6 6.2 36023 COMRAT 110.00 36025*LEOVO 110.00 7 SINGLE 5 72.4 3.5 4.9 36023 COMRAT 110.00 36028*TARECKLIA 110.00 9 SINGLE 5 85.8 3.8 4.4 36023*COMRAT 110.00 36031 CIADYR 110.00 8 SINGLE 5 84.8 2.5 3.0 36023 COMRAT 110.00 36032*CIMISLIA 110.00 5 SINGLE 5 97.2 14.1 14.6 36028 TARECKLIA 110.00 36038*VULCANESTI 110.00 13 SINGLE 5 84.8 3.3 3.9 36031 CIADYR 110.00 36038*VULCANESTI 110.00 12 SINGLE 5 84.8 5.8 6.7 34057*CHISINAU 110.00 34060 HANCESTI 110.00 3 SINGLE 6 84.8 18.2 21.2 34057*CHISINAU 110.00 36005 BESARABEASCA110.00 1 SINGLE 6 84.8 8.6 10.1 34057*CHISINAU 110.00 36032 CIMISLIA 110.00 2 SINGLE 6 97.2 14.4 14.6 34060*HANCESTI 110.00 36025 LEOVO 110.00 6 SINGLE 6 72.4 5.5 7.6 36005*BESARABEASCA110.00 36023 COMRAT 110.00 4 SINGLE 6 72.4 4.4 6.2 36012*ZARNESTI 110.00 36023 COMRAT 110.00 10 SINGLE 6 72.4 0.0 0.0 36012 ZARNESTI 110.00 36038*VULCANESTI 110.00 14 SINGLE 6 72.4 6.7 9.0 36023 COMRAT 110.00 36025*LEOVO 110.00 7 SINGLE 6 72.4 2.0 2.8 36023 COMRAT 110.00 36028*TARECKLIA 110.00 9 SINGLE 6 85.8 4.5 5.2 36023 COMRAT 110.00 36031*CIADYR 110.00 8 SINGLE 6 84.8 3.8 4.5 36023 COMRAT 110.00 36032*CIMISLIA 110.00 5 SINGLE 6 97.2 11.7 12.2 36028 TARECKLIA 110.00 36038*VULCANESTI 110.00 13 SINGLE 6 84.8 3.6 4.1 36031 CIADYR 110.00 36038*VULCANESTI 110.00 12 SINGLE 6 84.8 5.4 6.2 34057*CHISINAU 110.00 34060 HANCESTI 110.00 3 SINGLE 7 84.8 18.1 21.1 34057*CHISINAU 110.00 36005 BESARABEASCA110.00 1 SINGLE 7 84.8 9.6 11.2 34057*CHISINAU 110.00 36032 CIMISLIA 110.00 2 SINGLE 7 97.2 16.1 16.3 34060*HANCESTI 110.00 36025 LEOVO 110.00 6 SINGLE 7 72.4 6.6 9.0 36005*BESARABEASCA110.00 36023 COMRAT 110.00 4 SINGLE 7 72.4 5.3 7.5 36012 ZARNESTI 110.00 36023*COMRAT 110.00 10 SINGLE 7 72.4 6.5 9.2 36012*ZARNESTI 110.00 36038 VULCANESTI 110.00 14 SINGLE 7 72.4 0.0 0.0 36023 COMRAT 110.00 36025*LEOVO 110.00 7 SINGLE 7 72.4 3.1 4.3 36023 COMRAT 110.00 36028*TARECKLIA 110.00 9 SINGLE 7 85.8 4.5 5.3 36023 COMRAT 110.00 36031*CIADYR 110.00 8 SINGLE 7 84.8 2.6 3.2 36023 COMRAT 110.00 36032*CIMISLIA 110.00 5 SINGLE 7 97.2 13.3 13.9 36028 TARECKLIA 110.00 36038*VULCANESTI 110.00 13 SINGLE 7 84.8 4.0 4.6 36031 CIADYR 110.00 36038*VULCANESTI 110.00 12 SINGLE 7 84.8 6.2 7.1 34057*CHISINAU 110.00 34060 HANCESTI 110.00 3 SINGLE 8 84.8 17.8 20.7 34057*CHISINAU 110.00 36005 BESARABEASCA110.00 1 SINGLE 8 84.8 9.5 11.1 34057*CHISINAU 110.00 36032 CIMISLIA 110.00 2 SINGLE 8 97.2 15.9 16.1 34060*HANCESTI 110.00 36025 LEOVO 110.00 6 SINGLE 8 72.4 3.7 5.0 36005*BESARABEASCA110.00 36023 COMRAT 110.00 4 SINGLE 8 72.4 5.4 7.5 36012*ZARNESTI 110.00 36023 COMRAT 110.00 10 SINGLE 8 72.4 3.2 4.4 36012 ZARNESTI 110.00 36038*VULCANESTI 110.00 14 SINGLE 8 72.4 4.4 5.9 36023*COMRAT 110.00 36025 LEOVO 110.00 7 SINGLE 8 72.4 0.0 0.0
J-4
36023 COMRAT 110.00 36028*TARECKLIA 110.00 9 SINGLE 8 85.8 3.8 4.4 36023*COMRAT 110.00 36031 CIADYR 110.00 8 SINGLE 8 84.8 2.8 3.4 36023 COMRAT 110.00 36032*CIMISLIA 110.00 5 SINGLE 8 97.2 13.3 13.7 36028 TARECKLIA 110.00 36038*VULCANESTI 110.00 13 SINGLE 8 84.8 3.2 3.7 36031 CIADYR 110.00 36038*VULCANESTI 110.00 12 SINGLE 8 84.8 5.6 6.5 34057*CHISINAU 110.00 34060 HANCESTI 110.00 3 SINGLE 9 84.8 18.2 21.2 34057*CHISINAU 110.00 36005 BESARABEASCA110.00 1 SINGLE 9 84.8 9.1 10.6 34057*CHISINAU 110.00 36032 CIMISLIA 110.00 2 SINGLE 9 97.2 15.1 15.3 34060*HANCESTI 110.00 36025 LEOVO 110.00 6 SINGLE 9 72.4 6.1 8.4 36005*BESARABEASCA110.00 36023 COMRAT 110.00 4 SINGLE 9 72.4 4.7 6.7 36012*ZARNESTI 110.00 36023 COMRAT 110.00 10 SINGLE 9 72.4 3.8 5.3 36012 ZARNESTI 110.00 36038*VULCANESTI 110.00 14 SINGLE 9 72.4 4.6 6.2 36023 COMRAT 110.00 36025*LEOVO 110.00 7 SINGLE 9 72.4 2.4 3.5 36023*COMRAT 110.00 36028 TARECKLIA 110.00 9 SINGLE 9 85.8 0.0 0.0 36023 COMRAT 110.00 36031*CIADYR 110.00 8 SINGLE 9 84.8 3.4 4.1 36023 COMRAT 110.00 36032*CIMISLIA 110.00 5 SINGLE 9 97.2 12.3 12.9 36028*TARECKLIA 110.00 36038 VULCANESTI 110.00 13 SINGLE 9 84.8 1.2 1.4 36031 CIADYR 110.00 36038*VULCANESTI 110.00 12 SINGLE 9 84.8 6.1 7.1 34057*CHISINAU 110.00 34060 HANCESTI 110.00 3 SINGLE 10 84.8 18.2 21.2 34057*CHISINAU 110.00 36005 BESARABEASCA110.00 1 SINGLE 10 84.8 8.6 10.0 34057*CHISINAU 110.00 36032 CIMISLIA 110.00 2 SINGLE 10 97.2 14.3 14.5 34060*HANCESTI 110.00 36025 LEOVO 110.00 6 SINGLE 10 72.4 5.4 7.4 36005*BESARABEASCA110.00 36023 COMRAT 110.00 4 SINGLE 10 72.4 4.4 6.2 36012*ZARNESTI 110.00 36023 COMRAT 110.00 10 SINGLE 10 72.4 3.9 5.5 36012 ZARNESTI 110.00 36038*VULCANESTI 110.00 14 SINGLE 10 72.4 3.8 5.1 36023 COMRAT 110.00 36025*LEOVO 110.00 7 SINGLE 10 72.4 2.0 2.8 36023 COMRAT 110.00 36028*TARECKLIA 110.00 9 SINGLE 10 85.8 4.2 4.9 36023*COMRAT 110.00 36031 CIADYR 110.00 8 SINGLE 10 84.8 0.0 0.0 36023 COMRAT 110.00 36032*CIMISLIA 110.00 5 SINGLE 10 97.2 11.7 12.1 36028 TARECKLIA 110.00 36038*VULCANESTI 110.00 13 SINGLE 10 84.8 3.3 3.8 36031 CIADYR 110.00 36038*VULCANESTI 110.00 12 SINGLE 10 84.8 7.6 8.8 34057*CHISINAU 110.00 34060 HANCESTI 110.00 3 SINGLE 11 84.8 19.3 22.5 34057*CHISINAU 110.00 36005 BESARABEASCA110.00 1 SINGLE 11 84.8 11.9 13.8 34057*CHISINAU 110.00 36032 CIMISLIA 110.00 2 SINGLE 11 97.2 2.1 2.1 34060*HANCESTI 110.00 36025 LEOVO 110.00 6 SINGLE 11 72.4 8.7 11.9 36005*BESARABEASCA110.00 36023 COMRAT 110.00 4 SINGLE 11 72.4 7.5 10.6 36012*ZARNESTI 110.00 36023 COMRAT 110.00 10 SINGLE 11 72.4 2.2 3.1 36012 ZARNESTI 110.00 36038*VULCANESTI 110.00 14 SINGLE 11 72.4 5.7 7.8 36023 COMRAT 110.00 36025*LEOVO 110.00 7 SINGLE 11 72.4 5.2 7.4 36023 COMRAT 110.00 36028*TARECKLIA 110.00 9 SINGLE 11 85.8 5.2 6.0 36023 COMRAT 110.00 36031*CIADYR 110.00 8 SINGLE 11 84.8 1.4 1.6 36023*COMRAT 110.00 36032 CIMISLIA 110.00 5 SINGLE 11 97.2 0.0 0.0 36028 TARECKLIA 110.00 36038*VULCANESTI 110.00 13 SINGLE 11 84.8 5.1 5.9
J-5
36031 CIADYR 110.00 36038*VULCANESTI 110.00 12 SINGLE 11 84.8 7.1 8.2 34057*CHISINAU 110.00 34060 HANCESTI 110.00 3 SINGLE 12 84.8 18.2 21.2 34057*CHISINAU 110.00 36005 BESARABEASCA110.00 1 SINGLE 12 84.8 9.2 10.7 34057*CHISINAU 110.00 36032 CIMISLIA 110.00 2 SINGLE 12 97.2 15.3 15.6 34060*HANCESTI 110.00 36025 LEOVO 110.00 6 SINGLE 12 72.4 6.2 8.5 36005*BESARABEASCA110.00 36023 COMRAT 110.00 4 SINGLE 12 72.4 4.9 6.9 36012*ZARNESTI 110.00 36023 COMRAT 110.00 10 SINGLE 12 72.4 3.6 5.0 36012 ZARNESTI 110.00 36038*VULCANESTI 110.00 14 SINGLE 12 72.4 4.6 6.2 36023 COMRAT 110.00 36025*LEOVO 110.00 7 SINGLE 12 72.4 2.6 3.6 36023 COMRAT 110.00 36028*TARECKLIA 110.00 9 SINGLE 12 85.8 1.2 1.4 36023 COMRAT 110.00 36031*CIADYR 110.00 8 SINGLE 12 84.8 3.2 3.8 36023 COMRAT 110.00 36032*CIMISLIA 110.00 5 SINGLE 12 97.2 12.6 13.1 36028*TARECKLIA 110.00 36038 VULCANESTI 110.00 13 SINGLE 12 84.8 0.0 0.0 36031 CIADYR 110.00 36038*VULCANESTI 110.00 12 SINGLE 12 84.8 6.0 7.0 34057*CHISINAU 110.00 34060 HANCESTI 110.00 3 SINGLE 13 84.8 18.1 21.1 34057*CHISINAU 110.00 36005 BESARABEASCA110.00 1 SINGLE 13 84.8 9.6 11.2 34057*CHISINAU 110.00 36032 CIMISLIA 110.00 2 SINGLE 13 97.2 16.1 16.3 34060*HANCESTI 110.00 36025 LEOVO 110.00 6 SINGLE 13 72.4 6.7 9.2 36005*BESARABEASCA110.00 36023 COMRAT 110.00 4 SINGLE 13 72.4 5.2 7.4 36012*ZARNESTI 110.00 36023 COMRAT 110.00 10 SINGLE 13 72.4 3.3 4.6 36012 ZARNESTI 110.00 36038*VULCANESTI 110.00 14 SINGLE 13 72.4 5.0 6.8 36023 COMRAT 110.00 36025*LEOVO 110.00 7 SINGLE 13 72.4 3.0 4.3 36023 COMRAT 110.00 36028*TARECKLIA 110.00 9 SINGLE 13 85.8 5.2 6.0 36023*COMRAT 110.00 36031 CIADYR 110.00 8 SINGLE 13 84.8 7.4 8.9 36023 COMRAT 110.00 36032*CIMISLIA 110.00 5 SINGLE 13 97.2 13.3 13.8 36028 TARECKLIA 110.00 36038*VULCANESTI 110.00 13 SINGLE 13 84.8 4.6 5.4 36031*CIADYR 110.00 36038 VULCANESTI 110.00 12 SINGLE 13 84.8 0.0 0.0 MONITORED VOLTAGE REPORT: SYSTEM CONTINGENCY <-------- B U S --------> V-CONT V-INIT V-MAX V-MIN 'SUB ' RANGE BASE CASE 34057 CHISINAU 110.00 1.01261 1.01261 1.10000 0.90000 'SUB ' RANGE BASE CASE 34060 HANCESTI 110.00 1.01153 1.01153 1.10000 0.90000 'SUB ' RANGE BASE CASE 36005 BESARABEASCA110.00 0.98540 0.98540 1.10000 0.90000 'SUB ' RANGE BASE CASE 36012 ZARNESTI 110.00 0.99257 0.99257 1.10000 0.90000 'SUB ' RANGE BASE CASE 36023 COMRAT 110.00 0.98351 0.98351 1.10000 0.90000 'SUB ' RANGE BASE CASE 36025 LEOVO 110.00 0.98433 0.98433 1.10000 0.90000 'SUB ' RANGE BASE CASE 36028 TARECKLIA 110.00 1.00767 1.00767 1.10000 0.90000 'SUB ' RANGE BASE CASE 36031 CIADYR 110.00 0.98233 0.98233 1.10000 0.90000 'SUB ' RANGE BASE CASE 36032 CIMISLIA 110.00 0.99294 0.99294 1.10000 0.90000 'SUB ' RANGE BASE CASE 36038 VULCANESTI 110.00 1.01844 1.01844 1.10000 0.90000 'SUB ' RANGE SINGLE 1 34057 CHISINAU 110.00 1.01040 1.01261 1.10000 0.90000 'SUB ' RANGE SINGLE 1 34060 HANCESTI 110.00 1.01401 1.01153 1.10000 0.90000 'SUB ' RANGE SINGLE 1 36005 BESARABEASCA110.00 0.98447 0.98540 1.10000 0.90000 'SUB ' RANGE SINGLE 1 36012 ZARNESTI 110.00 0.99227 0.99257 1.10000 0.90000 'SUB ' RANGE SINGLE 1 36023 COMRAT 110.00 0.98303 0.98351 1.10000 0.90000 'SUB ' RANGE SINGLE 1 36025 LEOVO 110.00 0.98489 0.98433 1.10000 0.90000 'SUB ' RANGE SINGLE 1 36028 TARECKLIA 110.00 1.00742 1.00767 1.10000 0.90000 'SUB ' RANGE SINGLE 1 36031 CIADYR 110.00 0.98202 0.98233 1.10000 0.90000 'SUB ' RANGE SINGLE 1 36032 CIMISLIA 110.00 0.99152 0.99294 1.10000 0.90000 'SUB ' RANGE SINGLE 1 36038 VULCANESTI 110.00 1.01831 1.01844 1.10000 0.90000 'SUB ' RANGE SINGLE 2 34057 CHISINAU 110.00 1.01241 1.01261 1.10000 0.90000 'SUB ' RANGE SINGLE 2 34060 HANCESTI 110.00 1.01146 1.01153 1.10000 0.90000 'SUB ' RANGE SINGLE 2 36005 BESARABEASCA110.00 0.96797 0.98540 1.10000 0.90000 'SUB ' RANGE SINGLE 2 36012 ZARNESTI 110.00 0.98971 0.99257 1.10000 0.90000 'SUB ' RANGE SINGLE 2 36023 COMRAT 110.00 0.97764 0.98351 1.10000 0.90000 'SUB ' RANGE SINGLE 2 36025 LEOVO 110.00 0.97997 0.98433 1.10000 0.90000 'SUB ' RANGE SINGLE 2 36028 TARECKLIA 110.00 1.00561 1.00767 1.10000 0.90000 'SUB ' RANGE SINGLE 2 36031 CIADYR 110.00 0.97939 0.98233 1.10000 0.90000 'SUB ' RANGE SINGLE 2 36032 CIMISLIA 110.00 0.98902 0.99294 1.10000 0.90000 'SUB ' RANGE SINGLE 2 36038 VULCANESTI 110.00 1.01842 1.01844 1.10000 0.90000
J-6
'SUB ' RANGE SINGLE 3 34057 CHISINAU 110.00 1.01240 1.01261 1.10000 0.90000 'SUB ' RANGE SINGLE 3 34060 HANCESTI 110.00 1.01128 1.01153 1.10000 0.90000 'SUB ' RANGE SINGLE 3 36005 BESARABEASCA110.00 0.97301 0.98540 1.10000 0.90000 'SUB ' RANGE SINGLE 3 36012 ZARNESTI 110.00 0.98392 0.99257 1.10000 0.90000 'SUB ' RANGE SINGLE 3 36023 COMRAT 110.00 0.96711 0.98351 1.10000 0.90000 'SUB ' RANGE SINGLE 3 36025 LEOVO 110.00 0.97217 0.98433 1.10000 0.90000 'SUB ' RANGE SINGLE 3 36028 TARECKLIA 110.00 1.00111 1.00767 1.10000 0.90000 'SUB ' RANGE SINGLE 3 36031 CIADYR 110.00 0.97340 0.98233 1.10000 0.90000 'SUB ' RANGE SINGLE 3 36032 CIMISLIA 110.00 0.96196 0.99294 1.10000 0.90000 'SUB ' RANGE SINGLE 3 36038 VULCANESTI 110.00 1.01739 1.01844 1.10000 0.90000 'SUB ' RANGE SINGLE 4 34057 CHISINAU 110.00 1.01251 1.01261 1.10000 0.90000 'SUB ' RANGE SINGLE 4 34060 HANCESTI 110.00 1.01185 1.01153 1.10000 0.90000 'SUB ' RANGE SINGLE 4 36005 BESARABEASCA110.00 0.98078 0.98540 1.10000 0.90000 'SUB ' RANGE SINGLE 4 36012 ZARNESTI 110.00 0.98935 0.99257 1.10000 0.90000 'SUB ' RANGE SINGLE 4 36023 COMRAT 110.00 0.97730 0.98351 1.10000 0.90000 'SUB ' RANGE SINGLE 4 36025 LEOVO 110.00 0.96630 0.98433 1.10000 0.90000 'SUB ' RANGE SINGLE 4 36028 TARECKLIA 110.00 1.00524 1.00767 1.10000 0.90000 'SUB ' RANGE SINGLE 4 36031 CIADYR 110.00 0.97901 0.98233 1.10000 0.90000 'SUB ' RANGE SINGLE 4 36032 CIMISLIA 110.00 0.98916 0.99294 1.10000 0.90000 'SUB ' RANGE SINGLE 4 36038 VULCANESTI 110.00 1.01804 1.01844 1.10000 0.90000 'SUB ' RANGE SINGLE 5 34057 CHISINAU 110.00 1.01239 1.01261 1.10000 0.90000 'SUB ' RANGE SINGLE 5 34060 HANCESTI 110.00 1.01154 1.01153 1.10000 0.90000 'SUB ' RANGE SINGLE 5 36005 BESARABEASCA110.00 0.98951 0.98540 1.10000 0.90000 'SUB ' RANGE SINGLE 5 36012 ZARNESTI 110.00 0.99281 0.99257 1.10000 0.90000 'SUB ' RANGE SINGLE 5 36023 COMRAT 110.00 0.98342 0.98351 1.10000 0.90000 'SUB ' RANGE SINGLE 5 36025 LEOVO 110.00 0.98410 0.98433 1.10000 0.90000 'SUB ' RANGE SINGLE 5 36028 TARECKLIA 110.00 1.00800 1.00767 1.10000 0.90000 'SUB ' RANGE SINGLE 5 36031 CIADYR 110.00 0.98258 0.98233 1.10000 0.90000 'SUB ' RANGE SINGLE 5 36032 CIMISLIA 110.00 0.99238 0.99294 1.10000 0.90000 'SUB ' RANGE SINGLE 5 36038 VULCANESTI 110.00 1.01900 1.01844 1.10000 0.90000 'SUB ' RANGE SINGLE 6 34057 CHISINAU 110.00 1.01232 1.01261 1.10000 0.90000 'SUB ' RANGE SINGLE 6 34060 HANCESTI 110.00 1.01129 1.01153 1.10000 0.90000 'SUB ' RANGE SINGLE 6 36005 BESARABEASCA110.00 0.98395 0.98540 1.10000 0.90000 'SUB ' RANGE SINGLE 6 36012 ZARNESTI 110.00 1.00146 0.99257 1.10000 0.90000 'SUB ' RANGE SINGLE 6 36023 COMRAT 110.00 0.98168 0.98351 1.10000 0.90000 'SUB ' RANGE SINGLE 6 36025 LEOVO 110.00 0.98308 0.98433 1.10000 0.90000 'SUB ' RANGE SINGLE 6 36028 TARECKLIA 110.00 1.00767 1.00767 1.10000 0.90000 'SUB ' RANGE SINGLE 6 36031 CIADYR 110.00 0.98191 0.98233 1.10000 0.90000 'SUB ' RANGE SINGLE 6 36032 CIMISLIA 110.00 0.99203 0.99294 1.10000 0.90000 'SUB ' RANGE SINGLE 6 36038 VULCANESTI 110.00 1.01943 1.01844 1.10000 0.90000 'SUB ' RANGE SINGLE 7 34057 CHISINAU 110.00 1.01222 1.01261 1.10000 0.90000 'SUB ' RANGE SINGLE 7 34060 HANCESTI 110.00 1.01127 1.01153 1.10000 0.90000 'SUB ' RANGE SINGLE 7 36005 BESARABEASCA110.00 0.98009 0.98540 1.10000 0.90000 'SUB ' RANGE SINGLE 7 36012 ZARNESTI 110.00 0.95722 0.99257 1.10000 0.90000 'SUB ' RANGE SINGLE 7 36023 COMRAT 110.00 0.97650 0.98351 1.10000 0.90000 'SUB ' RANGE SINGLE 7 36025 LEOVO 110.00 0.97933 0.98433 1.10000 0.90000 'SUB ' RANGE SINGLE 7 36028 TARECKLIA 110.00 1.00579 1.00767 1.10000 0.90000 'SUB ' RANGE SINGLE 7 36031 CIADYR 110.00 0.97927 0.98233 1.10000 0.90000 'SUB ' RANGE SINGLE 7 36032 CIMISLIA 110.00 0.98885 0.99294 1.10000 0.90000 'SUB ' RANGE SINGLE 7 36038 VULCANESTI 110.00 1.01933 1.01844 1.10000 0.90000 'SUB ' RANGE SINGLE 8 34057 CHISINAU 110.00 1.01264 1.01261 1.10000 0.90000 'SUB ' RANGE SINGLE 8 34060 HANCESTI 110.00 1.01130 1.01153 1.10000 0.90000 'SUB ' RANGE SINGLE 8 36005 BESARABEASCA110.00 0.98560 0.98540 1.10000 0.90000 'SUB ' RANGE SINGLE 8 36012 ZARNESTI 110.00 0.99286 0.99257 1.10000 0.90000 'SUB ' RANGE SINGLE 8 36023 COMRAT 110.00 0.98374 0.98351 1.10000 0.90000 'SUB ' RANGE SINGLE 8 36025 LEOVO 110.00 0.98722 0.98433 1.10000 0.90000 'SUB ' RANGE SINGLE 8 36028 TARECKLIA 110.00 1.00798 1.00767 1.10000 0.90000 'SUB ' RANGE SINGLE 8 36031 CIADYR 110.00 0.98263 0.98233 1.10000 0.90000 'SUB ' RANGE SINGLE 8 36032 CIMISLIA 110.00 0.99288 0.99294 1.10000 0.90000 'SUB ' RANGE SINGLE 8 36038 VULCANESTI 110.00 1.01879 1.01844 1.10000 0.90000 'SUB ' RANGE SINGLE 9 34057 CHISINAU 110.00 1.01182 1.01261 1.10000 0.90000 'SUB ' RANGE SINGLE 9 34060 HANCESTI 110.00 1.01094 1.01153 1.10000 0.90000 'SUB ' RANGE SINGLE 9 36005 BESARABEASCA110.00 0.97796 0.98540 1.10000 0.90000 'SUB ' RANGE SINGLE 9 36012 ZARNESTI 110.00 0.98920 0.99257 1.10000 0.90000 'SUB ' RANGE SINGLE 9 36023 COMRAT 110.00 0.97381 0.98351 1.10000 0.90000 'SUB ' RANGE SINGLE 9 36025 LEOVO 110.00 0.97749 0.98433 1.10000 0.90000 'SUB ' RANGE SINGLE 9 36028 TARECKLIA 110.00 1.02336 1.00767 1.10000 0.90000 'SUB ' RANGE SINGLE 9 36031 CIADYR 110.00 0.97872 0.98233 1.10000 0.90000 'SUB ' RANGE SINGLE 9 36032 CIMISLIA 110.00 0.98749 0.99294 1.10000 0.90000 'SUB ' RANGE SINGLE 9 36038 VULCANESTI 110.00 1.02092 1.01844 1.10000 0.90000 'SUB ' RANGE SINGLE 10 34057 CHISINAU 110.00 1.01253 1.01261 1.10000 0.90000 'SUB ' RANGE SINGLE 10 34060 HANCESTI 110.00 1.01144 1.01153 1.10000 0.90000 'SUB ' RANGE SINGLE 10 36005 BESARABEASCA110.00 0.98608 0.98540 1.10000 0.90000 'SUB ' RANGE SINGLE 10 36012 ZARNESTI 110.00 0.99323 0.99257 1.10000 0.90000 'SUB ' RANGE SINGLE 10 36023 COMRAT 110.00 0.98446 0.98351 1.10000 0.90000 'SUB ' RANGE SINGLE 10 36025 LEOVO 110.00 0.98505 0.98433 1.10000 0.90000 'SUB ' RANGE SINGLE 10 36028 TARECKLIA 110.00 1.00825 1.00767 1.10000 0.90000 'SUB ' RANGE SINGLE 10 36031 CIADYR 110.00 0.98133 0.98233 1.10000 0.90000 'SUB ' RANGE SINGLE 10 36032 CIMISLIA 110.00 0.99361 0.99294 1.10000 0.90000 'SUB ' RANGE SINGLE 10 36038 VULCANESTI 110.00 1.01882 1.01844 1.10000 0.90000 'SUB ' RANGE SINGLE 11 34057 CHISINAU 110.00 1.01268 1.01261 1.10000 0.90000 'SUB ' RANGE SINGLE 11 34060 HANCESTI 110.00 1.01154 1.01153 1.10000 0.90000 'SUB ' RANGE SINGLE 11 36005 BESARABEASCA110.00 0.97789 0.98540 1.10000 0.90000 'SUB ' RANGE SINGLE 11 36012 ZARNESTI 110.00 0.98755 0.99257 1.10000 0.90000 'SUB ' RANGE SINGLE 11 36023 COMRAT 110.00 0.97328 0.98351 1.10000 0.90000 'SUB ' RANGE SINGLE 11 36025 LEOVO 110.00 0.97681 0.98433 1.10000 0.90000 'SUB ' RANGE SINGLE 11 36028 TARECKLIA 110.00 1.00402 1.00767 1.10000 0.90000
J-7
'SUB ' RANGE SINGLE 11 36031 CIADYR 110.00 0.97715 0.98233 1.10000 0.90000 'SUB ' RANGE SINGLE 11 36032 CIMISLIA 110.00 1.00893 0.99294 1.10000 0.90000 'SUB ' RANGE SINGLE 11 36038 VULCANESTI 110.00 1.01831 1.01844 1.10000 0.90000 'SUB ' RANGE SINGLE 12 34057 CHISINAU 110.00 1.01200 1.01261 1.10000 0.90000 'SUB ' RANGE SINGLE 12 34060 HANCESTI 110.00 1.01108 1.01153 1.10000 0.90000 'SUB ' RANGE SINGLE 12 36005 BESARABEASCA110.00 0.97931 0.98540 1.10000 0.90000 'SUB ' RANGE SINGLE 12 36012 ZARNESTI 110.00 0.98973 0.99257 1.10000 0.90000 'SUB ' RANGE SINGLE 12 36023 COMRAT 110.00 0.97555 0.98351 1.10000 0.90000 'SUB ' RANGE SINGLE 12 36025 LEOVO 110.00 0.97870 0.98433 1.10000 0.90000 'SUB ' RANGE SINGLE 12 36028 TARECKLIA 110.00 0.98042 1.00767 1.10000 0.90000 'SUB ' RANGE SINGLE 12 36031 CIADYR 110.00 0.97929 0.98233 1.10000 0.90000 'SUB ' RANGE SINGLE 12 36032 CIMISLIA 110.00 0.98843 0.99294 1.10000 0.90000 'SUB ' RANGE SINGLE 12 36038 VULCANESTI 110.00 1.02033 1.01844 1.10000 0.90000 'SUB ' RANGE SINGLE 13 34057 CHISINAU 110.00 1.01180 1.01261 1.10000 0.90000 'SUB ' RANGE SINGLE 13 34060 HANCESTI 110.00 1.01096 1.01153 1.10000 0.90000 'SUB ' RANGE SINGLE 13 36005 BESARABEASCA110.00 0.97618 0.98540 1.10000 0.90000 'SUB ' RANGE SINGLE 13 36012 ZARNESTI 110.00 0.98786 0.99257 1.10000 0.90000 'SUB ' RANGE SINGLE 13 36023 COMRAT 110.00 0.97140 0.98351 1.10000 0.90000 'SUB ' RANGE SINGLE 13 36025 LEOVO 110.00 0.97573 0.98433 1.10000 0.90000 'SUB ' RANGE SINGLE 13 36028 TARECKLIA 110.00 1.00483 1.00767 1.10000 0.90000 'SUB ' RANGE SINGLE 13 36031 CIADYR 110.00 0.93289 0.98233 1.10000 0.90000 'SUB ' RANGE SINGLE 13 36032 CIMISLIA 110.00 0.98598 0.99294 1.10000 0.90000 'SUB ' RANGE SINGLE 13 36038 VULCANESTI 110.00 1.02059 1.01844 1.10000 0.90000 CONTINGENCY LEGEND: LABEL EVENTS SINGLE 1 : OPEN LINE FROM BUS 34057 [CHISINAU 110.00] TO BUS 34060 [HANCESTI 110.00] CKT 3 SINGLE 2 : OPEN LINE FROM BUS 34057 [CHISINAU 110.00] TO BUS 36005 [BESARABEASCA110.00] CKT 1 SINGLE 3 : OPEN LINE FROM BUS 34057 [CHISINAU 110.00] TO BUS 36032 [CIMISLIA 110.00] CKT 2 SINGLE 4 : OPEN LINE FROM BUS 34060 [HANCESTI 110.00] TO BUS 36025 [LEOVO 110.00] CKT 6 SINGLE 5 : OPEN LINE FROM BUS 36005 [BESARABEASCA110.00] TO BUS 36023 [COMRAT 110.00] CKT 4 SINGLE 6 : OPEN LINE FROM BUS 36012 [ZARNESTI 110.00] TO BUS 36023 [COMRAT 110.00] CKT 10 SINGLE 7 : OPEN LINE FROM BUS 36012 [ZARNESTI 110.00] TO BUS 36038 [VULCANESTI 110.00] CKT 14 SINGLE 8 : OPEN LINE FROM BUS 36023 [COMRAT 110.00] TO BUS 36025 [LEOVO 110.00] CKT 7 SINGLE 9 : OPEN LINE FROM BUS 36023 [COMRAT 110.00] TO BUS 36028 [TARECKLIA 110.00] CKT 9 SINGLE 10 : OPEN LINE FROM BUS 36023 [COMRAT 110.00] TO BUS 36031 [CIADYR 110.00] CKT 8 SINGLE 11 : OPEN LINE FROM BUS 36023 [COMRAT 110.00] TO BUS 36032 [CIMISLIA 110.00] CKT 5 SINGLE 12 : OPEN LINE FROM BUS 36028 [TARECKLIA 110.00] TO BUS 36038 [VULCANESTI 110.00] CKT 13 SINGLE 13 : OPEN LINE FROM BUS 36031 [CIADYR 110.00] TO BUS 36038 [VULCANESTI 110.00] CKT 12
J-8
Table J-1 The busses with maximum and minimum voltage levels from the loading report
Line Tripped Buss Name Voltage [p.u.]
No line tripped Vulcanesti 1,018 Ciadyr 0,982 Chisinau-Hancesti Vulcanesti 1,018 Ciadyr 0,982 Chisinau -Besarabeasca Vulcanesti 1,018 Ciadyr 0,968 Chisinau-Cimislia Vulcanesti 1,017 Cimislia 0,962 Hancesti-Leovo Vulcanesti 1,018 Comrat 0,977 Besarabeasca-Comrat Vulcanesti 1,019 Ciadyr 0,983 Zarnesti-Comrat Vulcanesti 1,019 Comrat 0,981 Zarnesti-Vulcanesti Vulcanesti 0,019 Zarnesti 0,957 Comrat-Leovo Vulcanesti 1,019 Ciadyr 0,982 Comrat-Tarecklia Vulcanesti 1,021 Comrat 0,973 Comrat-Ciadyr Vulcanesti 1,018 Ciadyr 0,981 Comrat-Cimislia Vulcanesti 1,018 Comrat 0,973 Tarecklia-Vulcanesti Vulcanesti 1,02 Comrat 0,976 Ciadyr-Vulcanesti Vulcanesti 1,021 Ciadyr 0,933
K-1
Appendix K Base Case – Line Diagram with Line Capacities
Figure K-1 One line diagram with line capacities
Reactive Power Flow
400 kV Line
330 kV Line
110 kV Line
Active Power Flow
Load
Generator
Three winding
transformer
Switched shunt
Line Offline
L-1
Appendix L Scenario I – Overload Report
ACCC OVERLOAD REPORT: MONITORED BRANCHES AND INTERFACES LOADED ABOVE 100.0 % OF RATING SET A
% LOADING VALUES ARE % MVA FOR TRANSFORMERS AND % CURRENT FOR NON-TRANSFORMER BRANCHES
INCLUDES VOLTAGE REPORT
AC CONTINGENCY RESULTS FILE: Accc.acc
DISTRIBUTION FACTOR FILE: Dfx.dfx
SUBSYSTEM DESCRIPTION FILE: Sub.sub
MONITORED ELEMENT FILE: Mon.mon
CONTINGENCY DESCRIPTION FILE: Cont.con
**PERCENT LOADING UNITS**
%MVA FOR TRANSFORMERS
% I FOR NON-TRANSFORMER BRANCHES
**OPTIONS USED IN CONTINGENCY ANALYSIS**
Solution engine: Full Newton-Raphson (FNSL)
Solution options
Tap adjustment: Stepping
Area interchange control: Disable
Phase shift adjustment: Disable
Dc tap adjustment: Disable
Switch shunt adjustment: Lock all
Non diverge: Enable
Mismatch tolerance (MW ): **************************
Dispatch mode: Disable
Violation with generators set at:
('genA = ', 61, ' genB = ', 0, ' genC = ', 0, ' genD = ', 0, ' genE = ', 0)
<---------------- MULTI-SECTION LINE ----------------> <----------------- MONITORED BRANCH -----------------> CONTINGENCY RATING FLOW %
MONITORED VOLTAGE REPORT:
SYSTEM CONTINGENCY <-------- B U S --------> V-CONT V-INIT V-MAX V-MIN
'SUB ' RANGE SINGLE 2 36005 BESARABEASCA110.00 1.10054 1.07221 1.10000 0.90000
Violation with generators set at:
('genA = ', 0, ' genB = ', 26, ' genC = ', 0, ' genD = ', 0, ' genE = ', 0)
<---------------- MULTI-SECTION LINE ----------------> <----------------- MONITORED BRANCH -----------------> CONTINGENCY RATING FLOW %
MONITORED VOLTAGE REPORT:
SYSTEM CONTINGENCY <-------- B U S --------> V-CONT V-INIT V-MAX V-MIN
'SUB ' RANGE SINGLE 6 36012 ZARNESTI 110.00 1.10092 1.05221 1.10000 0.90000
Violation with generators set at:
('genA = ', 0, ' genB = ', 0, ' genC = ', 31, ' genD = ', 0, ' genE = ', 0)
<---------------- MULTI-SECTION LINE ----------------> <----------------- MONITORED BRANCH -----------------> CONTINGENCY RATING FLOW %
MONITORED VOLTAGE REPORT:
SYSTEM CONTINGENCY <-------- B U S --------> V-CONT V-INIT V-MAX V-MIN
'SUB ' RANGE SINGLE 8 36025 LEOVO 110.00 1.10125 1.03956 1.10000 0.90000
Violation with generators set at:
('genA = ', 0, ' genB = ', 0, ' genC = ', 0, ' genD = ', 85, ' genE = ', 0)
<---------------- MULTI-SECTION LINE ----------------> <----------------- MONITORED BRANCH -----------------> CONTINGENCY RATING FLOW %
MONITORED VOLTAGE REPORT:
SYSTEM CONTINGENCY <-------- B U S --------> V-CONT V-INIT V-MAX V-MIN
L-2
'SUB ' RANGE SINGLE 13 36023 COMRAT 110.00 0.89329 1.00134 1.10000 0.90000
Violation with generators set at:
('genA = ', 0, ' genB = ', 0, ' genC = ', 0, ' genD = ', 0, ' genE = ', 103)
<---------------- MULTI-SECTION LINE ----------------> <----------------- MONITORED BRANCH -----------------> CONTINGENCY RATING FLOW %
36023 COMRAT 110.00 36032*CIMISLIA 110.00 5 SINGLE 3 97.2 100.6 102.6
MONITORED VOLTAGE REPORT:
SYSTEM CONTINGENCY <-------- B U S --------> V-CONT V-INIT V-MAX V-MIN
CONTINGENCY LEGEND:
LABEL EVENTS
SINGLE 1 : OPEN LINE FROM BUS 34057 [CHISINAU 110.00] TO BUS 34060 [HANCESTI 110.00] CKT 3
SINGLE 2 : OPEN LINE FROM BUS 34057 [CHISINAU 110.00] TO BUS 36005 [BESARABEASCA110.00] CKT 1
SINGLE 3 : OPEN LINE FROM BUS 34057 [CHISINAU 110.00] TO BUS 36032 [CIMISLIA 110.00] CKT 2
SINGLE 4 : OPEN LINE FROM BUS 34060 [HANCESTI 110.00] TO BUS 36025 [LEOVO 110.00] CKT 6
SINGLE 5 : OPEN LINE FROM BUS 36005 [BESARABEASCA110.00] TO BUS 36023 [COMRAT 110.00] CKT 4
SINGLE 6 : OPEN LINE FROM BUS 36012 [ZARNESTI 110.00] TO BUS 36023 [COMRAT 110.00] CKT 10
SINGLE 7 : OPEN LINE FROM BUS 36012 [ZARNESTI 110.00] TO BUS 36038 [VULCANESTI 110.00] CKT 14
SINGLE 8 : OPEN LINE FROM BUS 36023 [COMRAT 110.00] TO BUS 36025 [LEOVO 110.00] CKT 7
SINGLE 9 : OPEN LINE FROM BUS 36023 [COMRAT 110.00] TO BUS 36028 [TARECKLIA 110.00] CKT 9
SINGLE 10 : OPEN LINE FROM BUS 36023 [COMRAT 110.00] TO BUS 36031 [CIADYR 110.00] CKT 8
SINGLE 11 : OPEN LINE FROM BUS 36023 [COMRAT 110.00] TO BUS 36032 [CIMISLIA 110.00] CKT 5
SINGLE 12 : OPEN LINE FROM BUS 36028 [TARECKLIA 110.00] TO BUS 36038 [VULCANESTI 110.00] CKT 13
SINGLE 13 : OPEN LINE FROM BUS 36031 [CIADYR 110.00] TO BUS 36038 [VULCANESTI 110.00] CKT 12
M-1
Appendix M Scenario I Reactive Power Compensation – Overload Report
ACCC OVERLOAD REPORT: MONITORED BRANCHES AND INTERFACES LOADED ABOVE 100.0 % OF RATING SET A
% LOADING VALUES ARE % MVA FOR TRANSFORMERS AND % CURRENT FOR NON-TRANSFORMER BRANCHES
INCLUDES VOLTAGE REPORT
AC CONTINGENCY RESULTS FILE: Accc.acc
DISTRIBUTION FACTOR FILE: Dfx.dfx
SUBSYSTEM DESCRIPTION FILE: Sub.sub
MONITORED ELEMENT FILE: Mon.mon
CONTINGENCY DESCRIPTION FILE: Cont.con
**PERCENT LOADING UNITS**
%MVA FOR TRANSFORMERS
% I FOR NON-TRANSFORMER BRANCHES
**OPTIONS USED IN CONTINGENCY ANALYSIS**
Solution engine: Full Newton-Raphson (FNSL)
Solution options
Tap adjustment: Stepping
Area interchange control: Disable
Phase shift adjustment: Disable
Dc tap adjustment: Disable
Switch shunt adjustment: Lock all
Non diverge: Enable
Mismatch tolerance (MW ): **************************
Dispatch mode: Disable
Violation with generators set at:
('genA = ', 75, ' genB = ', 0, ' genC = ', 0, ' genD = ', 0, ' genE = ', 0)
<---------------- MULTI-SECTION LINE ----------------> <----------------- MONITORED BRANCH -----------------> CONTINGENCY RATING FLOW %
36005*BESARABEASCA110.00 36023 COMRAT 110.00 4 SINGLE 2 72.4 72.5 100.2
MONITORED VOLTAGE REPORT:
SYSTEM CONTINGENCY <-------- B U S --------> V-CONT V-INIT V-MAX V-MIN
Violation with generators set at:
('genA = ', 0, ' genB = ', 79, ' genC = ', 0, ' genD = ', 0, ' genE = ', 0)
<---------------- MULTI-SECTION LINE ----------------> <----------------- MONITORED BRANCH -----------------> CONTINGENCY RATING FLOW %
36012*ZARNESTI 110.00 36038 VULCANESTI 110.00 14 SINGLE 6 72.4 73.0 100.9
36012*ZARNESTI 110.00 36023 COMRAT 110.00 10 SINGLE 7 72.4 72.6 100.2
MONITORED VOLTAGE REPORT:
SYSTEM CONTINGENCY <-------- B U S --------> V-CONT V-INIT V-MAX V-MIN
Violation with generators set at:
('genA = ', 0, ' genB = ', 0, ' genC = ', 75, ' genD = ', 0, ' genE = ', 0)
<---------------- MULTI-SECTION LINE ----------------> <----------------- MONITORED BRANCH -----------------> CONTINGENCY RATING FLOW %
36023 COMRAT 110.00 36025*LEOVO 110.00 7 SINGLE 4 72.4 72.9 100.7
34060 HANCESTI 110.00 36025*LEOVO 110.00 6 SINGLE 8 72.4 72.5 100.2
MONITORED VOLTAGE REPORT:
SYSTEM CONTINGENCY <-------- B U S --------> V-CONT V-INIT V-MAX V-MIN
Violation with generators set at:
('genA = ', 0, ' genB = ', 0, ' genC = ', 0, ' genD = ', 92, ' genE = ', 0)
<---------------- MULTI-SECTION LINE ----------------> <----------------- MONITORED BRANCH -----------------> CONTINGENCY RATING FLOW %
36031*CIADYR 110.00 36038 VULCANESTI 110.00 12 SINGLE 10 84.8 85.1 100.4
N-2
36023 COMRAT 110.00 36031*CIADYR 110.00 8 SINGLE 13 84.8 84.9 100.1
MONITORED VOLTAGE REPORT:
SYSTEM CONTINGENCY <-------- B U S --------> V-CONT V-INIT V-MAX V-MIN
Violation with generators set at:
('genA = ', 0, ' genB = ', 0, ' genC = ', 0, ' genD = ', 0, ' genE = ', 99)
<---------------- MULTI-SECTION LINE ----------------> <----------------- MONITORED BRANCH -----------------> CONTINGENCY RATING FLOW %
36023 COMRAT 110.00 36032*CIMISLIA 110.00 5 SINGLE 3 97.2 97.3 100.1
34057*CHISINAU 110.00 36032 CIMISLIA 110.00 2 SINGLE 11 97.2 97.6 100.4
MONITORED VOLTAGE REPORT:
SYSTEM CONTINGENCY <-------- B U S --------> V-CONT V-INIT V-MAX V-MIN
CONTINGENCY LEGEND:
LABEL EVENTS
SINGLE 1 : OPEN LINE FROM BUS 34057 [CHISINAU 110.00] TO BUS 34060 [HANCESTI 110.00] CKT 3
SINGLE 2 : OPEN LINE FROM BUS 34057 [CHISINAU 110.00] TO BUS 36005 [BESARABEASCA110.00] CKT 1
SINGLE 3 : OPEN LINE FROM BUS 34057 [CHISINAU 110.00] TO BUS 36032 [CIMISLIA 110.00] CKT 2
SINGLE 4 : OPEN LINE FROM BUS 34060 [HANCESTI 110.00] TO BUS 36025 [LEOVO 110.00] CKT 6
SINGLE 5 : OPEN LINE FROM BUS 36005 [BESARABEASCA110.00] TO BUS 36023 [COMRAT 110.00] CKT 4
SINGLE 6 : OPEN LINE FROM BUS 36012 [ZARNESTI 110.00] TO BUS 36023 [COMRAT 110.00] CKT 10
SINGLE 7 : OPEN LINE FROM BUS 36012 [ZARNESTI 110.00] TO BUS 36038 [VULCANESTI 110.00] CKT 14
SINGLE 8 : OPEN LINE FROM BUS 36023 [COMRAT 110.00] TO BUS 36025 [LEOVO 110.00] CKT 7
SINGLE 9 : OPEN LINE FROM BUS 36023 [COMRAT 110.00] TO BUS 36028 [TARECKLIA 110.00] CKT 9
SINGLE 10 : OPEN LINE FROM BUS 36023 [COMRAT 110.00] TO BUS 36031 [CIADYR 110.00] CKT 8
SINGLE 11 : OPEN LINE FROM BUS 36023 [COMRAT 110.00] TO BUS 36032 [CIMISLIA 110.00] CKT 5
SINGLE 12 : OPEN LINE FROM BUS 36028 [TARECKLIA 110.00] TO BUS 36038 [VULCANESTI 110.00] CKT 13
SINGLE 13 : OPEN LINE FROM BUS 36031 [CIADYR 110.00] TO BUS 36038 [VULCANESTI 110.00] CKT 12
Appendix N Scenario II - Overload Report
ACCC OVERLOAD REPORT: MONITORED BRANCHES AND INTERFACES LOADED ABOVE 100.0 % OF RATING SET A
% LOADING VALUES ARE % MVA FOR TRANSFORMERS AND % CURRENT FOR NON-TRANSFORMER BRANCHES
INCLUDES VOLTAGE REPORT
AC CONTINGENCY RESULTS FILE: Accc.acc
DISTRIBUTION FACTOR FILE: Dfx.dfx
SUBSYSTEM DESCRIPTION FILE: Sub.sub
MONITORED ELEMENT FILE: Mon.mon
CONTINGENCY DESCRIPTION FILE: Cont.con
**PERCENT LOADING UNITS**
%MVA FOR TRANSFORMERS
% I FOR NON-TRANSFORMER BRANCHES
**OPTIONS USED IN CONTINGENCY ANALYSIS**
Solution engine: Full Newton-Raphson (FNSL)
Solution options
Tap adjustment: Stepping
Area interchange control: Disable
Phase shift adjustment: Disable
Dc tap adjustment: Disable
Switch shunt adjustment: Lock all
Non diverge: Enable
Mismatch tolerance (MW ): **************************
Dispatch mode: Disable
Violation with generators set at:
('genA = ', 30, ' genB = ', 14, ' genC = ', 28, ' genD = ', 84, ' genE = ', 102)
<---------------- MULTI-SECTION LINE ----------------> <----------------- MONITORED BRANCH -----------------> CONTINGENCY RATING FLOW %
MONITORED VOLTAGE REPORT:
SYSTEM CONTINGENCY <-------- B U S --------> V-CONT V-INIT V-MAX V-MIN
O-2
'SUB ' RANGE SINGLE 2 36005 BESARABEASCA110.00 1.10031 1.06269 1.10000 0.90000
Violation with generators set at:
('genA = ', 29, ' genB = ', 15, ' genC = ', 28, ' genD = ', 84, ' genE = ', 102)
<---------------- MULTI-SECTION LINE ----------------> <----------------- MONITORED BRANCH -----------------> CONTINGENCY RATING FLOW %
MONITORED VOLTAGE REPORT:
SYSTEM CONTINGENCY <-------- B U S --------> V-CONT V-INIT V-MAX V-MIN
'SUB ' RANGE SINGLE 7 36012 ZARNESTI 110.00 1.10294 1.04131 1.10000 0.90000
'SUB ' RANGE SINGLE 11 36031 CIADYR 110.00 1.10011 1.09693 1.10000 0.90000
Violation with generators set at:
('genA = ', 29, ' genB = ', 14, ' genC = ', 29, ' genD = ', 84, ' genE = ', 102)
<---------------- MULTI-SECTION LINE ----------------> <----------------- MONITORED BRANCH -----------------> CONTINGENCY RATING FLOW %
MONITORED VOLTAGE REPORT:
SYSTEM CONTINGENCY <-------- B U S --------> V-CONT V-INIT V-MAX V-MIN
'SUB ' RANGE SINGLE 11 36031 CIADYR 110.00 1.10006 1.09685 1.10000 0.90000
Violation with generators set at:
('genA = ', 29, ' genB = ', 14, ' genC = ', 28, ' genD = ', 85, ' genE = ', 102)
<---------------- MULTI-SECTION LINE ----------------> <----------------- MONITORED BRANCH -----------------> CONTINGENCY RATING FLOW %
MONITORED VOLTAGE REPORT:
SYSTEM CONTINGENCY <-------- B U S --------> V-CONT V-INIT V-MAX V-MIN
'SUB ' RANGE SINGLE 11 36031 CIADYR 110.00 1.10027 1.09717 1.10000 0.90000
Violation with generators set at:
('genA = ', 29, ' genB = ', 14, ' genC = ', 28, ' genD = ', 84, ' genE = ', 103)
<---------------- MULTI-SECTION LINE ----------------> <----------------- MONITORED BRANCH -----------------> CONTINGENCY RATING FLOW %
36023 COMRAT 110.00 36032*CIMISLIA 110.00 5 SINGLE 3 97.2 100.6 100.6
MONITORED VOLTAGE REPORT:
SYSTEM CONTINGENCY <-------- B U S --------> V-CONT V-INIT V-MAX V-MIN
CONTINGENCY LEGEND:
LABEL EVENTS
SINGLE 1 : OPEN LINE FROM BUS 34057 [CHISINAU 110.00] TO BUS 34060 [HANCESTI 110.00] CKT 3
SINGLE 2 : OPEN LINE FROM BUS 34057 [CHISINAU 110.00] TO BUS 36005 [BESARABEASCA110.00] CKT 1
SINGLE 3 : OPEN LINE FROM BUS 34057 [CHISINAU 110.00] TO BUS 36032 [CIMISLIA 110.00] CKT 2
SINGLE 4 : OPEN LINE FROM BUS 34060 [HANCESTI 110.00] TO BUS 36025 [LEOVO 110.00] CKT 6
SINGLE 5 : OPEN LINE FROM BUS 36005 [BESARABEASCA110.00] TO BUS 36023 [COMRAT 110.00] CKT 4
SINGLE 6 : OPEN LINE FROM BUS 36012 [ZARNESTI 110.00] TO BUS 36023 [COMRAT 110.00] CKT 10
SINGLE 7 : OPEN LINE FROM BUS 36012 [ZARNESTI 110.00] TO BUS 36038 [VULCANESTI 110.00] CKT 14
SINGLE 8 : OPEN LINE FROM BUS 36023 [COMRAT 110.00] TO BUS 36025 [LEOVO 110.00] CKT 7
SINGLE 9 : OPEN LINE FROM BUS 36023 [COMRAT 110.00] TO BUS 36028 [TARECKLIA 110.00] CKT 9
SINGLE 10 : OPEN LINE FROM BUS 36023 [COMRAT 110.00] TO BUS 36031 [CIADYR 110.00] CKT 8
SINGLE 11 : OPEN LINE FROM BUS 36023 [COMRAT 110.00] TO BUS 36032 [CIMISLIA 110.00] CKT 5
SINGLE 12 : OPEN LINE FROM BUS 36028 [TARECKLIA 110.00] TO BUS 36038 [VULCANESTI 110.00] CKT 13
SINGLE 13 : OPEN LINE FROM BUS 36031 [CIADYR 110.00] TO BUS 36038 [VULCANESTI 110.00] CKT 12
Appendix O Scenario II Reactive Power Compensation – Overload Report
ACCC OVERLOAD REPORT: MONITORED BRANCHES AND INTERFACES LOADED ABOVE 100.0 % OF RATING SET A
% LOADING VALUES ARE % MVA FOR TRANSFORMERS AND % CURRENT FOR NON-TRANSFORMER BRANCHES
INCLUDES VOLTAGE REPORT
AC CONTINGENCY RESULTS FILE: Accc.acc
DISTRIBUTION FACTOR FILE: Dfx.dfx
SUBSYSTEM DESCRIPTION FILE: Sub.sub
MONITORED ELEMENT FILE: Mon.mon
O-2
CONTINGENCY DESCRIPTION FILE: Cont.con
**PERCENT LOADING UNITS**
%MVA FOR TRANSFORMERS
% I FOR NON-TRANSFORMER BRANCHES
**OPTIONS USED IN CONTINGENCY ANALYSIS**
Solution engine: Full Newton-Raphson (FNSL)
Solution options
Tap adjustment: Stepping
Area interchange control: Disable
Phase shift adjustment: Disable
Dc tap adjustment: Disable
Switch shunt adjustment: Lock all
Non diverge: Enable
Mismatch tolerance (MW ): **************************
Dispatch mode: Disable
Violation with generators set at:
('genA = ', 57, ' genB = ', 68, ' genC = ', 68, ' genD = ', 91, ' genE = ', 72)
<---------------- MULTI-SECTION LINE ----------------> <----------------- MONITORED BRANCH -----------------> CONTINGENCY RATING FLOW %
MONITORED VOLTAGE REPORT:
SYSTEM CONTINGENCY <-------- B U S --------> V-CONT V-INIT V-MAX V-MIN
'SUB ' RANGE SINGLE 3 36028 TARECKLIA 110.00 0.89946 0.94045 1.10000 0.90000
Violation with generators set at:
('genA = ', 56, ' genB = ', 69, ' genC = ', 68, ' genD = ', 91, ' genE = ', 72)
<---------------- MULTI-SECTION LINE ----------------> <----------------- MONITORED BRANCH -----------------> CONTINGENCY RATING FLOW %
MONITORED VOLTAGE REPORT:
SYSTEM CONTINGENCY <-------- B U S --------> V-CONT V-INIT V-MAX V-MIN
'SUB ' RANGE SINGLE 3 36028 TARECKLIA 110.00 0.89942 0.94036 1.10000 0.90000
Violation with generators set at:
('genA = ', 56, ' genB = ', 68, ' genC = ', 69, ' genD = ', 91, ' genE = ', 72)
<---------------- MULTI-SECTION LINE ----------------> <----------------- MONITORED BRANCH -----------------> CONTINGENCY RATING FLOW %
MONITORED VOLTAGE REPORT:
SYSTEM CONTINGENCY <-------- B U S --------> V-CONT V-INIT V-MAX V-MIN
'SUB ' RANGE SINGLE 3 36028 TARECKLIA 110.00 0.89951 0.94047 1.10000 0.90000
Violation with generators set at:
('genA = ', 56, ' genB = ', 68, ' genC = ', 68, ' genD = ', 92, ' genE = ', 72)
<---------------- MULTI-SECTION LINE ----------------> <----------------- MONITORED BRANCH -----------------> CONTINGENCY RATING FLOW %
36031*CIADYR 110.00 36038 VULCANESTI 110.00 12 SINGLE 10 84.8 84.9 100.1
36023 COMRAT 110.00 36031*CIADYR 110.00 8 SINGLE 13 84.8 84.9 100.1
MONITORED VOLTAGE REPORT:
SYSTEM CONTINGENCY <-------- B U S --------> V-CONT V-INIT V-MAX V-MIN
'SUB ' RANGE SINGLE 3 36028 TARECKLIA 110.00 0.89942 0.94036 1.10000 0.90000
Violation with generators set at:
('genA = ', 56, ' genB = ', 68, ' genC = ', 68, ' genD = ', 91, ' genE = ', 73)
<---------------- MULTI-SECTION LINE ----------------> <----------------- MONITORED BRANCH -----------------> CONTINGENCY RATING FLOW %
MONITORED VOLTAGE REPORT:
SYSTEM CONTINGENCY <-------- B U S --------> V-CONT V-INIT V-MAX V-MIN
'SUB ' RANGE SINGLE 3 36028 TARECKLIA 110.00 0.89934 0.94057 1.10000 0.90000
O-3
CONTINGENCY LEGEND:
LABEL EVENTS
SINGLE 1 : OPEN LINE FROM BUS 34057 [CHISINAU 110.00] TO BUS 34060 [HANCESTI 110.00] CKT 3
SINGLE 2 : OPEN LINE FROM BUS 34057 [CHISINAU 110.00] TO BUS 36005 [BESARABEASCA110.00] CKT 1
SINGLE 3 : OPEN LINE FROM BUS 34057 [CHISINAU 110.00] TO BUS 36032 [CIMISLIA 110.00] CKT 2
SINGLE 4 : OPEN LINE FROM BUS 34060 [HANCESTI 110.00] TO BUS 36025 [LEOVO 110.00] CKT 6
SINGLE 5 : OPEN LINE FROM BUS 36005 [BESARABEASCA110.00] TO BUS 36023 [COMRAT 110.00] CKT 4
SINGLE 6 : OPEN LINE FROM BUS 36012 [ZARNESTI 110.00] TO BUS 36023 [COMRAT 110.00] CKT 10
SINGLE 7 : OPEN LINE FROM BUS 36012 [ZARNESTI 110.00] TO BUS 36038 [VULCANESTI 110.00] CKT 14
SINGLE 8 : OPEN LINE FROM BUS 36023 [COMRAT 110.00] TO BUS 36025 [LEOVO 110.00] CKT 7
SINGLE 9 : OPEN LINE FROM BUS 36023 [COMRAT 110.00] TO BUS 36028 [TARECKLIA 110.00] CKT 9
SINGLE 10 : OPEN LINE FROM BUS 36023 [COMRAT 110.00] TO BUS 36031 [CIADYR 110.00] CKT 8
SINGLE 11 : OPEN LINE FROM BUS 36023 [COMRAT 110.00] TO BUS 36032 [CIMISLIA 110.00] CKT 5
SINGLE 12 : OPEN LINE FROM BUS 36028 [TARECKLIA 110.00] TO BUS 36038 [VULCANESTI 110.00] CKT 13
SINGLE 13 : OPEN LINE FROM BUS 36031 [CIADYR 110.00] TO BUS 36038 [VULCANESTI 110.00] CKT 12
P-1
Appendix P Scenario II – Contingency Loading Report
ACCC LOADING REPORT: MONITORED BRANCHES AND INTERFACES USING RATING SET A % LOADING VALUES ARE % MVA FOR TRANSFORMERS AND % CURRENT FOR NON-TRANSFORMER BRANCHES INCLUDES VOLTAGE REPORT AC CONTINGENCY RESULTS FILE: CONTINGENCYALLA.acc DISTRIBUTION FACTOR FILE: C:\Users\Joel\Desktop\Testfiler\Dfx.dfx SUBSYSTEM DESCRIPTION FILE: C:\Users\Joel\Desktop\Testfiler\Sub.sub MONITORED ELEMENT FILE: C:\Users\Joel\Desktop\Testfiler\Mon.mon CONTINGENCY DESCRIPTION FILE: C:\Users\Joel\Desktop\Testfiler\Cont.con **PERCENT LOADING UNITS** %MVA FOR TRANSFORMERS % I FOR NON-TRANSFORMER BRANCHES **OPTIONS USED IN CONTINGENCY ANALYSIS** Solution engine: Full Newton-Raphson (FNSL) Solution options Tap adjustment: Stepping Area interchange control: Disable Phase shift adjustment: Disable Dc tap adjustment: Enable Switch shunt adjustment: Enable all Non diverge: Disable Mismatch tolerance (MW ): 0.5 Dispatch mode: Disable <---------------- MULTI-SECTION LINE ----------------> <----------------- MONITORED BRANCH -----------------> CONTINGENCY RATING FLOW % 34057 CHISINAU 110.00 34060*HANCESTI 110.00 3 BASE CASE 84.8 23.3 27.3 34057 CHISINAU 110.00 36005*BESARABEASCA110.00 1 BASE CASE 84.8 19.4 21.5 34057 CHISINAU 110.00 36032*CIMISLIA 110.00 2 BASE CASE 97.2 69.7 66.5 34060 HANCESTI 110.00 36025*LEOVO 110.00 6 BASE CASE 72.4 28.4 36.8 36005*BESARABEASCA110.00 36023 COMRAT 110.00 4 BASE CASE 72.4 5.4 7.1 36012 ZARNESTI 110.00 36023*COMRAT 110.00 10 BASE CASE 72.4 11.1 14.5 36012*ZARNESTI 110.00 36038 VULCANESTI 110.00 14 BASE CASE 72.4 17.9 23.8 36023 COMRAT 110.00 36025*LEOVO 110.00 7 BASE CASE 72.4 3.9 5.0 36023*COMRAT 110.00 36028 TARECKLIA 110.00 9 BASE CASE 85.8 27.8 30.8 36023 COMRAT 110.00 36031*CIADYR 110.00 8 BASE CASE 84.8 19.4 20.9 36023 COMRAT 110.00 36032*CIMISLIA 110.00 5 BASE CASE 97.2 30.0 28.7 36028*TARECKLIA 110.00 36038 VULCANESTI 110.00 13 BASE CASE 84.8 26.0 30.2 36031*CIADYR 110.00 36038 VULCANESTI 110.00 12 BASE CASE 84.8 57.5 61.8 34057*CHISINAU 110.00 34060 HANCESTI 110.00 3 SINGLE 1 84.8 0.0 0.0 34057 CHISINAU 110.00 36005*BESARABEASCA110.00 1 SINGLE 1 84.8 19.1 21.2 34057 CHISINAU 110.00 36032*CIMISLIA 110.00 2 SINGLE 1 97.2 69.1 66.0 34060 HANCESTI 110.00 36025*LEOVO 110.00 6 SINGLE 1 72.4 29.1 37.8 36005*BESARABEASCA110.00 36023 COMRAT 110.00 4 SINGLE 1 72.4 5.8 7.5 36012 ZARNESTI 110.00 36023*COMRAT 110.00 10 SINGLE 1 72.4 11.2 14.6 36012*ZARNESTI 110.00 36038 VULCANESTI 110.00 14 SINGLE 1 72.4 18.0 23.9 36023 COMRAT 110.00 36025*LEOVO 110.00 7 SINGLE 1 72.4 4.6 6.0 36023*COMRAT 110.00 36028 TARECKLIA 110.00 9 SINGLE 1 85.8 28.0 31.0 36023 COMRAT 110.00 36031*CIADYR 110.00 8 SINGLE 1 84.8 19.3 20.8 36023 COMRAT 110.00 36032*CIMISLIA 110.00 5 SINGLE 1 97.2 30.7 29.3 36028*TARECKLIA 110.00 36038 VULCANESTI 110.00 13 SINGLE 1 84.8 26.1 30.4 36031*CIADYR 110.00 36038 VULCANESTI 110.00 12 SINGLE 1 84.8 57.6 62.0
P-2
34057 CHISINAU 110.00 34060*HANCESTI 110.00 3 SINGLE 2 84.8 21.9 25.7 34057*CHISINAU 110.00 36005 BESARABEASCA110.00 1 SINGLE 2 84.8 0.0 0.0 34057 CHISINAU 110.00 36032*CIMISLIA 110.00 2 SINGLE 2 97.2 76.0 72.5 34060 HANCESTI 110.00 36025*LEOVO 110.00 6 SINGLE 2 72.4 32.0 41.4 36005*BESARABEASCA110.00 36023 COMRAT 110.00 4 SINGLE 2 72.4 24.8 31.2 36012 ZARNESTI 110.00 36023*COMRAT 110.00 10 SINGLE 2 72.4 13.2 17.3 36012*ZARNESTI 110.00 36038 VULCANESTI 110.00 14 SINGLE 2 72.4 20.0 26.6 36023 COMRAT 110.00 36025*LEOVO 110.00 7 SINGLE 2 72.4 6.1 7.9 36023*COMRAT 110.00 36028 TARECKLIA 110.00 9 SINGLE 2 85.8 32.1 35.3 36023 COMRAT 110.00 36031*CIADYR 110.00 8 SINGLE 2 84.8 16.7 18.0 36023 COMRAT 110.00 36032*CIMISLIA 110.00 5 SINGLE 2 97.2 23.7 22.6 36028*TARECKLIA 110.00 36038 VULCANESTI 110.00 13 SINGLE 2 84.8 29.8 34.7 36031*CIADYR 110.00 36038 VULCANESTI 110.00 12 SINGLE 2 84.8 60.2 64.8 34057*CHISINAU 110.00 34060 HANCESTI 110.00 3 SINGLE 3 84.8 18.0 21.2 34057*CHISINAU 110.00 36005 BESARABEASCA110.00 1 SINGLE 3 84.8 34.0 40.1 34057*CHISINAU 110.00 36032 CIMISLIA 110.00 2 SINGLE 3 97.2 0.0 0.0 34060*HANCESTI 110.00 36025 LEOVO 110.00 6 SINGLE 3 72.4 42.4 58.8 36005*BESARABEASCA110.00 36023 COMRAT 110.00 4 SINGLE 3 72.4 11.1 15.7 36012 ZARNESTI 110.00 36023*COMRAT 110.00 10 SINGLE 3 72.4 19.4 27.7 36012*ZARNESTI 110.00 36038 VULCANESTI 110.00 14 SINGLE 3 72.4 25.6 36.8 36023 COMRAT 110.00 36025*LEOVO 110.00 7 SINGLE 3 72.4 18.1 25.3 36023*COMRAT 110.00 36028 TARECKLIA 110.00 9 SINGLE 3 85.8 43.2 52.1 36023 COMRAT 110.00 36031*CIADYR 110.00 8 SINGLE 3 84.8 9.5 11.0 36023 COMRAT 110.00 36032*CIMISLIA 110.00 5 SINGLE 3 97.2 99.6 99.1 36028 TARECKLIA 110.00 36038*VULCANESTI 110.00 13 SINGLE 3 84.8 41.8 51.4 36031*CIADYR 110.00 36038 VULCANESTI 110.00 12 SINGLE 3 84.8 68.0 79.0 34057 CHISINAU 110.00 34060*HANCESTI 110.00 3 SINGLE 4 84.8 27.2 31.9 34057 CHISINAU 110.00 36005*BESARABEASCA110.00 1 SINGLE 4 84.8 24.2 27.1 34057 CHISINAU 110.00 36032*CIMISLIA 110.00 2 SINGLE 4 97.2 78.5 75.5 34060*HANCESTI 110.00 36025 LEOVO 110.00 6 SINGLE 4 72.4 0.0 0.0 36005*BESARABEASCA110.00 36023 COMRAT 110.00 4 SINGLE 4 72.4 1.5 1.9 36012 ZARNESTI 110.00 36023*COMRAT 110.00 10 SINGLE 4 72.4 14.4 19.0 36012*ZARNESTI 110.00 36038 VULCANESTI 110.00 14 SINGLE 4 72.4 21.1 28.3 36023 COMRAT 110.00 36025*LEOVO 110.00 7 SINGLE 4 72.4 27.5 34.7 36023*COMRAT 110.00 36028 TARECKLIA 110.00 9 SINGLE 4 85.8 34.3 38.1 36023 COMRAT 110.00 36031*CIADYR 110.00 8 SINGLE 4 84.8 15.2 16.5 36023 COMRAT 110.00 36032*CIMISLIA 110.00 5 SINGLE 4 97.2 21.1 20.3 36028*TARECKLIA 110.00 36038 VULCANESTI 110.00 13 SINGLE 4 84.8 31.9 37.6 36031*CIADYR 110.00 36038 VULCANESTI 110.00 12 SINGLE 4 84.8 61.7 67.1 34057 CHISINAU 110.00 34060*HANCESTI 110.00 3 SINGLE 5 84.8 23.6 27.8 34057 CHISINAU 110.00 36005*BESARABEASCA110.00 1 SINGLE 5 84.8 24.9 27.4 34057 CHISINAU 110.00 36032*CIMISLIA 110.00 2 SINGLE 5 97.2 67.9 64.9 34060 HANCESTI 110.00 36025*LEOVO 110.00 6 SINGLE 5 72.4 27.3 35.5
P-3
36005*BESARABEASCA110.00 36023 COMRAT 110.00 4 SINGLE 5 72.4 0.0 0.0 36012 ZARNESTI 110.00 36023*COMRAT 110.00 10 SINGLE 5 72.4 10.5 13.8 36012*ZARNESTI 110.00 36038 VULCANESTI 110.00 14 SINGLE 5 72.4 17.3 23.0 36023 COMRAT 110.00 36025*LEOVO 110.00 7 SINGLE 5 72.4 3.7 4.9 36023*COMRAT 110.00 36028 TARECKLIA 110.00 9 SINGLE 5 85.8 26.6 29.5 36023 COMRAT 110.00 36031*CIADYR 110.00 8 SINGLE 5 84.8 20.2 21.7 36023 COMRAT 110.00 36032*CIMISLIA 110.00 5 SINGLE 5 97.2 31.8 30.4 36028*TARECKLIA 110.00 36038 VULCANESTI 110.00 13 SINGLE 5 84.8 24.8 28.9 36031*CIADYR 110.00 36038 VULCANESTI 110.00 12 SINGLE 5 84.8 56.7 61.0 34057 CHISINAU 110.00 34060*HANCESTI 110.00 3 SINGLE 6 84.8 23.4 27.5 34057 CHISINAU 110.00 36005*BESARABEASCA110.00 1 SINGLE 6 84.8 20.9 23.3 34057 CHISINAU 110.00 36032*CIMISLIA 110.00 2 SINGLE 6 97.2 72.5 69.3 34060 HANCESTI 110.00 36025*LEOVO 110.00 6 SINGLE 6 72.4 30.1 39.1 36005*BESARABEASCA110.00 36023 COMRAT 110.00 4 SINGLE 6 72.4 3.9 5.1 36012*ZARNESTI 110.00 36023 COMRAT 110.00 10 SINGLE 6 72.4 0.0 0.0 36012*ZARNESTI 110.00 36038 VULCANESTI 110.00 14 SINGLE 6 72.4 7.7 10.2 36023 COMRAT 110.00 36025*LEOVO 110.00 7 SINGLE 6 72.4 4.9 6.3 36023*COMRAT 110.00 36028 TARECKLIA 110.00 9 SINGLE 6 85.8 30.9 34.2 36023 COMRAT 110.00 36031*CIADYR 110.00 8 SINGLE 6 84.8 17.4 18.7 36023 COMRAT 110.00 36032*CIMISLIA 110.00 5 SINGLE 6 97.2 27.2 26.0 36028*TARECKLIA 110.00 36038 VULCANESTI 110.00 13 SINGLE 6 84.8 28.9 33.6 36031*CIADYR 110.00 36038 VULCANESTI 110.00 12 SINGLE 6 84.8 59.6 64.1 34057 CHISINAU 110.00 34060*HANCESTI 110.00 3 SINGLE 7 84.8 23.5 27.6 34057 CHISINAU 110.00 36005*BESARABEASCA110.00 1 SINGLE 7 84.8 22.0 24.3 34057 CHISINAU 110.00 36032*CIMISLIA 110.00 2 SINGLE 7 97.2 74.2 70.8 34060 HANCESTI 110.00 36025*LEOVO 110.00 6 SINGLE 7 72.4 31.3 40.5 36005*BESARABEASCA110.00 36023 COMRAT 110.00 4 SINGLE 7 72.4 2.9 3.7 36012*ZARNESTI 110.00 36023 COMRAT 110.00 10 SINGLE 7 72.4 7.8 9.8 36012*ZARNESTI 110.00 36038 VULCANESTI 110.00 14 SINGLE 7 72.4 0.0 0.0 36023 COMRAT 110.00 36025*LEOVO 110.00 7 SINGLE 7 72.4 5.5 7.1 36023*COMRAT 110.00 36028 TARECKLIA 110.00 9 SINGLE 7 85.8 33.1 36.4 36023 COMRAT 110.00 36031*CIADYR 110.00 8 SINGLE 7 84.8 16.0 17.2 36023 COMRAT 110.00 36032*CIMISLIA 110.00 5 SINGLE 7 97.2 25.5 24.3 36028*TARECKLIA 110.00 36038 VULCANESTI 110.00 13 SINGLE 7 84.8 30.8 35.9 36031*CIADYR 110.00 36038 VULCANESTI 110.00 12 SINGLE 7 84.8 60.9 65.5 34057 CHISINAU 110.00 34060*HANCESTI 110.00 3 SINGLE 8 84.8 23.4 27.5 34057 CHISINAU 110.00 36005*BESARABEASCA110.00 1 SINGLE 8 84.8 19.5 21.8 34057 CHISINAU 110.00 36032*CIMISLIA 110.00 2 SINGLE 8 97.2 70.0 67.2 34060 HANCESTI 110.00 36025*LEOVO 110.00 6 SINGLE 8 72.4 27.5 34.6 36005*BESARABEASCA110.00 36023 COMRAT 110.00 4 SINGLE 8 72.4 5.4 7.1 36012 ZARNESTI 110.00 36023*COMRAT 110.00 10 SINGLE 8 72.4 11.2 14.9 36012*ZARNESTI 110.00 36038 VULCANESTI 110.00 14 SINGLE 8 72.4 18.0 24.0 36023*COMRAT 110.00 36025 LEOVO 110.00 7 SINGLE 8 72.4 0.0 0.0
P-4
36023*COMRAT 110.00 36028 TARECKLIA 110.00 9 SINGLE 8 85.8 28.0 31.2 36023 COMRAT 110.00 36031*CIADYR 110.00 8 SINGLE 8 84.8 19.3 20.8 36023 COMRAT 110.00 36032*CIMISLIA 110.00 5 SINGLE 8 97.2 29.6 28.4 36028*TARECKLIA 110.00 36038 VULCANESTI 110.00 13 SINGLE 8 84.8 26.2 30.6 36031*CIADYR 110.00 36038 VULCANESTI 110.00 12 SINGLE 8 84.8 57.7 62.3 34057 CHISINAU 110.00 34060*HANCESTI 110.00 3 SINGLE 9 84.8 23.7 27.9 34057 CHISINAU 110.00 36005*BESARABEASCA110.00 1 SINGLE 9 84.8 24.0 26.5 34057 CHISINAU 110.00 36032*CIMISLIA 110.00 2 SINGLE 9 97.2 77.8 74.0 34060 HANCESTI 110.00 36025*LEOVO 110.00 6 SINGLE 9 72.4 33.6 43.3 36005*BESARABEASCA110.00 36023 COMRAT 110.00 4 SINGLE 9 72.4 0.8 1.1 36012 ZARNESTI 110.00 36023*COMRAT 110.00 10 SINGLE 9 72.4 15.9 20.6 36012*ZARNESTI 110.00 36038 VULCANESTI 110.00 14 SINGLE 9 72.4 22.5 29.8 36023 COMRAT 110.00 36025*LEOVO 110.00 7 SINGLE 9 72.4 7.2 9.3 36023*COMRAT 110.00 36028 TARECKLIA 110.00 9 SINGLE 9 85.8 0.0 0.0 36023 COMRAT 110.00 36031*CIADYR 110.00 8 SINGLE 9 84.8 13.4 14.4 36023 COMRAT 110.00 36032*CIMISLIA 110.00 5 SINGLE 9 97.2 22.1 21.1 36028*TARECKLIA 110.00 36038 VULCANESTI 110.00 13 SINGLE 9 84.8 1.2 1.4 36031*CIADYR 110.00 36038 VULCANESTI 110.00 12 SINGLE 9 84.8 63.5 68.2 34057 CHISINAU 110.00 34060*HANCESTI 110.00 3 SINGLE 10 84.8 23.0 27.0 34057 CHISINAU 110.00 36005*BESARABEASCA110.00 1 SINGLE 10 84.8 16.5 18.4 34057 CHISINAU 110.00 36032*CIMISLIA 110.00 2 SINGLE 10 97.2 64.7 61.9 34060 HANCESTI 110.00 36025*LEOVO 110.00 6 SINGLE 10 72.4 25.1 32.7 36005*BESARABEASCA110.00 36023 COMRAT 110.00 4 SINGLE 10 72.4 8.3 10.8 36012 ZARNESTI 110.00 36023*COMRAT 110.00 10 SINGLE 10 72.4 8.3 11.0 36012*ZARNESTI 110.00 36038 VULCANESTI 110.00 14 SINGLE 10 72.4 15.4 20.6 36023 COMRAT 110.00 36025*LEOVO 110.00 7 SINGLE 10 72.4 4.4 5.8 36023*COMRAT 110.00 36028 TARECKLIA 110.00 9 SINGLE 10 85.8 22.7 25.3 36023*COMRAT 110.00 36031 CIADYR 110.00 8 SINGLE 10 84.8 0.0 0.0 36023 COMRAT 110.00 36032*CIMISLIA 110.00 5 SINGLE 10 97.2 35.0 33.5 36028*TARECKLIA 110.00 36038 VULCANESTI 110.00 13 SINGLE 10 84.8 21.0 24.7 36031*CIADYR 110.00 36038 VULCANESTI 110.00 12 SINGLE 10 84.8 76.9 84.4 34057 CHISINAU 110.00 34060*HANCESTI 110.00 3 SINGLE 11 84.8 25.4 29.8 34057 CHISINAU 110.00 36005*BESARABEASCA110.00 1 SINGLE 11 84.8 13.2 14.7 34057 CHISINAU 110.00 36032*CIMISLIA 110.00 2 SINGLE 11 97.2 99.6 96.0 34060 HANCESTI 110.00 36025*LEOVO 110.00 6 SINGLE 11 72.4 21.8 28.3 36005*BESARABEASCA110.00 36023 COMRAT 110.00 4 SINGLE 11 72.4 11.8 15.4 36012 ZARNESTI 110.00 36023*COMRAT 110.00 10 SINGLE 11 72.4 7.1 9.4 36012*ZARNESTI 110.00 36038 VULCANESTI 110.00 14 SINGLE 11 72.4 14.0 18.6 36023 COMRAT 110.00 36025*LEOVO 110.00 7 SINGLE 11 72.4 6.2 8.0 36023*COMRAT 110.00 36028 TARECKLIA 110.00 9 SINGLE 11 85.8 20.1 22.4 36023 COMRAT 110.00 36031*CIADYR 110.00 8 SINGLE 11 84.8 24.5 26.3 36023*COMRAT 110.00 36032 CIMISLIA 110.00 5 SINGLE 11 97.2 0.0 0.0 36028*TARECKLIA 110.00 36038 VULCANESTI 110.00 13 SINGLE 11 84.8 18.7 21.7
P-5
36031*CIADYR 110.00 36038 VULCANESTI 110.00 12 SINGLE 11 84.8 52.4 56.2 34057 CHISINAU 110.00 34060*HANCESTI 110.00 3 SINGLE 12 84.8 23.7 27.8 34057 CHISINAU 110.00 36005*BESARABEASCA110.00 1 SINGLE 12 84.8 23.9 26.4 34057 CHISINAU 110.00 36032*CIMISLIA 110.00 2 SINGLE 12 97.2 77.6 73.7 34060 HANCESTI 110.00 36025*LEOVO 110.00 6 SINGLE 12 72.4 33.5 43.2 36005*BESARABEASCA110.00 36023 COMRAT 110.00 4 SINGLE 12 72.4 0.9 1.2 36012 ZARNESTI 110.00 36023*COMRAT 110.00 10 SINGLE 12 72.4 15.8 20.4 36012*ZARNESTI 110.00 36038 VULCANESTI 110.00 14 SINGLE 12 72.4 22.4 29.7 36023 COMRAT 110.00 36025*LEOVO 110.00 7 SINGLE 12 72.4 7.0 9.1 36023 COMRAT 110.00 36028*TARECKLIA 110.00 9 SINGLE 12 85.8 1.1 1.2 36023 COMRAT 110.00 36031*CIADYR 110.00 8 SINGLE 12 84.8 13.5 14.5 36023 COMRAT 110.00 36032*CIMISLIA 110.00 5 SINGLE 12 97.2 22.3 21.2 36028*TARECKLIA 110.00 36038 VULCANESTI 110.00 13 SINGLE 12 84.8 0.0 0.0 36031*CIADYR 110.00 36038 VULCANESTI 110.00 12 SINGLE 12 84.8 63.4 68.0 34057*CHISINAU 110.00 34060 HANCESTI 110.00 3 SINGLE 13 84.8 23.8 28.0 34057 CHISINAU 110.00 36005*BESARABEASCA110.00 1 SINGLE 13 84.8 25.9 30.5 34057 CHISINAU 110.00 36032*CIMISLIA 110.00 2 SINGLE 13 97.2 82.3 81.9 34060 HANCESTI 110.00 36025*LEOVO 110.00 6 SINGLE 13 72.4 35.4 48.5 36005*BESARABEASCA110.00 36023 COMRAT 110.00 4 SINGLE 13 72.4 6.1 8.4 36012*ZARNESTI 110.00 36023 COMRAT 110.00 10 SINGLE 13 72.4 18.5 25.9 36012 ZARNESTI 110.00 36038*VULCANESTI 110.00 14 SINGLE 13 72.4 24.7 34.4 36023 COMRAT 110.00 36025*LEOVO 110.00 7 SINGLE 13 72.4 12.3 16.9 36023*COMRAT 110.00 36028 TARECKLIA 110.00 9 SINGLE 13 85.8 40.9 48.5 36023 COMRAT 110.00 36031*CIADYR 110.00 8 SINGLE 13 84.8 76.8 85.3 36023 COMRAT 110.00 36032*CIMISLIA 110.00 5 SINGLE 13 97.2 19.3 19.2 36028 TARECKLIA 110.00 36038*VULCANESTI 110.00 13 SINGLE 13 84.8 40.3 47.9 36031*CIADYR 110.00 36038 VULCANESTI 110.00 12 SINGLE 13 84.8 0.0 0.0 MONITORED VOLTAGE REPORT: SYSTEM CONTINGENCY <-------- B U S --------> V-CONT V-INIT V-MAX V-MIN 'SUB ' RANGE BASE CASE 34057 CHISINAU 110.00 1.00253 1.00253 1.10000 0.90000 'SUB ' RANGE BASE CASE 34060 HANCESTI 110.00 1.00370 1.00370 1.10000 0.90000 'SUB ' RANGE BASE CASE 36005 BESARABEASCA110.00 1.06186 1.06186 1.10000 0.90000 'SUB ' RANGE BASE CASE 36012 ZARNESTI 110.00 1.03927 1.03927 1.10000 0.90000 'SUB ' RANGE BASE CASE 36023 COMRAT 110.00 1.05257 1.05257 1.10000 0.90000 'SUB ' RANGE BASE CASE 36025 LEOVO 110.00 1.06497 1.06497 1.10000 0.90000 'SUB ' RANGE BASE CASE 36028 TARECKLIA 110.00 1.01340 1.01340 1.10000 0.90000 'SUB ' RANGE BASE CASE 36031 CIADYR 110.00 1.09688 1.09688 1.10000 0.90000 'SUB ' RANGE BASE CASE 36032 CIMISLIA 110.00 1.07797 1.07797 1.10000 0.90000 'SUB ' RANGE BASE CASE 36038 VULCANESTI 110.00 1.00080 1.00080 1.10000 0.90000 'SUB ' RANGE SINGLE 1 34057 CHISINAU 110.00 1.00000 1.00253 1.10000 0.90000 'SUB ' RANGE SINGLE 1 34060 HANCESTI 110.00 1.00734 1.00370 1.10000 0.90000 'SUB ' RANGE SINGLE 1 36005 BESARABEASCA110.00 1.06102 1.06186 1.10000 0.90000 'SUB ' RANGE SINGLE 1 36012 ZARNESTI 110.00 1.03871 1.03927 1.10000 0.90000 'SUB ' RANGE SINGLE 1 36023 COMRAT 110.00 1.05190 1.05257 1.10000 0.90000 'SUB ' RANGE SINGLE 1 36025 LEOVO 110.00 1.06508 1.06497 1.10000 0.90000 'SUB ' RANGE SINGLE 1 36028 TARECKLIA 110.00 1.01289 1.01340 1.10000 0.90000 'SUB ' RANGE SINGLE 1 36031 CIADYR 110.00 1.09629 1.09688 1.10000 0.90000 'SUB ' RANGE SINGLE 1 36032 CIMISLIA 110.00 1.07667 1.07797 1.10000 0.90000 'SUB ' RANGE SINGLE 1 36038 VULCANESTI 110.00 1.00049 1.00080 1.10000 0.90000 'SUB ' RANGE SINGLE 2 34057 CHISINAU 110.00 1.00239 1.00253 1.10000 0.90000 'SUB ' RANGE SINGLE 2 34060 HANCESTI 110.00 1.00297 1.00370 1.10000 0.90000 'SUB ' RANGE SINGLE 2 36005 BESARABEASCA110.00 1.09945 1.06186 1.10000 0.90000 'SUB ' RANGE SINGLE 2 36012 ZARNESTI 110.00 1.03792 1.03927 1.10000 0.90000 'SUB ' RANGE SINGLE 2 36023 COMRAT 110.00 1.05905 1.05257 1.10000 0.90000 'SUB ' RANGE SINGLE 2 36025 LEOVO 110.00 1.06659 1.06497 1.10000 0.90000 'SUB ' RANGE SINGLE 2 36028 TARECKLIA 110.00 1.01085 1.01340 1.10000 0.90000 'SUB ' RANGE SINGLE 2 36031 CIADYR 110.00 1.09560 1.09688 1.10000 0.90000 'SUB ' RANGE SINGLE 2 36032 CIMISLIA 110.00 1.07896 1.07797 1.10000 0.90000 'SUB ' RANGE SINGLE 2 36038 VULCANESTI 110.00 0.99682 1.00080 1.10000 0.90000
P-6
'SUB ' RANGE SINGLE 3 34057 CHISINAU 110.00 1.00000 1.00253 1.10000 0.90000 'SUB ' RANGE SINGLE 3 34060 HANCESTI 110.00 0.99584 1.00370 1.10000 0.90000 'SUB ' RANGE SINGLE 3 36005 BESARABEASCA110.00 0.98041 1.06186 1.10000 0.90000 'SUB ' RANGE SINGLE 3 36012 ZARNESTI 110.00 0.96062 1.03927 1.10000 0.90000 'SUB ' RANGE SINGLE 3 36023 COMRAT 110.00 0.96774 1.05257 1.10000 0.90000 'SUB ' RANGE SINGLE 3 36025 LEOVO 110.00 0.98874 1.06497 1.10000 0.90000 'SUB ' RANGE SINGLE 3 36028 TARECKLIA 110.00 0.93988 1.01340 1.10000 0.90000 'SUB ' RANGE SINGLE 3 36031 CIADYR 110.00 1.01574 1.09688 1.10000 0.90000 'SUB ' RANGE SINGLE 3 36032 CIMISLIA 110.00 1.03389 1.07797 1.10000 0.90000 'SUB ' RANGE SINGLE 3 36038 VULCANESTI 110.00 0.95769 1.00080 1.10000 0.90000 'SUB ' RANGE SINGLE 4 34057 CHISINAU 110.00 1.00000 1.00253 1.10000 0.90000 'SUB ' RANGE SINGLE 4 34060 HANCESTI 110.00 1.00587 1.00370 1.10000 0.90000 'SUB ' RANGE SINGLE 4 36005 BESARABEASCA110.00 1.05313 1.06186 1.10000 0.90000 'SUB ' RANGE SINGLE 4 36012 ZARNESTI 110.00 1.02777 1.03927 1.10000 0.90000 'SUB ' RANGE SINGLE 4 36023 COMRAT 110.00 1.04769 1.05257 1.10000 0.90000 'SUB ' RANGE SINGLE 4 36025 LEOVO 110.00 1.09532 1.06497 1.10000 0.90000 'SUB ' RANGE SINGLE 4 36028 TARECKLIA 110.00 1.00139 1.01340 1.10000 0.90000 'SUB ' RANGE SINGLE 4 36031 CIADYR 110.00 1.08521 1.09688 1.10000 0.90000 'SUB ' RANGE SINGLE 4 36032 CIMISLIA 110.00 1.07052 1.07797 1.10000 0.90000 'SUB ' RANGE SINGLE 4 36038 VULCANESTI 110.00 0.99118 1.00080 1.10000 0.90000 'SUB ' RANGE SINGLE 5 34057 CHISINAU 110.00 1.00206 1.00253 1.10000 0.90000 'SUB ' RANGE SINGLE 5 34060 HANCESTI 110.00 1.00367 1.00370 1.10000 0.90000 'SUB ' RANGE SINGLE 5 36005 BESARABEASCA110.00 1.07127 1.06186 1.10000 0.90000 'SUB ' RANGE SINGLE 5 36012 ZARNESTI 110.00 1.03886 1.03927 1.10000 0.90000 'SUB ' RANGE SINGLE 5 36023 COMRAT 110.00 1.04945 1.05257 1.10000 0.90000 'SUB ' RANGE SINGLE 5 36025 LEOVO 110.00 1.06352 1.06497 1.10000 0.90000 'SUB ' RANGE SINGLE 5 36028 TARECKLIA 110.00 1.01345 1.01340 1.10000 0.90000 'SUB ' RANGE SINGLE 5 36031 CIADYR 110.00 1.09641 1.09688 1.10000 0.90000 'SUB ' RANGE SINGLE 5 36032 CIMISLIA 110.00 1.07671 1.07797 1.10000 0.90000 'SUB ' RANGE SINGLE 5 36038 VULCANESTI 110.00 1.00165 1.00080 1.10000 0.90000 'SUB ' RANGE SINGLE 6 34057 CHISINAU 110.00 1.00119 1.00253 1.10000 0.90000 'SUB ' RANGE SINGLE 6 34060 HANCESTI 110.00 1.00266 1.00370 1.10000 0.90000 'SUB ' RANGE SINGLE 6 36005 BESARABEASCA110.00 1.06048 1.06186 1.10000 0.90000 'SUB ' RANGE SINGLE 6 36012 ZARNESTI 110.00 1.04270 1.03927 1.10000 0.90000 'SUB ' RANGE SINGLE 6 36023 COMRAT 110.00 1.05290 1.05257 1.10000 0.90000 'SUB ' RANGE SINGLE 6 36025 LEOVO 110.00 1.06365 1.06497 1.10000 0.90000 'SUB ' RANGE SINGLE 6 36028 TARECKLIA 110.00 1.01305 1.01340 1.10000 0.90000 'SUB ' RANGE SINGLE 6 36031 CIADYR 110.00 1.09609 1.09688 1.10000 0.90000 'SUB ' RANGE SINGLE 6 36032 CIMISLIA 110.00 1.07653 1.07797 1.10000 0.90000 'SUB ' RANGE SINGLE 6 36038 VULCANESTI 110.00 1.00278 1.00080 1.10000 0.90000 'SUB ' RANGE SINGLE 7 34057 CHISINAU 110.00 1.00084 1.00253 1.10000 0.90000 'SUB ' RANGE SINGLE 7 34060 HANCESTI 110.00 1.00236 1.00370 1.10000 0.90000 'SUB ' RANGE SINGLE 7 36005 BESARABEASCA110.00 1.06380 1.06186 1.10000 0.90000 'SUB ' RANGE SINGLE 7 36012 ZARNESTI 110.00 1.09994 1.03927 1.10000 0.90000 'SUB ' RANGE SINGLE 7 36023 COMRAT 110.00 1.05864 1.05257 1.10000 0.90000 'SUB ' RANGE SINGLE 7 36025 LEOVO 110.00 1.06666 1.06497 1.10000 0.90000 'SUB ' RANGE SINGLE 7 36028 TARECKLIA 110.00 1.01242 1.01340 1.10000 0.90000 'SUB ' RANGE SINGLE 7 36031 CIADYR 110.00 1.09649 1.09688 1.10000 0.90000 'SUB ' RANGE SINGLE 7 36032 CIMISLIA 110.00 1.07877 1.07797 1.10000 0.90000 'SUB ' RANGE SINGLE 7 36038 VULCANESTI 110.00 1.00050 1.00080 1.10000 0.90000 'SUB ' RANGE SINGLE 8 34057 CHISINAU 110.00 1.00222 1.00253 1.10000 0.90000 'SUB ' RANGE SINGLE 8 34060 HANCESTI 110.00 1.00553 1.00370 1.10000 0.90000 'SUB ' RANGE SINGLE 8 36005 BESARABEASCA110.00 1.05441 1.06186 1.10000 0.90000 'SUB ' RANGE SINGLE 8 36012 ZARNESTI 110.00 1.03317 1.03927 1.10000 0.90000 'SUB ' RANGE SINGLE 8 36023 COMRAT 110.00 1.04280 1.05257 1.10000 0.90000 'SUB ' RANGE SINGLE 8 36025 LEOVO 110.00 1.09759 1.06497 1.10000 0.90000 'SUB ' RANGE SINGLE 8 36028 TARECKLIA 110.00 1.00816 1.01340 1.10000 0.90000 'SUB ' RANGE SINGLE 8 36031 CIADYR 110.00 1.09058 1.09688 1.10000 0.90000 'SUB ' RANGE SINGLE 8 36032 CIMISLIA 110.00 1.07250 1.07797 1.10000 0.90000 'SUB ' RANGE SINGLE 8 36038 VULCANESTI 110.00 0.99846 1.00080 1.10000 0.90000 'SUB ' RANGE SINGLE 9 34057 CHISINAU 110.00 1.00000 1.00253 1.10000 0.90000 'SUB ' RANGE SINGLE 9 34060 HANCESTI 110.00 1.00156 1.00370 1.10000 0.90000 'SUB ' RANGE SINGLE 9 36005 BESARABEASCA110.00 1.06717 1.06186 1.10000 0.90000 'SUB ' RANGE SINGLE 9 36012 ZARNESTI 110.00 1.04055 1.03927 1.10000 0.90000 'SUB ' RANGE SINGLE 9 36023 COMRAT 110.00 1.06587 1.05257 1.10000 0.90000 'SUB ' RANGE SINGLE 9 36025 LEOVO 110.00 1.06962 1.06497 1.10000 0.90000 'SUB ' RANGE SINGLE 9 36028 TARECKLIA 110.00 1.00455 1.01340 1.10000 0.90000 'SUB ' RANGE SINGLE 9 36031 CIADYR 110.00 1.09818 1.09688 1.10000 0.90000 'SUB ' RANGE SINGLE 9 36032 CIMISLIA 110.00 1.08077 1.07797 1.10000 0.90000 'SUB ' RANGE SINGLE 9 36038 VULCANESTI 110.00 1.00228 1.00080 1.10000 0.90000 'SUB ' RANGE SINGLE 10 34057 CHISINAU 110.00 1.00395 1.00253 1.10000 0.90000 'SUB ' RANGE SINGLE 10 34060 HANCESTI 110.00 1.00485 1.00370 1.10000 0.90000 'SUB ' RANGE SINGLE 10 36005 BESARABEASCA110.00 1.05693 1.06186 1.10000 0.90000 'SUB ' RANGE SINGLE 10 36012 ZARNESTI 110.00 1.03083 1.03927 1.10000 0.90000 'SUB ' RANGE SINGLE 10 36023 COMRAT 110.00 1.04255 1.05257 1.10000 0.90000 'SUB ' RANGE SINGLE 10 36025 LEOVO 110.00 1.06047 1.06497 1.10000 0.90000 'SUB ' RANGE SINGLE 10 36028 TARECKLIA 110.00 1.00435 1.01340 1.10000 0.90000 'SUB ' RANGE SINGLE 10 36031 CIADYR 110.00 1.07383 1.09688 1.10000 0.90000 'SUB ' RANGE SINGLE 10 36032 CIMISLIA 110.00 1.07482 1.07797 1.10000 0.90000 'SUB ' RANGE SINGLE 10 36038 VULCANESTI 110.00 0.98853 1.00080 1.10000 0.90000 'SUB ' RANGE SINGLE 11 34057 CHISINAU 110.00 1.00000 1.00253 1.10000 0.90000 'SUB ' RANGE SINGLE 11 34060 HANCESTI 110.00 1.00407 1.00370 1.10000 0.90000 'SUB ' RANGE SINGLE 11 36005 BESARABEASCA110.00 1.05946 1.06186 1.10000 0.90000 'SUB ' RANGE SINGLE 11 36012 ZARNESTI 110.00 1.04276 1.03927 1.10000 0.90000 'SUB ' RANGE SINGLE 11 36023 COMRAT 110.00 1.04423 1.05257 1.10000 0.90000 'SUB ' RANGE SINGLE 11 36025 LEOVO 110.00 1.06307 1.06497 1.10000 0.90000 'SUB ' RANGE SINGLE 11 36028 TARECKLIA 110.00 1.01872 1.01340 1.10000 0.90000
P-7
'SUB ' RANGE SINGLE 11 36031 CIADYR 110.00 1.10000 1.09688 1.10000 0.90000 'SUB ' RANGE SINGLE 11 36032 CIMISLIA 110.00 1.06764 1.07797 1.10000 0.90000 'SUB ' RANGE SINGLE 11 36038 VULCANESTI 110.00 1.00823 1.00080 1.10000 0.90000 'SUB ' RANGE SINGLE 12 34057 CHISINAU 110.00 1.00006 1.00253 1.10000 0.90000 'SUB ' RANGE SINGLE 12 34060 HANCESTI 110.00 1.00171 1.00370 1.10000 0.90000 'SUB ' RANGE SINGLE 12 36005 BESARABEASCA110.00 1.06915 1.06186 1.10000 0.90000 'SUB ' RANGE SINGLE 12 36012 ZARNESTI 110.00 1.04179 1.03927 1.10000 0.90000 'SUB ' RANGE SINGLE 12 36023 COMRAT 110.00 1.06836 1.05257 1.10000 0.90000 'SUB ' RANGE SINGLE 12 36025 LEOVO 110.00 1.07148 1.06497 1.10000 0.90000 'SUB ' RANGE SINGLE 12 36028 TARECKLIA 110.00 1.07314 1.01340 1.10000 0.90000 'SUB ' RANGE SINGLE 12 36031 CIADYR 110.00 1.09949 1.09688 1.10000 0.90000 'SUB ' RANGE SINGLE 12 36032 CIMISLIA 110.00 1.08224 1.07797 1.10000 0.90000 'SUB ' RANGE SINGLE 12 36038 VULCANESTI 110.00 1.00194 1.00080 1.10000 0.90000 'SUB ' RANGE SINGLE 13 34057 CHISINAU 110.00 1.00000 1.00253 1.10000 0.90000 'SUB ' RANGE SINGLE 13 34060 HANCESTI 110.00 0.99793 1.00370 1.10000 0.90000 'SUB ' RANGE SINGLE 13 36005 BESARABEASCA110.00 1.00193 1.06186 1.10000 0.90000 'SUB ' RANGE SINGLE 13 36012 ZARNESTI 110.00 0.98936 1.03927 1.10000 0.90000 'SUB ' RANGE SINGLE 13 36023 COMRAT 110.00 0.98218 1.05257 1.10000 0.90000 'SUB ' RANGE SINGLE 13 36025 LEOVO 110.00 1.00819 1.06497 1.10000 0.90000 'SUB ' RANGE SINGLE 13 36028 TARECKLIA 110.00 0.97160 1.01340 1.10000 0.90000 'SUB ' RANGE SINGLE 13 36031 CIADYR 110.00 1.06273 1.09688 1.10000 0.90000 'SUB ' RANGE SINGLE 13 36032 CIMISLIA 110.00 1.03284 1.07797 1.10000 0.90000 'SUB ' RANGE SINGLE 13 36038 VULCANESTI 110.00 0.99314 1.00080 1.10000 0.90000 CONTINGENCY LEGEND: LABEL EVENTS SINGLE 1 : OPEN LINE FROM BUS 34057 [CHISINAU 110.00] TO BUS 34060 [HANCESTI 110.00] CKT 3 SINGLE 2 : OPEN LINE FROM BUS 34057 [CHISINAU 110.00] TO BUS 36005 [BESARABEASCA110.00] CKT 1 SINGLE 3 : OPEN LINE FROM BUS 34057 [CHISINAU 110.00] TO BUS 36032 [CIMISLIA 110.00] CKT 2 SINGLE 4 : OPEN LINE FROM BUS 34060 [HANCESTI 110.00] TO BUS 36025 [LEOVO 110.00] CKT 6 SINGLE 5 : OPEN LINE FROM BUS 36005 [BESARABEASCA110.00] TO BUS 36023 [COMRAT 110.00] CKT 4 SINGLE 6 : OPEN LINE FROM BUS 36012 [ZARNESTI 110.00] TO BUS 36023 [COMRAT 110.00] CKT 10 SINGLE 7 : OPEN LINE FROM BUS 36012 [ZARNESTI 110.00] TO BUS 36038 [VULCANESTI 110.00] CKT 14 SINGLE 8 : OPEN LINE FROM BUS 36023 [COMRAT 110.00] TO BUS 36025 [LEOVO 110.00] CKT 7 SINGLE 9 : OPEN LINE FROM BUS 36023 [COMRAT 110.00] TO BUS 36028 [TARECKLIA 110.00] CKT 9 SINGLE 10 : OPEN LINE FROM BUS 36023 [COMRAT 110.00] TO BUS 36031 [CIADYR 110.00] CKT 8 SINGLE 11 : OPEN LINE FROM BUS 36023 [COMRAT 110.00] TO BUS 36032 [CIMISLIA 110.00] CKT 5 SINGLE 12 : OPEN LINE FROM BUS 36028 [TARECKLIA 110.00] TO BUS 36038 [VULCANESTI 110.00] CKT 13 SINGLE 13 : OPEN LINE FROM BUS 36031 [CIADYR 110.00] TO BUS 36038 [VULCANESTI 110.00] CKT 12
Q-1
Appendix Q Scenario II – Line Diagram for Line Capacities
Figure Q-1 One line diagram with line capacities
Reactive Power Flow
400 kV Line
330 kV Line
110 kV Line
Active Power Flow
Load
Generator
Three winding
transformer
Switched shunt
Line Offline
R-1
Appendix R Scenario II All Generators – Results
Figure R-1 Shows the iterations with all generators in scenario I.
0
50
100
150
200
250
300
1
56
11
1
16
6
22
1
27
6
33
1
38
6
44
1
49
6
55
1
60
6
66
1
71
6
77
1
82
6
88
1
93
6
99
1
10
46
11
01
11
56
12
11
12
66
13
21
13
76
14
31
14
86
15
41
15
96
16
51
17
06
17
61
18
16
18
71
19
26
19
81
20
36
20
91
21
46
Po
we
r [M
W]
Iteration
Cimislia
Ciadyr
Total Generation
Besarabeasca
Leovo
Zarnesti
R-2
Figure R-2 Histogram over the maximum generation without reactive power compensation
Figure R-3 Results from the second iteration with a narrow interval for each generator
Figure R-4 F Histogram over the maximum generation with reactive power compensation
0
200
400
600
Fre
qu
en
cy
Power [MW]
Generation without reactive power compensation
0
50
100
150
200
250
300
1 6 11 16 21 26 31 36 41 46 51
Po
we
r [M
W]
Iteration
Total Generation
Besarabeasca
Zarnesti
Leovo
Ciadyr
Cimislia
02000400060008000
10000
0-2
02
0-4
04
0-6
06
0-8
06
0-1
00
10
0-1
20
12
0-1
40
14
0-1
60
16
0-1
80
18
0-2
00
20
0-2
20
22
0-2
40
24
0-2
60
26
0-2
80
28
0-3
00
30
0-3
20
32
0-3
40
34
0-3
60
Fre
qu
en
cy
Power [MW]
Generation with reactive power compensation
S-1
Appendix S The Contingency and Automation Process in PSS/E
The Contingency and Automation Process in PSS/E
S-1 Contingency Analysis
PSS/E has an effective way of performing a contingency analysis without having to trip each line by
itself manually. To execute a contingency analysis in PSS/E you will first have to create files of three
different file types; one that describe the subsystem concerned by the analysis (.sub), one that
describes what changes should be mad in the system (.con) and finally one that controls which values
that should be monitored (.mon). These files then combine in the Distribution Factor Data File (.dfx)
which in turn is used to create the Contingency Solution Output file (.acc) which gives you the
contingency report with the specified data given. The .sub, .con and .mon files can be automatically
created within PSS/E or manually.
Different kind of reports can be given but the main ones are the Spreadsheet Overload report, the
Spreadsheet Load report and the Available Capacity report, all these reports are spreadsheet
compatible. The overload report names branches that have been overloaded during the contingency
analysis and/or busses whose voltage levels deviate from the given levels in the monitor file. The
load report shows voltage values and used capacity for all busses and branches defined in the
subsystem file. The capacity report shows the contingency worst case run; it shows you all the busses
in the subsystem file together with the highest usage of line capacity during the entire contingency
study, which line that was tripped for each worst case scenario is also given. There are also non
spreadsheet reports for the first two stated and also a Non-converged network report which is
important to find solutions that have not converged aka “blown ups”.
For the creation of the Subsystem Description Data File one have to choose a specific area (busses,
branches etc.) of which to study, the area can be selected in several ways using the program
description of area, zones, by owners, by base kV or by simply hand picking the specific busses
needed for the intended contingency analysis. Several subsystems can be defined and studied at
once, up to one hundred different subsystems can be included in one .sub file. The default code
created by PSS/E is as follows:
COM SUBSYSTEM description file entry created by PSS®E Config File Builder
SUBSYSTEM 'example'
'Bus nr'
'Bus nr'
END
Busses are entered by the command BUS followed by the bus number before the end statements,
the same true for areas (AREA), zones (ZONE), owners (OWNER), per kV level (KV) followed by the
specified kV level. The COM statement is followed by a comment to the sub, mon and con files.
When creating the Monitored Element Data File in PSS/E options are given for which voltage range
that is to be monitored as maximum and minimum, also it is possible to specify a specific voltage
deviation. The default code created by the PSS/E with all branches and busses specified in the
subsystem monitored is as follows:
S-2
COM MONITORED element file entry created by PSS®E Config File Builder
MONITOR VOLTAGE RANGE SUBSYSTEM 'example' 0.950 1.050
MONITOR BRANCHES IN SUBSYSTEM 'example'
END
If any specific branch, bus, transformer etc. would need extra supervision it can be added before the
end statement.
The Automatic Contingency File given by PSS/E looks as follows:
COM CONTINGENCY description file entry created by PSS®E Config File Builder
SINGLE BRANCH IN SUBSYSTEM 'example'
END
This is done with the assumption that only the tripping of a single branches are under interest and
thus the only selected criteria while creating the file in PSS/E. Other branches can be included by
using the statement 'branch nr' TO 'branch nr ' See Appendix Tfor sub, mon and con files used in the
simulations. [33]
S-2 The Automation Process
There are several ways to automate a process with PSS/E; the main methods are connected to the
creation of response files. The response files can be created using the PSS/E recorder function where
the basic principle is that the recorder, after started, records your actions within PSS/E and saves the
“commands” in a response file.
Figure S-1 Shows the recorder function within PSS/E
The basic response file with the file extension .idv creates a response file with the PSS/E batch
commands. This makes it a viable option for basic automations such as changing bus values or
generator output but for more advance operations. For more advance operations where it is
necessary to directly write new commands within the response file it is necessary to be familiar with
the PSSE batch commands. [33]
To facilitate the automation process IPLAN has been developed as a direct programing language
design for PSS/E. With IPLAN it is not possible to create a response file directly with the recorder i.e.
the file or script has to be written manually in a text editor. Being developed specifically for PSS/E it
does not have the diversity of a modern programing language. [33]
From version PSS/E-30 the program comes with an interface making it possible to implement Python
programing in the automation process [34]. Python is a modern, powerful, dynamic, interpreted
S-3
object-oriented program language often compared to Tcl, Perl, Ruby, Scheme or Java [35]. The
Python script can be created through the recorder function in PSS/E, as were the case for the idv
files, but now with the Python extension .py. Python programing language makes editing of the
produced script much easier. It is of course also possible to create the script from scratch in a text
editor to grasp each function fully. [33]
To run a response file or a Python script file one can go through the recorder function; pressing play
gives you the option to open a file which if opened automatically runs it. The main module, psspy, is
a wrapper function for the PSS/E Application Program Interface (API). PSS/E also comes with a built in
Python interpreter, the IDLE interactive interpreter Python Shell, this shell opens by running the
RunIdle.py file which is included in the EXAMPLE directory in the PSS/E folder. The IDLE shell is a
platform making it possible to edit and run the Python script. It also has an extensive help function
clarifying built in modules in the API. [36]
T-1
Appendix T Sub, Mon and Con files for the contingency analysis
Figure T-1 Contingency file created for the contingency analysis
Figure T-2 Monitor file created for the contingency analysis
Figure T-3 Subsystem file created for the contingency analysis
U-1
Appendix U Division of the Work Between the Authors
The report has two authors where some of the work has been performed together and some parts
are the responsibility of a single author. Below follows a description dividing the responsibilities.
The background to the project was necessary for a joint discussion leading up to the aim and
goals of the project, in this part all necessary contacts were made. This section is not possible
to divide between the two authors.
The theory can be divided as parts written by one single author:
o Active and reactive power – Joel Eriksson
o Introduction to the electrical system – Simon Gozdz Englund
o Components in the grid – Simon Gozdz Englund
o Per-Unit system – Joel Eriksson
o Equivalents in electrical system – Joel Eriksson
o Static Modelling – Joel Eriksson
The wind power research was the responsibility of Simon Gozdz Englund
The method with constructing the model was based on an iterative process where parts
were successively created; the process cannot be divided between the two authors.
The automation process, using Python programming, within PSS/E was the responsibility of
Joel Eriksson
The scenarios were jointly decided and executed by Joel Eriksson
The economic aspects were the responsibility of Simon Gozdz Englund
The discussion was a carried out between the two authors and must thus be the
responsibility of both of the authors.
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