DC Machine Armature Windings Overview

 
Lecture # 2
 
DC 
M
ACHINE 
C
ONSTRUCTION 
- 
A
RMATURE
 
W
INDING
 
 
o
T
h
e
 
w
i
n
d
i
n
g
s
 
o
f
 
a
r
m
a
t
u
r
e
s
 
a
r
e
 
c
o
n
n
e
c
t
e
d
 
i
n
 
d
i
f
f
e
r
e
n
t
 
w
a
y
s
 
(
L
a
p
 
w
i
n
d
i
n
g
a
n
d
 
w
a
v
e
 
w
i
n
d
i
n
g
 
)
 
d
e
p
e
n
d
i
n
g
 
o
n
 
t
h
e
 
r
e
q
u
i
r
e
m
e
n
t
s
 
o
f
 
t
h
e
 
m
a
c
h
i
n
e
.
o
The 
difference 
in how the coils are interconnected at the
 
commutator
segments and the number of segments
 
used.
 
 
 
19
 
DC 
M
ACHINE 
C
ONSTRUCTION 
- 
A
RMATURE
 
W
INDING
Lap
 
Wound
 
 
o
L
a
p
 
W
o
u
n
d
 
A
r
m
a
t
u
r
e
s
:
 
a
r
e
 
u
s
e
d
 
i
n
 
m
a
c
h
i
n
e
s
 
d
e
s
i
g
n
e
d
 
f
o
r
 
l
o
w
v
o
l
t
a
g
e
 
a
n
d
 
h
i
g
h
 
c
u
r
r
e
n
t
 
a
r
m
a
t
u
r
e
s
 
a
r
e
 
c
o
n
s
t
r
u
c
t
e
d
 
w
i
t
h
 
l
a
r
g
e
 
w
i
r
e
b
e
c
a
u
s
e
 
o
f
 
h
i
g
h
 
c
u
r
r
e
n
t
.
o
E
x
a
m
p
l
e
:
 
I
t
 
i
s
 
u
s
e
d
 
i
n
 
t
h
e
 
s
t
a
r
t
e
r
 
m
o
t
o
r
 
o
f
 
a
l
m
o
s
t
 
a
l
l
 
a
u
t
o
m
o
b
i
l
e
s
.
o
T
h
e
 
w
i
n
d
i
n
g
s
 
o
f
 
a
 
l
a
p
 
w
o
u
n
d
 
a
r
m
a
t
u
r
e
 
a
r
e
 
c
o
n
n
e
c
t
e
d
 
i
n
 
p
a
r
a
l
l
e
l
.
o
T
h
i
s
 
p
e
r
m
i
t
s
 
t
h
e
 
c
u
r
r
e
n
t
 
c
a
p
a
c
i
t
y
 
o
f
 
e
a
c
h
 
w
i
n
d
i
n
g
 
t
o
 
b
e
 
a
d
d
e
d
 
a
n
d
p
r
o
v
i
d
e
s
 
a
 
h
i
g
h
e
r
 
o
p
e
r
a
t
i
n
g
 
c
u
r
r
e
n
t
.
o
N
o
.
 
o
f
 
p
a
r
a
l
l
e
l
 
c
u
r
r
e
n
t
 
p
a
t
h
s
,
 
a
 
=
 
P
 
;
P
 
=
 
N
o
.
 
o
f
 
p
o
l
e
s
(
s
i
m
p
l
e
x
 
l
a
p
 
w
i
n
d
i
n
g
 
)
o
N
o
.
 
o
f
 
p
a
r
a
l
l
e
l
 
c
u
r
r
e
n
t
 
p
a
t
h
s
,
 
a
 
=
 
2
 
 
P
 
;
 
P
 
=
 
N
o
.
 
o
f
 
p
o
l
e
s
(
d
u
p
l
e
x
 
l
a
p
 
w
i
n
d
i
n
g
 
)
 
o
 
I
n
 
g
e
n
e
r
a
l
,
 
a
 
=
 
P
 
 
p
l
e
x
 
L
a
p
 
w
o
u
n
d
 
a
r
m
a
t
u
r
e
s
 
20
 
 
 
DC 
M
ACHINE 
C
ONSTRUCTION 
- 
A
RMATURE
 
W
INDING
Wave 
Wound
 
 
21
 
o
W
a
v
e
 
W
o
u
n
d
 
A
r
m
a
t
u
r
e
s
 
a
r
e
 
u
s
e
d
 
i
n
 
m
a
c
h
i
n
e
s
 
d
e
s
i
g
n
e
d
 
f
o
r
 
h
i
g
h
v
o
l
t
a
g
e
 
a
n
d
 
l
o
w
 
c
u
r
r
e
n
t
.
o
T
h
e
i
r
 
w
i
n
d
i
n
g
s
 
c
o
n
n
e
c
t
e
d
 
i
n
 
s
e
r
i
e
s
.
o
W
h
e
n
 
t
h
e
 
w
i
n
d
i
n
g
s
 
a
r
e
 
c
o
n
n
e
c
t
e
d
 
i
n
 
s
e
r
i
e
s
,
 
t
h
e
 
v
o
l
t
a
g
e
 
o
f
 
e
a
c
h
 
w
i
n
d
i
n
g
a
d
d
s
,
 
b
u
t
 
t
h
e
 
c
u
r
r
e
n
t
 
c
a
p
a
c
i
t
y
 
r
e
m
a
i
n
s
 
t
h
e
 
s
a
m
e
.
o
E
x
a
m
p
l
e
:
 
s
m
a
l
l
 
g
e
n
e
r
a
t
o
r
 
i
n
 
h
a
n
d
-
c
r
a
n
k
e
d
 
m
e
g
a
-
o
h
m
m
e
t
e
r
s
.
 
W
a
v
e
 
w
o
u
n
d
 
a
r
m
a
t
u
r
e
s
 
 
 
DC 
M
ACHINE 
C
ONSTRUCTION 
- 
A
RMATURE
 
W
INDING
Wave 
Wound
 
 
22
 
o
F
o
r
 
a
 
s
i
m
p
l
e
x
 
w
a
v
e
 
w
i
n
d
i
n
g
 
t
h
e
r
e
 
w
i
l
l
 
a
l
w
a
y
s
 
b
e
 
t
w
o
 
p
a
r
a
l
l
e
l
 
p
a
t
h
s
r
e
g
a
r
d
l
e
s
s
 
o
f
 
t
h
e
 
n
u
m
b
e
r
 
o
f
 
p
o
l
e
s
 
(
a
=
2
)
.
o
A
 
d
u
p
l
e
x
 
w
a
v
e
 
w
i
n
d
i
n
g
 
w
i
l
l
 
d
o
u
b
l
e
 
t
h
e
 
n
u
m
b
e
r
 
o
f
 
p
a
r
a
l
l
e
l
 
p
a
t
h
s
 
p
r
e
s
e
n
t
i
n
 
t
h
e
 
s
i
m
p
l
e
x
 
(
a
 
=
 
2
 
 
2
)
.
o
I
n
 
g
e
n
e
r
a
l
 
a
 
=
 
2
 
 
p
l
e
x
o
The number of coils on an armature is not
 
important.
o
W
h
a
t
 
i
s
 
i
m
p
o
r
t
a
n
t
 
i
s
 
t
h
e
 
t
o
t
a
l
 
n
u
m
b
e
r
 
o
f
 
c
o
n
d
u
c
t
o
r
s
 
(
Z
)
 
o
n
 
t
h
e
a
r
m
a
t
u
r
e
 
a
n
d
 
t
h
e
 
n
u
m
b
e
r
 
o
f
 
p
a
r
a
l
l
e
l
 
p
a
t
h
s
.
o
T
h
e
 
n
u
m
b
e
r
 
o
f
 
c
o
n
d
u
c
t
o
r
s
 
p
e
r
 
p
a
t
h
 
i
s
 
t
h
e
 
t
o
t
a
l
 
n
u
m
b
e
r
 
o
f
 
a
r
m
a
t
u
r
e
c
o
n
d
u
c
t
o
r
s
 
d
i
v
i
d
e
d
 
b
y
 
2
.
 
 
 
P
RINCIPLES 
OF VOLTAGE AND TORQUE
 
GENERATION
 
 
23
 
V
o
l
t
a
g
e
 
i
n
d
u
c
e
d
 
i
n
 
a
 
c
o
i
l
:
 
Rec
a
ll
 
w
h
e
r
e
 
k
a
 
i
s
 
t
h
e
 
a
r
m
a
t
u
r
e
 
c
o
n
s
t
a
n
t
,
 
N
 
i
s
 
t
h
e
 
n
u
m
b
e
r
 
o
f
 
c
o
i
l
 
t
u
r
n
s
,
 
a
n
d
 
Z
 
i
s
 
t
h
e
t
o
t
a
l
 
n
u
m
b
e
r
 
o
f
 
c
o
n
d
u
c
t
o
r
s
.
 
(
Z
 
=
 
2
N
)
 
O
r
 
 
 
g
 
ZP
ϕ
ω
 
N
P
ϕ
ω
E
 
=
 
=
 
π
 
In order to include 
the 
effect 
of the number of parallel paths 
(
a
)
, 
the
 
above
equation is modified as
 
follows
ZPϕω
 
NPϕω
E
g
 
=
 
2πa
 
=
 
πa
E
g
 
=
 
k
a
ϕω
 
;
 
where
 
ZP
 
NP
k
a 
= 
2πa 
=
 
πa
 
M
ACHINE 
M
AIN 
W
INDINGS
 
O
VERVIEW
 
 
24
W
i
n
d
i
n
g
 
L
a
p
a
 
=
 
P
 
 
p
l
e
x
W
a
v
e
a
 
=
 
2
 
 
p
l
e
x
S
e
p
a
r
a
t
e
l
y
 
E
x
c
i
t
e
d
 
S
e
l
f
 
e
x
c
i
t
e
d
A
r
m
a
t
u
r
e
F
i
e
l
d
S
e
r
i
e
s
 
S
h
u
n
t
 
C
o
m
p
o
u
n
d
 
 
P
e
r
m
a
n
e
n
t
 
M
a
g
n
e
t
D
i
f
f
e
r
e
n
t
i
a
l
 
C
o
m
p
o
u
n
d
C
o
m
m
u
t
a
t
i
v
e
 
C
o
m
p
o
u
n
d
 
I
DENTIFYING
 
W
INDINGS
 
 
25
 
o
The windings of a dc motor can be identified with an
 
ohmmeter.
o
T
h
e
 
s
h
u
n
t
 
f
i
e
l
d
 
w
i
n
d
i
n
g
 
c
a
n
 
b
e
 
i
d
e
n
t
i
f
i
e
d
 
b
y
 
t
h
e
 
f
a
c
t
 
t
h
a
t
 
i
t
 
h
a
s
 
a
 
h
i
g
h
r
e
s
i
s
t
a
n
c
e
 
a
s
 
c
o
m
p
a
r
e
d
 
t
o
 
t
h
e
 
o
t
h
e
r
 
t
w
o
 
w
i
n
d
i
n
g
s
.
o
T
h
e
 
s
e
r
i
e
s
 
f
i
e
l
d
 
a
n
d
 
a
r
m
a
t
u
r
e
 
w
i
n
d
i
n
g
s
 
h
a
v
e
 
a
 
v
e
r
y
 
l
o
w
 
r
e
s
i
s
t
a
n
c
e
.
T
h
e
y
 
c
a
n
 
b
e
 
i
d
e
n
t
i
f
i
e
d
,
 
h
o
w
e
v
e
r
,
 
b
y
 
t
u
r
n
i
n
g
 
t
h
e
 
m
o
t
o
r
 
s
h
a
f
t
.
o
W
h
e
n
 
t
h
e
 
o
h
m
m
e
t
e
r
 
i
s
 
c
o
n
n
e
c
t
e
d
 
t
o
 
t
h
e
 
s
e
r
i
e
s
 
f
i
e
l
d
 
a
n
d
 
t
h
e
 
m
o
t
o
r
 
s
h
a
f
t
i
s
 
t
u
r
n
e
d
,
 
t
h
e
 
o
h
m
m
e
t
e
r
 
r
e
a
d
i
n
g
 
w
i
l
l
 
n
o
t
 
b
e
 
a
f
f
e
c
t
e
d
.
 
W
h
e
n
 
t
h
e
o
h
m
m
e
t
e
r
 
i
s
 
c
o
n
n
e
c
t
e
d
 
t
o
 
t
h
e
 
a
r
m
a
t
u
r
e
 
w
i
n
d
i
n
g
 
a
n
d
 
t
h
e
 
m
o
t
o
r
 
s
h
a
f
t
 
i
s
t
u
r
n
e
d
,
 
t
h
e
 
r
e
a
d
i
n
g
 
w
i
l
l
 
b
e
c
o
m
e
 
c
h
a
n
g
e
a
b
l
e
 
a
s
 
t
h
e
 
b
r
u
s
h
e
s
 
m
a
k
e
 
a
n
d
b
r
e
a
k
 
c
o
n
t
a
c
t
 
w
i
t
h
 
d
i
f
f
e
r
e
n
t
 
c
o
m
m
u
t
a
t
o
r
 
s
e
g
m
e
n
t
s
.
 
 
 
P
RINCIPLES 
OF VOLTAGE AND TORQUE
 
GENERATION
 
 
(a) The armature resistance
 
R
a
For simplex lap, 
a = P x 
Plex 
= 6
 
paths
Each path must
 
have
Z
path 
=Z
T
/a 
= 600/6 =100
 
cond.
R
path 
= 
Z
path 
x 
R
z 
= 100 
 0.04 = 4
 
R
a 
= 
R
path 
/ a = 4/6 = 0.667
 
 
2
 
6
 
 
Given
: 
Plex
=1 , 
P
=6 
, 
Z
T
=600 cond , 
R
z
=0.04 
 , 
V
z
=0.48 V , 
I
z
=15
 
A
 
E
x
a
m
p
l
e
 
1
:
An armature is wound 
simplex lap 
in a 6-pole 
generator. 
The 
total 
number
 
of
conductors is 600. The resistance per conductor is 0.04 
 
and the induce
voltage 
per conductor is 0.48 
V. 
If 
the 
wire is rated 15 
A,
 
find:
S
o
l
.
 
P
RINCIPLES 
OF VOLTAGE AND TORQUE
 
GENERATION
 
 
 
 
E
x
a
m
p
l
e
 
1
:
An armature is wound 
simplex lap 
in a 6-pole 
generator. 
The 
total 
number
 
of
conductors is 600. The resistance per conductor is 0.04 
 
and the induce
voltage 
per conductor is 0.48 
V. 
If 
the 
wire is rated 15 
A,
 
find:
S
o
l
.
(b)
The armature voltage
 
E
g
E
g 
= 
E
path 
= 
Z
path 
x 
V
z 
= 
100 
 0.48 = 48
 
V
(c)
The rated armature current
I
a 
 
I
a 
= a x 
I
z 
= 6
 15 = 90
 
A
(d)
The rated power of the
 
armature
P
o 
= 
E
g 
x 
I
a 
= 48 
 90 = 
4320
 
W
 
2
 
7
 
Example
 
2:
An armature is wound 
simplex wave 
in a 6-pole
generator. 
The 
total 
number
 
of  conductors is 600.
The resistance per conductor is 0.04 
 
and the
induce  voltage per conductor is 0.48 
V. 
If 
the 
wire is
rated 15 A,
 
find:
Sol.
 
 
 
(a) The armature resistance
 
R
a
For simplex wave, 
a = 2 x 
Plex 
= 2
 
paths
Each path must
 
have
Z
path 
=Z
T
/a 
= 600/2 =300
 
cond.
R
path 
= 
Z
path 
x 
R
z 
= 300 
 0.04 = 12
 
 
R
a
 
 
=
 
R
p
a
th
 
/ a =
 
12
/
2
 
=
 
6
 
 
28
Given
: 
P
lex=1 
, 
P
=6 
, 
Z
T
=600 cond. , 
R
z
=0.04 
 , 
V
z
=0.48 V , 
I
z
=15
 
A
 
P
RINCIPLES 
OF VOLTAGE AND TORQUE
 
GENERATION
 
 
 
 
E
x
a
m
p
l
e
 
2
:
An armature is wound 
simplex wave 
in a 6-pole 
generator. 
The 
total 
number
 
of
conductors is 600. The resistance per conductor is 0.04 
 
and the induce
voltage per conductor is 0.48 
V. 
If 
the 
wire is rated 15 A,
 
find:
S
o
l
.
(b)
The armature voltage
 
E
g
E
g 
= 
E
path 
= 
Z
path 
x 
V
z 
= 
300 
 0.48 = 
144
 
V
(c)
The rated armature current
I
a 
 
I
a 
= a x 
I
z 
= 2 
 15 = 30
 
A
(d)
The rated power of the
 
armature
P
o 
= 
E
g 
x 
I
a 
= 
144 
 30 = 
4320
 
W
 
29
 
P
RINCIPLES 
OF VOLTAGE AND TORQUE
 
GENERATION
 
 
ZP
 
300
 
× 8
 
150
k
a  
=
 
2πa
 
=
 
×
 
8
 
=
 
π
 
S
o
l
.
(
a
)
 
F
o
r
 
s
i
m
p
l
e
x
 
l
a
p
;
 
a
 
=
 
P
 
=
 
8
 
g
 
π
 
150
E
 
=
 
× 2 × 
10
−3 
×
 
180
 
E
g
 
= 17.2
 
V
 
(
b
)
 
F
o
r
 
s
i
m
p
l
e
x
 
w
a
v
e
;
 
a
 
=
 
2
 
E
g
 
=
 
ZPϕ
 
ω
 
2
πa
 
300
 
 
8
 
2
 
10
3
 
180
 
E
g
 
 
2

 
2
 
E
g 
 68.75
 
V
 
E
x
a
m
p
l
e
 
3
:
An 8-pole generator has a 
total 
of 300 conductors. It is driven at 180
 
rad/s
and the flux/pole 
is 
2 mWb. Find 
the 
average voltage generated by the
armature if it 
is 
wound: (a) simplex lap, (b) simplex
 
wave.
 
30
 
 
 
E
g 
= 
k
a
ϕ
 
ω
 
P
RINCIPLES 
OF VOLTAGE AND TORQUE
 
GENERATION
 
 
31
 
F
o
r
 
s
i
m
p
l
e
x
 
w
a
v
e
;
 
a
 
=
 
2
 
E
g 
=
 
k
a
ϕω
ZP
k
a 
= 
2πa
 
=
 
800 
×
 
32
 
×
 
2
 
=
 
64
00
 
π
 
ϕ
 
=
 
× 
32 
×
 
120
 
800 × 
32 
×
 
5.76
 
= 
164
 
mWb
 
 
 
ω
 
=
 
5
5
 
×
 
=
 
5
.
7
6
 
ra
d
/
s
 
E
x
a
m
p
l
e
 
 
4
:
A 32-pole generator has 800 conductors. It is driven at 55 rpm. Find 
the
 
flux
per pole necessary to generate an average voltage of 120 
V, 
if the
 
armature
is wound: (a) simplex lap, (b) simplex
 
wave.
 
E
g
 
=
 
60
ZPϕω
 
2
πa
 
⇒ ϕ
 
=
 
2πaE
g
 
ZPω
 
S
o
l
.
(
a
)
 
F
o
r
 
s
i
m
p
l
e
x
 
l
a
p
;
 
a
 
=
 
P
 
=
 
3
2
 
E
g
 
a
 
120 ×
 
π
 
ϕ
 
=
 
=
k
 
ω
 
6400 
×
 
5.76
 
ϕ = 
10.24
 
mWb
 
P
RINCIPLES 
OF VOLTAGE AND TORQUE
 
GENERATION
 
 
32
 
Z
 
P
 
64
0
8
 
32
0
 
k
a 
 
2 
a
 
 
2

8
 
 
 
S
o
l
.
(
a
)
 
F
o
r
 
s
i
m
p
l
e
x
 
l
a
p
;
 
a
 
=
 
P
 
=
 
8
E
g 
 
k
a 
 
 
E
 
 
 

g
 
 
 
821
 
rad
 
/
 
s
 
k
a
 
460

320
 
5.5
10
3
 
 
 
(
b
)
 
F
o
r
 
s
i
m
p
l
e
x
 
w
a
v
e
;
 
a
 
=
 
2
 
E
x
a
m
p
l
e
 
 
 
 
5
:
An eight -pole generator has a 
total 
of 640 conductors and a flux per pole
 
of
5.5 mWb. Find 
the 
speed it must be driven at to generate 460 V if
 
the
armature is wound: (a) 
simplex 
lap
, 
(b) 
simplex
 
wave
.
 
g
 
ZP
ϕ
ω
E
 
=
 
2
πa
 
2πaE
g
⇒ ω
 
=
 
ZPϕ
 
ω
 
=
 
2
πa
E
 
g
 
=
 
× 2 ×
 
460
 
ZPϕ
 
640 
× 8 × 5.5 ×
 
10
−3
 
ω = 205.3
 
rad/s
 
P
RINCIPLES 
OF VOLTAGE AND TORQUE
 
GENERATION
 
 
33
 
(
b
)
 
F
o
r
 
s
i
m
p
l
e
x
 
w
a
v
e
;
 
a
 
=
 
2
 
a
 
ZP
 
22
40
 
×
 
1
6
 
1
1
2
0
k
 
=
 
=
 
=
2πa
 
 
×
 16
 
π
 
 
 
 
 
955
 
2
 
 
100
 
rad 
/
 
s
 
S
o
l
.
(
a
)
 
F
o
r
 
s
i
m
p
l
e
x
 
l
a
p
;
 
a
 
=
 
P
 
=
 
1
6
 
1120
 
3
 
E
g
 
 
 
5
10
 
100
 
 
178.3
 
V
 
 
E
g
 
 
8960
 
 
5
10
3
 
100
 
 
1426
 
V
 
 
E
x
a
m
p
l
e
 
6
:
A 16-pole generator has a 
total 
of 2240 armature conductors, a flux per
pole of 5 mWb and is driven at 955 rpm. Find 
the 
generated voltage if
 
the
armature is wound: (a) 
simplex 
lap
, 
(b) 
simplex
 
wave
.
 
ZP
 
2240 
×
 
16
k
a  
=
 
2πa
 
=
 
×
 
2
 
=
 
8
9
6
0
 
π
 
E
g 
= 
k
a
ϕ
 
ω
 
60
E
g  
= 
k
a
ϕ
 
ω
 
P
RINCIPLES 
OF VOLTAGE AND TORQUE
 
GENERATION
 
 
34
 
g
 
ZP
ϕ
ω
E
 
=
 
2
πa
 
 
 
 
 
300
 
 
2
 
 
31.42
 
rad
 
/
 
s
60
 
2πaE
g
 
P
 
=
 
=
 
× 2 ×
 
535
 
 
ω
 
648 
× 0.0555 ×
 
31.42
 
= 
5.95 
P =
 
6
 
E
g
 
=
 
=
 
ZPϕω
 
648 
× 6 × 55.5 × 
10
−3 
×
 
31.42
 
2πa
 
×
 
2
 
= 539.2
 
V
 
E
x
a
m
p
l
e
 
7
:
A certain 
simplex wave-wound 
dc 
generator, 
running at a speed of 300 rpm
is 
to 
generate an induced emf of about 535 
V. 
the 
flux/pole 
being 55.5
 
mWb.
Determine the number of poles if the number of conductors is
 
648.
 
S
o
l
.
F
o
r
 
s
i
m
p
l
e
x
 
w
a
v
e
;
 
a
 
=
 
2
 
The 
exact induced 
emf for 
6-pole
 
generator
 
is
 
1.
An 
8-pole armature is wound 
simplex 
wave. It has a total of 1200 conductors, each
having a resistance of 35 
m
. 
The average generated voltage per conductor is 0.56 V.
If the conductors are rated 15 A, find: (a) the armature resistance, (b) the armature
voltage, (c) the rated armature current, and 
(d) 
the rated power of the
 
armature.
2.
The armature in an eight-pole generator is wound 
simplex 
lap. It is 
rated 
230 V, 5 
kW.
If it 
has 
a total of 1200 conductors and the total armature resistance is 0.8 
, find: (a)
the rated current per conductor, (b) the generated voltage per conductor, and 
(c) 
the
resistance per
 
conductor.
3.
Repeat problem 2 if the armature is 
simplex 
wave
 
wound.
4.
A six-pole generator has a total of 900 conductors. 
When 
it is driven at 60
 rad/s, its
armature generates 230V. Find the required flux per pole if the armature is wound (a)
Simplex 
lap, (b) 
Simplex
 
wave.
5.
A four-pole generator has a total of 1440 conductors and a flux per pole of 4.6 mWb.
When 
it is driven at 64
 rad/s the generated voltage is 265 V. Is the armature wound
simplex 
lap, 
simplex 
wave, or
 
neither?
 
Extra
 
Problems
 
 
35
 
 
Slide Note
Embed
Share

Learn about the construction and types of armature windings in DC machines, including lap wound and wave wound armatures. Discover how lap wound armatures are suitable for low voltage, high current applications, while wave wound armatures are used in high voltage, low current scenarios. Understand the principles of voltage and torque generation in armature coils. Explore the differences between lap wound and wave wound configurations and their applications in different types of machines.


Uploaded on Jul 23, 2024 | 0 Views


Download Presentation

Please find below an Image/Link to download the presentation.

The content on the website is provided AS IS for your information and personal use only. It may not be sold, licensed, or shared on other websites without obtaining consent from the author. Download presentation by click this link. If you encounter any issues during the download, it is possible that the publisher has removed the file from their server.

E N D

Presentation Transcript


  1. Lecture # 2

  2. DC MACHINE CONSTRUCTION - ARMATURE WINDING o The windings of armatures are connected in different ways (Lapwinding and wave winding ) depending on the requirements of themachine. o The difference in how the coils are interconnected at thecommutator segments and the number of segmentsused. 19

  3. DC MACHINE CONSTRUCTION - ARMATURE WINDING Lap Wound o Lap Wound Armatures: are used in machines designed for low voltage and high current armatures are constructed with largewire because of high current. o Example: It is used in the starter motor of almost allautomobiles. o The windings of a lap wound armature are connected inparallel. o This permits the current capacity of each winding to be addedand provides a higher operating current. o No. of parallel current paths, a = P ; P = No. ofpoles (simplex lap winding ) o No. of parallel current paths, a = 2 P ; P = No. ofpoles (duplex lap winding ) Lap woundarmatures o In general, a = P plex 20

  4. DC MACHINE CONSTRUCTION - ARMATURE WINDING Wave Wound o Wave Wound Armatures are used in machines designed forhigh voltage and low current. o Their windings connected in series. o When the windings are connected in series, the voltage of eachwinding adds, but the current capacity remains thesame. o Example: small generator in hand-crankedmega-ohmmeters. Wave woundarmatures

  5. DC MACHINE CONSTRUCTION - ARMATURE WINDING Wave Wound o For a simplex wave winding there will always be two parallelpaths regardless of the number of poles (a=2). o A duplex wave winding will double the number of parallel pathspresent in the simplex (a = 2 2). o In general a = 2 plex o The number of coils on an armature is notimportant. o What is important is the total number of conductors (Z) onthe armature and the number of parallelpaths. o The number of conductors per path is the total number ofarmature conductors divided by 2.

  6. PRINCIPLES OF VOLTAGE AND TORQUE GENERATION Voltage induced in a coil: ZP NP Recall E = = g 2 In order to include the effect of the number of parallel paths (a), theabove equation is modified as follows ZP Eg= 2 a NP a = Or ZP NP Eg= ka ; where ka = 2 a = a where ka is the armature constant, N is the number of coil turns, and Z is the total number of conductors. (Z = 2N)

  7. MACHINE MAIN WINDINGS OVERVIEW Winding Armature Field Wave Lap Separately Excited Permanent Magnet Self excited a = 2 plex a = P plex Compound Shunt Series Differential Compound Commutative Compound

  8. IDENTIFYINGWINDINGS The windings of a dc motor can be identified with anohmmeter. o o The shunt field winding can be identified by the fact that it has ahigh resistance as compared to the other twowindings. o The series field and armature windings have a very low resistance. They can be identified, however, by turning the motorshaft. o When the ohmmeter is connected to the series field and the motorshaft is turned, the ohmmeter reading will not be affected. When the ohmmeter is connected to the armature winding and the motor shaft is turned, the reading will become changeable as the brushes make and break contact with different commutatorsegments.

  9. PRINCIPLES OF VOLTAGE AND TORQUE GENERATION Example 1: An armature is wound simplex lap in a 6-pole generator. The total numberof conductors is 600. The resistance per conductor is 0.04 and the induce voltage per conductor is 0.48 V. If the wire is rated 15 A,find: Sol. Given: Plex=1 , P=6 , ZT=600 cond , Rz=0.04 , Vz=0.48 V , Iz=15 A (a) The armature resistanceRa For simplex lap, a = P x Plex = 6paths Each path must have Zpath =ZT/a = 600/6 =100cond. Rpath = Zpath x Rz = 100 0.04 = 4 Ra = Rpath / a = 4/6 = 0.667 26

  10. PRINCIPLES OF VOLTAGE AND TORQUE GENERATION Example 1: An armature is wound simplex lap in a 6-pole generator. The total numberof conductors is 600. The resistance per conductor is 0.04 and the induce voltage per conductor is 0.48 V. If the wire is rated 15 A,find: Sol. (b) The armature voltage Eg Eg = Epath = Zpath x Vz = 100 0.48 = 48V (c) The rated armature current Ia Ia = a x Iz = 6 15 = 90 A (d) The rated power of the armature Po = Eg x Ia = 48 90 = 4320W 27

  11. Example 2: An armature is wound simplex wave in a 6-pole generator. The total number of conductors is 600. The resistance per conductor is 0.04 and the induce voltage per conductor is 0.48 V. If the wire is rated 15 A, find: (a) The armature resistanceRa For simplex wave, a = 2 x Plex = 2paths Given: Plex=1 , P=6 , ZT=600 cond. , Rz=0.04 , Vz=0.48 V , Iz=15 A Sol. Each path must have Zpath =ZT/a = 600/2 =300cond. Rpath = Zpath x Rz = 300 0.04 = 12 Ra= Rpath/ a = 12/2 = 6 28

  12. PRINCIPLES OF VOLTAGE AND TORQUE GENERATION Example 2: An armature is wound simplex wave in a 6-pole generator. The total numberof conductors is 600. The resistance per conductor is 0.04 and the induce voltage per conductor is 0.48 V. If the wire is rated 15 A,find: Sol. (b) The armature voltage Eg Eg = Epath = Zpath x Vz = 300 0.48 = 144V (c) The rated armature current Ia Ia = a x Iz = 2 15 = 30 A (d) The rated power of the armature Po = Eg x Ia = 144 30 = 4320W 29

  13. PRINCIPLES OF VOLTAGE AND TORQUE GENERATION Example 3: An 8-pole generator has a total of 300 conductors. It is driven at 180rad/s and the flux/pole is 2 mWb. Find the average voltage generated by the armature if it is wound: (a) simplex lap, (b) simplexwave. Sol. (a) For simplex lap; a = P = 8 (b) For simplex wave; a = 2 Eg=ZP ZP 300 8 150 ka =2 a=2 8= 2 a 300 8 2 10 3 180 2 2 Eg = 68.75 V Eg = ka Eg= 150 2 10 3 180 E = g Eg = 17.2 V 30

  14. PRINCIPLES OF VOLTAGE AND TORQUE GENERATION Example 4: A 32-pole generator has 800 conductors. It is driven at 55 rpm. Find the flux per pole necessary to generate an average voltage of 120 V, if the armature is wound: (a) simplex lap, (b) simplexwave. Sol. (a) For simplex lap; a = P = 32 For simplex wave; a = 2 2 Eg = ka = 55 = 5.76 rad/s 60 ZP 800 32 2 2 =6400 ka = 2 a= =2 aEg ZP 2 a Eg= ZP Eg 120 6400 5.76 = = 2 32 120 800 32 5.76= 164 mWb k a = = 10.24 mWb

  15. PRINCIPLES OF VOLTAGE AND TORQUE GENERATION Example 5: An eight -pole generator has a total of 640 conductors and a flux per poleof 5.5 mWb. Find the speed it must be driven at to generate 460 V ifthe armature is wound: (a) simplex lap, (b) simplexwave. Sol. (b) For simplex wave; a = 2 (a) For simplex lap; a = P = 8 2 aEg ZP Eg = ka = E = g 2 a ZP 640 8 2 8= Z P 320 ka =2 a= =2 aEg= ZP 2 2 460 640 8 5.5 10 3 E 460 = g= =821rad/s = 205.3 rad/s 320 5.5 10 3 ka

  16. PRINCIPLES OF VOLTAGE AND TORQUE GENERATION Example 6: A 16-pole generator has a total of 2240 armature conductors, a flux per pole of 5 mWb and is driven at 955 rpm. Find the generated voltage ifthe armature is wound: (a) simplex lap, (b) simplexwave. Sol. (a) For simplex lap; a = P = 16 (b) For simplex wave; a = 2 ZP 2240 16 1120 =8960 ZP 2240 16 2 2 k = = = ka =2 a= a 2 a 2 16 = 955 2 =100 Eg = ka rad /s 60 Eg = ka Eg=8960 5 10 3 100 =1426 V 1120 3 Eg= 5 10 100 =178.3V

  17. PRINCIPLES OF VOLTAGE AND TORQUE GENERATION Example 7: A certain simplex wave-wound dc generator, running at a speed of 300 rpm is to generate an induced emf of about 535 V. the flux/pole being 55.5 mWb. Determine the number of poles if the number of conductors is648. Sol. For simplex wave; a = 2 =300 2 = 31.42 rad/s 60 ZP E = g 2 a 2 aEg Z 2 2 535 648 0.0555 31.42= 5.95 P = 6 P = = The exact induced emf for 6-pole generator is 648 6 55.5 10 3 31.42 2 2 ZP 2 a Eg= = = 539.2 V

  18. Extra Problems 1. An 8-pole armature is wound simplex wave. It has a total of 1200 conductors, each having a resistance of 35 m . The average generated voltage per conductor is 0.56 V. If the conductors are rated 15 A, find: (a) the armature resistance, (b) the armature voltage, (c) the rated armature current, and (d) the rated power of the armature. 2. The armature in an eight-pole generator is wound simplex lap. It is rated 230 V, 5 kW. If it has a total of 1200 conductors and the total armature resistance is 0.8 , find: (a) the rated current per conductor, (b) the generated voltage per conductor, and (c) the resistance per conductor. 3. Repeat problem 2 if the armature is simplex wave wound. 4. A six-pole generator has a total of 900 conductors. When it is driven at 60 rad/s, its armature generates 230V. Find the required flux per pole if the armature is wound (a) Simplex lap, (b) Simplex wave. 5. A four-pole generator has a total of 1440 conductors and a flux per pole of 4.6 mWb. When it is driven at 64 rad/s the generated voltage is 265 V. Is the armature wound simplex lap, simplex wave, or neither?

Related


More Related Content

giItT1WQy@!-/#giItT1WQy@!-/#giItT1WQy@!-/#giItT1WQy@!-/#giItT1WQy@!-/#giItT1WQy@!-/#giItT1WQy@!-/#giItT1WQy@!-/#giItT1WQy@!-/#giItT1WQy@!-/#giItT1WQy@!-/#giItT1WQy@!-/#