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Ahmed M. T. Ibraheem Alnaib, Lecturer.
Dep. of Electrical Power Technology Eng., Technical college / Mosul, Northern Technical University.
Electrical and Electronic Engineering
Electrical Machine:
Classification of Motors:
Ahmed M. T. Ibraheem Alnaib, Lecturer.
Dep. of Electrical Power Technology Eng., Technical college / Mosul, Northern Technical University.
DC Motor:
Futures of DC Motors:
1- Most of the electrical machines in service are AC types.
2- DC machine are of considerable industrial importance.
3- DC machine mainly used as DC motors and the DC generators are rarely used.
4- DC motors provides a fine control of the speed which can not be attained by AC
motors.
5- DC motors can develop rated torque at all speeds from standstill to rated speed.
6- Developed torque at standstill is many times greater than the torque developed by an
AC motor of equal power and speed rating.
Application of DC Machines:
The DC machine can operate as either a motor or a generator; at present its use as a
generator is limited because of the widespread use of ac power.
Large DC motors are used in machine tools, printing presses, fans, pumps,
cranes, paper mill, traction, textile mills and so forth.
Small DC machines (fractional horsepower rating) are used primarily as control
device-such as tachogenerators for speed sensing and servomotors for position
and tracking, and used in Robots.
Advantages of DC Machines:
High starting torque
• Rapid acceleration and deceleration.
• Speed can be easily controlled over wide speed range.
• Used in tough gobs (traction motors, electric trains, electric cars,….)
• Built in wide range of sizes.
Disadvantages of DC Machines:
• Needs regular maintenance
• Cannot be used in explosive area.
• High cost.
Ahmed M. T. Ibraheem Alnaib, Lecturer.
Dep. of Electrical Power Technology Eng., Technical college / Mosul, Northern Technical University.
Construction of DC Machine:
Across-section of a 4-pole DC motor is shown in figure below:
The construction generally consists of:
1- Yoke:
This is the outer part of the DC motor. It provides the mechanical supports for the poles and acts
as a protecting cover for the whole machine. It carries the magnetic flux produced by the poles. Yokes
are made out of cast iron or cast steel.
2- Field pole:
The field poles are mounted inside the yoke, are made of thin lamination stacked together, it
consist of pole cores and pole shoes as shown in figure below.
.
Ahmed M. T. Ibraheem Alnaib, Lecturer.
Dep. of Electrical Power Technology Eng., Technical college / Mosul, Northern Technical University.
The pole shoes serve two purposes.
(i) They spread out the flux in the air gap and also being the larger cross section reduced
the reluctance of the magnetic path, thus the mean turn length of the wire will reduced
thereby its reduce its weight and cost.
(ii) They support the field coils.
3- Field winding:
The field coils are wound on the poles. There are two types of field windings:
a- Shunt field winding: large number of turns of small section copper conductor is
used (fine wire). It is connected in parallel with the armature windings.
b- Series field winding: few turns of heavy cross section conductor is used. . It is
connected in series with the armature windings.
A DC motor may have both field windings wound on the same pole.
- Shunt motor: motor with only shunt field windings.
- Series DC motor: motor with only series field windings.
- Compound DC motor: motor with both field windings (shunt & series).
-
Ahmed M. T. Ibraheem Alnaib, Lecturer.
Dep. of Electrical Power Technology Eng., Technical college / Mosul, Northern Technical University.
4- Armature:
a. Armature core: it carries the armature winding, is made of sheet-steel
laminations. The laminations are stacked together to form a cylindrical structure
as shown in figure below.
b. Armature windings: is the heart of the DC motor in which the torque is
developed.
5- Commutatator:
The commutator, whose function is to facilitate the collection of current from the
armature, It consists of copper segments tightly fastened together with mica/micanite
insulating separators on an insulated base. The whole commutator forms a rigid and
solid assembly of insulated copper strips and can rotate at high speeds. Each
Ahmed M. T. Ibraheem Alnaib, Lecturer.
Dep. of Electrical Power Technology Eng., Technical college / Mosul, Northern Technical University.
commutator segment is provided with a ’riser’ where the ends of the armature coils get
connected.
No. of segments = No. of armature windings
6- Brushes:
Are the elements which are connecting the armature windings (through commutator)
to the external terminal of the motor. The brush pressure on the commutator should be
just right, because low pressure leads to poor contacts which results in excessive
sparking and burning the commutator. While high pressure lead overheating the
commutator.
Ahmed M. T. Ibraheem Alnaib, Lecturer.
Dep. of Electrical Power Technology Eng., Technical college / Mosul, Northern Technical University.
Principle of operation of a DC motor:
In a DC motor:
Field poles are supplied by DC excitation current, which produces a DC magnetic
field.
Armature winding (conductor) is supplied by dc current through the brushes, and
commutator.
According to the Lorents force equation, a current-carrying conductor when
placed in a magnetic field experiences a force that tend to move it, as shown in the
following figure.
All the conductors placed on the periphery of a DC motor are subjected to these forces.
These forces cause the armature to rotate in the clockwise direction. Therefore, the
armature of a DC motor rotates in the direction of the torque developed by the motor.
Ahmed M. T. Ibraheem Alnaib, Lecturer.
Dep. of Electrical Power Technology Eng., Technical college / Mosul, Northern Technical University.
BACK e.m.f.:
Due to the rotation of the armature coil (i.e. a conductor) in the magnetic field, the
motor works as a DC generator and induced e.m.f acts in the circuit, this opposes the
current. This induced e.m.f is called back e.m.f ().


 machine constant
: No. of poles
: Total of armature conductors
: No. of parallel paths in armature
 in case of Lap windings
 in case of Wave windings
: Flux/pole in weber


 Armature speed in revolution per minutes (rpm)

 (is produced by the generator action of the motor)
Ahmed M. T. Ibraheem Alnaib, Lecturer.
Dep. of Electrical Power Technology Eng., Technical college / Mosul, Northern Technical University.
Types of DC Motors:
1- Separately Excited DC Motor:
A shunt field windings are supplied from a separate constant DC power source
(like Battery) for producing the magnetic
flux, are represented by resistor Rf. The
resistor Rfc represents an external variable
resistor (sometimes lumped together with
the field coil resistance) used to control the
amount of current in the field circuit.
The armature windings are represented
by back e.m.f Eb and a resistor Ra. are
supplied from a DC power source ()



: Resistance of field winding.
: Resistance of control rheostat used in field circuit.
= +: total field resistance
: Resistance of armature circuit.
Ahmed M. T. Ibraheem Alnaib, Lecturer.
Dep. of Electrical Power Technology Eng., Technical college / Mosul, Northern Technical University.

2- Self-Excited DC Motor:
A field windings gets its power from the armature terminals of the motor.
a- Shunt DC motor:
A shunt winding gets its power from the armature terminals of the motor. shunt
field winding connected across (in parallel with) the armature terminals.




b- Series DC motor:
The series field winding connected in series with the armature windings.

󰇛 󰇜



Ahmed M. T. Ibraheem Alnaib, Lecturer.
Dep. of Electrical Power Technology Eng., Technical college / Mosul, Northern Technical University.

c- Compound DC motor:
Both shunt and series field windings are connected with the armature windings in
short-shunt or long-shunt.
1- Short shunt compound DC Motor:
When the shunt field winding is connected directly across the armature terminals,
it is called a short-shunt compound motor.


  

󰇛 󰇜 󰇛  󰇜
2- Long shunt compound DC motor:
When the shunt field winding is connected across the load, it is called a long-shunt
compound motor.



󰇛 󰇜 󰇛  󰇜
󰇛 󰇜
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Ahmed M. T. Ibraheem Alnaib, Lecturer.
Dep. of Electrical Power Technology Eng., Technical college / Mosul, Northern Technical University.

Efficiency󰇛󰇜:
The efficiency of a DC motor is the ratio of its mechanical output power 󰇛
󰇜 to the
electrical input power 󰇛󰇜.
󰇛󰇜
󰇛󰇜
 󰇛󰇜 
: is mechanical output power as mentioned previously, then it in (Horse Power H.P
unit) to convert its unit to Watt unit should be multiplied by 476.
 󰇛󰇜
󰇛󰇜 
 = 󰇛
󰇛 󰇜󰇜 

󰇛 󰇜
󰇛
󰇛 󰇜󰇜  
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Power-Flow Diagram:
A DC motor is a machine which converts electrical energy (or power) into
mechanical energy (or power).


    
Power-Flow Diagram of a DC Motor
Pin = Electrical input power =
 
Pd = Developed power (Electro mechanical power) =  
Po = Output power (Shaft power) =
Ts = Applied shaft torque
Rotational Losses = Mechanical losses + Magnetic losses
Pcu = Copper losses


Ahmed M. T. Ibraheem Alnaib, Lecturer.
Dep. of Electrical Power Technology Eng., Technical college / Mosul, Northern Technical University.

Losses in DC Machines:
The various losses occurring in a DC machines can be sub-divided as follows:
1- Copper losses.
Whenever current flows in a wire, a copper loss associated with it, it consists of:
Armature copper loss = Ia2 * Ra. This loss is about 30 to 40% of full-load losses.
The loss due to brush contact resistance; It is usually added to the armature copper
losses.
Field copper loss. This loss is about 20 to 30% of full-load losses.
1- Shunt copper loss = If2 * Rf.
2- Series copper loss = Iser2 * Rser.
2- Magnetic losses (Iron or Core losses):
This loss is about 20 to 30% of full-load losses. It consists of:
Hysteresis loss.
Eddy current loss.
3- Mechanical losses:
This loss is about 10 to 20% of full-load losses. It consist of:
These consist of:
Friction between the bearings and the shaft.
Friction between the brushes and the commutator.
Air-friction or winding loss of rotating armature.
Usually, magnetic and mechanical losses are collectively known as Rotational
Losses.
Rotational Losses = magnetic losses + mechanical losses
4- Stray losses:
These losses cannot be easily accounted.
- For large machine above (100 H.P); stray losses = 1% of the output power.
- For small machine are neglected.
------------------------------------------------------------------------------------
Ahmed M. T. Ibraheem Alnaib, Lecturer.
Dep. of Electrical Power Technology Eng., Technical college / Mosul, Northern Technical University.

Example 1: Find the efficiency of DC compound motor (long shunt), 25H.P, 230V,
shunt field resistance equal to 115Ω, series field resistance equal to 0.03Ω, armature
resistance equal to 0.18 Ω, rotational losses at load equal to 1088W, = 92A.
Sol:
Example 2: Find the efficiency of DC compound motor (long shunt); armature current
(101.3 A), rotate at (1800 rpm), total no. of armature conductor (476), flux/pole (0.015
wb), no. of parallel path (p=2), shunt field resistance (150Ω), series field resistance
(0.04Ω), armature resistance (0.1Ω), rotational losses at load (1827W).
Ahmed M. T. Ibraheem Alnaib, Lecturer.
Dep. of Electrical Power Technology Eng., Technical college / Mosul, Northern Technical University.

Example 3: A 300V DC shunt motor, shunt resistance (150 Ω), armature resistance (0.2
Ω), the source supplied current equal to 36 A, core losses (210 W), running at 1500
r.p.m. , friction losses (100 W).
Find: 1- back e.m.f. , 2- efficiency, 3- developed torque, 4- shaft torque.
Example 4: A 240 V short shunt compound DC motor, series resistance (0.09 Ω),
shunt resistance (80 Ω), armature resistance (0.11 Ω), the source supplied current equal
to 15 A, core losses (210 W), running at 1500 r.p.m. , friction losses (100 W).
Find: 1- back e.m.f. , 2- efficiency, 3- developed torque, 4- shaft torque.
Speed Control of DC Motor:
1- Speed control of separately excited DC motor:
We know that back e.m.f. is produced by the generator action of the motor. Hence
back e.m.f. 
 .
Let
be the applied voltage and and Ra is the armature circuit current and resistance
respectively.
Then


󰇛
󰇜 

Ahmed M. T. Ibraheem Alnaib, Lecturer.
Dep. of Electrical Power Technology Eng., Technical college / Mosul, Northern Technical University.

Or N
)( aa RIV
since P Z & A are constants for a particular motor.
From this formula it follows that the speed of a D.C. motor can be regulated by:
(i) Armature Control: Adjusting the terminal voltage (
) applied to the
armature
This method implies changing the voltage applied to the armature of the motor
without changing the voltage applied to its field. Therefore, the motor must be
separately excited to use armature voltage control.

Since Ia Ra drop is very small as compared to the applied voltage

, if applied voltage is constant
(ii) Field control: Adjusting the field resistance RF (and thus the field flux)
N
/1
, if applied voltage
is constant
Hence speed is inversely proportional to flux / per pole if the applied voltage is
constant. Then the speed can be increased by decrease the flux and vice versa.
The flux of DC motor can be changed by changing the field current (
), with
help of external field resistance ( ).

 
2- Speed control of shunt DC motor:
Here the speed control is similar to the speed control of separately excited DC
motor.

, if applied voltage is constant
, if applied voltage
is constant
But the difference is that:
Ahmed M. T. Ibraheem Alnaib, Lecturer.
Dep. of Electrical Power Technology Eng., Technical college / Mosul, Northern Technical University.

- The armature terminal voltage is adjusted by the external armature resistance ( ).
Because terminal voltage cannot be varied should be constant (if it varied caused to
to be varied also).
- The field current (
) is controlled by an external field resistance ( ).
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