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Dc machines are characterized by their versatility.
By means of various combinations of shunt-, series-, and separately-excited field
windings they can be designed to display a wide variety of volt-ampere or speed-torque
characteristics for both dynamic and steady-state operation.
Because of the ease with which they can be controlled, systems of dc machines have been
frequently used in applications requiring a wide range of motor speeds or precise control
of motor output.
§7.1 Introduction
The essential features of a dc machine are shown schematically in Fig. 7.1.
Fig. 7.1(b) shows the circuit representation of the machine.
The stator has salient poles and is excited by one or more field coils.
The air-gap flux distribution created by the field windings is symmetric about the
center line of the field poles. This axis is called the field axis or direct axis.
The ac voltage generated in each rotating armature coil is converted to dc in the external
armature terminals by means of a rotating commutator and stationary brushes to which the
armature leads are connected.
The commutator-brush combination forms a mechanical rectifier, resulting in a dc
armature voltage as well as an armature-mmf wave which is fixed in space.
The brushes are located so that commutation occurs when the coil sides are in the
neutral zone, midway between the field poles.
The axis of the armature-mmf wave is 90 electrical degrees from the axis of the field
poles, i.e., in the quadrature axis.
The armature-mmf wave is along the brush axis.
Figure 7.1 Schematic representations of a dc machine.
Recall equation (4.81). Note that the torque is proportional to the product of the
magnitudes of the interacting fields and to the sine of the electrical space angle between
their magnetic axes. The negative sign indicates that the electromechanical torque acts
in a direction to decrease the displacement angle between the fields.
2
sr r r
poles
sin
22
T
π
F
δ
⎛⎞
=− Φ
⎜⎟
⎝⎠
(4.81)
1
For the dc machine, the electromagnetic torque can be expressed in terms of
the interaction of the direct-axis air-gap per pole
mech
T
d
Φ
and the space-fundamental
component
of the armature-mmf wave, in a form similar to (4.81). Note that
a1
F
r
sin 1
δ
= .
2
mech d a1
pole
22
T
π
⎛⎞
=Φ
⎜⎟
⎝⎠
F
i
(7.1)
mech a d a
TK
=
Φ (7.2)
a
a
poles
2
C
K
π m
= (7.3)
a
K : a constant determined by the design of the winding, the winding constant
a
i = current in external armature circuit
a
C = total number of conductors in armature winding,
m = number of parallel paths through winding
The rectified voltage between brushes, known also as the speed voltage, is
a
e
aad
eK
m
ω
=
Φ (7.4)
The generated voltage as observed from the brushes is the sum of the rectified
voltage of all the coils in series between brushes and is shown by the rippling line
labeled
in Fig. 7.2.
a
e
With a dozen or so commutator segments per pole, the ripple becomes very small and
the average generated voltage observed from the brushes equals the sum of the
average values of the rectified coils voltages.
Figure 7.2 Rectified coil voltages and resultant voltage between brushes in a dc machine.
Note that the electric power equals the mechanical power.
aa mech m
ei T
ω
=
(7.5)
The flux-mmf characteristic is referred to as the magnetization curve.
The direct-axis air-gap flux is produced by the combined mmf of the field
winding.
ff
Ni
∑
The form of a typical magnetization curve is shown in Fig. 7.3(a).
The dashed straight line through the origin coinciding with the straight portion of the
magnetization curves is called the air-gap line.
It is assumed that the armature mmf has no effect on the direct-axis flux because the
axis of the armature-mmf wave is along the quadrature axis and hence perpendicular
to the field axis. (This assumption needs reexamining!)
Note the residual magnetism in the figure. The magnetic material of the field does
not fully demagnetize when the net field mmf is reduced to zero.
It is usually more convenient to express the magnetization curve in terms of the
2
armature emf at a constant speed
a0
e
m0
ω
as shown in Fig. 7.3(b).
a
ad
mm
e
K
a0
0
e
ω
ω
=Φ= (7.6)
m
a
m0
()e
a0
e
ω
ω
= (7.7)
a
0
()
n
e
n
=
a0
e (7.8)
Fig. 7.3(c) shows the magnetization curve with only one field winding excited.
This curve can easily be obtained by test methods.
Figure 7.3 Typical form of magnetization curves of a dc machine.
Various methods of excitation of the field windings are shown in Fig. 7.4.
Figure 7.4 Field-circuit connections of dc machines:
(a) separate excitation, (b) series, (c) shunt, (d) compound.
Consider first dc generators.
Separately-excited generators.
Self-excited generators: series generators, shunt generators, compound generators.
With self-excited generators, residual magnetism must be present in the machine
iron to get the self-excitation process started.
3
N.B.: long- and short-shunt, cumulatively and differentially compound.
Typical steady-state volt-ampere characteristics are shown in Fig. 7.5, constant-speed
operation being assumed.
The relation between the steady-state generated emf and the armature terminal
voltage
is
a
E
a
V
4
aaaa
VEIR
=
− (7.10)
Figure 7.5 Volt-ampere characteristics of dc generators.
Any of the methods of excitation used for generators can also be used for motors.
Typical steady-state dc-motor speed-torque characteristics are shown in Fig. 7.6, in
which it is assumed that the motor terminals are supplied from a constant-voltage
source.
In a motor the relation between the emf generated in the armature and and the
armature terminal voltage
is
a
E
a
V
aaa
VEIR
a
=
+ (7.11)
a
a
a
VE
I
R
a
−
= (7.12)
The application advantages of dc machines lie in the variety of performance
characteristics offered by the possibilities of shunt, series, and compound excitation.
Figure 7.6 Speed-torque characteristics of dc motors.
§7.4 Analytical Fundamentals: Electric-Circuit Aspects
Analysis of dc machines: electric-circuit and magnetic-circuit aspects
Torque and power:
The electromagnetic torque
mech
T
adamech
IKT
Φ
=
(7.13)
The generated voltage
a
E
mdaa
ω
Φ
=
KE (7.14)
m
C
K
π
2
poles
a
a
= (7.15)
: electromagnetic power
aa
IE
ada
m
aa
mech
IK
IE
T Φ==
ω
(7.16)
Note that the electromagnetic power differs from the mechanical power at the machine
shaft by the rotational losses and differs from the electric power at the machine terminals
by the shunt-field and armature
R
I
2
losses.
Voltage and current (Refer to Fig. 7.12.):
a
V : the terminal voltage of the armature winding
t
V : the terminal voltage of the dc machine, including the voltage drop across the
series-connected field winding
ta
VV = if there is no series field winding
a
R : the resistance of armature, : the resistance of the series field
s
R
aaaa
RIEV
±
=
(7.17)
(
)
saaat
RRIEV
+
±
=
(7.18)
faL
III
±
=
(7.19)
Figure 7.12 Motor or generator connection diagram with current directions.
5
6
For compound machines, Fig. 7.12 shows a long-shunt connection and the short-shunt
connection is illustrated in Fig. 7.13.
Figure 7.13 Short-shunt compound-generator connections.
§7.5 Analytical Fundamentals: Magnetic-Circuit Aspects
The net flux per pole is that resulting from the combined mmf’s of the field and armature
windings.
First we consider the mmf intentionally placed on the stator main poles to create the
working flux, i.e., the main-field mmf, and then we include armature-reaction effects.
§7.5.1 Armature Reaction Neglected
With no load on the machine or with armature-reaction effects ignored, the resultant mmf is the
algebraic sum of the mmf’s acting on the main or direct axis.
ff ss
Main field mmf NI NI
−
=± (7.20)
s
fs
f
Gross mmf equivalent shunt-field amperes
N
II
N
⎛⎞
=+
⎜⎟
⎝⎠
(7.21)
An example of a no-load magnetization characteristic is given by the curve for 0
=
a
I in
Fig. 7.14.
The generated voltage at any speed
a
E
m
ω
is given by
m
a0
m0
a
E
ω
ω
⎛⎞
=
⎜⎟
⎝⎠
E
(7.22)
0
0
aa
E
n
n
E
⎟
⎟
⎠
⎞
⎜
⎜
⎝
⎛
=
(7.23)
7
Figure 7.14 Magnetization curves for a 100-kW, 250-V, 1200-r/min dc machine.
Also shown are field-resistance lines for the discussion of self-excitation in § 7.6.1.
8
§7.5.2 Effects of Armature Reaction Included
Current in the armature winding gives rise to a demagnetizing effect caused by a cross-
magnetizing armature reaction.
One common approach is to base analyses on the measured performance of the machine.
Data are taken with both the field and armature excited, and the tests are conducted
so that the effects on generated emf of varying both the main-field excitation and
armature mmf can be noted.
Refer to Fig. 7.14. The inclusion of armature reaction becomes simply a matter of
using the magnetization curve corresponding to the armature current involved.
The load-saturation curves are displaced to the right of the no-load curve by an
amount which is a function of
a
I
.
The effect of armature reaction is approximately the same as a demagnetizing mmf
acting on the main-field axis.
ar
F
ar f f s s
Net mmf gross mmf FNINIAR=−=+− (7.24)
Over the normal operating range, the demagnetizing effect of armature reaction may
be assumed to be approximately proportional to the armature current.
The amount of armature of armature reaction present in Fig. 7.14 is definitely more
than one would expect to find in a normal, well-designed machine operating at
normal currents.
9
§7.6 Analysis of Steady-State Performance
Generator operation and motor operation
For a generator, the speed is usually fixed by the prime mover, and problems often
encountered are to determine the terminal voltage corresponding to a specified load and
excitation or to find the excitation required for a specified load and terminal voltage.
For a motor, problems frequently encountered are to determine the speed corresponding to
a specific load and excitation or to find the excitation required for specific load and speed
conditions; terminal voltage is often fixed at the value of the available source.
§7.6.1 Generator Analysis
Analysis is based on the type of field connection.
Separately-excited generators are the simplest to analyze.
Its main-field current is independent of the generator voltage.
For a given load, the equivalent main-field excitation is given by (7.21) and the
associated armature-generated voltage
is determined by the appropriate
magnetization curve.
a
E
The voltage , together with (7.17) or (7.18), fixes the terminal voltage.
a
E
Shunt-excited generators will be found to self-excite under properly chosen operating
condition under which the generated voltage will build up spontaneously.
The process is typically initiated by the presence of a small amount of residual
magnetism in the field structure and the shunt-field excitation depends on the
terminal voltage. Consider the field-resistance line, the line 0a in Fig. 7.14.
The tendency of a shunt-connected generator to self-excite can be observed by
examining the buildup of voltage for an unloaded shunt generator.
– Buildup continues until the volt-ampere relations represented by the
magnetization curve and the field-resistance line are simultaneously satisfied.
10
Figure 7.15 Equivalent circuit for analysis of voltage buildup in a self-excited dc generator.
Note that in Fig. 7.15,
() (
f
af a af
di
LL e RRi
dt
+=−+
)
f
(7.25)
The field resistance line should also include the armature resistance.
Notice that if the field resistance is too high, as shown by line 0b in Fig. 7.14, voltage
buildup will not be achieved.
The critical field resistance, corresponding to the slope of the field-resistance line
tangent to the magnetization curve, is the resistance above which buildup will not be
obtained.
11
§7.6.2 Motor Analysis
The terminal voltage of a motor is usually held substantially constant or controlled to a specific
value. Motor analysis is most nearly resembles that for separately-excited generators.
Speed is an important variable and often the one whose value is to be found.
aaaa
RIEV
±
=
(7.17)
(
)
saaat
RRIEV
+
±
=
(7.18)
s
fs
f
Gross mmf equivalent shunt-field amperes
N
II
N
⎛⎞
=+
⎜⎟
⎝⎠
(7.21)
adamech
IKT
Φ
=
(7.13)
mdaa
ω
Φ
=
KE (7.14)
m
a0
m0
a
E
ω
ω
⎛⎞
=
⎜⎟
⎝⎠
E
(7.22)
0
0
aa
E
n
n
E
⎟
⎟
⎠
⎞
⎜
⎜
⎝
⎛
=
(7.23)
12
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