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8/19/2019 DC II
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Figure 1: Permanent Magnet DC Motor Equivalent Circuit
Rotating DC Motors Part II
II.1 DC Motor Equivalent Circuit
The next step in our consideration of DC motors is to develop an equivalent circuit which
can be used to better understand motor operation. The armatures in real motors usuallyconsist of many windings of relatively thin wire. Recall that thin wires have larger
resistance than thick wires. The equivalent circuit then must include a resistor a R which
accounts for the total resistance of the armature winding. Figure 1 shows the equivalent
circuit for a DC motor. DC V represents the applied voltage which causes the armature
current to flow, a R is the resistance of the armature, anda
E is the generated or induced
“back EMF” in the armature.
Figure 1 shows that armature current, a I , flows from the positive terminal of the voltage
source, V DC , and the value of a I is determined by ( ) /a DC a a I V E R= − . The back EMF
acts to limit the flow of armature current, but g E must always be less than DC V in order
for a I to be positive. The equivalent circuit for the DC motor can be analyzed using any
circuit technique learned earlier in this course.
II.2 Power in DC Motors
The power input to a DC motor is simply the input current multiplied by the applied
voltage:
DC a IN V I P = .
Due to electrical and mechanical losses in the motor, the mechanical power out of themotor must be less than the electrical power in. The most obvious electrical loss is due to
the armature resistance, aalosselec R I P 2= . As discussed in previous sections, power losses
also occur due to:- friction between parts of the machine
a I a
R
DC V
a E K
υ ω =
+
-
+
-
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- magnetic inefficiencies of the material used
- air resistance (windage) of the rotating armature
- small resistance across the brushes used to couple current onto thecommutator
These losses can be approximated collectively by specifying an overall value formechanical power lost,
lossmechP .
As with any other system which does not store energy, the electrical power input to a DC
motor must equal the sum of the mechanical power output and the various lossmechanisms:
lossmechlosselecOUT IN PPPP ++=
The output power can be calculated from the power balance equation above, or from the
product of output torque and angular velocity:
ω load OUT T P =
Mechanical power is often expressed in units of horsepower, hp. This is a non-SI unit of
power equal to 746 watts. If torque is expressed in N·m and angular velocity is
expressed in units of radians per second , then the units out of ω load OUT T P = will be
expressed in watts. To convert to horsepower, simply divide the answer in watts by 746.
A power conversion diagram is a useful tool to document the power flow in a motor. It
clearly shows that the input power is electrical and that the output power is mechanical.
The power developed, Pd , denotes the change from electrical to mechanical power.
Figure 2 : Power Conversion Diagram
II.3 Efficiency
Efficiency of a system can be generally defined as the ratio of power output relative to power input. In DC motors this becomes the mechanical power out relative to the
electrical power in:
IN OUT PP /=η
a DC IN I V P = d a a d P E I T ω = =
aalosselec R I P2= ω lossmechlossmech T P =
ω load OUT T P =
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The expression for power out, ω load OUT T P = , can be recast to provide a simple equation
for efficiency as follows. Earlier in this chapter, developed torque was given as
ad I K T ν
= . Multiplying both sides of this equation by the angular velocity, ω , gives:
T d ω = K v I a ω
But T d ω equals the power developed, Pd . Thus:
Pd = K v I aω
Back EMF was also defined earlier asa
E K ν
ω = . Hence, we can arrive at a new
equation for mechanical power developed as shown at the dashed line in Figure 2 above:
d d a a aP T K I E I
ν ω ω = = =
In many cases the friction losses will be small compared to the armature loss. If we assume that mechanical losses can be ignored , the efficiency of a DC motor can beexpressed simply as the ratio of back EMF to applied voltage because:
lossmechload d T T T +=
and if: 0=lossmechT
then: load d T T =
hence:
OUT load d a a aP T T K I E I
ν ω ω ω = = = =
and
(100 %) (100 %) (100 %)OUT a a a
IN DC a DC
P E I E
P V I V η = = =
Again, this final equation assumes all mechanical losses are ignored .
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Here is a summary of the rotating motor equations:
Rotating Motor Equations
Pin – Pelec loss = Pd ↓ mechanical ↓
↑ electrical ↑ Pd – Pmech loss = Pout Power equation (Pout = Pload)
Td – Tmech loss = Tout Torque equation (Tout = Tload)
↑ energy conversion here (T = P / ω , or, P = T ω)(“d” subscript means “developed”)
Pin = VDC Ia
Pelec loss = Ia2 Ra
Pd = Ea * Ia = Td ω = Kv Ia ω
Ea = Kv ω
Td = Kv Ia
η = Pout / Pin
If “no load”, then Pout and Tout = 0,and Pd = Pmech loss , Td = Tmech loss
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Example II-1: A permanent magnet DC motor is rated for 25 V, 2 A and 1300 rpm. If the machine
is 90% efficient at rated conditions find a R and
ν K if m N T
lossmech ⋅= 0334.0 .
SOLUTION: We use the given rated electrical information to determine the power into the motor.
W AV I V P a DC IN 50)2)(25( ===
The efficiency value then enables us to calculate the output power at rated conditions.
W W POUT 45)50)(90.0( ==
We can calculate the power loss at rated conditions by
W
rev
rad
s
rev
m N
T Plossmechlossmech
55.4
1
2
60
min1
min
1300
)3340.0(
=
⋅=
=
π
ω
The power developed must be
W W W P
PPP
d
OUT lossmechd
55.494555.4 =+=
+=
Now, we can solve forν
K .
sV K
rpm AK W
I K T P ad d
⋅=
=
==
182.0
301300)2(55.49
ν
ν
ν
π
ω ω
To find a R :
25 (2 ) (0.182 ) (1300)30
0.11
DC a a a
DC a a
a
a
V R I E
V R I K
R A V s
R
ν ω
π
= +
= +
= + ⋅
= Ω
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A power conversion diagram shows another approach to this problem if we consider electrical power
loss in the armature.
From the power conversion diagram.
Ω=
=
=
=++=
++=
11.0
)2(45.0
45.0
4555.450
2
2
a
a
aalosselec
losselec
losselec
OUT lossmechlosselec IN
R
R AW
R I P
W P
W W PW
PPPP
a DC IN I V P = d a a d P E I T ω = =
aalosselec R I P2= ω lossmechlossmech T P =
ω load OUT T P =
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