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M706SM DETERMINE MINING LIMITS FROM THE GSM

PROGRAM SUMMARY

M706SM is used to determine the vertical mining limitsbased upon the maximum stripping ratio and mining andquality parameters. It calculates stripping ratio, overbur-den and seam thickness, and the lowest minable pit eleva-tion within each ver tical column of the Gridded SeamModel.

PROGRAM FLOW DIAGRAM

RUN FILE:

INPUT: CALCS:

OUTPUT:

REQUIREMENTS AND CONSIDERATIONS

This program is used to determine the vertical mininglimit (lowest elevation) in a GSM (File 15) from variousmining and quality criter ia . This mining limit is stored forlater use by the M708SM reserve program to define sur -face and deep reserves.

The total thickness of coal and waste, str ip ratio andlowest minable elevation in each vertical column arestored in the GSM Summary File (File 14). This file maybe displayed by the M606 and M607 programs. It may alsobe updated by the M610-series programs to a llow con-tinuous mining through small waste areas.

The GSM should be displayed and checked before run-ning M706SM. Seams should contain valid elevations andbe continuous within the areas of interest, as suggested inthe introduction to this section.

M706SM is often run several times. The first run is usedto determine the total available coal without applyingquality parameter limits or seam limits. Subsequent runscan be made with various limits applied and multipleFiles 14 can be used to store the results from these vari-ous runs. The area to be included in the M706SM run isspecified in GSM columns and rows. This area will de-fault to the full model if limits are not entered. There arethree items of information that must exist for each blockprior to an M706SM run. Surface elevations for eachblock must reside in a File 13. The top elevation of eachseam (Z TOP) and seam thickness (THICK) must bestored in a GSM File 15.

Pr ior to running M706SM, a GSM Summary File (File 14)must be initialized with M102TS/V1 and M601V1. Thefollowing five items must be included:

OVBDN – OverburdenTFE ED – Coal thicknessMINED – MinabilityZ PIT – Pit e levationRATIO – Str ipping ratio (OVBDN/TFEE D)

M102TS will automatically provide these File 14 descrip-tors if you do not have an auxiliary file. The defaultminimum and maximum for each item may have to bechanged.

- Seam numbers

- Row & colum n range

- Mining param eters

- Item labels

- PCF

- File 13

- File 15

- Sum coal and waste forspecified b locks and seamsin the GSM

- Output data to File 14

- File 14

- Row by row sum mary fi le

- Printer Output File

MineSight®Proprietary Software: Mintec, Inc. M706SM - DETERMINE MINING LIMITS FROM THE GSM

Revised: 1–August–94 Page 706SM-1

M706SM will stor e the tota l waste in a column inOVBDN, the total coal thickness in TFE ED, the bottomof the last coal seam in Z PIT and the stripping ratio(OVBDN/TFE ED) in RATIO .

The calculation of total thickness of coal and waste isdone according to the following rules. For each gr id cell:

1. Top of seam must be at or below surface topography.If not, only the thickness of the seam below topogra-phy is used.

2. Subtract mining loss from seam thickness and add towaste.

3. Top of seam must be above the maximum miningdepth. If the top is above, but the bottom isn’t, theentire seam is used.

4. Subtract weathering depth. Any weathered coal isadded to waste.

5. D ilution thickness is added to coal. Normally dilutionis taken from above the seam. However, if d ilutionthickness is less than waste above seam, dilution istaken from bottom of seam.

6. Coal thickness must be equal to or greater than theminimum seam thickness. If not, the coal is consid-ered waste.

7. Quality parameters must be within the limits speci-fied. If not, the coal is considered waste.

8. The stripping ratio must be less than or equal to themaximum value specified for all seams.

See the Technical Section for more descr iption. Quanti-tative items, such as tons of cleaned coal, mega-BTUs,etc. may be used with or in place of quality items. Quan-titative items are summed as compared to quality itemswhich are averaged.

Restriction

M706SM is limited to a maximum of 20 seams used duringa single run.

MineSight®M706SM - DETERMINE MINING LIMITS FROM THE GSM Proprietary Software: Mintec, Inc.

Page 706SM-2 Revised: 1–August–94

M706SM—DETERMINE MINING LIMITS FROM THE GSM

RUN FILE OPERATION

1. NAMES LINE (must be the first line entered)

ME DS-706SM 10= filename 13= filename 14= filename;ME DS-706SM 15= filename 19= filename 3= filenamewhere

ME DS-706SM (must be the first 10 columns)10= the name of the PROJE CT CONTROL FILE13= the name of the 2-D SU RFACE FILE14= the name of the GSM SU MMARY FILE (optional)15= the name of the GRIDDE D SE AM MODEL FILE19= the name of the ASCII Row by Row Summary File 3= the name of the PRINTE R OUTPU T FILE

2. RUN INFORMATION LINE (max. of 80 columns)

A single line of text that will be printed at the top of each page of pr inter output from the run.

3. RUN OPTIONS ( in any order & free-field format )

U SR = U SE R INITIALS (e.g. ABC)

IOP2 = 0 USE A LL SE AMS BE TWE E N IOP9 & IOP10= 1 RE AD GSM SE AM RE F#

NOTE : If IOP2= 1, then IOP9= 1 and IOP10= total # of seams.

IOP4 = 0 USE IOP5-8 VALU E S FOR A RE A OF TH E R UN= 1 RE AD SE VE RAL COLUMN & ROW SPE CIFICATIONS

IOP5 = FIRST GSM COLUMN TO ACCE SS (Default= 1)IOP6 = LAST GSM COLUMN TO ACCE SS (Default= NX)

IOP7 = FIRST GSM ROW TO ACCE SS (Default= 1)IOP8 = LAST GSM R OW TO ACCE SS (Default= NY)

IOP9 = FIRST GSM SE AM TO ACCE SS (Default= 1)IOP10 = LAST GSM SE AM TO ACCE SS (Default= NZ)

NOTE : If IOP2= 1, set IOP10= # of seams to read.

IOP11 = 0 OMIT E XTRA OU TPUT= n ROW NU MBE R FOR E XTE NDE D PRINT OUTPUT

IOP14 = 0 FOR R E GULAR SUMMARY OF WASTE & FE ED= 1 NO SUMMARY OF WASTE & FE E D (if coal does not meet specifications)

IOP16 = LOWE ST SE AM TO CH E CK MINING LIMITS (Default= L ast Seam)



IOP17 = 0 MINING LOSS IN UNITS O F PE RCE NT OF SE AM THICKNE SS= 1 MINING LOSS IN UNITS O F THICKNE SS

NOTE : Also set if CMD= U SE PCT LOSS1 or CMD= USE TH ICK LOSS1.

IOP18 = 0 CLE ANING LOSS IN UNITS OF PE RCE NT O F SE AM TH ICKNE SS= 1 CLE ANING LOSS IN UNITS OF TH ICKNE SS

NOTE : Also set if CMD= U SE PCT LOSS2 or CMD= USE TH ICK LOSS2.

IOP19 = 0 CHE CK SEAM TH ICKNE SS BE FORE MINING & CLE ANING LOSSE S= 1 CHE CK SEAM TH ICKNE SS AFTE R MINING & CLE ANING LOSSE S

PAR1 = D E FAULT DILUTION THICKNE SS

NOTE : For each seam not specified in a CMD= INCL SE AM DILTN ...

PAR2 = D E FAULT MINING LOSS (PRIMARY LOSS), PE RCE NT OR THICKNE SS

NOTE : As specified by IOP17 or CMD. This loss is the tota l loss at the top and bottomof each seam not specified in a CMD= INCL LOSS... Specify in percent or thickness de-pending upon IOP17.

PAR3 = WE ATHE RING DEPTH (Default= 0)

NOTE : Any coal that is within weathered zone is considered waste.

PAR4 = MAXIMUM MINING DE PTH (Default= 9999)

PAR6 = MAXIMUM OVE RALL STRIP RATIO (TOTAL WASTE /TOTAL FE E D) (Default= 99)

PAR7 = COAL IMPE RIAL TONNAGE FACTOR (CU.FE ET/TON OF COAL)

NOTE : Use coal specific gravity for metr ic units. This parameter is required.

PAR8 = D IVISOR FOR OUTPUT TOTALS (Default= 1000)

PAR10 = 0 CRE ATE FILE 14 (a ll items will be reset)= 1 UPDATE FILE 14 (used for secondary areas)

PAR11 = D E FAULT CLE ANING LOSS (SE CONDARY LOSS), PE RCENT OR TH ICKNE SS

NOTE : As specified by IOP18 or CMD.



To specify equipment waste factors for each seam (optional)

CMD = E QU IP WASTE FACTOR nn iseam jseamwhere

nn = str ipping index multip lieriseam = first seam# for th is factorjseam = last seam# for th is factor

When this opt ion is used , overburden thicknesses will be mult ip lied by the stripping index mult ip lieronly for the determinat ion of the ver tica l mining limit. Resource calculations will not use the exagger -ated thickness. The stripping index multip lier is based on the lowest cost equipment being unity (one)and other equipment hor izons being a mult ip le of the lowest cost (higher cost/lower cost).

To specify mining & cleaning losses by seam (optional)

CMD = INCL LOSS mining cleaning seam#where

mining = mining losscleaning = cleaning lossseam# = seam to which loss is to be applied

I f this command is not used, PAR2 and PAR11 will be used for mining and cleaning losses.

To specify losses in terms of percent or th ickness

CMD = USE PCT LOSS1 (for mining loss in percent—(Default)CMD = USE PCT LOSS2 (for c leaning loss in percent—(Default)CMD = USE THICK LOSS1 ( for mining loss in thickness)CMD = USE THICK LOSS2 ( for cleaning loss in th ickness)

NOTE : You can optionally use IOP17 and IOP18.

To specify minimum thickness for each seam (optional)

CMD = INCL MIN THICK min-value seam#where

min-value = minimum acceptable th icknessseam# = seam number

To specify dilution thickness for each seam (optional)

CMD = INCL SE AM DILTN thick seam#

Thickness of seam will be increased and thickness of waste decreased by thick for each specified seam.The quality p arameters will not be diluted. If not specified, PAR1 will be used.



To limit by File 13 topography (REQU IRE D)

ITMn = label-13 TOPO min maxwhere

label-13 = File 13 topography itemTOPO = Keyword for the programmin = Minimum acceptable top omax = Maximum acceptable topo

NOTE : If min and max are 0, a ll topo is used.

To limit by the seam top in File 15 (REQU IRE D)

ITMn = label-15 Z TOP min maxwhere

label-15 = File 15 top of seam itemZ TOP = Keyword for the programmin = Minimum acceptable Z TOPmax = Maximum acceptable Z TOP

NOTE : If min and max are 0, a ll seam tops are used.

To limit by the thickness of coal in File 15 (RE QUIRE D)

ITMn = label-15 COAL min maxwhere

label-15 = File 15 coal thickness itemCOAL = Keyword for the programmin = Minimum acceptable thicknessmax = Maximum acceptable th ickness

NOTE : If min and max are 0, a ll th icknesses are used.

To limit reserves by ranges on quality parameters (op tional)

ITMn = label-15 Q.P. min maxwhere

label-15 = File 15 quality parameter ( i.e., BTU)Q.P. = Keyword for the programmin = Minimum acceptable Q .P.max = Maximum acceptable Q .P.

NOTE : If min and max are 0, a ll quality parameters are used.



To limit reserves by ranges on quantity items (opt ional)

ITMn = label-15 QUANT min max divisorwhere

label-15 = File 15 quantity itemQUANT = Keyword for the programmin = Minimum acceptable valuemax = Maximum acceptable valuedivisor = Factor to reduce quantity item

To specify a parting item in the GSM (opt ional)

ITMn = label-15 PART

Coal thickness will be reduced by the part ing value.

Other commands (optional)

CMD = STORE ITE MS ovbdn tfeed rat io spit seam# (optional)

I f item labels are omitted, the first four items will be automatically stored.

CMD = COAL UNITS ARE label (optional)CMD = WASTE UNITS ARE label (optional)where

L abel is VOL, VOLUME , ME TE RS, YARDS, TON or TONNE . Default is TONS.

E ND

4. SEAM REFERENCE NUMBER LINES ( If IOP2= 1)

U p to 20 seam reference numbers per line in free-field format are allowed. I f there are more than 20seams, use a second reference number line.



5. AREA SPECIFICATION LINES

Specify areas for calculations in one of the following ways:

• IOP4= 1 with column and row limit lines conta ining:

kseq IX1 IX2 IY1 IY2 IZ1 IZ2where

kseq = sequence number for output identificationIX1 = first column of areaIX2 = last column of areaIY1 = first row of areaIY2 = last row of areaIZ1 = first seam of areaIZ2 = last seam of area

• IOP4= 0 with area specified by IOP5-8.



M706SM SAMPLE RUN FILE # 1

COAL -706SM 10= COAL10.DAT 13= COAL13.DAT 14= COAL14.DAT;COAL -706SM 15= COAL15.DAT 19= SUM706.A 3= COL706.LA** DE TE RMINE U NRE STRICTE D MAXIMUM MINABLE LIMITS **

U SR = A BC

IOP2 = 0 / 0= USE ALL SE AMS IOP9-10; 1= RE AD SE AM RE F# TO BE USE DIOP5 = 01 00 / FIRST & LAST GSM COLUMNS TO USEIOP7 = 01 00 / FIRST & LAST GSM ROWS TO USEIOP9 = 1 3 / FIRST & LAST GSM SE AMS TO U SE

PAR1 = 0.0 / D ILUTION THICKNE SSPAR2 = 0.0 / MINING LOSS: SU M OF TOP & BOTTOM SE AM LOSSPAR3 = 0.0 / WE ATHE RING DEPTHPAR4 = 9999. / MAXIMUM MINING DE PTHPAR6 = 9999. / MAX. OVE RALL STRIP RATIO (CU.YD. WASTE/TONS COAL)PAR7 = 25.0 / COAL TONNAGE FACTOR (CU.FT/TON COAL)PAR8 = 1000. / D IVISOR FOR OUTPUT TOTALS

ITM1 = TOPOG TOPO 0.0 0.0COM RE QU IRE D SURFACE E LE VATION FROM FILE 13

ITM2 = Z TOP Z TOP 0.0 0.0COM RE QU IRE D TOP OF SE AM E LE VATION FROM FILE 15

ITM3 = THICK COAL 0.0 0.0COM RE QU IRE D SE AM THICKNE SS VALU E FROM FILE 15

E ND




COAL -706SM 10= COAL10.DAT 13= COAL13.DAT 14= COAL14.DAT;COAL -706SM 15= COAL15.DAT 3= COL706.LB 19= SU M706.A0** SA MPLE RUN — MINABLE LIMITS AT 15:1 STRIP RATIO**

U SR = A BC

IOP2 = 0 / 0= USE ALL SE AMS IOP9-10; 1= RE AD SE AM RE F# TO BE U SE DIOP5 = 1 00 / FIRST & LAST GSM COLS TO U SEIOP7 = 1 00 / FIRST & LAST GSM ROWS TO USEIOP9 = 1 3 / FIRST & LAST GSM SE AMS TO USEIOP11 = 50 / R OW # FOR E XTE NDE D OUTPUT

PAR1 = 0.0 / D ILUTION THICKNE SSPAR2 = 0.0 / MINING LOSS: SU M OF TOP & BOTTOM SE AM LOSSPAR3 = 0.0 / WEATHE RING DE PTHPAR4 = 1000 / MAX. MINING DE PTHPAR6 = 15.0 / MAX. OVE RALL STRIP RATIO (YD. WASTE /TONS COAL)PAR7 = 25.0 / COAL TONNAGE FACTOR (CU.FT/TON COAL)PAR8 = 1000 / D IVISOR FOR OUTPUT TOTALS

I-O = 1ITM1 = TOPOG TOPO 0 0COM REQU IRE D FILE 13 TOPOG E LE VATION

ITM2 = Z TOP ZTOP 0 0COM REQU IRE D FILE 15 TOP O F SE AM E LE V

ITM3 = THICK COAL 0 0COM REQU IRE D FILE 15 SE AM TH ICKNE SS

ITM4 = BTU Q.P. 0 0ITM5 = SU LF Q.P. 0 0

CMD = STORE ITE MS OVBDN TFE E D RATIO Z PIT

CMD = COAL UNITS ARE TONCMD = WASTE U NITS ARE YARDS

E ND




COAL -708SM 10= COAL10.DAT 13= COAL13.DAT 15= COAL15.DAT; COAL -708SM 19= COL708.OC 3= COL708.LC** GE OLOGIC R E SE RVE S WITH MIN. SE AM TH ICKNE SS = 1.5 FE E T

DOC MAX. MINING DE PTH FROM SURFACE = 500 FE E TDOC WE ATHE RING DE PTH = 20 FE E T; SE AM LOSSE S

U SR = A BCCOM* GE OL. RE SE RVE S @ + 1.5FT, MINE PARM SE T# 1

IOP1 = 0 / 0= CALC MINING LIMITS (TOPOG-PAR4); 1= RE AD LIMITS FROM FILE 14IOP2 = 0 / U SE ALL SEAMS; IOP9-10IOP3 = 0 / 0= CALCULATE OVE RBURDE N (OPE N PIT) ; 1= IGNORE (UNDE RGROU ND)IOP4 = 1 / SUMMARIZ E RE SE RVE S FROM COLUMN & ROW SPE CIFICATIONS

IOP9 = 1 / FIRST GSM SE AM TO U SEIOP10 = 3 / LAST G SM SE AM TO U SE

PAR1 = 0.0 / D ILUTION THICKNE SSPAR2 = 0.4 / MINING LOSS: SU M OF TOP & BOTTOM SE AM LOSSCMD = INCL LOSS 0.7 0.0 1 / DRAGLINE LOSS SE AM # 1PAR11 = 0.0 / CLE ANING LOSS (SE CONDARY LOSS)PAR3 = 20. / WE ATHE RING DEPTHPAR4 = 500. / MAXIMUM MINING DE PTHPAR6 = 10. / MAX. OVE RALL STRIP RATIO (CU.YD. WASTE/TONS COAL)PAR7 = 25.0 / COAL TONNAGE FACTOR (CU.FT/TON COAL)PAR8 = 1000. / D IVISOR FOR OUTPUT TOTALS

ITM1 = TOPOG TOPO 0.0 0.0COM RE QU IRE D TOPO SU RFACE ITE M FROM FILE 13ITM2 = Z TOP Z TOP 0.0 0.0COM RE QU IRE D TOP OF SE AM E LE V. FROM FILE 15ITM3 = THICK COAL 1.5 0.0COM RE QU IRE D SE AM THICKNE SS FROM FILE 15

ITM4 = BTU Q.P. 0.0 0.0 / QUALITY PARAME TE RITM5 = ASH Q.P. 0.0 0.0 / QUALITY PARAME TE RITM6 = SULF Q.P. 0.0 0.0 / QUALITY PARAME TE RITM7 = MOIST Q.P. 0.0 0.0 / QUALITY PARAME TE R

I-O = 1E ND1 1 72 1 96 1 3




COAL -706SM 10= COAL10.DAT 13= COAL13.DAT 14= COAL14.DAT; COAL -706SM 15= COAL15.DAT 3= COL706.LD** DE TE RMINE MINABLE LIMITS WITHIN CONSTRAINTS **

U SR = A BC

IOP1 = 15 / U SE THE GSMIOP2 = 0 / 0= USE ALL SE AMS IOP9-10; 1= RE AD SE AM RE F# TO BE U SE DIOP5 = 1 / FIRST GSM COLUMN TO USEIOP6 = 0 / LAST G SM COLUMN TO USE (0= DE FAULT TO PCF)IOP7 = 1 / FIRST GSM ROW TO USEIOP8 = 0 / LAST G SM R OW TO USE (0= DE FAULT TO PCF)IOP9 = 1 / FIRST GSM SE AM TO U SEIOP10 = 3 / LAST G SM SE AM TO U SE

PAR1 = 0.25 / D ILUTION THICKNE SSPAR2 = 0.40 / MINING LOSS FOR ALL SE AMS, EXCE PT FOR # 1PAR3 = 20.0 / WEATHE RING DE PTHPAR4 = 500. / MAX MINING DE PTHPAR6 = 10.0 / MAX S.R .PAR7 = 25.0 / COAL TONNAGE FACTOR

PAR11 = 0.70 / MINING LOSS FOR SE AM # 1, DUE TO DRAGLINE

ITM1 = TOPOG TOPO 0.0 0.0COM REQU IRE D SURFACE E LE VATION FROM FILE 13

ITM2 = Z TOP ZTOP 0.0 0.0COM REQU IRE D TOP OF SE AM E LEVATION FROM FILE 15

ITM3 = THICK COAL 1.5 0.0COM REQU IRE D SE AM TH ICKNE SS VALU E FROM FILE 15

ITM4 = BTU Q.P. 9000. 15000.COM OPTIONAL Q UALITY PARAME TE R CONSTRAINTS

ITM5 = MOIST Q.P. 0.0 15.0COM OPTIONAL Q UALITY PARAME TE R CONSTRAINTS

ITM6 = ASH Q.P. 0.0 12.0COM OPTIONAL Q UALITY PARAME TE R CONSTRAINTS

ITM7 = SU LF Q.P. 0.00 1.00COM OPTIONAL Q UALITY PARAME TE R CONSTRAINTS

E ND



HOW TO DEBUG AN M706SM RUN

1. Test M706SM on a small area (IOP5-8) and set I-O= 2 and IOP11= row number for debug. Checkcalculations by hand to ensure accuracy.

2. ** M706SM ERROR: NZ NOT SET IN PCF

will occur if you let IOP9 default and the PCF does not have a value for DZ.

3. ** ERROR READING FILE # 13 FOR ROW xxx** ERROR READING FILE # 14 FOR ROW xxx** ERROR READING FILE # 15 FOR ROW xxx

will occur if there is a problem reading data from the M i n e S i g h t ® Data Files.

4. FILE 14 EXISTS, BUT HAS NOT BEEN INITIALIZED WITH M601V1M601V1 MUST BE RUN TO SET FILE 14 TO INITIAL VALUES

M601V1 must be run to in itialize File 14 after it has been created with M102TS/V1.

5. ** ERROR: PAR7 TONNAGE FACTOR NOT SET **

Program will set the tonnage factor equal to 1.0 and continue to run.

6. ** THERE ARE ERRORS IN THE MINING LOSSES **** THE PERCENT LOSS IS GREATER THAN 99% **

E ither the primary or secondary loss has been calculated as greater than 0.99. Check the run file.

7. Check the Mi n e S i g h t ® er ror messages in the Appendix.



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MineSight®

Proprietary Software: Mintec, inc. M708SM - GSM RESERVE CALCULATIONS

Revised: 24-Oct-04 Page 708-9

IOP28 = 0 BLK% ITEM IS APPLIED AGAINST BOTH ORE AND WASTE= 1 BLK% ITEM IS APPLIED AGAINST ORE ONLY

IOP29 = OPTIONAL CUT/BLOCK NUMBER TO USE FOR PARTIALS FILE (when IOP4 = -1)

IOP30 = 1 WEIGH Q.P. VALUES BY TONNAGE

PAR1 = DEFAULT DILUTION THICKNESS FOR EACH SEAM NOT SPECIFIED IN CMD=INCL SEAM DILTN...

PAR2 = DEFAULT MINING LOSS (Primary Loss)

NOTE: Percent or thickness as specified by IOP17 or CMD. This loss is the total loss at the top andbottom of each seam not specified in CMD=INCL LOSS...

PAR3 = WEATHERING DEPTH TO WASTE SEAM (FEED) MATERIAL (optional)

PAR4 = MAXIMUM MINING DEPTH TO APPLY FROM ORIGINAL TOPO SURFACE (If IOP1=0)= MINIMUM MINING ELEVATION (If IOP1=1)

(mine down to this elevation, but not below)

PAR7 = COAL IMPERIAL TONNAGE FACTOR (cu.feet/ton of coal)

NOTE: Use coal specific gravity for metric units.

PAR8 = DIVISOR FOR OUTPUT TOTALS (Default=1000)

PAR11 = DEFAULT CLEANING LOSS (SECONDARY LOSS)

NOTE: Percent or thickness as specified by IOP18 or CMD.

ITMn = label-14 ZPIT (Default=ZPIT)or label-13 ZPIT (Default=ZPIT)

NOTE: Label-14 (or label-13) is the vertical mining limits stored in File 14 (File 13). Use if IOP1=1.

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M708S0 CREATE AN AUXILIARY SCHEDULE FILE

PROGRAM SUMMARY

M708S0 reads extra volume data lines from the run file( i.e. for extra waste areas) and creates a new binaryschedule file.


RUN FILE:

INPUT: CALCS:

OUTPUT:


This routine will create an auxiliary binary schedule file(unsor ted) which can be appended to a schedule file fromM708SM. This file usually contains extra volume informa-tion for waste areas.

Extra volume is specified by:

seq# = Sequence numbercol = Column of modelrow = Row of modelzref = Seam reference numberquant = Volume of wastethick = Thickness of overburden/interburden

Thick value is optional. If missing, thickness is quant/areaand block partial is 100%. If thickness value is provided,block partial is calculated.

The pattern number in the schedule file is generated withthe CMD = MOVE CUT and CMD = MINE CUTcommands. See M708SM documentation for more infor-mation on these options.

- Schedule com mand

- Direct ion of cuts

- Extra volume data

- PCF - Generate a new binaryschedule fi le with a patternnumber

- Binary (unsorted) schedulef ile


MineSight®

Proprietary Software: Mintec, Inc. M708S0 - CREATE AN AUXILIARY SCHEDULE FILE

Revised 30–September–93 Page 708S0-1

M708S0—CREATE AN AUXILIARY SCHEDULE FILE

RUN FILE OPERATION

1. NAMES LINE (must be first line entered)

ME DS-708S0 10= filename 19= filename 3= filenamewhere

ME DS-708S0 (must be t he f irst 10 colu mns)10= the name of the PROJE CT CONTROL FILE19= the name of the Output Unsor ted Schedule File 3= the name of the PRINTE R OUTPU T FILE

2. RUN INFORMATION LINE (max. of 80 colu mns)

A sin gle line of text that will be printed at t he top of each page of pr in ter output from the run.

3. RUN OPTIONS ( in any order & free-f ield format )

U SR = USER INITIALS (e.g., ABC)

PAR7 = TONNAGE FACTOR

CMD = SCHE D FE E D rateCMD = SCHE D WASTE rate

where rate is the target amount

CMD = MOVE CUTS directionCMD = MINE CUT1 direct ion TO directionCMD = MINE CUT2 direct ion TO direction

where direction is one of N, S, E or W.

E ND

4. EXTRA VOLUME DATA LINES ( free format )

seq# col row zref quant th ickwhere

seq# = Sequence numbercol = Colu mn of modelrow = Row of modelzref = Seam reference n umberquant = Volu me of wastethick = Optional valu e for t hickness of overburden/interburden.

NOTE : If m issin g, thickness is quant/area and block partial is 100%. If th ickness valu e isprovided, block part ia l is calculated .

MineSight®Proprietary Software: Mintec, Inc. M708S0 - CREATE AN AUXILIARY SCHEDULE FILE


M708S0 SAMPLE RUN FILE

COAL -708S0 10= COAL10.DAT 3= COL708.LA0 19= COL708.OSC** CRE ATE A NE W SCH E DU LE FILE **

U SR = ABC

PAR7 = 10.0CMD = SCHE D FE E D 50000. / 500000 TONS OF COALCMD = MOVE CUTS NORTH / MINING D IRE CTIONCMD = MINE CUT1 E AST TO WE ST / MINING DIRE CTION FOR ODD CUTSCMD = MINE CUT2 E AST TO WE ST / MINING DIRE CTION FOR E VE N CU TS

E ND1 10 10 10 100001 11 10 10 100001 12 10 10 110001 13 10 10 14000 1.11 14 10 10 11000 1.21 15 10 10 12000 .91 10 11 10 10000 2.01 11 11 10 100001 12 11 10 110001 13 11 10 140001 14 11 10 110001 15 11 10 120001 10 12 10 100001 11 12 10 100001 12 12 10 110001 13 12 10 140001 14 12 10 110001 15 12 10 120001 10 13 10 100001 11 13 10 100001 12 13 10 110001 13 13 10 140001 14 13 10 110001 15 13 10 12000

HOW TO DEBUG AN M708S0 RUN

1. INCORRECT ENTRY

I f you omit the CMD = M OVE CUTS or CMD = MINE CU Tn from the run file, you will beprompted for the directions. An invalid direct ion (some other than N, S, E or W) will cause thiser ror.

2. Check t he M i n e S i g h t ® er ror messages in the Appendix.

MineSight®M708S0 - CREATE AN AUXILIARY SCHEDULE FILE Proprietary Software: Mintec, Inc.

Page 708S0-4 Revised 30–September–93

M709SM RESERVE TARGETING

PROGRAM SUMMARY

M709SM targets reserves based upon mining rates usingthe sorted output from M708SM.


RUN FILE:

INPUT: CALCS:

OUTPUT:


The purpose of M709SM is to accumulate and summarizequantities of feed and waste until the specified quantityor target is reached. Targeting may be requested foreither feed or waste.

Targeting is invoked with the command:

CMD = SCHED FEED rate CMD = SCHED WASTE rate CMD = SCHED QUANT rate

where rate is the target amount and QUANT is a quantityitem in the GSM. Targeting on waste involves targeting oninterburden and overburden before any adjustments fordilution or losses.

You may invoke one of three procedures to simulate thephysical mining operations, using a command like:

CMD = SEAM LAGS n

where n is the number of cut sequences to lag behindbefore beginning the second and following seams.

Mining seam by seam within cuts: LAGS= 0

M709SM targeting uses a simplified procedure to simu-late a mining operation: within an area (cut, etc.), theentire top seam is mined in the specified direction, thenthe entire second seam is mined, etc., until the productiontarget is achieved. When the first sequence is exhausted,the second sequence (cut) is started. This procedure isper formed if there is no LAG command or when thecommand CMD= SEAM LAGS 0 is given.

Mine seams columnwise within cuts: LAGS = -1

M709SM targeting may also be performed by taking allseams from top to bottom within each column of the minemodel, before mining any adjacent column. This proce-dure is used when the command CMD= SEAM LAGS -1is given.

- target rate

- Lag

- PCF

- Sorted Work File

- Read sorted work f i le f romM708SM

- Target on specified targetrate

- Summarize reserves

- Generate a report

- M122 plot f ile

- Resource Summ ary File


MineSight®Proprietary Software: Mintec, Inc. M709SM - RESERVE TARGETING

Revised: 10–October–95 Page 709SM-1

Mining seam by seam with a lag between seams

M709SM targeting may be performed by mining all of thetop seam, cut by cut, until it is n cut sequences ahead ofthe next lower seam. The top two seams are then minedtogether until seam two is n cut sequences ahead of thethird seam, etc.

The mining pattern was established in the M708SM run,where two separate actions were specified: (1) the direc-tion of movement for the entire area (or cut) and (2) thedirection of mining within the area (or cut). This miningpattern is unique for each block of a given seam.

When M708SM is run with a CMD= SCHE D..., it createsa work file with reserve data as shown following.

Word# Variable Description of WRK708.SCHvariable

1 N2BE Seq# for block to be mined (bytes 1-4)

2 NSE Q Cut sequence# from user input(bytes 5-8)

3 row-column Location, R OW*1000 +COLUMN

4 IZ Seam# (bytes 13-16)

5 708-types LUSE *100 + ICOD whereLUSE 1= 1st seam; 2= 2nd, ETC.ICOD = 1-7 mining category

6 FE ED Thickness of feed

7 OVBDN Thickness of overburden,interburden

8 SMWST Thickness of internal waste =LOSS + PRTNG 9

10 ZTOP Top elevation = Z TOP +D ilution-thickness

11 Q.P.1 First quality parameter

12 Q.P.2 Second quality parameter/ quantitative item

13-20 Other items

NOTE : FEE D & WASTE quantities are stored after thelast Q .P. Average mining depth is stored if there is room.

This work file must be sorted before running M709SM, asfollows:

• Mining seam by seam within cuts: LAGS= 0

• Sort by cut sequence# (word 2), then by seam# (word4), and then by # for block to be mined (word 1).

• Mining seams columnwise within cuts: LAGS= -1

• Sort by cut sequence# (word 2), then by # for block tobe mined (word 1), and then by seam# (word 4).

• Mining seam by seam with a lag between seams:LAGS= n

Same sort as LAGS= 0.

To sort the work file, use a system sort routine that sortson a character basis (even though the file is binary).

To mine one seam at a time, sort the file by cut se-quence# , seam# , and block sequence# (words 2, 4 and1). O n the VAX, the following command will perform thesort (two bytes are added to the byte number for theVAX) .

To mine by vertical columns, sort by cut sequence# , blocksequence# and seam# (words 2, 1 and 4). On the VAX,the following command will perform the sor t.

SORT WRK708.SCH WRK708.SRT/KEY= (PO= 7,SIZE= 4) /KEY= (PO= 3,SIZE= 4) /KEY= (PO= 15,SIZE= 4)

SORT WRK708.SCH WRK708.SRT/KEY= (PO= 7,SIZE= 4)/KEY= (PO= 15,SIZE= 4) /KEY= (PO= 3,SIZE= 4)

MineSight®M709SM - RESERVE TARGETING Proprietary Software: Mintec, Inc.

Page 709SM-2 Revised: 10–October–95

M709SM - RESERVE TARGETING

To run M709SM, copy the run file that was used for M708SM. Change the Names Line so thatreferences to M708SM are changed to M709SM. File 30 on the Names Line should be removed or elsechanged to the name of the sor ted schedule file. File 29 should be added. I t is used in plotting byM709PL. All other options in the run file should be left unchanged. Not a ll opt ions are used, but shouldbe kept in the run file for documentat ion purposes. You may optionally add the command CMD= SE AM LAGS n.

The cr itical parameters and files for M709SM are shown below.

RUN FILE OPERATION


ME DS-709SM 10= filename 29= filename 30= filename; ME DS-709SM 3= filename where

ME DS-709SM (must be the first 10 columns) 10= the name of the PROJE CT CONTROL FILE 29= the name of the OPTIONAL PLOT FILE FOR E ND OF PE RIOD ANNOTATIONS30= the name of the SO RTE D SCHE DULE FILE (WRK708.SRT BY D E FAULT) 3= the name of the PRINTE R OUTPU T FILE




U SR = USER INITIALS (e.g. A BC)

IOP2 = SE AM RE F# TO BE USED IN RUN = 0 USE ALL SE AMS FROM IOP9 TO IOP10 = 1 RE AD SE AM RE FE RE NCE NUMBE RS/LABE LS

NOTE : If IOP2= 1, seams can be read by RE F# after the E ND line or by label in anITM= sm-label GSMz... line.

IOP3 = GOVE RN CALCULATION OF OVERBURDE N = 0 CALCU LATE OVE RBURDEN (OPE N PIT) = 1 IGNORE OVE RBU RDE N (UNDE RGROU ND)

IOP9 = FIRST GSM SE AM TO ACCESS (Default= 1)IOP10 = LAST GSM SE AM TO ACCE SS (Default= NZ )

PAR5 = OPTIMAL MINIMUM THICKNE SS FOR INCLU SION OF OVE RBU RDEN AND INTE RBURDE N QUANTITIE S WH EN USING CMD = SCHE D FE ED ONLY. THICKNE SSE S LESS TH AN PAR5 ARE SU MME D IN TH E MISCE LLANE OUS WASTE CATE GORY.

MinesSight®Proprietary Software: Mintec, Inc. M709SM - RESERVE TARGETING


PAR7 = COAL IMPE RIAL TONNAGE FACTOR (cu.feet/ton of coal)

NOTE : Use coal specific gravity for metr ic units.

OR

To specify the pr imary reserve parameters by seam (opt ional)

CMD = sm-label_1 PARAM sg thick loss1 loss2 equipCMD = sm-label_2 PARAM DILTN diltk qp1 qp2, etc.where label is

sm-label= PCF seam labelPARAM= Keyword for reserve parameterssg = Specific gravity, tonnage factorthick = Minimum seam thicknessloss1 = Pr imary mining lossloss2 = Second cleaning lossequip = Maximum depth of equipmentPARAMDILTN = Keyword for dilution parametersdiltk = Seam dilution thicknessqp# = Seam dilution quality parameters

If PARAM commands are not used, PAR2 and PAR11 will be used for all mining and cleaning losses.

When equipment waste depths are used, overburden thicknesses that exceed the limit will be listed asOVE RBU RDE N E XCE SS on the report . Overburden within the limit will be listed as OVE RBURDE NQUANT. Interburden will be handled in the same manner as overburden equipment waste depths.

CMD = COAL UNITS ARE label CMD = WASTE U NITS ARE labelwhere

L abel is VOL, VOLUME , ME TE RS, YARDS, TON or TONNE . Default is TONS.

CMD = SCHE D FE E D rate orCMD = SCHE D WASTE rate

Note: Select only one SCH ED command.where

rate = Target amount.

CMD = RATE IS rate per1 per2where

per1 is the number of the first period to apply ’rate’per2 is the number of the last per iod to apply ’rate’



CMD = MOVE CUTS directionCMD = MINE CUT1 star t TO endCMD = MINE CUT2 star t TO endwhere

direction = Nor th, south, east, or west

NOTE : The first letters may be used (N, S, E , or W)

start = Nor th, south, east, or westend = Nor th, south, east, or west

NOTE : Cuts 1 and 2 are mined in the specified direct ions and the sequence is repeatedfor cuts 3 and 4, etc. It is acceptable to mine always in the same direction or to reversedirection for alternate cuts.

If the major axis of the cuts moves to the nor th, then mine cuts e ither west to east or eastto west. I f the major axis of the cuts moves to the east, then mine cuts either move northto south or south to nor th.

CMD = SE AM LAGS n where

LAGS = > 1 The number of cut sequences to lag behind before beginning the second and following seams.

LAGS = 0 Mine seam by seam within cuts.LAGS = -1 Mine seams columnwise within cuts.

4. SEAM REFERENCE NUMBER LINES ( If IOP2= 1)

U p to 20 seam reference numbers per line in free-fie ld format are a llowed. I f there are more than 20 seams,use a second reference number line.

NOTE : If IOP2= 1, to read GSM seam reference numbers, then IOP9= 1 and IOP10= to-tal # of seams.




All ITM commands are needed to set up appropr iate labels for the target reports.

COAL -709SM 10= COAL10.DAT 13= COAL13.DAT 15= COAL15.DAT; COAL -709SM 3= COL709.LA 29= COL709.PLT 19= COL709.OA ** TE ST TA RGE TING AT 500,000 TON COAL PE RIODS

U SR = ABC

IOP1 = 0 / 0= CALC MINING LIMITS (TOPOG-PAR4) COM 1= RE AD LIMITS FROM FILE 14 IOP2 = 0 / U SE ALL SE AMS; IOP9-10 IOP3 = 0 / 0= CALCULATE OVE RBU RDE N (OPE N PIT)COM 1= IGNORE (UNDE RGROUND)

IOP4 = 0 / 0= CUT INPUT; 1= COL & ROW SPE CS

IOP9 = 1 / FIRST GSM SE AM TO USE

IOP10 = 3 / LAST GSM SE AM TO U SE

PAR1 = 0.0 / D ILU TION TH ICKNE SS PAR2 = 0.0 / MINING LOSS: SUM OF TOP & BOTTOM SE AM LOSS

PAR11 = 0.0 / CLE ANING LOSS (SE CONDARY LOSS) PAR3 = 0. / WE ATHE RING DE PTH PAR4 = 2000. / MAXIMU M MINING DEPTH PAR7 = 25.0 / COAL TONNAGE FACTOR (CU.FT/TON COAL) PAR8 = 1. / D IVISOR FOR OUTPUT TOTALS

ITM1 = TOPOG TOPO 0.0 0.0 COM RE QUIRED TOPO SURFACE ITE M FROM FILE 13

ITM2 = Z TOP Z TOP 0.0 0.0 COM RE QUIRED TOP OF SE AM ELE V. FROM FILE 15

ITM3 = THICK COAL 2.5 99.0 COM RE QUIRED SE AM TH ICKNE SS FROM FILE 15

ITM4 = BTU Q.P. 0.0 0.0 / QUALITY PARAME TE R ITM5 = ASH Q.P. 0.0 0.0 / QUALITY PARAME TE R ITM6 = SU LF Q.P. 0.0 0.0 / QUALITY PARAME TER CMD = SCHE D FE E D 500000. / 500000 TONS OF COALCMD = MOVE CUTS NORTH / MINING DIRE CTION CMD = MINE CUT1 E AST TO WE ST / MINING DIRECTION FOR O DD CUTS CMD= MINE CUT2 E AST TO WE ST / MINING D IRE CTION FOR E VE N CUTS

I-O= 1

E ND




COAL -709SM 10= COAL10.DAT 13= COAL13.DAT 15= COAL15.DAT; COAL -709SM 3= COL709.LB 29= COL709.PL1 19= COL709.OB ** SE RIE S # 1 RE SE RVE S

DOCMAX. MINING D E PTH FROM SURFACE = 500 FE E T DOCWE ATH E RING DE PTH = 20 FE E T; SE AM LOSSE S

U SR = ABC COM* SE RIE S# 1 R E SE RVE S @ + 1.5FT, MINE PARM SE T# 1

IOP1 = 0 / 0= CALC MINING LIMITS (TOPOG-PAR4) COM 1= RE AD LIMITS FROM FILE 14IOP2 = 0 / USE ALL SE AMS; IOP9-10 IOP3 = 0 / 0= CALCULATE OVE RBU RDE N (OPE N PIT)COM 1= IGNORE (UNDE RGROU ND)IOP4 = 0 / 0= CUT INPUT; 1= COL & ROW SPE CS IOP9 = 1 / FIRST GSM SE AM TO USE IOP10 = 3 / LAST GSM SE AM TO U SE

PAR1 = 0.0 / D ILU TION TH ICKNE SS PAR2 = 0.4 / MINING LOSS: SUM OF TOP & BOTTOM SE AM LOSS CMD = INCL LOSS 0.7 0.0 1 / D RAGLINE LOSS SE AM # 1

PAR11 = 0.0 / CLE ANING LOSS (SE CONDARY LOSS)

PAR3 = 20. / WE ATH E RING DE PTH

PAR4 = 500. / MAXIMUM MINING DE PTH

PAR6 = 10. / MAX. OVE RALL STRIP RATIO (CU.YD. WASTE /TONS COAL)

PAR7 = 25.0 / COAL TONNAGE FACTOR (CU.FT/TON COAL)

PAR8 = 1000. / D IVISOR FOR OUTPUT TOTALS

ITM1 = TOPOG TOPO 0.0 0.0 COM REQU IRE D TOPO SU RFACE ITEM FROM FILE 13

ITM2 = Z TOP Z TOP 0.0 0.0 COM REQU IRE D TOP OF SE AM E LEV. FROM FILE 15

ITM3 = THICK COAL 0.0 0.0 COM REQU IRE D SE AM TH ICKNE SS FROM FILE 15

ITM4 = BTU Q.P. 0.0 0.0 / QUALITY PARAME TER ITM5 = ASH Q.P. 0.0 0.0 / QUALITY PARAME TERITM6 = SU LF Q .P. 0.0 0.0 / QUALITY PARAME TE R ITM7 = MOIST Q.P. 0.0 0.0 / Q UALITY PARAME TE R

CMD = SCHE D WASTE 16000000 / 16 MILL YDS**3. OF WASTE PE R ANNUM CMD = MOVE CUTS WE ST / MINING DIRE CTION CMD = MINE CUT1 NORTH TO SOU TH / MINING DIRE CTION FOR ODD CUTS CMD = MINE CUT2 SO UTH TO NORTH / MINING DIRE CTION FOR EVE N CUTS I -O = 1 E ND




1. ERRORS IN OPENING WORK FILES

will appear if the sor ted schedule file does not exist .

2. I f results do not look cor rect, check that you are using the same run file that was used forM708SM.

3. Check the M i n e S i g h t ® er ror messages in the Appendix.



M709S1 PLOT END OF TARGET PERIODS

PROGRAM SUMMARY

M709S1 is used to plot lines at the end of targeting pe-riod(s) and to label the lines with either the per iod num-bers or seam numbers.


RUNFILE

INPUT: CALCS:

OUTPUT:


M709S1 reads the original cut geometry from the cutoutlines file (as used in M708SM). The program alsoreads the coordinates of the center of each block wheremining ends in each period for all seams from M709SM.The program draws a line perpendicular to the cutthrough the center of the block in which the period ends.Labels are placed on both sides of the line with the appro-pr iate period numbers or seam labels.

Data entry for M709S1 consists of a run file, the cutoutline file and the end of period marker file fromM709SM. The program is capable of labeling either theend of all seams for a given period (set IO P1= 0) or theend of a ll per iods for a given seam (set IO P1= 1). Theprogram creates plot commands for the seam or periodnumber input as IO P2. If p lotting the end points of allper iods for one seam, specify the starting period numberas IO P3. Note that the program will increment this num-ber by one for labeling each subsequent period.

The cut geometry data is read from the same file as thatinput to M708SM for this particular targeting sequence.The program will use this data for drawing perpendicularlines across the cuts at the end of a per iod. If the end of aper iod coincides with the end of a cut, the line will bedrawn at the furthest extent of the cut.

The end of period marker data is generated by M709SMby entering a name for the end of per iod marker file (File29). This file contains a line for the end of each seam foreach period. Therefore, it is possible to use the samemarker file for many plots.

The following limitations apply to M709S1:

• No cut can contain more than 200 points.

• No more than 200 cuts can be used in a single run.

• No more than 100 periods can be plotted in a single run.

The M122 plot file contains the commands to draw thelines across the cuts and the labels on each side of thelines. Therefore, in order to get a complete picture, p lotthe original cut outlines from a separate U SE RF file.

- Label type

- Seam or period

- Start ing label

- PCF

- Plot fi le f romM709SM

- Write plot comm ands forthe end of period l ines andlabels into an M122 p lot f ile

- M122 plot f ile


MineSight®Proprietary Software: Mintec, Inc. M709S1 - PLOT END OF TARGET PERIODS


M709S1 - PLOT END OF TARGET PERIODS

RUN FILE OPERATION


COAL -709S1 10= filename 19= filename 29= filename; COAL -709S1 30= filename 3= filename where

COAL -709S1 (must be the first 10 columns) 10 = the name of the PROJE CT CONTROL FILE 19 = the name of the M122 Plot File 30 = the name of the Cut Boundary Input File (used by M708SM)29 = the name of the E nd of Per iod Marker File ( from M709SM) 3 = the name of the PRINTE R OUTPU T FILE


A single line of text information that will be printed at the top of each page of pr inter output from therun.


U SR = USER INITIALS (e.g. A BC)

IOP1 = 0 PLOT THE END OF ALL SE AMS FOR ONE PE RIOD = 1 PLOT THE END OF ALL PERIODS FOR ONE SE AM

IOP2 = SE AM TO PLOT ( if IOP1= 1) O R PE RIOD TO PLOT (If IOP1= 0)

IOP3 = NUMBE R TO BE GIN LABE LING WITH FOR PE RIOD 1 ( If IOP1= 1)

NOTE : IOP3 is not used if IOP1= 0.

PAR1 = PLOT SCALE (in user units)

PAR2 = WIDTH OF CUTS ( in user units)

E ND



M709S1 SAMPLE RUN FILE # 1

COAL -709S1 10= COAL10.DAT 19= COL709.122 30= COL653.SM1; COAL -709S1 29= COL709.PLT 3= COL709.LA PLOT THE E ND OF SE AM # 1 AT THE E ND O F ALL PE RIODS

COM WHE RE :COM COAL10.DAT = THE NAME OF TH E PROJE CT CONTROL FILE COM COL709.122 = THE NAME O F THE OUTPUT PLOT COMMAND FILE COM COL653.SM1 = THE NAME O F THE CUT BOU NDARY INPUT FILE COM (SA ME FILE AS USE D IN M708SM) COM COL709.PLT = THE NAME OF THE E ND OF PE RIOD MARKE R FILE COM (GE NE RATE D IN M709SM) COM COL709.LPL = THE NAME OF THE PRINTE R OU TPUT FILE

U SR = ABC

IOP1 = 1 / 0= PLOT TH E E ND OF ALL SE AMS FOR ONE PE RIOD COM 1= PLOT TH E E ND OF A LL PE RIODS FOR ONE SE AM IOP2 = 2 / SE AM TO PLOT ( IOP1= 1) OR PE RIOD TO PLOT (IOP1= 0) IOP3 = 10 / NUMBE R TO BE GIN LABE LING WITH FOR PE RIOD 1 (IOP1= 1)COM IOP3 IS NOT USE D IF IOP1 = 0

PAR1 = 2500. / PLOT SCALE IN USE R U NITS AR2 = 50. / WIDTH OF CUTS IN USE R UNITS

E ND

MineSight®M709S1 - PLOT END OF TARGET PERIODS Proprietary Software: Mintec, Inc.

Page 709S1-4 Revised 30–September–93

M709S1 SAMPLE RUN FILE # 2

COAL -709S1 10= COAL10.DAT 19= COL709.122 30= COL653.SM1;COAL -709S1 29= COL709.PLT 3= COL709.LB

PLOT THE E ND OF ALL SE AMS AT THE E ND OF PE RIOD # 10

COM WHE RE :

COM COAL10.DAT = THE NAME OF TH E PROJE CT CONTROL FILE ‘COM COL709.122 = THE NAME O F THE OUTPUT PLOT COMMAND FILE COM COL653.SM1 = THE NAME OF THE CUT BOU NDARY INPUT FILE COM (SA ME FILE AS USE D IN M708SM) COM COL709.PLT = THE NAME OF TH E E ND OF PE RIOD MARKE R FILE COM (GE NE RATE D IN M709SM) COM COL709.LP2 = THE NAME OF THE PRINTE R OUTPU T FILE

U SR = ABC

IOP1 = 0 / 0= PLOT TH E E ND OF A LL SE AMS FOR ONE PE RIOD COM 1= PLOT TH E E ND OF A LL PE RIODS FOR ONE SE AMIOP2 = 10 / SE AM TO PLOT (IOP1= 1) OR PE RIOD TO PLOT (IOP1= 0)IOP3 = 0 / NU MBE R TO BEGIN LABE LING WITH FOR PE RIOD 1 ( IOP1= 1) COM IOP3 IS NOT USE D IF IOP1 = 0

PAR1 = 2500. / PLOT SCALE IN USE R U NITS PAR2 = 50. / WIDTH OF CUTS IN USE R UNITS

E ND

HOW TO DEBUG AN M709S1 RUN

1. MAXIMUM NUMBER OF CUTS (200) EXCEEDED

Start targeting process over using a smaller number of cuts.

2. MAXIMUM NUMBER OF POINTS IN CUT (200) EXCEEDED

Reduce the number of points in each cut to fewer than 200.

3. MAXIMUM NUMBER OF PERIODS (100) EXCEEDED

Start targeting process over with fewer cuts or split the end of period marker file into twosmaller files, each with fewer than 100 per iods.

4. Check the Mi n e S i g h t ® er ror messages in the Appendix.



M712SM GSM RESERVE SUMMARY

PROGRAM SUMMARY

M712SM reads the ASCII Resource Summary File fromM708SM and produces a formatted report.


RUN FILE:

INPUT: CALCS:

OUTPUT:


Befor e run ning this rout ine, r un M708SM and /orM709SM to produce an ASCII Resource Summary File.The run file for th is routine should be the same asM708SM except for the following changes:

Names Line - change all references of 708 to 712. Removethe reference to File 30.

Add IO P31-32 as appropriate.

The options and parameters from the M708SM run fileare used by M712SM for documentation purposes only.

- M713SM is interact ive

- PCF

- asci i Resource Sum-mary File

- Produce format ted report


MineSight®Proprietary Software: Mintec, Inc. M712SM — GSM RESERVE SUMMARY

Revised 1–August–94 Page 712SM-1

M712SM - GSM RESERVE SUMMARY

RUN FILE OPERATION


COAL -712SM 10= filename 13= filename 15= filename;COAL -712SM 19= filename 3= filename where

COAL -712SM (must be the first 10 columns) 10 = the name of the PROJE CT CONTROL FILE 13 = the name of the 2-D SU RFACE FILE 15 = the name of the MINE MODE L FILE 19 = the name of the ASCII Resource Summary File from M708SM 3 = the name of the PRINTE R OUTPU T FILE


A single line of text information that will be printed at the top of each page of pr inter output from therun.


U se the run options from the M708SM run file with the following additions:

IOP31 = 0 PRINT ALL COLUMNS = 1 OMIT OVE RBURDEN/INTE RBU RDE N

IOP32 = 0 PRINT ALL SU MMARY LINES = 1 PRINT TOTAL LINE S ONLY

E ND

MineSight®Proprietary Software: Mintec, Inc. M712SM—GSM RESERVE SUMMARY

Revised 1–August–94 Page 712SM-3


COAL -712SM 10= COAL10.DAT 13= COAL13.DAT 15= COAL15.DAT;

COAL -712SM 3= COL712.LA 19= COL708.OA

** TE ST TA RGE TING AT 500,000 TON COAL PE RIODS

U SR = ABC

IOP1 = 0 / 0= CALC MINING LIMITS (TOPOG-PAR4) COM 1= RE AD LIMITS FROM FILE 14 IOP2 = 0 / U SE ALL SE AMS; IOP9-10 IOP3 = 0 / 0= CALCULATE OVE RBU RDE N (OPE N PIT)COM 1= IGNORE (UNDE RGROUND)IOP4 = 0 / 0= CUT INPUT; 1= COL & ROW SPE CS IOP9 = 1 / FIRST GSM SE AM TO USE IOP10 = 3 / LAST GSM SE AM TO U SE IOP31 = 0 / 0 = PRINT ALL COLU MNS, 1 = OMIT OVE R/INTE RBURDE N IOP32 = 0 / 0= PRINT A LL SUMMARY LINE S, 1= PRINT TOTAL LINE S O NLY PAR1 = 0.0 / D ILU TION TH ICKNE SS PAR2 = 0.0 / MINING LOSS: SUM OF TOP & BOTTOM SE AM LOSS PAR11 = 0.0 / CLE ANING LOSS (SE CONDARY LOSS) PAR3 = 0. / WE ATHE RING DE PTH PAR4 = 2000. / MAXIMU M MINING DEPTH PAR7 = 25.0 / COAL TONNAGE FACTOR (CU.FT/TON COAL) PAR8 = 1. / D IVISOR FOR OUTPUT TOTALS

ITM1 = TOPOG TOPO 0.0 0.0 COM RE QUIRED TOPO SURFACE ITE M FROM FILE 13 ITM2 = Z TOP Z TOP 0.0 0.0 COM RE QUIRED TOP OF SE AM ELE V. FROM FILE 15 ITM3 = THICK COAL 2.5 99.0 COM RE QUIRED SE AM TH ICKNE SS FROM FILE 15

ITM4 = BTU Q.P. 0.0 0.0 / QUALITY PARAME TE R ITM5 = ASH Q.P. 0.0 0.0 / QUALITY PARAME TE R

ITM6 = SU LF Q.P. 0.0 0.0 / QUALITY PARAME TER CMD = SCHE D FE E D 500000. / 500000 TONS OF COAL CMD = MOVE CUTS NORTH / MINING DIRE CTION CMD = MINE CUT1 E AST TO WE ST / MINING DIRECTION FOR O DD CUTS CMD = MINE CUT2 E AST TO WE ST / MINING DIRECTION FOR E VE N CUTS I-O = 1 E ND


1. You must have an ASCII Resource Summary File that was produced by M708SM.


MineSight®M712SM—GSM RESERVE SUMMARY Proprietary Software: Mintec, Inc.

Page 712SM-4 Revised 1–August–94

M713SM MERGE M708SM RESERVES SUMMARY OUTPUTFILES FOR M714SM

PROGRAM SUMMARY

M713SM is an interactive program used to merge a num-ber of M708SM reserves summary output files for report-ing with M714SM. M713SM is mainly used for reportingGSM reserves when pre-strip benches or dragline chop-cut is involved and the cuts in plan must be offset toaccount for topography differences. In these cases, thecuts are generated at each bench and run from one file 13surface item to another to get the reserves for that bench.The reserves summary files from M708SM are then com-bined and reported.


RUN FILE:

INPUT: CALCS:

OUTPUT:


Before M713SM is run, each set of cuts at each miningbench must be run through M708SM to get the reservessummary file. The reserves summary files and their benchname are then input to M713SM for merging.

The same items must be selected in the same order foreach M708SM run. Keep track of any auxilary surfaces asthey are treated the same way in the reserves summaryfiles as a GSM seam level.

It is often more convenient to run the M713SM, sort, andM714SM runs from a procedure.

- M713SM is interac tive

- PCF

- M708SM ReserveSumm ary Fi les andbench names

- Waste is sp l it into overbur-den, interburden, and losses

- Merged summ ary fi le for in-put to M714SM


MineSight®Proprietary Software: Mintec, Inc. M713SM—MERGE 708SM RESERVES OUTPUT FOR M714SM

Revised 30–September–93 Page 713SM-1

M713SM—MERGE M708SM RESERVES SUMMARY OUTPUT

PROGRAM OPERATION

1. ME DS M713SM < CR> (Command may vary according to which computer you are using.)

2. ENTER PCF NAME

E nter the name of the Project Control file.

3. ENTER PRINT FILE NAME OR < CR>

E nter the name of a file to receive the pr int output from M713SM. If < CR> is used, the outputwill be in the default pr int file (FOR003.DAT on most computers).

4. PLEASE ENTER YOUR USER CODE:

E nter up to 5 characters for your in itials.

5. ENTER OUTPUT FILENAME. ENTER EXIT TO QUIT.

E nter the name for the unsor ted merged output file.

6. ENTER NUMBER OF DECIMAL PLACES FOR ITEMS.

E nter the number of decimal places for each item outp ut by M708SM. Include thickness and en-ter them all on one line. If not entered, then a default of 2 is used. This is str ictly a cosmetic re-por t option.

7. ENTER NAMES OF AUXILIARY SURFACES.

E nter the item names of any auxiliary sur faces that were used in the M708SM runs. When an aux-iliary sur face is used in an M708SM run, it is t reated like a G SM seam level in the reserves sum-mary files. I f there weren’t any auxiliary sur faces used, press < CR> .

8. ENTER INPUT FILENAME. ENTER EXIT TO QUIT.

E nter the filename of the first /next input reserves summary file.

9. ENTER BENCH NAME FOR THIS FILE.

E nter the bench name for th is input reserves summary file. This is the name that will be used forrepor ting.

10. Repeat steps 8 and 9 until a ll reserves summary file names have been entered. When all fileshave been entered, enter E XIT.

MineSight®Proprietary Software: Mintec, Inc. M713SM—MERGE 708SM RESERVES OUTPUT FOR M714SM


M713SM SAMPLE OUTPUT FILE

0 0 0 OVERBURBEN INTERBURDEN LOSSES FEED . . .1 0 1 BCH1 RED 2875. 0. 2750. 0. . . .1 0 2 BCH1 BLUE 0. 2062. 125. 1544. . . .1 0 3 BCH1 GREEN 0. 4000. 103. 1003. . . .2 0 1 BCH2 RED 3975. 0. 2056. 0. . . .2 0 2 BCH2 BLUE 0. 3097. 108. 2134 . . .2 0 3 BCH2 GREEN 0. 4000. 459. 1783. . . .


1. NO MATCH FOR SEAM IN PCF

will appear if there’s a seam repor ted in the reserves summary file that is not in the PCF.


MineSight®M713SM—MERGE 708SM RESERVES OUTPUT FOR M714SM Proprietary Software: Mintec, Inc.

Page 713SM-4 Revised 30–September–93

M714SM REPORT MERGED M708SM RESERVESSUMMARY FILES

PROGRAM SUMMARY

M714SM is used to generate a report from a mergedsummary file that has been output by M713SM.


RUN FILE:

INPUT: CALCS:

OUTPUT:


The report can be generated in bench, cut order or in cut,bench order . If bench, cut order is to be used, the outputfile from M713SM can be used as is. To repor t in cut,bench order the M713SM file must first be sor ted by cut.

The reporting of the seams at each report level is usercontrolled. Subtotals are reported as requested.

The waste can be repor ted as total burden, losses, andtotal waste or overburden, interburden, and total waste.If there was coal in the pre-strip benches, then the over -burden/interburden split is invalid as each M708SM runreports overburden as the material down to the first coal.

It is often more convenient to run the M713SM, sort andM714SM runs from a procedure.

- Order to report

- Level of detail and subtotalsto report

- Other reporting opt ions

- PCF

- Merged , sortedSumm ary Fi le fromM713SM

- Material volumes and ton-nages are accum ulated .

- Reserves report


MineSight®Proprietary Software: Mintec, Inc. M714SM-REPORT MERGED M708SM RESERVE SUM. FILES


M714SM—REPORT MERGED M708SM RESERVES SUMMARY FILES

RUN FILE OPERATION

1. NAMES LINE (must be first line entered)

ME DS-714SM 10= filename 19= filename 3= filenamewhere

ME DS-714SM (must be the first 10 columns)10= the name of the PROJE CT CONTROL FILE19= the name of the Reserves Summary Input File 3= the name of the PRINTE R OUTPU T FILE




U SR = USER INITIALS (e.g., ABC)

IOP21 = 0 RE PORT BY BE NCH, CUT= 1 RE PORT BY CUT, BE NCH

IOP22 = 0 RE PORT ALL DE TAIL= 1 DON’T RE PORT SE AMS= 2 RE PORT TOP LE VE L ONLY= 3 RE PORT SUMMARY

IOP23 = 0 SU BTOTAL E ACH CHANGE= 1 SU BTOTAL TOP LE VE L ONLY= 2 SU MMARY REPORT ONLY

IOP24 = 0 RE PORT SE AMS IN GRAND TOTS ONLY= 1 RE PORT SE AM IN E ACH SUBTOTA L= 2 DON’T RE PORT SE AMS AT ALL

IOP25 = 0 RE PORT BURDE N & LOSSE S= 1 RE PORT OVE RBURDE N & INTE RBURDE N

E ND

MineSight®Proprietary Software: Mintec, Inc. M714SM-REPORT MERGED M708SM RESERVE SUM. FILES


4. DECIMAL PLACES FOR ITEMS

E nter the number of decimals places for each item output by M708SM. Include thickness and enterthem all on one line. If not entered, a default of 2 is used.

5. NAMES OF AUXILIARY SURFACES or BLANK LINE

E nter the item names of any auxiliary sur faces that were used in M708SM runs. When an auxiliarysur face is used in an M708SM run, it is treated like a GSM seam level in the reserves summary files. Ifthere weren’t any auxiliary sur faces used , leave a blank line.

6. NAMES OF BENCHES BEING REPORTED

E nter the names of the benches to report. Benches must be in the same order as in the M713SM outputfile.

M714SM SAMPLE RUN FILE

ME DS-714SM 10= COAL10.DAT 19= GSM1.RES 3= GSM1.RPT * * RE PORT ME RGE D SU MMARY FILE S * *

U SR = ABC

IOP21 = 1 /0= RE PORT BY BE NCH,CUT 1= BY CU T,BE NCHIOP22 = 0 /0= ALL DE TAIL,1= NO SE AMS,2= TOP LE VE L ONLY,3= SUMMARYIOP23 = 0 /0= SU BTOTAL E ACH CHANGE ,1= TOP LE VE L ONLY,2= SUMMARYIOP24 = 0 /0= RE PORT SE AMS IN GRAND TOTS O NLY,1= E ACH SU BTOTAL,2= NE VE RIOP25 = 0 /0= RE PORT BURDEN&LOSSES,1= OVB,INTE RB

I-O = 0

E ND1 1 0 Decimal places for items

Auxiliary surfaces (none–leave blank)BCH1BCH2

Benches to report


1. NO MATCH FOR SEAM IN PCF

will appear if there’s a seam repor ted in the reserves summary file that is not in the PCF.


MineSight®M714SM-REPORT MERGED M708SM RESERVE SUM. FILES Proprietary Software: Mintec, Inc.

Page 714SM-4 Revised 30–September–93

INTRODUCTION TO STRATIFORM DEPOSIT TONNAGE CALCULAT IONS

Tonnage (and volume) calculations are performed at sev-eral d ifferent stages dur ing the life of a deposit, frominitial exploration through mine operations. The differentcalculation methods will produce different levels of sig-nificance and detail in reference to the physical mining ofthe deposit. You should have adequate understanding oflimitations and assumptions of the different methods.

M ineSight® provides different levels and types of re-source calculations for stratiform deposits. It is your re-sponsibility to test each result, compare it to any otherestimates and to make judgment about the results.

First level calculations are performed within vertical col-umns only. H ighwall or p it slopes are not considered forsurface mining and waste quantities may be understatedfor typical projects. First level calculations are useful inexploration, feasibility and basic engineering studies.

Second level calculations account for mining slope anglesand should provide a more precise estimate of waste to bemined. Tonnage calculations for feed material should bethe same as for the first level calculations. Second levelcalculations require more steps and longer run times thando first level calculations.

First level calculations are often used in basic analyses toquickly look at various alternatives, areas and parame-ters. After alternatives have been narrowed to a fewchoices, the level of detail is increased (equipment con-siderations, slopes, etc.) and refined calculations are per-formed.

First Level Tonnage Calculations

Areas of influence (polygons) by dr illhole might be con-sidered as a special type of first level calculation. How-ever, this method is really just a basic star ting point andshould be termed drillhole analysis. Areas of influenceshould form an upper bound for many stratiform depos-its.

Within MineSight® , first level calculations are basedon the Gridded Seam Model (GSM) and surface topogra-phy. Diagram 1 is useful in visualizing first level calcula-tions.

Diagram 1

Overburden is measured vertically from the surface to-pography to the top of the first seam below the topogra-phy. Interburden is measured vertically from the bottomof one seam to the top of the seam below. Thickness ismeasured vertically from the top of each seam.

All surfaces must be predefined (calculated) before ton-nage calculations are per formed. Surfaces are stored inthe GSM except for topography. If a seam has beenwashed out or otherwise removed, the elevations must becarried through (with a zero thickness) if actual opera-tions will mine the separate areas in a continuous pass.

Floor Sample

#3

#2

Parting Roof

COAL SEAM #2

TOPOGRAPHY

OVERBURDEN

Roof Sample

INTER BURDEN

Roof Sample

Floor SampleCOAL SEAM #1

MineSight®Proprietary Software: Mintec, Inc. Tecnical Section - GSM

Revised 30–September–93 Page TECH GSM-1

Programs that perform first level GSM calculations are:M 706SM (D eter min e th e Ver tica l M ining L imit ) ,M708SM (Basic GSM Resources by Mine Categories)and M709SM (Targeting from G SM Resources).

The order in which first level calculations are per formedon a block by block basis is as fo llows:

1. Retrieve the block partial ( fraction between 0 and1) which represents a portion of a cut or area out-line. If there is only a percentage of the block avail-able, reduce the block partial for calculation.(Figure 7)

2. Retrieve the FEE D (ver tical length) and internalparting thicknesses and calculate the actual th ick-ness of FEE D if parting is included in the FE EDlength.

3. For seams with a valid top of seam elevation, checkfor interaction with sur face topography. If part ofthe seam is above the sur face, reset the top of seamelevation and calculate the remaining FE ED thick-ness. If the entire seam is above the sur face, omituse of the seam.

4. Check for overlap with the previous seam. If partof the seam over laps the previous seam, reset thetop of seam at the previous bottom and calculatethe remaining FE ED. If the seam completely over -laps the previous seam, omit use of the seam. (Fig-ure 3)

5. Calculate the seam D EPTH below sur face topogra-phy and calculate the overburden/interburdenthickness from the bottom of the last surface.

6. Check if any of the seam is within the weather ingdepth. If part of the seam is within the weatheringdepth, then calculate the remaining FEE D thick-ness below that depth. (Figure 2)

Note that if the seam thickness is reduced for anyof the above reasons, the parting will be assumedto be contained within the reduced thickness. Par t-ing length will be limited to the reduced FE EDthickness.

7. Dilution thickness is added to the coal. (Figure 5)

8. If requested, check for the minimum seam thick-ness before mining losses are taken out.

9. Retr ieve the primary mining loss and conver t it toa thickness if the loss was specified as a percent-age. If a secondary cleaning loss was specified as apercentage, use the thickness remaining after thepr imary loss as a basis for determining the secon-dary loss. Reduce the FE E D length by the sum ofthe mining and cleaning losses.

10. Check any remaining mining limits, such as ver ticalmining depth and minimum thickness. (Figure 4)

11. Check for any quality restrictions.

M706SM

M709SM

MINING LIMITSFILE 14

RESOURCE

REPORTS

FILE 13

TOPOGRAPHY

FILE 15

GSM

M708SM

TARGETINGRESOURCES

SUMMARYFILES

MineSight®Tecnical Section - GSM Proprietary Software: Mintec, Inc.

Page TECH GSM-2 Revised 30–September–93

26000

22000

16000

14000

24000

20000

18000

12000

10000

8000

6000

8000

1000

0

1200

0

1400

0

1600

0

1800

0

NO

RT

H

EAST

BOUNDARY POINTS OF LINE 1

LAST POINTLINE 2

LAST POINTLINE 1

BOUNDARY POINTS OF LINE 2

CUT # 1

CUT # 2

FIRST POINTLINE 2 FIRST POINT

LINE 1

Figure 1 - Illustration of Boundary Line Conventions. (See M701SM and M665V1 for explanation of cut generation usage.)



Figure 2 - Weathering

If top of seam > bottom of weathered zone, decreaseseam thickness. If resultant seam thickness < minimumthickness, seam will be wasted.

Figure 3 - Overlapping Seam

Top of seam B set to bottom of Seam A. Over lappingseams can be produced if there are negative partings.

TOPO

WEATHERING

DEPTH

SEAMTHICKNESS

SEAM ABOVE TOPO(IN AIR)

SEAM A

SEAM A

SEAM B

RESET TO BOTTOM

OF SEAM A



Figure 4 - Maximum Mining Limit

If seam top > maximum mining limit, use entire seam.Maximum mining depth is related to equipment con-straints.

TOPO

MAXIMUM MINING LIMIT

SEAM A

USE ENTIRE SEAMTO THIS POINT

DO NOT USE SEAM



Figure 5 - Dilution

Dilution is normally taken from above seam. If dilutionthickness > waste above, take dilution from bottom ofseam (eg. Seam C).

For Seam C, D ilution should include all waste thicknessbetween Seam B and Seam C, with the remainder takenfrom below Seam C. D ilution below SeamC should betotal d ilution for Seam C minus thickness of d ilutiontaken from above Seam C.

Therefore:

Total D ilution Seam C = D ilution C1 + Dilution C2

TOPO

SEAM A

SEAM B

SEAM C

SEAM D

DILUTION A

DILUTION B

DILUTION C1

DILUTION D

DILUTION C2



Figure 6 - Equipment Depth

Keeps track of two categories of waste: 1) materia l that can be removed with a certain piece of equipment and 2) excess material.

Figure 7 - Block Percent

Assume block A and block B have a block percentage of55 % (ie. block is intersected by topo).

This option is used in areas of steep topography.

TOPO

SEAM A

EQUIPMENT DEPTH

EXCESSOVERBURDEN

CUT CUT

45% 75%A B

B. If cut partial (75)>block%(55), set cut partial= block % (55).

A. If cut partial (45)<block% (55), use all ofblock within outline



M706SM Options

Figure 8 - IOP14 W aste Summary Option

If IOP14= 0, report waste 1 and waste 2 separately. IfIOP14= 1, report waste 1 and waste 2 combined.

Figure 9 - Stripping Index

Gives relatvie index of cost.

TOPO

WASTE 1

WASTE 2DOES

NOT MEET

REQUIREMENTS

TOPO

BUCKET/WHEEL, TRK-SHOVEL => STRIP INDEX = 2.5

DRAGLINE LINE => STRIP INDEX = 1.0

SEAM ASCRAPER => STRIP INDEX = 4.0



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