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৪৯তম বিসিএস ⎯ তথ্য ও যোগাযোগ প্রযুক্তি (EEE) [ ৮৯২]

পরীক্ষা৪৯তম বিসিএস ⎯ তথ্য ও যোগাযোগ প্রযুক্তি (EEE) [ ৮৯২]তারিখতারিখ অনির্ধারিতসময়30 minutes
মোট প্রশ্ন৪৯
সিলেবাস
Exam 5 i) Synchronous Motors ii) Three-Phase Induction Motors iii) Starting and Speed Control Methods iv) Single-Phase Induction Motor v) Stepper Motors [Source: Class–4 and relevant books]
ঘনত্ব
উত্তর
উত্তরিতবর্তমানপুনরায় দেখুনঅসম্পূর্ণ

৪৯তম বিসিএস ⎯ তথ্য ও যোগাযোগ প্রযুক্তি (EEE) [ ৮৯২]

৪৯তম বিসিএস ⎯ তথ্য ও যোগাযোগ প্রযুক্তি (EEE) [ ৮৯২] · তারিখ অনির্ধারিত · ৪৯ প্রশ্ন

.
When the synchronous motor runs at synchronous speed, the voltage induced in the damper winding is- 
  1. maximum
  2. minimum
  3. zero
  4. one
সঠিক উত্তর:
zero
উত্তর
সঠিক উত্তর:
zero
ব্যাখ্যা

When the motor runs at synchronous speed, there is no relative motion between rotor and revolving flux produced by stator currents. Hence e.m.f. in the damper winding placed on the rotor is zero.

(Principles of Electrical Machines by V.K. Mehta, Rohit mehta)

.
In a synchronous motor, the power factor is influenced by the:
  1. Stator resistance
  2. Rotor resistance
  3. Excitation voltage
  4. Load current
সঠিক উত্তর:
Excitation voltage
উত্তর
সঠিক উত্তর:
Excitation voltage
ব্যাখ্যা
Power Factor in Synchronous Motors:

The power factor (PF) of a synchronous motor is the ratio of real power (active power) to apparent power. It indicates how effectively the motor is converting electrical power into useful mechanical power. The power factor of a synchronous motor can be leading, lagging, or unity, depending on the motor’s excitation.

Key Factors Affecting Power Factor:
The power factor in a synchronous motor is influenced by the relationship between the rotor's magnetic field and the stator's rotating magnetic field. This relationship is controlled by the excitation voltage, which is applied to the field windings of the motor.

Explanation of the Role of Excitation Voltage:
Excitation Voltage:
The excitation voltage (or the DC voltage applied to the field windings) controls the magnetic field in the rotor. This field interacts with the rotating magnetic field produced by the stator. The strength of the rotor’s magnetic field determines the motor's power factor.(Electric Machinery and Transformers by Bhag S. Guru and Huseyin R. Hiziroglu)


Underexcited Motor (Insufficient excitation):
When the excitation voltage is low, the motor becomes underexcited, meaning it produces a weak magnetic field in the rotor. In this case, the motor will draw lagging current, resulting in a lagging power factor.


Overexcited Motor (Excessive excitation):
When the excitation voltage is high, the rotor produces a strong magnetic field, and the motor operates in an overexcited condition. In this case, the motor will draw a leading current, resulting in a leading power factor.


Unity Power Factor:
If the excitation voltage is adjusted properly, the motor can operate at a unity power factor (PF = 1), meaning the current and voltage are perfectly in phase, and there is no reactive power.


Why the Other Options Are Incorrect:
(ক) Stator resistance:
The stator resistance has a small effect on the motor’s efficiency and losses, but it does not significantly impact the power factor in the same way as excitation voltage does. The stator resistance primarily affects the losses and efficiency, but not the power factor directly.


(খ) Rotor resistance:
The rotor resistance affects the losses in the rotor and influences the efficiency of the motor. However, like stator resistance, rotor resistance does not directly control the power factor. The power factor is more dependent on the strength of the magnetic field in the rotor, which is controlled by the excitation voltage.


(ঘ) Load current:
While the load current affects the torque and output power of the motor, it does not directly determine the power factor. The current drawn by the motor can be either leading or lagging, depending on the excitation voltage, but the load current alone does not dictate the power factor.
.
For a given load, the normal field excitation of synchronous motor is that which gives the power factor of what?
  1. unity
  2. 0.8 lagging
  3. 0.8 leading.
  4. none of the above
সঠিক উত্তর:
unity
উত্তর
সঠিক উত্তর:
unity
ব্যাখ্যা

The resultant flux d in a synchronous motor is fixed in value as the applied stator voltage is constant. Since synchronous motor is a doubly excited machine, both d.c. and a.c, sources may co-operate to produce this fixed resultant flux o. For a given mechanical load, if the entire resultant flux is provided by d.c, excitation alone, the stator will absorb no reactive power (as it is not contributing to the resultant flux). Hence the p.f. of the motor will be unity.

(Principles of Electrical Machines by V.K. Mehta, Rohit mehta)

.
The synchronous reactance in the equivalent circuit primarily determines:
  1. The motor’s starting torque
  2. The motor’s speed
  3. The motor’s voltage regulation
  4. The motor’s power factor
সঠিক উত্তর:
The motor’s voltage regulation
উত্তর
সঠিক উত্তর:
The motor’s voltage regulation
ব্যাখ্যা

Synchronous Reactance (Xs​):The synchronous reactance is the combined reactance of the stator inductance and the magnetic leakage reactance in a synchronous motor. It is a key parameter in the equivalent circuit of the motor, and it represents the opposition to the flow of alternating current (AC) due to the motor’s inductive characteristics.
The synchronous reactance contributes to the impedance seen by the stator, and it significantly impacts the motor's ability to regulate voltage under varying load conditions.


Voltage Regulation:Voltage regulation refers to the ability of the motor to maintain a constant terminal voltage despite changes in the load. When the load on the synchronous motor increases, the terminal voltage can drop due to the drop in the current through the motor’s reactance. The larger the synchronous reactance, the larger the voltage drop under load, resulting in poorer voltage regulation.
The voltage regulation can be calculated as the difference between the no-load voltage and the full-load voltage as a percentage of the full-load voltage. The higher the synchronous reactance, the greater the drop in voltage from no-load to full-load conditions, leading to a larger voltage regulation.


Why the Other Options Are Incorrect:
(ক) The motor’s starting torque:The starting torque of a synchronous motor is primarily influenced by the initial conditions when the motor is started. Synchronous motors typically do not generate a large starting torque, as they need to be synchronized with the supply frequency. The starting torque is more influenced by the synchronous reactance and the field excitation, but not as directly as voltage regulation.


(খ) The motor’s speed:The speed of a synchronous motor is determined by the supply frequency and the number of poles in the motor, and it is fixed at synchronous speed. The synchronous reactance does not directly affect the motor's speed, as it operates at synchronous speed once started.


(ঘ) The motor’s power factor: While the synchronous reactance does influence the power factor (it is related to the phase difference between current and voltage), it is not the primary determinant of the motor’s power factor. The excitation voltage plays a more significant role in determining the power factor of the motor.

Source: Electric Machinery Fundamentals by Stephen J. Chapman

.
At full-load, the rotor poles of a synchronous motor are displaced by a mechanical angle of 1° from their no-load position. If the machine has 40 poles, then torque angle is....
  1. 40° electrical
  2. 20° electrical
  3. 10° electrical
  4. none of the above
সঠিক উত্তর:
20° electrical
উত্তর
সঠিক উত্তর:
20° electrical
ব্যাখ্যা

The equation provided below represents the angle of the field (δ) in the context of an alternating current (AC) system, possibly related to synchronous machines or rotating magnetic fields. Let’s break down the formula and the calculation:

The Formula:

δ = (p * α) / 2

Where:

δ = Angle of the field (likely in degrees or radians),

p = Number of poles of the motor (or machine),

α = The electrical angle (possibly related to the phase angle or the electrical angle of the rotor).

Given Values:

p = 40 (this indicates the number of poles),

α = 1 (it seems this represents a unit angle or phase angle, often taken as 1 for simplicity or normalization).

Calculation:

Substitute the given values into the formula:

δ = (40 × 1) / 2 = 20°

δ = 20°: This result represents the angle of the rotor’s magnetic field relative to the stator’s magnetic field. It could be interpreted as the angle between the rotor field and the stator field in an AC system like a synchronous motor. This angle is critical in the operation of machines, as it affects torque production, efficiency, and synchrony between the rotor and stator.


Source: Principles of Electrical Machines by V.K. Mehta, Rohit Mehta

.
If the excitation of a synchronous motor is reduced, what happens to the motor’s power factor?
  1. The power factor becomes more leading
  2. The power factor becomes more lagging
  3. The power factor remains unaffected
  4. The motor becomes unstable
সঠিক উত্তর:
The power factor becomes more lagging
উত্তর
সঠিক উত্তর:
The power factor becomes more lagging
ব্যাখ্যা

Effect of Reduced Excitation on Power Factor:
When the excitation of a synchronous motor is reduced, it means that the strength of the rotor's magnetic field is decreased. This change affects the relationship between the rotor’s magnetic field and the stator’s rotating magnetic field.

1. Underexcited Condition (Reduced Excitation):Underexcitation occurs when the excitation voltage (DC current supplied to the field windings) is reduced. With reduced excitation, the rotor’s magnetic field becomes weaker, causing the motor to lag more behind the stator’s rotating magnetic field. This results in an increased lagging current. As a result, the power factor of the motor becomes more lagging. In a lagging power factor, the current lags the voltage, meaning that more reactive power is drawn, and less real power is converted into useful mechanical energy.

2. Why Power Factor Becomes Lagging: The synchronous motor operates at a power factor that can be leading or lagging, depending on the level of excitation:

Overexcited (higher excitation): The motor’s power factor is leading, meaning the motor produces a strong rotor field and supplies reactive power to the system.

Underexcited (reduced excitation): The motor’s power factor becomes more lagging, meaning it draws more reactive power from the supply, making the motor act like an inductive load (similar to a lagging power factor).

3. Impact of Reduced Excitation: More Lagging Power Factor: With lower excitation, the rotor’s magnetic field is weaker, and the motor draws more current to maintain torque production. This current is lagging because of the weaker field, increasing the reactive power and making the motor more inductive.
If excitation continues to decrease too much, the motor may become unstable, but typically, in most practical cases, a slight reduction in excitation leads to a more lagging power factor.


Reference Book:
Electric Machinery and Transformers by Bhag S. Guru and Huseyin R. Hiziroglu.

.
A synchronous capacitor is an over-excited motor running at which load?
  1. full-load
  2. half full-load
  3. no-load
  4. none of the above
সঠিক উত্তর:
no-load
উত্তর
সঠিক উত্তর:
no-load
ব্যাখ্যা

 An over-excited loaded synchronous motor supplies reactive power to the 3-phase line as well as absorbs active power (kW). But an unloaded over-excited synchronous motor performs only one function i.e., delivers reactive power to the 3-phase line, like a capacitor. Hence, the name synchronous capacitor.

(Principles of Electrical Machines by V.K. Mehta, Rohit mehta)

.
When the pull-out torque occurs in a synchronous motor, the poles of the rotor are..
  1. mid-way between N and S poles of stator
  2. coincident with stator poles
  3. 45° (electrical)
  4. none of the above
সঠিক উত্তর:
mid-way between N and S poles of stator
উত্তর
সঠিক উত্তর:
mid-way between N and S poles of stator
ব্যাখ্যা

Pull-out Torque:The pull-out torque is the maximum torque that a synchronous motor can develop. It is the point where the motor operates at the maximum load it can handle before it begins to lose synchrony with the stator field and slips out of synchronization. At the pull-out torque, the motor can no longer maintain synchrony with the rotating magnetic field of the stator and will either slow down or stop if the load is increased beyond this point.

Rotor Position During Pull-out Torque:At the point of pull-out torque, the rotor is slipping just enough to cause the poles of the rotor to be positioned mid-way between the North (N) and South (S) poles of the stator. In other words, when the motor is about to slip out of synchronization, the magnetic poles of the rotor are at an angle relative to the magnetic poles of the stator. Specifically, the rotor poles are positioned midway between the stator's North and South poles.
This position corresponds to the maximum torque condition, where the motor can no longer maintain synchronous operation at a constant speed due to excessive load.


Source: Principles of Electrical Machines by V.K. Mehta, Rohit mehta

.
What is the relation among synchronous speed (Ns), rotor speed(N)?
  1. N = (s - 1)Ns
  2. N = (s +1)Ns
  3. N = (1 -s) Ns
  4. N = SNs
সঠিক উত্তর:
N = (1 -s) Ns
উত্তর
সঠিক উত্তর:
N = (1 -s) Ns
ব্যাখ্যা

Synchronous Speed (Ns): The synchronous speed of a synchronous motor is the speed at which the magnetic field of the stator rotates. It is given by the formula:

Ns = (120 × f) / p

Where:

Ns = Synchronous speed (in r.p.m.),

f = Supply frequency (in Hz),

p = Number of poles of the motor.

Rotor Speed (N):The rotor of a synchronous motor rotates at a speed close to the synchronous speed, but the difference between the synchronous speed and the rotor speed is due to **slip** (s).

Slip is defined as:

s = (Ns - N) / Ns

Where:

N = Rotor speed (in r.p.m.),

Ns = Synchronous speed (in r.p.m.),

s = Slip of the motor.

Rearranging the equation to solve for N (Rotor speed), we get:

N = Ns (1 - s)

(Principles of Electrical Machines by V.K. Mehta, Rohit mehta)

১০.
If a 4-pole induction motor has a synchronous speed of 1500 r.p.m., then, supply frequency is- 
  1. 50 Hz.
  2. 60Hz
  3. 25 Hz
  4. 80 Hz
সঠিক উত্তর:
50 Hz.
উত্তর
সঠিক উত্তর:
50 Hz.
ব্যাখ্যা

The formula for synchronous speed of an induction motor is:

Ns = (120 × f) / P

Where:
Ns = Synchronous speed (in r.p.m.)
f = Supply frequency (in Hz)
P = Number of poles

Given:
Ns = 1500 r.p.m.
P = 4

Calculation:
f = (Ns × P) / 120

f = (1500 × 4) / 120

f = 6000 / 120

f = 50 Hz

Answer:
The supply frequency is 50 Hz.


(Principles of Electrical Machines by V.K. Mehta, Rohit mehta)

১১.
The rotational direction of the field in a three-phase induction motor is dependant upon ?
  1. number of poles
  2. magnitude of supply voltage
  3. supply frequency
  4. phase sequence of supply voltage
সঠিক উত্তর:
phase sequence of supply voltage
উত্তর
সঠিক উত্তর:
phase sequence of supply voltage
ব্যাখ্যা
Rotating Magnetic Field

The rotating magnetic field in a 3-phase induction motor is created by the stator when a 3-phase AC supply is applied to the stator windings. This rotating magnetic field causes the rotor to rotate, and the direction of rotation is determined by how the phases of the supply voltage are applied to the motor.

Effect of Phase Sequence:
The phase sequence refers to the order in which the phases of the 3-phase supply voltage reach their maximum positive value (i.e., the sequence in which the voltages are applied to the stator windings). In a 3-phase system, the phase sequence can be either:

Positive sequence (ABC): The phases reach their maximum value in the order A, B, C.


Negative sequence (ACB): The phases reach their maximum value in the order A, C, B.


Positive sequence (ABC): In this case, the rotating magnetic field will rotate in a clockwise direction (when viewed from the non-driving end of the motor).


Negative sequence (ACB): In this case, the rotating magnetic field will rotate in a counterclockwise direction.


Thus, the direction of rotation of the field, and hence the rotor, is determined by the phase sequence of the supply voltage.

 (Principles of Electrical Machines by V.K. Mehta, Rohit mehta)
১২.
The rotor winding of a 3-phase wound rotor induction motor is generally of which type of connection?
  1. star
  2. delta
  3. partly star and partly delta
  4. none of the above
সঠিক উত্তর:
star
উত্তর
সঠিক উত্তর:
star
ব্যাখ্যা

So that additional external resistance may be inserted in the rotor circuit at starting to increase the starting torque and decrease the starting cur-rent. As the motor gains speed, these external resistances are cut out of the rotor circuit.

(Principles of Electrical Machines by V.K. Mehta, Rohit mehta)

১৩.
The torque characteristic of a 3-phase induction motor is similar to which of the other motors?
  1. d.c. series motor.
  2. d.c. shunt motor
  3. d.c. differentially compounded motor
  4. d.c. cumulatively compounded motor
সঠিক উত্তর:
d.c. shunt motor
উত্তর
সঠিক উত্তর:
d.c. shunt motor
ব্যাখ্যা

 The torque characteristic of a 3-phase induction motor is similar to that of a DC shunt motor. Here’s why:

Torque Characteristics:
3-Phase Induction Motor:

The torque of a 3-phase induction motor increases with the square of the voltage and is proportional to the slip. The torque-speed characteristic of a 3-phase induction motor starts from zero torque at synchronous speed, increases to a maximum value, and then decreases as the motor approaches stall (pull-out torque). This is a characteristic that is somewhat similar to the behavior of DC motors.

DC Shunt Motor:The torque-speed characteristic of a DC shunt motor is relatively flat over a range of speeds. Like the induction motor, the torque in a DC shunt motor increases almost linearly with the armature current. In both types of motors, the torque increases with the increase in load current (or load), and the torque drops at high speeds.

The most important similarity is that both motors exhibit a positive torque-speed characteristic, where the torque increases with increasing load up to a certain point and then begins to decrease as the motor reaches its maximum operating speed or torque. 


Source: Principles of Electrical Machines by V.K. Mehta, Rohit mehta

১৪.
The conditions of an induction motor on no-load resemble those of a transformers whose secondary is- 
  1. short-circuited
  2. open-circuited
  3. supplying a variable resistive load
  4. none of the above
সঠিক উত্তর:
open-circuited
উত্তর
সঠিক উত্তর:
open-circuited
ব্যাখ্যা

 Induction Motor on No-Load: When an induction motor is running on no-load, the rotor is rotating at a speed close to the synchronous speed, and the motor is drawing only the magnetizing current (no significant torque is required from the motor). The rotor currents are induced by the rotating magnetic field created by the stator, but there is very little current flowing in the rotor, as the motor is not doing any mechanical work.This situation is similar to a transformer under no-load conditions.

Transformer Under No-Load: When a transformer operates on no-load, the secondary winding is open-circuited, meaning there is no load connected to the secondary side. In this case, the transformer still draws a small no-load current from the supply, primarily to magnetize the core and overcome core losses (hysteresis and eddy currents). This no-load current is similar to the magnetizing current in an induction motor, which is required to create the magnetic field but does not do any useful work.

Source: Principles of Electrical Machines by V.K. Mehta, Rohit mehta.

১৫.
The operation of an induction motor is based on what?
  1. Lenz's law
  2. Ampere's law
  3. Mutual induction
  4. Self induction
সঠিক উত্তর:
Mutual induction
উত্তর
সঠিক উত্তর:
Mutual induction
ব্যাখ্যা

In an induction motor, only stator winding is fed from a.c. supply. The rotor winding derives voltage and power from the externally energised stator winding through the principle of mutual induction.

(Principles of Electrical Machines by V.K. Mehta, Rohit mehta)

১৬.
At no-load, the rotor core loss of a 3-phase induction motor is- 
  1. large
  2. small
  3. zero
  4. one
সঠিক উত্তর:
zero
উত্তর
সঠিক উত্তর:
zero
ব্যাখ্যা

Rotor Core Loss at No-Load:

Core Loss (Iron Loss):
The core loss in the rotor of an induction motor primarily consists of hysteresis loss and eddy current loss. These losses are caused by the alternating magnetic field in the rotor, which induces currents in the rotor core.

However, at no-load, the rotor is rotating at a speed close to the synchronous speed, and the slip (the difference between synchronous speed and rotor speed) is very small. Because core losses are proportional to the square of the slip, at no-load conditions, the slip is so low that the core losses are negligible.

Rotor Current and Losses:
At no-load, the motor is not delivering torque, and only a small current is induced in the rotor due to the rotating magnetic field of the stator. This small current causes only minimal losses in the rotor core. Essentially, the rotor is not "working" to produce torque, and therefore the core losses are almost zero.

Core Losses and Load:
Rotor core losses increase with the load on the motor because as the load increases, the slip increases, which results in higher induced currents in the rotor. At no-load, the motor is essentially idle in terms of torque production, so the core losses are minimal.

Source: Electric Machinery Fundamentals by Stephen J. Chapman.

১৭.
If the slip of the induction motor increases, then, current in the stator winding -
  1. is increased
  2. is decreased
  3. remains unchanged
  4. none of the above
সঠিক উত্তর:
is increased
উত্তর
সঠিক উত্তর:
is increased
ব্যাখ্যা

As the slip increases in an induction motor, the relative speed between the rotor and the magnetic field increases, which results in higher current in the stator winding. This is because the motor requires more current to produce the additional torque to overcome the increased load at higher slip.

(Electric Machinery Fundamentals by Stephen J. Chapman)

১৮.
An S-pole alternator runs at 750 r.p.m. and supplies power to a 6-pole induction motor which has a full-load slip of 3%. The full-load speed of the motor is- 
  1. 1050 г.р.m.
  2. 970 г.р.m.
  3. 960 r.p.m
  4. 1170 г.р.m.
সঠিক উত্তর:
970 г.р.m.
উত্তর
সঠিক উত্তর:
970 г.р.m.
ব্যাখ্যা

f = NP/120 = 50Hz

Ns​ = 120×f/P​ = (120* 50)/6 =1000

% slip s = (Ns-N)/Ns 
⇒ 3 = (1000-N)/1000
⇒ N = 970

১৯.
The starting torque of a 3-phase induction motor has maximum value. The rotor power factor is then
  1. 0.8 lag
  2. 0.6 lag
  3. 0.707 lag
  4. 0 lag
সঠিক উত্তর:
0.707 lag
উত্তর
সঠিক উত্তর:
0.707 lag
ব্যাখ্যা

২০.
A 12-pole, 3-phase, star-connected induction motor runs at 600 V, 50 Hz. It has a rotor resistance of 0.03 2/phase and stand- still reactance of 0.5 2/phase. The slip corresponding to maximum torque under running conditions is
  1. 2%
  2. 4%
  3. 6%
  4. 9%
সঠিক উত্তর:
6%
উত্তর
সঠিক উত্তর:
6%
ব্যাখ্যা

Given Data:

Number of poles (p) = 12

Supply voltage = 600 V

Frequency = 50 Hz

Rotor resistance per phase (R2) = 0.03 Ω/phase

Stand-still reactance per phase (X2) = 0.5 Ω/phase

We are tasked with calculating the slip corresponding to the maximum torque under running conditions.

### Formula for Slip corresponding to Maximum Torque:

The slip corresponding to the maximum torque in a 3-phase induction motor is given by the formula:

s = (R2) / (X2)

Where:

R2 = Rotor resistance per phase

X2 = Stand-still reactance per phase

### Calculation:

Substituting the given values for R2 and X2:

s = 0.03 / 0.5 = 0.06 or 6%

২১.
An 8-pole, 50 Hz, 3-phase induction motor has an equivalent rotor resistance of 0.07 S/phase. If its stalling speed is 630 r.p.m., what is the rotor reactance/phase?
  1. 0.44 ohm
  2. 1.5 ohm
  3. 0.25 ohm
  4. 1.3 ohm
সঠিক উত্তর:
0.44 ohm
উত্তর
সঠিক উত্তর:
0.44 ohm
২২.
In an induction motor, the ratio of rotor Cu loss and rotor input is given by
  1. s
  2. 1-s
  3. 1/s
  4. s/1-s
সঠিক উত্তর:
s
উত্তর
সঠিক উত্তর:
s
ব্যাখ্যা

Here, Copper loss=Pcu, 

Mechanical Power develop in Rotor = Pm

Rotor input = P2

P2 : Pcu : Pm = 1 : s : 1-s  

P2/Pcu = 1/s 

(A.C and D.C Machines by B.L.Thereja)

২৩.
The efficiency of an induction motor
  1. can be greater than 1 - s
  2. cannot be greater than 1 - s
  3. data insufficient
  4. none of the above
সঠিক উত্তর:
can be greater than 1 - s
উত্তর
সঠিক উত্তর:
can be greater than 1 - s
২৪.
no-load speed of an induction motor depends upon
  1. the supply frequency
  2. the number of its poles
  3. the maximum flux/phase
  4. only (i) and (ii)
সঠিক উত্তর:
only (i) and (ii)
উত্তর
সঠিক উত্তর:
only (i) and (ii)
ব্যাখ্যা
The synchronous speed Ns​ of an induction motor (which is the theoretical maximum speed it could reach if there were no losses or slip) is given by the formula:

Ns​=(120×f)/P

The no-load speed N0 is very close to the synchronous speed because at no load, the motor operates at very low slip. The slip sss is nearly zero at no load, which means the motor speed approaches the synchronous speed.

Thus, the no-load speed is determined by the supply frequency and the number of poles, as the synchronous speed depends on these two factors. (A.C and D.C Machines by B.L.Thereja)
২৫.
Which of the following is true about the shape of the torque-slip curve for a three-phase induction motor?
  1. It is a straight line with a positive slope
  2. It is a hyperbolic curve with a peak at maximum torque
  3. It is a straight line with a negative slope
  4. It is a parabolic curve with a sharp drop
সঠিক উত্তর:
It is a hyperbolic curve with a peak at maximum torque
উত্তর
সঠিক উত্তর:
It is a hyperbolic curve with a peak at maximum torque
ব্যাখ্যা
The torque-slip curve of a 3-phase induction motor shows how the torque (T) varies with the slip (s), where the slip is the difference between the synchronous speed and the actual rotor speed. This curve provides insight into how the motor performs under different load conditions.

Shape of the Torque-Slip Curve:The curve is not linear; it has a hyperbolic shape.At low slip values, the torque increases as the slip increases from zero.
The torque continues to increase until it reaches a maximum value at a certain slip, known as the slip corresponding to maximum torque. After this point, the torque decreases as the slip increases further. As the load increases and the rotor slows down, the torque decreases, and the motor eventually reaches stall when the slip reaches 100%.


Key Features:
Peak of Maximum Torque: The maximum torque is achieved at a specific slip value and is often referred to as the breakdown torque. This is the highest torque the motor can develop under normal operating conditions.

Beyond this point, if the slip increases further, the torque drops off rapidly, and the motor could eventually stall if the load becomes too high.
.(Electric Machinery and Transformers by Bhag S. Guru and Huseyin R. Hiziroglu)
২৬.
In a squirrel cage induction motor, the maximum torque developed under running conditions is ...
  1. equal to starting torque
  2. full-load torque
  3. less than starting torque
  4. much higher than full-load torque
সঠিক উত্তর:
much higher than full-load torque
উত্তর
সঠিক উত্তর:
much higher than full-load torque
ব্যাখ্যা

Starting Torque: When the motor starts, it has a high slip (close to 1), which means the relative speed between the rotating magnetic field and the rotor is large. This results in a high induced current in the rotor, producing a high starting torque. However, as the motor speeds up, the slip decreases and the torque reduces.

Full-load Torque: At full load, the motor operates at a lower slip (typically around 2-6% for most motors), which means the rotor is rotating closer to the synchronous speed. The torque at full load is typically the designed torque required to drive the load.
Maximum (Breakdown) Torque: The maximum torque occurs at a certain slip that is neither too high nor too low. At this point, the electromagnetic torque is at its peak, and it is usually much higher than the full-load torque. This breakdown torque is the point at which the motor can handle the highest load without stalling, but if the load exceeds this torque, the motor will stall.

The maximum torque occurs at a slip that is typically greater than the slip at full load but less than the starting slip. This results in a higher torque than at full load, which is one of the distinguishing features of squirrel cage induction motors.

Source: Principles of Electrical Machines by V.K. Mehta, Rohit mehta

২৭.
The speed of a slip-ring induction motor can be changed by ..
  1. changing the applied voltage
  2. changing rotor circuit resistance
  3. insertion and variation of a foreign voltage in the rotor circuit
  4. all above
সঠিক উত্তর:
all above
উত্তর
সঠিক উত্তর:
all above
ব্যাখ্যা
1. Changing the applied voltage :

Speed and voltage relationship: In an induction motor, the synchronous speed NsN_sNs​ is determined by the frequency and the number of poles. However, the applied voltage to the stator affects the motor's operating characteristics, such as its torque and starting conditions.
Changing applied voltage: By changing the applied voltage (using a variable frequency drive or other means), the motor's speed can be influenced, especially when the voltage is varied in coordination with the frequency. This is typically done in variable-speed drives (VSD) or inverter-controlled systems, where both the frequency and the voltage are adjusted to control speed.


2. Changing rotor circuit resistance :
Slip and rotor resistance: The speed of a slip-ring induction motor is related to its slip, which in turn depends on the load and the rotor resistance.
Effect of rotor resistance: By adding external resistors in the rotor circuit (via the slip rings), the effective rotor resistance increases, which in turn increases the slip for a given load. This causes the motor's speed to decrease.
Speed control: Increasing the rotor resistance (by adding external resistance through the slip rings) reduces the maximum torque speed and can also allow the motor to start at a lower speed. This method is commonly used for starting the motor and speed control in certain applications.


3. Insertion and variation of a foreign voltage in the rotor circuit :
Foreign voltage: This refers to injecting a voltage into the rotor circuit from an external source. This method is used for speed control in slip-ring induction motors.
Effect on speed: By applying a foreign voltage (which can be varied) to the rotor, the slip can be controlled and adjusted, directly influencing the motor speed. This method can provide fine control over the motor's operating speed. (Principles of Electrical Machines by V.K. Mehta, Rohit mehta)
২৮.
A 3-phase induction motor is connected to a supply of normal voltage. The e.m.f. induced between the slip rings at standstill is 72 V and the resistance and standstill reactance/phase are 0.5 2 and 3.5 2 respectively. The rotor is star-connected. The rotor phase current at starting when the rings are short-circuited is
  1. 14.25 A
  2. 11.76 A
  3. 7.24 A
  4. 9:82 A
সঠিক উত্তর:
11.76 A
উত্তর
সঠিক উত্তর:
11.76 A
ব্যাখ্যা

Induced e.m.f. between the slip rings at standstill = 72 V

Resistance per phase = 0.5 Ω

Standstill reactance per phase = 3.5 Ω

rotor e.m.f per phase =72/√3 =3.54

Rotor impedance/phase at standstill, = √{(o.5)2 +(3.5)2}  = 3.54 ohm

Rotor current/phase at starting,= 41.5/3.54 =11.76

২৯.
Which of the following starting methods is most effective in reducing the inrush current for large motors?
  1. Direct-On-Line
  2. Star-Delta
  3. Autotransformer
  4. All methods are equally effective
সঠিক উত্তর:
Autotransformer
উত্তর
সঠিক উত্তর:
Autotransformer
ব্যাখ্যা

Starting Methods and Inrush Current:

Direct-On-Line (DOL): In the Direct-On-Line (DOL) starting method, the motor is connected directly to the full supply voltage. This results in a very high inrush current, typically 5-7 times the motor's full-load current, which can cause significant stress on the power supply and electrical components.

Star-Delta Starting: The Star-Delta starting method involves connecting the motor windings in star configuration during startup, which reduces the voltage across each winding to 1/√3 of the line voltage. After the motor reaches a certain speed, the connection is switched to delta to apply the full line voltage. The inrush current is reduced compared to DOL starting, but it is still higher than the autotransformer method.

Autotransformer Starting: The Autotransformer method uses an autotransformer to reduce the voltage applied to the motor during startup. By applying a reduced voltage (typically 50% or 60% of the line voltage), the inrush current is significantly reduced, typically to 2-3 times the motor’s full-load current. After the motor accelerates to a certain speed, the autotransformer is bypassed, and the motor is connected to the full line voltage. This method is the most effective in reducing inrush current because it limits the voltage applied to the motor during startup, which directly reduces the inrush current.

(Reference: Electric Machinery Fundamentals by Stephen J. Chapman)

৩০.
In an induction motor, the speed can be controlled by adjusting the slip. As slip increases, what happens to the speed of the motor?
  1. Speed increases
  2. Speed decreases
  3. Speed remains constant
  4. Speed becomes zero
সঠিক উত্তর:
Speed decreases
উত্তর
সঠিক উত্তর:
Speed decreases
ব্যাখ্যা

**Synchronous Speed (N_s):**

The synchronous speed of an induction motor is determined by the supply frequency and the number of poles in the motor. It is given by the formula:

N_s = (120 × f) / P

Where:

N_s = Synchronous speed (in r.p.m.)

f = Supply frequency (in Hz)

P = Number of poles

2. **Rotor Speed (N):**

The actual speed of the rotor is related to the synchronous speed and the **slip (s)**. The relationship is given by:

s = (N_s - N) / N_s

Rearranging the equation to find rotor speed:

N = N_s (1 - s)

3. **Effect of Increasing Slip on Speed:**

As the slip increases, the rotor speed decreases. This is because slip is the difference between the synchronous speed and the actual rotor speed. Higher slip means a larger gap between the synchronous speed and rotor speed, causing the rotor to slow down further.

(Electric Machinery Fundamentals by Stephen J. Chapman)

৩১.
What effect does increasing rotor resistance have on the speed of an induction motor?
  1. Increases the speed
  2. Decreases the speed
  3. Has no effect on speed
  4. Changes the direction of rotation
সঠিক উত্তর:
Decreases the speed
উত্তর
সঠিক উত্তর:
Decreases the speed
ব্যাখ্যা

The **rotor resistance** of an induction motor plays a significant role in determining the slip of the motor. The slip (s) is the difference between the synchronous speed (N_s) and the actual rotor speed (N), and it is given by the formula:

s = (N_s - N) / N_s

Where:

N_s = Synchronous speed of the motor

N = Rotor speed

s = Slip

2. **Effect of Rotor Resistance on Torque and Slip:**

When the rotor resistance increases, the motor generates more current to produce the same torque. This increases the slip for a given load. As slip increases, the rotor speed decreases because the difference between synchronous speed and rotor speed becomes larger.

3. **Rotor Resistance and Motor Efficiency:**

Higher rotor resistance leads to higher losses, which decreases the efficiency of the motor. To compensate for the increased losses, the motor operates at a higher slip, resulting in slower rotor speed.

(Electric Machinery Fundamentals by Stephen J. Chapman)

৩২.
By the increase of number of stator pole which will change in three phase induction motor?
  1. Speed increase
  2. Speed decrease
  3. Voltage decrease
  4. Frequency decrease
সঠিক উত্তর:
Speed decrease
উত্তর
সঠিক উত্তর:
Speed decrease
ব্যাখ্যা

By the change of number of stator pole, the synchronous speed and hence rotor speed can be changed. Ns=120f/P

(Principles of Electrical Machines by V.K. Mehta, Rohit mehta)

৩৩.
If line frequency drops by 20%, the speed of induction motor drops by .
  1. 10%
  2. 20%
  3. 5%
  4. 40%
সঠিক উত্তর:
20%
উত্তর
সঠিক উত্তর:
20%
ব্যাখ্যা

The synchronous speed (NsN_sNs​) of an induction motor is directly related to the supply frequency (fff) and the number of poles (PPP) in the motor. The formula for synchronous speed is:

Where:

Ns​ = Synchronous speed (in r.p.m.),
f = Supply frequency (in Hz),
P = Number of poles in the motor.
Ns = 120f/P 

If the supply frequency drops, the synchronous speed will decrease proportionally, because the synchronous speed is directly proportional to the frequency.

If the frequency drops by 20%, the new frequency becomes 80% of the original frequency. This leads to the following relationship:

N_s' = 0.80 × N_s

When the line frequency drops by 20%, the speed of the induction motor(synchronous speed) will drop by 20% as well.

৩৪.
A 50 Hz motor can operate efficiently on a 60 Hz supply if the applied voltage is increased to the ratio of the square of the frequencies relative to the nameplate rating.
  1. 20%
  2. 80%
  3. 180%
  4. 120%
সঠিক উত্তর:
120%
উত্তর
সঠিক উত্তর:
120%
ব্যাখ্যা
V∝Фf, if frequency of supply line increase then voltage of induction motor increase.
৩৫.
Which of the following motors is best suited for low-torque applications such as fans and small pumps?
  1. Shaded-pole motor
  2. Capacitor-start motor
  3. Universal motor
  4. Squirrel cage motor
সঠিক উত্তর:
Shaded-pole motor
উত্তর
সঠিক উত্তর:
Shaded-pole motor
ব্যাখ্যা
Shaded-Pole Motor:A shaded-pole motor is a type of single-phase induction motor that has a very simple design.It is self-starting and operates on single-phase AC, making it ideal for low-power applications.The motor generates a weak starting torque, making it suitable for applications that require low-torque such as fans, small pumps, and ventilators. Due to the simplicity of its construction, it is inexpensive but typically not used for high-torque or high-efficiency applications.

Capacitor-Start Motor:A capacitor-start motor provides a higher starting torque than the shaded-pole motor, making it suitable for applications like pumps and compressors that need more starting power. However, it is more complex and typically used in applications requiring higher torque.

Universal Motor:A universal motor can run on both AC and DC power. It is capable of providing high speed and high torque, making it suitable for appliances like blenders, vacuum cleaners, and power tools. However, it is not suited for low-torque applications.

Squirrel Cage Motor:A squirrel cage motor is commonly used in three-phase systems and is widely found in industrial applications. While it can be used for many types of loads, its design is better suited for higher torque applications, such as pumps and fans that require more robust performance.
৩৬.
Which of the following is the main limitation of a single-phase induction motor?
  1. High efficiency
  2. High starting torque
  3. Limited starting power
  4. High cost
সঠিক উত্তর:
Limited starting power
উত্তর
সঠিক উত্তর:
Limited starting power
ব্যাখ্যা
Main Limitation of a Single-Phase Induction Motor: Limited Starting Power: A single-phase induction motor is not inherently self-starting. It requires an additional mechanism (such as a capacitor or shaded pole) to create a rotating magnetic field for starting.The main limitation of single-phase induction motors is that they provide low starting torque and limited starting power. This makes them unsuitable for high-torque applications that require substantial starting power, such as compressors or large pumps. The low starting power results from the fact that a single-phase AC supply cannot produce a rotating magnetic field on its own. Therefore, the motor needs some external means to create the starting torque, and even then, the torque is generally limited compared to that of a three-phase motor.
Reference Book: Electric Machinery and Transformers by Bhag S. Guru and Huseyin R. Hiziroglu
৩৭.
What is the typical power factor of a single-phase induction motor under full-load conditions?
  1. 0.8 to 0.9
  2. 0.3 to 0.5
  3. 1.0
  4. 0.1 to 0.2
সঠিক উত্তর:
0.8 to 0.9
উত্তর
সঠিক উত্তর:
0.8 to 0.9
ব্যাখ্যা

Power Factor of a Single-Phase Induction Motor:

Power Factor Definition:The power factor (PF) is the ratio of real power (active power) to apparent power. It indicates how effectively the motor is converting electrical power into mechanical power. A power factor of 1 indicates perfect efficiency, while a lower value indicates higher losses and inefficiency.

Single-Phase Induction Motor: A single-phase induction motor typically has a power factor ranging from 0.8 to 0.9 under full-load conditions. This means that the motor converts 80% to 90% of the electrical power it draws into useful mechanical power, with the rest being reactive power, which does not perform useful work. The power factor is affected by factors like the motor's load, the type of capacitor (if used), and the motor's design. At full load, the motor's power factor is generally in this range, though it can vary based on the type and quality of the motor.

Why the Other Options Are Incorrect:

(খ) 0.3 to 0.5:
This would represent a very low power factor, which is not typical for a single-phase induction motor under normal operating conditions. Such a low power factor is usually seen in highly inductive loads that are under very light load conditions.


(গ) 1.0:
A power factor of 1.0 (unity) is ideal, but it is rarely achieved in a single-phase induction motor. Typically, the motor operates with a power factor in the range of 0.8 to 0.9. A power factor of 1.0 would imply that there are no reactive power losses, which is unlikely in typical motor operations.

(ঘ) 0.1 to 0.2:
This range represents an extremely low power factor, which would not be typical for a properly operating single-phase induction motor. Such low power factors are usually associated with poorly designed or malfunctioning motors.


Reference Book: Electric Machinery Fundamentals by Stephen J. Chapman

৩৮.
The direction of the magnetic field in a single-phase induction motor can be altered by:
  1. Changing the direction of the rotor
  2. Reversing the supply voltage polarity
  3. Changing the number of poles in the stator
  4. Using a shaded-pole design
সঠিক উত্তর:
Reversing the supply voltage polarity
উত্তর
সঠিক উত্তর:
Reversing the supply voltage polarity
ব্যাখ্যা
Direction of Magnetic Field in a Single-Phase Induction Motor:

1. Stator Magnetic Field in Single-Phase Motors: In a single-phase induction motor, the magnetic field produced by the stator is not rotating. It alternates in polarity due to the single-phase AC supply, creating a pulsating magnetic field. The direction of this alternating magnetic field can be reversed by changing the polarity of the supply voltage.


2. Reversing the Supply Voltage Polarity: The direction of the magnetic field in the stator is determined by the direction of the current flowing through the stator windings. If you reverse the supply voltage polarity, the direction of the current in the stator windings also reverses, which in turn reverses the direction of the magnetic field. Reversing the supply voltage is the most straightforward way to change the direction of the magnetic field, which consequently reverses the direction of rotation of the motor.
৩৯.
The synchronous speed of a single-phase induction motor is determined by:
  1. Supply voltage
  2. Supply frequency and number of poles
  3. Rotor resistance
  4. Number of windings
সঠিক উত্তর:
Supply frequency and number of poles
উত্তর
সঠিক উত্তর:
Supply frequency and number of poles
ব্যাখ্যা

 The synchronous speed (Ns) of any induction motor, including a single-phase induction motor, is determined by the supply frequency (f) and the number of poles (P) in the motor. The formula for synchronous speed is:

Ns = 120 × fP

Where,

Ns = Synchronous speed (in revolutions per minute, r.p.m.),
f= Supply frequency (in Hertz, Hz),
P = Number of poles in the motor.
Reference Book: Electrical Machines, Drives, and Power Systems by Theodore Wildi

৪০.
The torque in a single-phase induction motor is primarily produced by:
  1. The interaction of rotor and stator magnetic fields
  2. The torque produced by a capacitor
  3. The rotor resistance
  4. The stator winding only
সঠিক উত্তর:
The interaction of rotor and stator magnetic fields
উত্তর
সঠিক উত্তর:
The interaction of rotor and stator magnetic fields
ব্যাখ্যা

Torque Production in a Single-Phase Induction Motor: In a single-phase induction motor, the torque is primarily produced by the interaction between the rotor's magnetic field and the stator's magnetic field. Here’s a breakdown of how this works:
 In a single-phase motor, the stator generates a pulsating magnetic field when supplied with single-phase AC power. This field alternates, but it does not rotate on its own like in a 3-phase motor. To make the motor self-starting, the pulsating field is "split" into two rotating magnetic fields using methods like shaded-pole design or a capacitor. This creates an effective rotating magnetic field that interacts with the rotor.

The rotor is subjected to the rotating magnetic field created by the stator. The rotor becomes magnetized and induces a magnetic field in response to the rotating field. The interaction of the rotor magnetic field with the stator magnetic field produces a force that results in torque.

The rotor experiences a force due to this interaction, which causes the rotor to rotate and produce mechanical output power. This is the fundamental principle of torque generation in induction motors, including single-phase induction motors.

Reference Book: Electric Machinery Fundamentals by Stephen J. Chapman

৪১.
What happens to the field in a single-phase induction motor when it is running under no-load conditions?
  1. The field becomes stronger
  2. The field becomes weaker
  3. The field becomes uniform
  4. The field is unstable
সঠিক উত্তর:
The field becomes weaker
উত্তর
সঠিক উত্তর:
The field becomes weaker
ব্যাখ্যা

Single-Phase Induction Motor's Operating Principle: A single-phase induction motor operates by generating a pulsating magnetic field in the stator. This magnetic field induces current in the rotor, creating a magnetic field that interacts with the stator's field to produce torque.
Under no-load conditions, the motor is running, but there is little to no mechanical load on the rotor. This means the rotor is rotating at a speed close to the synchronous speed (with minimal slip).

As a result, the torque required to maintain rotation is minimal, and the current drawn by the motor decreases. The magnetizing current, which is responsible for creating the magnetic field, becomes weaker because the motor doesn't need to supply a significant amount of energy to overcome mechanical load.
Effect on the Magnetic Field:
With the reduced load and lower current, the magnetic field produced by the stator weakens. This is because the stator’s field strength is directly related to the amount of current flowing through the windings, which is reduced at no-load.
The field is still present but weaker compared to the full-load condition, where the motor requires more power to generate torque to overcome the load.

৪২.
In the equivalent circuit of a single-phase induction motor, the magnetizing reactance represents:
  1. The magnetic field generated by the stator
  2. The resistance of the rotor
  3. The mechanical losses in the motor
  4. The air gap between the stator and rotor
সঠিক উত্তর:
The magnetic field generated by the stator
উত্তর
সঠিক উত্তর:
The magnetic field generated by the stator
ব্যাখ্যা

Magnetizing Reactance in a Single-Phase Induction Motor:

1. Magnetizing Reactance:In the equivalent circuit of a single-phase induction motor, the magnetizing reactance represents the reactance associated with the creation of the magnetic field in the motor. This reactance is linked to the stator winding's inductance and is responsible for the motor's ability to produce a magnetic field. The magnetizing reactance can be thought of as the component of the impedance that generates the magnetic flux in the motor, which is essential for inducing current in the rotor and producing torque.

2. Magnetic Field Generation:The magnetizing current (which causes the magnetizing reactance) creates the magnetic field in the stator. This magnetic field is the primary field that induces a current in the rotor, which interacts with the stator's magnetic field to produce torque. In other words, the magnetizing reactance is directly related to the magnetic field generated by the stator, and this magnetic field is essential for the motor's operation.

Why the Other Options Are Incorrect:

(খ) The resistance of the rotor:The rotor resistance in the equivalent circuit represents the resistance of the rotor winding, not the magnetizing reactance. Rotor resistance is associated with energy losses in the rotor due to its resistance.

(গ) The mechanical losses in the motor:Mechanical losses (like friction and windage losses) are not represented by the magnetizing reactance. These losses are typically modeled as separate losses in the motor’s equivalent circuit and do not affect the magnetic field generation directly.

(ঘ) The air gap between the stator and rotor:The air gap represents the physical distance between the stator and rotor and affects the overall motor performance. While the air gap impacts the magnetic flux density, it is not directly represented by the magnetizing reactance. The reactance primarily represents the magnetizing field created by the stator.

৪৩.
The power factor of a single-phase induction motor can be improved by:
  1. Increasing the rotor resistance
  2. Using a capacitor in series with the motor
  3. Reducing the supply voltage
  4. Increasing the excitation
সঠিক উত্তর:
Using a capacitor in series with the motor
উত্তর
সঠিক উত্তর:
Using a capacitor in series with the motor
ব্যাখ্যা

Power Factor Definition:The power factor (PF) of a motor is the ratio of real power (active power) to apparent power. It indicates how effectively the motor converts electrical energy into useful mechanical energy. A low power factor means that the motor is drawing more reactive power, which does not contribute to the actual work being done.

Improving Power Factor: A single-phase induction motor typically operates with a lagging power factor, meaning the current lags behind the voltage due to the inductive nature of the motor. This lagging power factor results in inefficient power usage. The power factor can be improved by reducing the lag between the voltage and the current.

Reference Book: Electric Machinery and Transformers by Bhag S. Guru and Huseyin R. Hiziroglu

৪৪.
In the split-phase method of starting a single-phase induction motor, the phase shift is produced by:
  1. A capacitor
  2. A secondary winding
  3. A series inductor
  4. A parallel inductor
সঠিক উত্তর:
A secondary winding
উত্তর
সঠিক উত্তর:
A secondary winding
ব্যাখ্যা

Split-Phase Induction Motor: In a split-phase induction motor, the motor is designed to create a phase shift in the stator's magnetic field to make it self-starting. Unlike a three-phase motor, which has a naturally rotating magnetic field, a single-phase motor cannot start on its own due to the lack of a rotating magnetic field. The split-phase method overcomes this limitation.


How Phase Shift is Created: In the split-phase method, the stator is equipped with two windings:
1. The main winding, which is responsible for the majority of the magnetic field.
2. A secondary (or auxiliary) winding, which is placed in parallel with the main winding but is designed to have different impedance (higher resistance and inductance) to create a phase difference.
This difference in impedance creates a phase shift between the currents in the two windings. As a result, a rotating magnetic field is created, which allows the motor to start and rotate.

৪৫.
A single-phase induction motor is inherently:
  1. Self-starting
  2. Not self-starting
  3. Fully automatic
  4. Both A and C
সঠিক উত্তর:
Not self-starting
উত্তর
সঠিক উত্তর:
Not self-starting
ব্যাখ্যা

Single-Phase Induction Motors: A single-phase induction motor is not self-starting under normal operating conditions. Unlike a three-phase motor, which generates a rotating magnetic field and can start on its own, a single-phase induction motor generates a pulsating magnetic field when supplied with single-phase AC. This pulsating field does not naturally cause the rotor to start rotating.
The rotor in a single-phase induction motor requires some additional mechanism to start rotating because a pulsating field cannot provide the necessary torque to get the motor moving.


Methods to Make it Self-Starting: To make a single-phase induction motor self-starting, external methods are employed. These include:
1. Split-phase method: A secondary winding with different impedance creates a phase shift, allowing the motor to start.
2. Capacitor-start motor: A capacitor is used to create a phase difference to start the motor.
3. Shaded-pole motor: A shaded pole design on the stator produces a rotating magnetic field to initiate rotation.
৪৬.
A variable-reluctance stepper motor is constructed of salient poles. material with
  1. paramagnetic
  2. diamagnetic
  3. ferromagnetic
  4. non-magnetic
সঠিক উত্তর:
ferromagnetic
উত্তর
সঠিক উত্তর:
ferromagnetic
ব্যাখ্যা
Salient Poles: A variable-reluctance stepper motor has a rotor with salient poles (protruding poles). These poles are typically made of ferromagnetic materials, which have high magnetic permeability. This allows the motor to interact effectively with the stator’s magnetic field.

Ferromagnetic Material: Ferromagnetic materials, such as iron, have a high magnetic permeability, meaning they can easily be magnetized and create a strong magnetic field. This makes them ideal for stepper motor rotors because they are essential for efficiently responding to the changing magnetic field produced by the stator.
In a variable-reluctance motor, the rotor positions itself according to the changes in the reluctance of the magnetic circuit, which is influenced by the ferromagnetic material in the rotor.(Principles of Electrical Machines by V.K. Mehta, Rohit mehta)
৪৭.
The stepping angle for a 3-phase, 24-pole PM stepper motor is ...
  1. 5°/step
  2. 10°/step
  3. 15°/step
  4. 2.5°/step
সঠিক উত্তর:
5°/step
উত্তর
সঠিক উত্তর:
5°/step
ব্যাখ্যা

Step angle: 
3 phase = m
24 pole = Nr
α = 360/mNr=360/(3*24) = 5°/step

(Principles of Electrical Machines by V.K. Mehta, Rohit mehta)

৪৮.
In a Variable Reluctance Stepper Motor, the number of stator poles (NS) is 8, and the number of rotor teeth (NR) is 6. What is the step angle of the motor?
  1. 10°
  2. 45°
  3. 15°
  4. 20°
সঠিক উত্তর:
15°
উত্তর
সঠিক উত্তর:
15°
৪৯.
The torque in a permanent magnet stepper motor is:
  1. Constant throughout the rotation
  2. Highest at the half-step position
  3. Dependent on the rotor position relative to the stator
  4. Indifferent to the rotor position
সঠিক উত্তর:
Dependent on the rotor position relative to the stator
উত্তর
সঠিক উত্তর:
Dependent on the rotor position relative to the stator
ব্যাখ্যা
Magnetic Field Interaction: In a permanent magnet stepper motor, the rotor is a permanent magnet that interacts with the rotating magnetic field created by the stator. The torque produced in the motor depends on the relative alignment between the rotor's magnetic field and the stator's magnetic field.


Rotor Position and Torque: The torque in a stepper motor is maximal when the rotor is aligned with the stator's magnetic field, i.e., when the poles of the rotor are directly aligned with the energized stator poles.The torque is lowest when the rotor is positioned between poles, i.e., when the rotor is not perfectly aligned with the stator poles but still partially attracted by the stator's field.


Dependence on Rotor Position: Since the rotor’s position relative to the stator determines the magnetic interaction, the torque is variable and depends on how well the rotor aligns with the stator at any given time during the motor's operation. As the rotor moves from one step to the next, the torque varies accordingly.
Reference Book: Electric Machinery and Transformers by Bhag S. Guru and Huseyin R. Hiziroglu