ELECTRICAL MACHINES – I
Unit -I
INTRODUCTION
Hans Christian Oersted (1777 – 1851)
1822
In 1820 he showed that a current
produces a magnetic field.
X
André-Marie Ampère (1775 – 1836)
French mathematics professor who only
a week after learning of Oersted’s discoveries in Sept. 1820 demonstrated
that parallel wires carrying currents
attract and repel each other.
attract
repel
A moving charge of 1 coulomb
per second is a current of
1 ampere (amp).
Michael Faraday (1791 – 1867) Self-taught English chemist and physicist
discovered electromagnetic induction in
1831 by which a changing magnetic field
induces an electric field.
Faraday’s electromagnetic
induction ring
A capacitance of 1 coulomb per volt
is called a farad (F)
Joseph Henry (1797 – 1878) American scientist, Princeton University
professor, and first Secretary of the
Smithsonian Institution.
Discovered self-
induction
Built the largest
electromagnets of
his day
Unit of inductance, L, is the “Henry”
Magnetic Fields and Circuits
A current i through a coil produces a
magnetic flux, f, in webers, Wb.
BAf A
df B A
H = magnetic field intensity in A/m.
v
i
+
-
N
B = magnetic flux density in Wb/m2.
B H
= magnetic permeability
Ampere's Law: d i H l
Hl Ni
NiFMagnetomotive force fF R
reluctance
Magnetic Flux
Magnetic flux, f, in webers, Wb.
1v 2v
2i1i
+ +
- -
2N1N
11 flux in coil 1 produced by current in coil 1f
12 flux in coil 1 produced by current in coil 2f
21 flux in coil 2 produced by current in coil 1f
22 flux in coil 2 produced by current in coil 2f
1 11 12 total flux in coil 1f f f
2 21 22 total flux in coil 2f f f
Current entering
"dots" produce
fluxes that add.
Faraday's Law
1v 2v
2i1i
+ +
- -
2N1N
1 1 1N f
Faraday's Law: induced voltage in coil 1 is
Sign of induced voltage v1 is such that the current i through
an external resistor would be opposite to the current i1 that
produces the flux f1.
Total flux linking coil 1:
1 11 1( )
d dv t N
dt dt
f
i
Example of Lenz's law Symbol L of inductance from Lenz
Mutual Inductance
1v 2v
2i1i
+ +
- -
2N1N
1 11 121 1 1 1( )
d d dv t N N N
dt dt dt
f f f
Faraday's Law
1 21 11 12( )
di div t L L
dt dt
In linear range, flux is proportional to current
self-inductance mutual inductance
Mutual Inductance
1v 2v
2i1i
+ +
- -
2N1N
1 21 11 12( )
di div t L L
dt dt
1 22 21 22( )
di div t L L
dt dt
12 21L L M Linear media
1 21 1( )
di div t L M
dt dt
1 22 2( )
di div t M L
dt dt
2 22L L1 11L LLet
Core losses
Hysteresis losses
Hysteresis losses
Hysteresis losses
Eddy current losses
Eddy current losses
How do we reduce Eddy current losses
SOLID
LAMINATED
Eddy current losses
Eddy current losses in windings
Can be a problem with thick wires
- Low voltage machines
- High speed machines
Force, torque and power
Universal modeling of terminal characteristic of electro-magnetic devices based on energy balance
Induced EMF
Induced emf could be classified into
two types
Dynamically induced EMF.
Statically induced EMF.
Statically induced emf
In statically induced emf, conductor is stationary with respect to the magnetic field.
Transformer is an example of statically induced emf. Here the windings are stationary,magnetic field is moving around
the conductor and produces the emf.
Statically induced emf
• The emf produced in a conductor due to the change in magnetic field is called statically induce emf .It could be classified
into two
• 1)self induced emf and 2)mutual induced emf
Dynamically induced emf
This is the EMF induced due to the motion of conductor in a magnetic field.
Mathematically
e = Blv volts
• e-induced emf
• B – flux density of magnetic field in Tesla
• l = length of conductor in meters
• v- velocity of conductor in m/s
Dynamically induced emf
If the conductor moves in an angle θ,the induced emf could be represented as
e= Blvsinθ
the direction of induced emf is given by
flemmings right hand rule.
Generator is an example of dynamically induced
emf.
UNIT - II
TRANSFORMERS
Introduction • A transformer is a static machines.
• The word ‘transformer’ comes form the word ‘transform’. • Transformer is not an energy conversion device, but is a device that
changes AC electrical power at one voltage level into AC electrical
power at another voltage level through the action of magnetic field,
without a change in frequency.
• It can be either to step-up or step down.
Generation Station
TX1 TX1
Distribution
s TX1
TX1
Transmission
System
33/13.5k
V
13.5/6.6kV
6.6kV/415
V Consumer
Transformer Construction
• Two types of iron-core construction: a) Core - type construction
b) Shell - type construction
• Core - type construction
Transformer Construction
• Shell - type construction
Ideal Transformer • An ideal transformer is a transformer which has no loses,
i.e. it’s winding has no ohmic resistance, no magnetic leakage, and therefore no I2 R and core loses.
• However, it is impossible to realize such a transformer in
practice.
• Yet, the approximate characteristic of ideal transformer will be used in characterized the practical transformer.
V1 V2
N1 : N2
E1 E2
I1 I2 V1 – Primary Voltage V2 – Secondary Voltage
E1 – Primary induced Voltage
E2 – secondary induced Voltage
N1:N2 – Transformer ratio
MZS
FKEE, UMP
Transformer Equation
• Faraday’s Law states that, – If the flux passes through a coil of wire, a voltage will be
induced in the turns of wire. This voltage is directly
proportional to the rate of change in the flux with respect
of time.
If we have N turns of wire,
dt
tdEmfV indind
)(
dt
tdNEmfV indind
)(
Lenz’s Law
MZS
FKEE, UMP
Transformer Equation
• For an ac sources,
– Let V(t) = Vm sint
i(t) = im sint
Since the flux is a sinusoidal function;
Then:
Therefore:
Thus:
tt m sin)(
tN
dt
tdNEmfV
m
mindind
cos
sin
mmindind fNNEmfV 2(max)
mmm
rmsind fNfNN
Emf
44.42
2
2)(
MZS
FKEE, UMP
Transformer Equation
• For an ideal transformer
• In the equilibrium condition, both the input power will be equaled to the
output power, and this condition is said to ideal condition of a transformer.
• From the ideal transformer circuit, note that,
•
m
m
fNE
fNE
22
11
44.4
44.4
1
2
2
1
2211 coscos
I
I
V
V
IVIV
poweroutputpowerInput
………………… (i)
2211 VEandVE
MZS
FKEE, UMP
Transformer Equation
aI
I
N
N
E
ETherefore
1
2
2
1
2
1,
Where, ‘a’ is the Voltage Transformation Ratio; which will
determine whether the transformer is going to be step-up
or step-down
E1 > E2 For a >1
For a <1 E1 < E2
MZS
FKEE, UMP
Transformer Rating
• Transformer rating is normally written in terms of
Apparent Power.
• Apparent power is actually the product of its rated
current and rated voltage. 2211 IVIVVA
Where,
I1 and I2 = rated current on primary and secondary winding.
V1 and V2 = rated voltage on primary and secondary winding.
Rated currents are actually the full load currents in
transformer
MZS
FKEE, UMP
Example
1. 1.5kVA single phase transformer has rated voltage of 144/240 V. Finds its full load current. Solution
AI
AI
FL
FL
6240
1500
45.10144
1500
2
1
Practical Transformer (Equivalent
Circuit)
V1 = primary supply voltage
V2 = 2nd terminal (load) voltage
E1 = primary winding voltage
E2 = 2nd winding voltage
I1 = primary supply current
I2 = 2nd winding current
I1’ = primary winding current
Io = no load current
V1 = primary supply voltage
V2 = 2nd terminal (load) voltage
E1 = primary winding voltage
E2 = 2nd winding voltage
I1 = primary supply current
I2 = 2nd winding current
I1’ = primary winding current
Io = no load current
V1
I1 R1 X1
RC
Ic
Xm
Im
Io
E1 E2 V2
I1’
N1: N2
R2 X2
Load
I2
Single Phase Transformer (Referred to
Primary) Actual Method
2
2
22
2
2
12 '' XaXORX
N
NX
2
2
22
2
2
12 '' RaRORR
N
NR
V1
I1 R1 X1
RC
Ic
Xm
Im
Io
E1 E2 V2
I2’ N1: N2
R2’
X2’
Load
I2
a
II
aVVORVN
NVE
22
222
2
1'
21
'
'
Single Phase Transformer (Referred to
Primary ) Approximate Method
2
2
22
2
2
12 '' RaRORR
N
NR
2
2
22
2
2
12 '' XaXORX
N
NX
V1
I1 R1 X1
RC
Ic
Xm
Im
Io
E1 E2 V2
I2’ N1: N2 R2
’ X2’
Load
I2
a
II
aVVORVN
NVE
22
222
2
1'
21
'
'
Example Problem
1. A 10 kVA single phase transformer 2000/440V has
primary resistance and reactance of 5.5 and 12
respectively, while the resistance and reactance of
secondary winding is 0.2 and 0.45 respectively.
Calculate:
i. The parameter referred to high voltage side and
draw the equivalent circuit
ii. The approximate value of secondary voltage at full
load of 0.8 lagging power factor, when primary
supply is 2000V
Example 1 (Cont)
Solution
R1=5.5 , X1=j12
R2=0.2 , X2=j0.45
i) Refer to H.V side (primary)
R2’=(4.55)2 (0.2) = 4.14,
X2’=j(4.55)20.45 = j9.32
Therefore,
R01=R1+R2’=5.5 + 4.13 = 9.64
X01=X1+X2’=j12 + j9. 32 = j21.32
V1 aV2
R01 X01
21.32 9.64
I1
Example 1 (Cont)
AV
VAIFL 5
2000
1010 3
1
Solution
ii) Secondary voltage
p.f = 0.8
Cos = 0.8
=36.87o
Full load,
From eqn
o
oo
oo
V
Vj
aVIjXRV
8.06.422
)55.4()87.365)(32.2164.9(02000
))((0
2
2
2101011
Transformer Losses
• Generally, there are two types of losses;
i. Iron losses :- occur in core parameters
ii. Copper losses :- occur in winding resistance
i. Iron Losses
ii Copper Losses
circuitopenccciron PRIPP 2)(
02
2
201
2
1
2
2
21
2
1
)()(,
)()(
RIRIPreferredifor
PRIRIPP
cu
circuitshortcucopper
Transformer Efficiency
• To check the performance of the device, by
comparing the output with respect to the input.
• The higher the efficiency, the better the system.
%100cos
cos
%100
%100,
22
22
cuc
lossesout
out
PPIV
IV
PP
P
PowerInput
PowerOutputEfficiency
%100cos
cos
%100cos
cos
2)(
)(
cuc
nload
cuc
loadfull
PnPnVA
nVA
PPVA
VA
Where, if ½ load, hence n = ½ ,
¼ load, n= ¼ ,
90% of full load, n =0.9 Where Pcu = Psc
Pc = Poc
Voltage Regulation
• The purpose of voltage regulation is basically to determine the percentage of voltage drop between no load and full load.
• Voltage Regulation can be determine based on 3 methods:
a) Basic Defination
b) Short – circuit Test
c) Equivalent Circuit
Voltage Regulation
(Basic Definition) • In this method, all parameter are being referred
to primary or secondary side.
• Can be represented in either
Down – voltage Regulation
%100.
NL
FLNL
V
VVRV
Up – Voltage Regulation
%100.
FL
FLNL
V
VVRV
Tap Changer
A transformer tap is a connection point along a transformer winding that allows a certain number of turns to be selected.
By this means, a transformer with a variable turns ratio is produced, enabling voltage regulation of the output. The tap selection is made via a tap changer mechanism.
Three Phase Transformers
3 single phase transformers connected together
1.Star/Delta winding arrangements
2. Easy to replace failed units
Common core device
1. Lighter and cheaper than 3 individual units
2. 6 rather than 12 external connections
3. Whole transformer must be replaced if single
winding fails .
For both cases analysis procedure identical!
UNIT-III
Electromechanical Energy
Conversion
Electromechanical Energy Conversion • The electromechanical energy conversion theory allows the representation of the electromagnetic force or torque
in terms of device variables, such as the currents and the displacement of the mechanical systems.
• An electromechanical system consists of an electric system, a mechanical system, and a means whereby the electric and mechanical systems can interact.
2
Electromechanical Energy Conversion
• Consider the block diagram depicted below.
3
Electric
System
Coupling
Field Mechanic
System
WE = We + WeL + WeS
Energy
supplied by
an electric
source
Energy transferred to
the coupling field by the
electric system
Energy losses of the
electric system.
Basically, I2R
Energy stored in the
electric o magnetic field
Electromechanical Energy Conversion
• The energy transferred to the coupling field can be represented by
4
WM = Wm + WmL + WmS Energy
supplied by a
mechanical
source
Energy transferred to
the coupling field from
the mechanical system
Energy losses of the
mechanical system
Energy stored in the
moving member and
compliance of the
mechanical system
WF = We + Wm
Total energy
transferred to
the coupling field
Energy transferred to
the coupling field by
the electric system
Energy transferred to the
coupling field from the
mechanical system
WF = Wf + WfL
Energy stored in the
electric system Energy dissipated as heat
(I2R)
Electromechanical Energy Conversion
• The electromechanical systems obey the law of conservation of energy.
• Energy Balance in an Electromechanical System
5
WF = Wf + WfL = We + Wm
WE WeL
WeS
WfL WmL
Wf WmS
WM
Electromechanical Energy Conversion
• If the losses are neglected, we will obtain the following formula,
6
WF = We + Wm
Energy transferred to
the coupling field by
the electric system
Energy transferred to
the coupling field from
the mechanical system
Electromechanical Energy Conversion
• Consider the electromechanical system given below,
7
x
x0
N +
- ef
i L r
V
+
-
k
f
fe
D
m
f
Electromechanical Energy Conversion • The equation for the electric system is-
• The equation for the mechanical system is-
8
fedt
diLriV
fexxKdt
dxD
dt
dxmf )( 02
2
Electromechanical Energy Conversion • The total energy supplied by the electric source is -
• The equation for the mechanical system is-
9
dtdt
dxfdxfWM
dtie
dt
diLridtiVW fE
Electromechanical Energy Conversion
• Substituting f from the equation of motion-
10
dxfexxK
dt
dxD
dt
dxmdxfW
system mechanical
the from field couplingthe to dtransferre
energy Total
springthe in storedEnergy Potential
(Wall)friction the due
loss Heat
mass the in storedenergy Kinetic
E
)( 02
2
Electromechanical Energy Conversion
11
dxfidtedW
dxfidteW
WWeW
Recall
dxfW
eff
eff
Mf
eM
*
Electromechanical Energy Conversion
• If dx=0 is assumed, then
12
0
dxf
fEf
idW
dtidt
didteWW
Electromechanical Energy Conversion
• Recalling the normalized magnetization curve,
13
),( xi d
idW f
diWc
i
Electromechanical Energy Conversion
14
0
),(
),(),(
),(
dx
f diii
xiW
dxx
xidi
i
xid
xi
Electromechanical Energy Conversion
15
0
),(
),(),(
),(
dx
c dxi
diW
dxx
xid
xidi
xii
Electromechanical Energy Conversion
• From the previous relationship, it can be shown that for one coil,
16
01
*
0
*
0
)(
)(
dxj
jjf
i
f
i
f
diW
case, general a For
idxLiW
i xL diW
Electromechanical Energy Conversion • For two coupled coils,
• For the general case with n-coupled coils,
17
22
22211212
112
1
2
1iLiiLiLW f
n
p
n
qqppqf iiLW
1 12
1
Electromagnetic Force
• Recalling,
18
x
x0
N +
- ef
i L r
V
+
-
k
f
fe
D
m
f
Electromagnetic Force
19
dt
de
dWdWdxf
dxfidteW
WWeW
f
fee
eff
Mf
Electromagnetic Force
20
fe
fe
dWdidxf
didtidt
didtedW
dxx
xidi
i
xid
),(),(
dxx
xiWdi
i
xiWdW
ff
f
),(),(
Substituting for d and dWf in fedx=id dWf, it can be shown
fe dWx
ixif
,
Electromagnetic Force
• Recall,
21
d
idW f
diWc
i
x
W
xixif
x
W
xi
x
W
WiW
f
e
fc
fc
),(
Electromagnetic Force
22
x
Wxif
x
W
xi
xixif
x
W
xixif
WiWWWi
ce
ce
f
e
cfcf
),(
),(
),(
UNIT-IV
DC MACHINES
Introduction
• The direct current (dc) machine can be used as a motor or as a generator.
• DC Machine is most often used for a motor.
• The major advantages of dc machines are the easy speed and torque regulation.
• However, their application is limited to mills, mines and trains. As examples, trolleys and underground subway cars may use dc motors.
• In the past, automobiles were equipped with dc dynamos to charge their batteries.
Construction
Construction (cont.,)
• The stator of the dc motor has poles, which are excited by dc current to produce magnetic fields.
• In the neutral zone, in the middle between the poles, commutating poles are placed to reduce sparking of the commutator. The commutating poles are supplied by dc current.
• Compensating windings are mounted on the main poles. These short-circuited windings damp rotor oscillations. .
Construction (cont.,)
• The poles are mounted on an iron core that provides a closed magnetic circuit.
• The motor housing supports the iron core, the brushes and the bearings.
• The rotor has a ring-shaped laminated iron core with slots.
• Coils with several turns are placed in the slots. The distance between the two legs of the coil is about 180 electric degrees.
Construction (cont.,) • The coils are connected in
series through the commutator segments.
• The ends of each coil are connected to a commutator segment.
• The commutator consists of insulated copper segments mounted on an insulated tube.
• Two brushes are pressed to the commutator to permit current flow.
• The brushes are placed in the neutral zone, where the magnetic field is close to zero, to reduce arcing.
DC Machines
• The rotor has a ring-shaped laminated iron core with slots.
• The commutator consists of insulated copper segments mounted on an insulated tube.
• Two brushes are pressed to the commutator to permit current flow.
• The brushes are placed in the neutral zone, where the magnetic field is close to zero, to reduce arcing.
DC Machines
• The commutator switches the current from one rotor coil to the adjacent coil,
• The switching requires the interruption of the coil current.
• The sudden interruption of an inductive current generates high voltages .
• The high voltage produces flashover and arcing between the commutator segment and the brush.
DC Machine Construction
|
Shaft
Brush
Copper
segment
Insulation
Rotor
Winding
N S
Ir_dc
Ir_dc
/2
Rotation
Ir_dc
/2
Ir_dc
12
3
4
5
6
7
8
Pole
winding
DC Machine Construction
Figure A. Details of the commutator of a dc motor.
DC Machine Construction
Figure B. DC motor stator with poles visible.
DC Machine Construction
Figure D. Cutaway view of a dc motor.
DC Generator
Operation
DC Generator Operation
• The N-S poles produce a dc magnetic field and the rotor coil turns in this field.
• A turbine or other machine drives the rotor.
• The conductors in the slots cut the magnetic flux lines, which induce voltage in the rotor coils.
• The coil has two sides: one is placed in slot a, the other in slot b.
30NS
Vdc
Bv
v
a
b
1
2
Ir_dc
(a) Rotor current flow from segment 1 to 2 (slot a to b)
30NS
Vdc
a
b
1
2
vv
B
Ir_dc
(b) Rotor current flow from segment 2 to 1 (slot b to a)
DC Generator Operation
• The conductors in slot a are cutting the field lines entering into the rotor from the north pole,
• The conductors in slot b are cutting the field lines exiting from the rotor to the south pole.
• The cutting of the field lines generates voltage in the conductors.
• The voltages generated in the two sides of the coil are added.
30NS
Vdc
Bv
v
a
b
1
2
Ir_dc
(a) Rotor current flow from segment 1 to 2 (slot a to b)
30NS
Vdc
a
b
1
2
vv
B
Ir_dc
(b) Rotor current flow from segment 2 to 1 (slot b to a)
DC Generator Operation
• The induced voltage is connected to the generator terminals through the commutator and brushes.
• The induced voltage in b is positive, and in a is negative.
• The positive terminal is connected to commutator segment 2 and to the conductors in slot b.
• The negative terminal is connected to segment 1 and to the conductors in slot a.
30NS
Vdc
Bv
v
a
b
1
2
Ir_dc
(a) Rotor current flow from segment 1 to 2 (slot a to b)
30NS
Vdc
a
b
1
2
vv
B
Ir_dc
(b) Rotor current flow from segment 2 to 1 (slot b to a)
DC Generator Operation
• When the coil passes the neutral zone:
– Conductors in slot a are then moving toward the south pole and cut flux lines exiting from the rotor
– Conductors in slot b cut the flux lines entering the in slot b.
• This changes the polarity of the induced voltage in the coil.
• The voltage induced in a is now positive, and in b is negative.
30NS
Vdc
Bv
v
a
b
1
2
Ir_dc
(a) Rotor current flow from segment 1 to 2 (slot a to b)
30NS
Vdc
a
b
1
2
vv
B
Ir_dc
(b) Rotor current flow from segment 2 to 1 (slot b to a)
DC Generator Operation
• The simultaneously the commutator reverses its terminals, which assures that the output voltage (Vdc) polarity is unchanged.
– the positive terminal is connected to ommutator segment 1 and to the conductors in slot a.
– The negative terminal is connected to segment 2 and to the conductors in slot b.
30NS
Vdc
Bv
v
a
b
1
2
Ir_dc
(a) Rotor current flow from segment 1 to 2 (slot a to b)
30NS
Vdc
a
b
1
2
vv
B
Ir_dc
(b) Rotor current flow from segment 2 to 1 (slot b to a)
UNIT-V
DC Motor
DC Motor Operation
• In a dc motor, the stator poles are supplied by dc excitation current, which produces a dc magnetic field.
• The rotor is supplied by dc current through the brushes, commutator and coils.
• The interaction of the magnetic field and rotor current generates a force that drives the motor
|
Shaft
Brush
Copper
segment
Insulation
Rotor
Winding
N S
Ir_dc
Ir_dc
/2
Rotation
Ir_dc
/2
Ir_dc
12
3
4
5
6
7
8
Pole
winding
DC Motor Operation
• The magnetic field lines enter into the rotor from the north pole (N) and exit toward the south pole (S).
• The poles generate a magnetic field that is perpendicular to the current carrying conductors.
• The interaction between the field and the current produces a Lorentz force,
• The force is perpendicular to both the magnetic field and conductor
(a) Rotor current flow from segment 1 to 2 (slot a to b)
Vdc
30NS
Bv
v
a
b
1
2
Ir_dc
(b) Rotor current flow from segment 2 to 1 (slot b to a)
30NS V
dc
a
b
1
2
B
v v
Ir_dc
DC Motor Operation
• The generated force turns the rotor until the coil reaches the neutral point between the poles.
• At this point, the magnetic field becomes practically zero together with the force.
• However, inertia drives the motor beyond the neutral zone where the direction of the magnetic field reverses.
• To avoid the reversal of the force direction, the commutator changes the current direction, which maintains the counterclockwise rotation. .
(a) Rotor current flow from segment 1 to 2 (slot a to b)
Vdc
30NS
Bv
v
a
b
1
2
Ir_dc
(b) Rotor current flow from segment 2 to 1 (slot b to a)
30NS V
dc
a
b
1
2
B
v v
Ir_dc
8.2.1 DC Motor Operation
• Before reaching the neutral zone, the current enters in segment 1 and exits from segment 2,
• Therefore, current enters the coil end at slot a and exits from slot b during this stage.
• After passing the neutral zone, the current enters segment 2 and exits from segment 1,
• This reverses the current direction through the rotor coil, when the coil passes the neutral zone.
• The result of this current reversal is the maintenance of the rotation.
(a) Rotor current flow from segment 1 to 2 (slot a to b)
Vdc
30NS
Bv
v
a
b
1
2
Ir_dc
(b) Rotor current flow from segment 2 to 1 (slot b to a)
30NS V
dc
a
b
1
2
B
v v
Ir_dc
EMF equation
Let
• Ø= flux/pole in Wb Z = total number of armature conductors P = number of poles A = number of parallel paths = 2 … for wave winding = P … for lap winding N = speed of armature in r.p.m. Eg= e.m.f. of the generator = e.m.f./parallel path
EMF equation
Armature Resistance (Ra)
• The resistance offered by the armature
circuit is known as armature resistance (Ra) and includes: (i) resistance of armature winding (ii) resistance of brushes The armature resistance depends upon the construction of machine. Except for small machines, its value is generally less than 1Ω.
Back EMF
• When the armature of a d.c. motor rotates under the influence of the driving torque, the armature conductors move through the magnetic field and hence e.m.f. is induced in them as in a generator The induced e.m.f. acts in opposite direction to the applied voltage V(Lenz’s law) and in known as back or counter e.m.f. Eb. The back e.m.f. Eb (= P Φ ZN/60 A) is always less than the applied voltage V, although this difference is small when the motor is running under normal conditions.
• Consider a shunt wound motor shown in Fig. (4.2). When d.c. voltage V is applied across the motor terminals, the field magnets are excited and armature conductors are supplied with current. Therefore, driving torque acts on the armature which begins to rotate. As the armature rotates, back e.m.f. Eb is induced which opposes the applied voltage V. The applied voltage V has to force current through the armature against the back e.m.f. Eb . The electric work done in overcoming and causing the current to flow against Eb is converted into mechanical energy developed in the armature. It follows, therefore, that energy conversion in a d.c. motor is only possible due to the production of back e.m.f. Eb.
Back EMF
• Net voltage across armature circuit = V – Eb
• If Ra is the armature circuit resistance, then, Ia = (V – Eb)/ Ra
• Since V and Ra are usually fixed, the value of Eb will determine the current drawn by the motor. If the speed of the motor is high, then back e.m.f. Eb (= P Φ ZN/60 A) is large and hence the motor will draw less armature current and viceversa.
Significance of Back E.M.F.
• The presence of back e.m.f. makes the d.c. motor a self-regulating machine i.e., it makes the motor to draw as much armature current as is just sufficient to develop the torque required by the load.
• Armature current,Ia = (V – Eb)/ Ra
• (i) When the motor is running on no load, small torque is required to overcome the friction and windage losses. Therefore, the armature current Ia is small and the back e.m.f. is nearly equal to the applied voltage. (ii) If the motor is suddenly loaded, the first effect is to cause the armature to slow down. Therefore, the speed at which the armature conductors move through the field is reduced and hence the back e.m.f. Eb falls. The decreased back e.m.f. allows a larger current to flow through the armature and larger current means increased driving torque. Thus, the driving torque increases as the motor slows down. The motor will stop slowing down when the armature current is just sufficient to produce the increased torque required by the load. (iii) If the load on the motor is decreased, the driving torque is momentarily in excess of the requirement so that armature is accelerated. As the armature speed increases, the back e.m.f. Eb also increases and causes the armature current Ia to decrease. The motor will stop accelerating when the armature current is just sufficient to produce the reduced torque required by the load.
• It follows, therefore, that back e.m.f. in a d.c. motor regulates the flow of armature current i.e., it automatically changes the armature current to meet the load requirement
Armature Reaction
• In a d.c. generator, the purpose of field winding is to produce magnetic field (called main flux) whereas the purpose of armature winding is to carry armature current. Although the armature winding is not provided for the purpose of producing a magnetic field, nevertheless the current in the armature winding will also produce magnetic flux (called armature flux). The armature flux distorts and weakens the main flux posing problems for the proper operation of the d.c. generator. The action of armature flux on the main flux is called armature reaction.
• It was hinted that current in the coil is reversed as the coil passes a brush. This phenomenon is termed as commutation. The criterion for good commutation is that it should be sparkless. In order to have sparkless commutation, the brushes should lie along magnetic neutral axis.
Armature Reaction
• So far we have assumed that the only flux acting in a d.c. machine is that due to the main poles called main flux. However, current flowing through armature conductors also creates a magnetic flux (called armature flux) that distorts and weakens the flux coming from the poles. This distortion and field weakening takes place in both generators and motors. The action of armature flux on the main flux is known as armature reaction. The phenomenon of armature reaction in a d.c. generator is shown in Fig. (2.1). Only one pole is shown for clarity. When the generator is on no-load, a smal1 current flowing in the armature does not appreciably affect the main flux Φ1 coming from the pole [See Fig 2.1 (i)]. When the generator is loaded, the current flowing through armature conductors sets up flux Φ1. Fig. (2.1) (ii) shows flux due to armature current alone. By superimposing Φ1 and Φ2, we obtain the resulting flux Φ3 as shown in Fig. (2.1) (iii). Referring to Fig (2.1) (iii), it is clear that flux density at; the trailing pole tip (point B) is increased while at the leading pole tip (point A) it is decreased. This unequal field distribution produces the following two effects: (i) The main flux is distorted. (ii) Due to higher flux density at pole tip B, saturation sets in. Consequently, the increase in flux at pole tip B is less than the decrease in flux under pole tip A. Flux Φ3 at full load is, therefore, less than flux Φ1 at no load. As we shall see, the weakening of flux due to armature reaction depends upon the position of brushes.
Armature Reaction
Geometrical and Magnetic
Neutral Axes • (i) The geometrical neutral axis (G.N.A.) is the axis that
bisects the angle between the centre line of adjacent poles [See Fig. 2.2 (i)]. Clearly, it is the axis of symmetry between two adjacent poles.
• (ii) The magnetic neutral axis (M. N. A.) is the axis drawn perpendicular to the mean direction of the flux passing through the centre of the armature. Clearly, no e.m.f. is produced in the armature conductors along this axis because then they cut no flux. With no current in the armature conductors, the M.N.A. coincides with G, N. A. as shown in Fig. [2.2(ii)]. In order to achieve sparkless commutation, the brushes must lie along M.N.A.
Geometrical and Magnetic
Neutral Axes • With no current in armature conductors, the M.N.A. coincides with G.N.A. However,
when current flows in armature conductors, the combined action of main flux and armature flux shifts the M.N.A. from G.N.A. In case of a generator, the M.N.A. is shifted in the direction of rotation of the machine. In order to achieve sparkless commutation, the brushes have to be moved along the new M.N.A. Under such a condition, the armature reaction produces the following two effects: 1. It demagnetizes or weakens the main flux. 2. It cross-magnetizes or distorts the main flux. Let us discuss these effects of armature reaction by considering a 2-pole generator (though the following remarks also hold good for a multipolar generator). (i) Fig. (2.3) (i) shows the flux due to main poles (main flux) when the armature conductors carry no current. The flux across the air gap is uniform. The m.m.f. producing the main flux is represented in magnitude and direction by the vector OFm in Fig. (2.3) (i). Note that OFm is perpendicular to G.N.A. (ii) Fig. (2.3) (ii) shows the flux due to current flowing in armature conductors alone (main poles unexcited). The armature conductors to the left of G.N.A. carry current “in” (x) and those to the right carry current “out” (•). The direction of magnetic lines of force can be found by cork screw rule. It is clear that armature flux is directed downward parallel to the brush axis. The m.m.f. producing the armature flux is represented in magnitude and direction by the vector OFA in Fig. (2.3) (ii).
Geometrical and Magnetic
Neutral Axes • (iii) Fig. (2.3) (iii) shows the flux due to the main poles and that due
to current in armature conductors acting together. The resultant m.m.f. OF is the vector sum of OFm and OFA as shown in Fig. (2.3) (iii). Since M.N.A. is always perpendicular to the resultant m.m.f., the M.N.A. is shifted through an angle θ. Note that M.N.A. is shifted in the direction of rotation of the generator. (iv) In order to achieve sparkless commutation, the brushes must lie along the M.N.A. Consequently, the brushes are shifted through an angle θ so as to lie along the new M.N.A. as shown in Fig. (2.3) (iv). Due to brush shift, the m.m.f. FA of the armature is also rotated through the same angle θ. It is because some of the conductors which were earlier under N-pole now come under S-pole and vice-versa. The result is that armature m.m.f. FA will no longer be vertically downward but will be rotated in the direction of rotation through an angle θ as shown in Fig. (2.3) (iv). Now FA can be resolved into rectangular components Fc and Fd.
Geometrical and Magnetic
Neutral Axes
Geometrical and Magnetic
Neutral Axes
Geometrical and Magnetic
Neutral Axes • (a) The component Fd is in direct opposition to the m.m.f. OFm due to main poles. It
has a demagnetizing effect on the flux due to main poles. For this reason, it is called the demagnetizing or weakening component of armature reaction.
• (b) The component Fc is at right angles to the m.m.f. OFm due to main poles. It distorts the main field. For this reason, it is called the crossmagnetizing or distorting component of armature reaction.
• It may be noted that with the increase of armature current, both demagnetizing and distorting effects will increase.
• Conclusions (i) With brushes located along G.N.A. (i.e., θ = 0°), there is no demagnetizing component of armature reaction (Fd = 0). There is only distorting or crossmagnetizing effect of armature reaction. (ii) With the brushes shifted from G.N.A., armature reaction will have both demagnetizing and distorting effects. Their relative magnitudes depend on the amount of shift. This shift is directly proportional to the armature current. (iii) The demagnetizing component of armature reaction weakens the main flux. On the other hand, the distorting component of armature reaction distorts the main flux. (iv) The demagnetizing effect leads to reduced generated voltage while crossmagnetizing effect leads to sparking at the brushes
Demagnetizing and cross
magnetizing conductors • With the brushes in the G.N.A. position, there is only cross-magnetizing effect of
armature reaction. However, when the brushes are shifted from the G.N.A. position, the armature reaction will have both demagnetizing and crossmagnetizing effects. Consider a 2-pole generator with brushes shifted (lead) θm mechanical degrees from G.N.A. We shall identify the armature conductors that produce demagnetizing effect and those that produce cross-magnetizing effect. (i) The armature conductors θ°m on either side of G.N.A. produce flux in direct opposition to main flux as shown in Fig. (2.4) (i). Thus the conductors lying within angles AOC = BOD = 2θm at the top and bottom of the armature produce demagnetizing effect. These are called demagnetizing armature conductors and constitute the demagnetizing ampere-turns of armature reaction (Remember two conductors constitute a turn).
• ii) The axis of magnetization of the remaining armature conductors lying between angles AOD and COB is at right angles to the main flux as shown in Fig. (2.4) (ii). These conductors produce the cross-magnetizing (or distorting) effect i.e., they produce uneven flux distribution on each pole. Therefore, they are called cross-magnetizing conductors and constitute the cross-magnetizing ampere-turns of armature reaction.
Demagnetizing and cross
magnetizing conductors
Calculation of Demagnetizing
Ampere-Turns Per Pole
(ATd/Pole) • It is sometimes desirable to neutralize the demagnetizing
ampere-turns of armature reaction. This is achieved by adding extra ampere-turns to the main field winding. We shall now calculate the demagnetizing ampere-turns per pole (ATd/pole). Let Z = total number of armature conductors I = current in each armature conductor = Ia/2 … for simplex wave winding = Ia/P … for simplex lap winding θm = forward lead in mechanical degrees Referring to Fig. (2.4) (i) above, we have, Total demagnetizing armature conductors= Conductors in angles AOC and BOD = 4θm/360 × Z
Calculation of Demagnetizing
Ampere-Turns Per Pole
(ATd/Pole)
• Since two conductors constitute one turn, Therefore Total demagnetizing ampere-turns =
Demagnetising ampere-turns Per Pole
(ATd/Pole)
Demagnetising ampere-turns Per Pole
(ATd/Pole) • Note. When a conductor passes a pair of poles, one cycle of voltage is
generated. We say one cycle contains 360 electrical degrees. Suppose there are P poles in a generator. In one revolution, there are 360 mechanical degrees and 360 ×P/2 electrical degrees.
Cross-Magnetizing Ampere-Turns Per
Pole (ATc/Pole)
• Demagnetizing ampere-turns per pole is given by
Cross-Magnetizing Ampere-Turns Per
Pole (ATc/Pole)
since two conductors make one turn)
Demagnetizing ampere-turns per pole is given by
Cross-Magnetizing Ampere-Turns Per
Pole (ATc/Pole)
• Therefore Cross-magnetizing ampere-turns/pole are
COMMUTATION
• Fig. (2.6) shows the schematic diagram of 2-pole lap-wound generator. There are two parallel paths between the brushes. Therefore, each coil of the winding carries one half (Ia/2 in this case) of the total current (Ia) entering or leaving the armature. Note that the currents in the coils connected to a brush are either all towards the brush (positive brush) or all directed away from the brush (negative brush). Therefore, current in a coil will reverse as the coil passes a brush. This reversal of current as the coil passes & brush is called commutation.
COMMUTATION
COMMUTATION
• The reversal of current in a coil as the coil passes the brush axis is called commutation. When commutation takes place, the coil undergoing commutation is shortcircuited by the brush. The brief period during which the coil remains shortcircuited is known as commutation period Tc. If the current reversal is completed by the end of commutation period, it is called ideal commutation. If the current reversal is not completed by that time, then sparking occurs between the brush and the commutator which results in progressive damage to both.
Ideal commutation
• Let us discuss the phenomenon of ideal commutation (i.e., coil has no inductance) in one coil in the armature winding shown in Fig. (2.6) above. For this purpose, we consider the coil A. The brush width is equal to the width of one commutator segment and one mica insulation. Suppose the total armature current is 40 A. Since there are two parallel paths, each coil carries a current of 20 A. (i) In Fig. (2.7) (i), the brush is in contact with segment 1 of the commutator. The commutator segment 1 conducts a current of 40 A to the brush; 20 A from coil A and 20 A from the adjacent coil as shown. The coil A has yet to undergo commutation.
Ideal commutation
Ideal commutation
• (ii) As the armature rotates, the brush will make contact with segment 2 and thus short-circuits the coil A as shown in Fig. (2.7) (ii). There are now two parallel paths into the brush as long as the short-circuit of coil A exists. Fig. (2.7) (ii) shows the instant when the brush is one-fourth on segment 2 and three-fourth on segment 1. For this condition, the resistance of the path through segment 2 is three times the resistance of the path through segment 1 (since contact resistance varies inversely as the area of contact of brush with the segment). The brush again conducts a current of 40 A; 30 A through segment 1 and 10 A through segment 2. Note that current in coil A (the coil undergoing commutation) is reduced from 20 A to 10 A.
Ideal commutation
• iii) Fig. (2.7) (iii) shows the instant when the brush is one-half on segment 2 and one-half on segment 1. The brush again conducts 40 A; 20 A through segment 1 and 20 A through segment 2 (since now the resistances of the two parallel paths are equal). Note that now. current in coil A is zero. (iv) Fig. (2.7) (iv) shows the instant when the brush is three-fourth on segment 2 and one-fourth on segment 1. The brush conducts a current of 40 A; 30 A through segment 2 and 10 A through segment 1. Note that current in coil A is 10 A but in the reverse direction to that before the start of commutation. The reader may see the action of the commutator in reversing the current in a coil as the coil passes the brush axis. (v) Fig. (2.7) (v) shows the instant when the brush is in contact only with segment 2. The brush again conducts 40 A; 20 A from coil A and 20 A from the adjacent coil to coil A. Note that now current in coil A is 20 A but in the reverse direction. Thus the coil A has undergone commutation. Each coil undergoes commutation in this way as it passes the brush axis. Note that during commutation, the coil under consideration remains shortcircuited by the brush.
Ideal commutation
• Fig. (2.8) shows the current-time graph for the coil A undergoing commutation. The horizontal line AB represents a constant current of 20 A upto the beginning of commutation. From the finish of commutation, it is represented by another horizontal line CD on the opposite side of the zero line and the same distance from it as AB i.e., the current has exactly reversed (- 20 A). The way in which current changes from B to C depends upon the conditions under which the coil undergoes commutation. If the current changes at a uniform rate (i.e., BC is a straight line), then it is called ideal commutation as shown in Fig. (2.8). Under such conditions, no sparking will take place between the brush and the commutator
Commutation Practical difficulties
• This is illustrated in Fig. (2.9). The straight line RC represents theThe ideal commutation (i.e., straight line change of current) cannot be attained in practice. This is mainly due to the fact that the armature coils have appreciable inductance. When the current in the coil undergoing commutation changes, self-induced e.m.f. is produced in the coil. This is generally called reactance voltage. This reactance voltage opposes the change of current in the coil undergoing commutation. The result is that the change of current in the coil undergoing commutation occurs more slowly than it would be under ideal commutation whereas the curve BE represents the change in current when self-inductance of the coil is taken into account. Note that current CE (= 8A in Fig. 2.9) is flowing from the commutator segment 1 to the brush at the instant when they part company. This results in sparking just as when any other current carrying circuit is broken. The sparking results in overheating of commutatorbrush contact and causing damage to both.
• Fig. (2.10) illustrates how sparking takes place between the commutator segment and the brush. At the end of commutation or short-circuit period, the current in coil A is reversed to a value of 12 A (instead of 20 A) due to inductance of the coil. When the brush breaks contact with segment 1, the remaining 8 A current jumps from segment 1 to the brush through air causing sparking between segment 1 and the brush.
Commutation Practical difficulties
Calculation of Reactance Voltage
• Reactance voltage = Coefficient of self-inductance × Rate of change of current When a coil undergoes commutation, two commutator segments remain shortcircuited by the brush. Therefore, the time of short circuit (or commutation period Tc) is equal to the time required by the commutator to move a distance equal to the circumferential thickness of the brush minus the thickness of one insultating strip of mica.
• Let Wb = brush width in cm,Wm = mica thickness in cm,v = peripheral speed of commutator in cm/s Commutation period, Tc = ( Wb – Wm )/v seconds The commutation period is very small, say of the order of 1/500 second.
• Let the current in the coil undergoing commutation change from + I to – I (amperes) during the commutation. If L is the inductance of the coil, then reactance voltage is given by;
• Reactance Voltage,(for linear commutation)
Methods of improving commutation
• mproving commutation means to make current reversal in the short-circuited coil as sparkless as possible. The following are the two principal methods of improving commutation: (i) Resistance commutation (ii) E.M.F. commutation We shall discuss each method in turn.
Resistance Commutation
• Resistance Commutation The reversal of current in a coil (i.e., commutation) takes place while the coil is short-circuited by the brush. Therefore, there are two parallel paths for the current as long as the short circuit exists. If the contact resistance between the brush and the commutator is made large, then current would divide in the inverse ratio of contact resistances (as for any two resistances in parallel). This is the key point in improving commutation. This is achieved by using carbon brushes (instead of Cu brushes) which have high contact resistance. This method of improving commutation is called resistance commutation. Figs. (2.11) and (2.12) illustrates how high contact resistance of carbon brush improves commutation (i.e., reversal of current) in coil A. In Fig. (2.11) (i), the brush is entirely on segment 1 and, therefore, the current in coil A is 20 A. The coil A is yet to undergo commutation. As the armature rotates, the brush shortcircuits the coil A and there are two parallel paths for the current into the brush. Fig. (2.11) (ii) shows the instant when the brush is one-fourth on segment 2 and three-fourth on segment 1. The equivalent electric circuit is shown in Fig. (2.11) (iii) where R1 and R2 represent the brush contact resistances on segments 1 and 2.
Resistance Commutation
Resistance Commutation • A resistor is not shown for coil A since it is assumed that the coil resistance
is negligible as compared to the brush contact resistance. The values of current in the parallel paths of the equivalent circuit are determined by the respective resistances of the paths. For the condition shown in Fig. (2.11) (ii), resistor R2 has three times the resistance of resistor R1. Therefore, the current distribution in the paths will be as shown. Note that current in coil A is reduced from 20 A to 10 A due to division of current in (he inverse ratio of contact resistances. If the Cu brush is used (which has low contact resistance), R1 R2 and the current in coil A would not have reduced to 10 A. As the carbon brush passes over the commutator, the contact area with segment 2 increases and that with segment 1 decreases i.e., R2 decreases and R1 increases. Therefore, more and more current passes to the brush through segment 2. This is illustrated in Figs. (2.12) (i) and (2.12) (ii), When the break between the brush and the segment 1 finally occurs [See Fig. 2.12 (iii)], the current in the coil is reversed and commutation is achieved. It may be noted that the main cause of sparking during commutation is the production of reactance voltage and carbon brushes cannot prevent it. Nevertheless, the carbon brushes do help in improving commutation. The other minor advantages of carbon brushes are: (i) The carbon lubricates and polishes the commutator. (ii) If sparking occurs, it damages the commutator less than with copper brushes and the damage to the brush itself is of little importance.
EMF commutation • In this method, an arrangement is made to neutralize the reactance voltage by
producing a reversing voltage in the coil undergoing commutation. The reversing voltage acts in opposition to the reactance voltage and neutralizes it to some extent. If the reversing voltage is equal to the reactance voltage, the effect of the latter is completely wiped out and we get sparkless commutation. The reversing voltage may be produced in the following two ways: (i) By brush shifting (ii) By using interpoles or compoles (i) By brush shifting In this method, the brushes are given sufficient forward lead (for a generator) to bring the short-circuited coil (i.e., coil undergoing commutation) under the influence of the next pole of opposite polarity. Since the short-circuited coil is now in the reversing field, the reversing voltage produced cancels the reactance voltage. This method suffers from the following drawbacks:
• (a) The reactance voltage depends upon armature current. Therefore, the brush shift will depend on the magnitude of armature current which keeps on changing. This necessitates frequent shifting of brushes. (b) The greater the armature current, the greater must be the forward lead for a generator. This increases the demagnetizing effect of armature reaction and further weakens the main field. (ii) By using interpoles or compoles The best method of neutralizing reactance voltage is by, using interpoles or compoles.
Interpoles or Compoles
• The best way to produce reversing voltage to neutralize the reactance voltage is by using interpoles or compoles. These are small poles fixed to the yoke and spaced mid-way between the main poles (See Fig. 2.13). They are wound with comparatively few turns and connected in series with the armature so that they carry armature current. Their polarity is the same as the next main pole ahead in the direction of rotation for a generator (See Fig. 2.13). Connections for a d.c. generator with interpoles is shown in Fig. (2.14).
Interpoles or Compoles
Functions of Interpoles • The machines fitted with interpoles have their brushes set on geometrical
neutral axis (no lead). The interpoles perform the following two functions: (i) As their polarity is the same as the main pole ahead (for a generator), they induce an e.m.f. in the coil (undergoing commutation) which opposes reactance voltage. This leads to sparkless commutation. The e.m.f. induced by compoles is known as commutating or reversing e.m.f. Since the interpoles carry the armature current and the reactance voltage is also proportional to armature current, the neutralization of reactance voltage is automatic. (ii) The m.m.f. of the compoles neutralizes the cross-magnetizing effect of armature reaction in small region in the space between the main poles. It is because the two m.m.f.s oppose each other in this region.
• Fig. (2.15) shows the circuit diagram of a shunt generator with commutating winding and compensating winding. Both these windings are connected in series with the armature and so they carry the armature current. However, the functions they perform must be understood clearly. The main function of commutating winding is to produce reversing (or commutating) e.m.f. in order to cancel the reactance voltage. In addition to this, the m.m.f. of the commutating winding neutralizes the crossmagnetizing ampere-turns in the space between the main poles. The compensating winding neutralizes the cross-magnetizing effect of armature reaction under the pole faces.
Functions of Interpoles
DC Generator Equivalent circuit
• The magnetic field produced by the stator poles induces a voltage in the rotor (or armature) coils when the generator is rotated.
• This induced voltage is represented by a voltage source.
• The stator coil has resistance, which is connected in series.
• The pole flux is produced by the DC excitation/field current, which is magnetically coupled to the rotor
• The field circuit has resistance and a source
• The voltage drop on the brushes represented by a battery
DC Generator Equivalent circuit
• Equivalent circuit of a separately excited dc generator.
Rf
Ra
Vbrush
VdcE
agV
f
max
If
Iag
Load
Mechanical
power in
Electrical
power out
DC Generator Equivalent circuit
• The magnetic field produced by the stator poles induces a voltage in the rotor (or armature) coils when the generator is rotated.
• The dc field current of the poles generates a magnetic flux
• The flux is proportional with the field current if the iron core is not saturated:
fag IK1
DC Generator Equivalent circuit
• The rotor conductors cut the field lines that generate voltage in the coils.
• The motor speed and flux equations are :
vBNE grag 2
2
gDv ggag DB
DC Generator Equivalent circuit
• The combination of the three equation results the induced voltage equation:
• The equation is simplified.
agrggr
g
grgrag NDBND
BNvBNE
222
fmfragrag IKIKNNE 1
DC Generator Equivalent circuit
• When the generator is loaded, the load current produces a voltage drop on the rotor winding resistance.
• In addition, there is a more or less constant 1–3 V voltage drop on the brushes.
• These two voltage drops reduce the terminal voltage of the generator. The terminal voltage is;
brushaagdcag VRIVE
DC Motor Equivalent circuit
• Equivalent circuit of a separately excited dc motor
• Equivalent circuit is similar to the generator only the current directions are different
Rf
Ra
Vbrush
VdcE
amV
f
max
If
Iam
Mechanical
power out
Electrical
power in
DC Power
supply
DC Motor Equivalent circuit
• The operation equations are:
• Armature voltage equation
brushaamamdc VRIEV
The induced voltage and motor speed vs angular
frequency
fmam IKE mn 2
DC Motor Equivalent circuit
• The operation equations are:
• The combination of the equations results in
The current is calculated from this equation. The output
power and torque are:
mamdcamfm RIVEIK
amamout IEP famm
out IIKP
T
Excitation methods
• There are four different methods for supplying the dc current to the motor or generator poles:
– Separate excitation;
– Shunt connection
– Series connection
– Compound
DC Motor Equivalent circuit
• Equivalent circuit of a shunt dc motor
DC Power
supply
Vdc
Eam
Iam
max R
f
If
Ra
Vbrush
Im
Pout
DC Motor Equivalent circuit
• Equivalent circuit of a series dc motor
Vdc
Eam
Rf
Ra
Vbrush
Im
max
DC Power
supply
Pout
DC Motor Equivalent circuit
• Equivalent circuit of a compound dc motor
Vdc
Eam
Rfs
Ra
Vbrush
Im
max
DC Power
supply
Rfp
Iam
Ifp
Pout
Generator characteristics
• The following are the three most important characteristics of a d.c. generator: 1. Open Circuit Characteristic (O.C.C.) This curve shows the relation between the generated e.m.f. at no-load (E0) and the field current (If) at constant speed. It is also known as magnetic characteristic or no-load saturation curve. Its shape is practically the same for all generators whether separately or self-excited. The data for O.C.C. curve are obtained experimentally by operating the generator at no load and constant speed and recording the change in terminal voltage as the field current is varied. 2. Internal or Total characteristic (E/Ia) This curve shows the relation between the generated e.m.f. on load (E) and the armature current (Ia). The e.m.f. E is less than E0 due to the demagnetizing effect of armature reaction. Therefore, this curve will lie below the open circuit characteristic (O.C.C.). The internal characteristic is of interest chiefly to the designer. It cannot be obtained directly by experiment. It is because a voltmeter cannot read the e.m.f. generated on load due to the voltage drop in armature resistance. The internal characteristic can be obtained from external characteristic if winding resistances are known because armature reaction effect is included in both characteristics
• 3. External characteristic (V/IL) This curve shows the relation between the terminal voltage (V) and load current (IL). The terminal voltage V will be less than E due to voltage drop in the armature circuit. Therefore, this curve will lie below the internal characteristic. This characteristic is very important in determining the suitability of a generator for a given purpose. It can be obtained by making simultaneous measurements of terminal voltage and load current (with voltmeter and ammeter) of a loaded generator.
Parallel operation of dc
generators • In a d.c. power plant, power is usually supplied from several generators of small ratings connected
in parallel instead of from one large generator. This is due to the following reasons: (i) Continuity of service If a single large generator is used in the power plant, then in case of its breakdown, the whole plant will be shut down. However, if power is supplied from a number of small units operating in parallel, then in case of failure of one unit, the continuity of supply can be maintained by other healthy units. (ii) Efficiency Generators run most efficiently when loaded to their rated capacity. Electric power costs less per kWh when the generator producing it is efficiently loaded. Therefore, when load demand on power plant decreases, one or more generators can be shut down and the remaining units can be efficiently loaded. (iii) Maintenance and repair Generators generally require routine-maintenance and repair. Therefore, if generators are operated in parallel, the routine or emergency operations can be performed by isolating the affected generator while load is being supplied by other units. This leads to both safety and economy. (iv) Increasing plant capacity In the modern world of increasing population, the use of electricity is continuously increasing. When added capacity is required, the new unit can be simply paralleled with the old units. (v) Non-availability of single large unit In many situations, a single unit of desired large capacity may not be available. In that case a number of smaller units can be operated in parallel to meet the load requirement. Generally a single large unit is more expensive.
Speed Control for shunt motor and separately excited dc motor
• Torque –speed characteristic for shunt and separately excited dc motor
a
ff
a
ff
a
a
a
aa
aa
R
nIK
R
IVK
excitedseparatelyassame
n
E
R
EV
n
IE
IEtorqueDeveloped
22
,
2
2
,
22
a
ff
R
IVKc
2
Starting torque
a
ff
R
nIKslope
2
22
nNL n n
m
=0 n=0
Speed Control for shunt motor and separately excited dc motor
• By referring to the Torque –speed characteristic for shunt and separately excited dc motor
• note that, there are three variables that can influence
the speed of the motor, V
If Ra
• Thus, there are three methods of controlling the speed of the shunt and separately excited dc motor,
i. Armature terminal – voltage speed control
ii. Field speed control
a
ff
a
ff
R
nIK
R
IVK
22
22
Variables
Speed Control for shunt motor and separately excited dc motor
i. Armature resistance speed control
- Speed may be controlled by changing Ra
- The total resistance of armature may be varied by means of a rheostat in series with the armature
- The armature speed control rheostat also serves as a starting resistor.
- From -n characteristic,
a
ff
a
ff
start
R
nIKslope
R
IVKc
2
2
22 Will be changed
Speed Control for shunt motor and separately excited dc motor
• Torque –speed characteristic
Ra1
nNL n n1
m
Ra2
Ra3
Ra1 < Ra2 < Ra3
n2 n3
Speed Control for shunt motor and separately excited dc motor
• Advantages armature resistance speed control:
i. Starting and speed control functions may be combined in one rheostat
ii. The speed range begins at zero speed
iii. The cost is much less than other system that permit control down to zero speed
iv. Simple method
• Disadvantages armature resistance speed control :
i. Introduce more power loss in rheostat
Speed Control for shunt motor and separately excited dc motor
ii. Field Speed Control
- Rheostat in series with field winding (shunt or separately ect.)
- If field current, If is varied, hence flux is also varied
- Not suitable for series field
- Refer to -n characteristic, - Slope and nNL will be changed
Speed Control for shunt motor and separately excited dc motor
• Torque –speed characteristic
If1 < If2 < If3
1 < 2 < 3
nNL3 n n1
m
n2 n3 nNL2
nNL1 Base speed
Speed Control for shunt motor and separately excited dc motor
• Advantages field speed control:
i. Allows for controlling at or above the base speed
ii. The cost of the rheostat is cheaper because If is small value
• Disadvantages field speed control :
i. Speed regulation is poor (S.R difference nLoaded & nno loaded)
ii. At high speed, flux is small, thus causes the speed of the machines becomes unstable
iii. At high speed also, the machines is unstable
Speed Control for shunt motor and separately excited dc motor
iii. Armature terminal – voltage speed control
- Use power electronics controller
- AC supply rectifier
- DC supply chopper
- Supply voltage to the armature is controlled
- Constant speed regulation
- From -n characteristic, - C and nNL will be change
- Slope constant
Speed Control for shunt motor and separately excited dc motor
• Torque –speed characteristic
nNL1 n n1
m
V3 < V2 < V1
n2 n3 nNL2 nNL3
Speed Control for shunt motor and separately excited dc motor
• Advantages armature terminal voltage speed control:
i. Does not change the speed regulation
ii. Speed is easily controlled from zero to maximum safe speed
• Disadvantages armature terminal voltage speed control :
i. Cost is higher because of using power electronic controller