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Saturday, 3 December 2011

GATE - 2012 Exams


BRAINWAVE
GATE-2012
Electrical Machines
Max. Marks: 45(Q.1 – Q.45  1 Mark)                                                                   Max. Time: 90 Min.s
1.For understanding the behaviour of a transformer, the following laws may be called for
1.      Lenz’s law       2. Newton’s second law                       3. Faraday’s laws of electromagnetic induction          
4. Ohm’s law         5. Fleming’s right hand rule     6. Right hand grip rule
From these the correct answer is
(a)    1,3,4    (b) 2,3,4,5        (c) 1,3,4,5,6     (d) 1,3,4,6 
2.In an ideal transformer, if K is some constant, then supply voltage V, in terms of its magnetizing current Im can be expressed as
(a) jKfIm          (b) jKf/Im         (c) –jKfIm        (d) –jKf/Im
3.A transformer has sometimes two or more ratings depending upon the use of
            (a) the cooling techniques        (b) the type of windings
            (c) the type of core                  (d) the type of insulation
4.A transformer at no load excited at rated voltage. Now a cut is made in the transformer yoke thus creating a small air gap. With this, the transformer core flux
            (a) will decrease and magnetizing current Im will increase
            (b) will remain constant and Im will increase
            (c) as well as Im both will increase
            (d) as well as Im both will decrease
5.If the secondary winding of an ideal transformer shown in the circuit has 40 turns, the number of turns in the primary winding for maximum power transfer to the 2 resistor will be
            (a) 20               (b) 40               (c) 80               (d) 160
6.In a single phase transformer, polarities of terminals a & b at any instant are shown in the fig. At the same instant,
            (a) c is +ve, d is +ve and flux is clockwise (cw) (b) c is -ve, d is +ve and flux is counter clockwise (ccw)
            (c) c is -ve, d is +ve and flux is clockwise (cw)  (d) c is +ve, d is -ve and flux is counter clockwise (ccw)
7.CRGO laminations in a transformer are used to minimise
(a) eddy current loss    (b) hysteresis loss    (c) both eddy current and hysteresis losses   (d) ohmic loss
8.If a transformer primary is energised from a square wave voltage source, then its output voltage will be
(a) zero                        (b) a sine wave                        (c) a triangular wave               (d) a pulsed wave
9. The no load current in a transformer lags the applied voltage by
            (a) 900                          (b) about 750                            (c) 00                            (d) about 1100
10. The leakage flux in a transformer depends upon
            (a) the applied voltage             (b) the frequency         (c) the load current      (d) the mutual flux
11. The useful flux of a transformer is 1 Wb. When it is loaded at 0.8 p.f lag, then its mutual flux
            (a) may decrease to 0.8Wb      (b) may increase to 1.01 Wb
            (c) remains constant                 (d) may decrease to 0.99 Wb
12.Two transformers of the same type, using the same grade of iron and conductor materials are designed to work at the same flux and current densities; but the linear dimensions of one are two times those of the other in all respects. Then the ratio of kVA ratings of the two transformers closely equals
            (a) 16                           (b) 8                             (c) 4                             (d) 2
13.A 220/440 V, 50Hz, 5 kVA, single phase transformer operates on 220 V, 40 Hz supply with secondary open circuited. Then
            (a) both eddy current & hysteresis looses decrease (b) both eddy current & hysteresis looses increase
            (c) eddy current loss remains the same but hysteresis loss increase
            (d) eddy current loss increases but hysteresis loss remains the same
14.The hysteresis & eddy current losses of a single phase transformer working on 200 V, 50 Hz supply are Ph & Pe respectively. The percentage decrease in these, when operated on a 160 V, 40 Hz supply are
            (a) 32, 36                     (b) 20, 36                     (c) 25, 50                     (d) 40, 80
15.The maximum efficiency for a transformer occurs at 80% of full load. Its core loss is Pc and ohmic loss is Poh. For this transformer, the ratio Pc/Poh is
            (a) 0.8                          (b) 1.25                                    (c) 0.64                                    (d) 0.8944
16. Frequency of the supply voltage to a transformer at no load is increased but the supply voltage is held constant. With this
            (1) eddy current loss remains constant but hysteresis loss increases
            (2) eddy current loss remains constant but hysteresis loss decreases               
            (3) magnetizing current increases but core loss current decreases
            (4) both magnetizing and core loss currents decrease
From these, the correct answer is
(a)    2,3             (b) 2,4                          (c) 1,3              (d) 1,4
17.The applied voltage to a transformer primary is increased keeping V/f constant. With this, the core loss will
            (a) decrease & magnetizing current Im will increase (b) increase & Im will also increase
            (c) remain constant & Im will also remain constant  (d) increase & Im will remain constant
18. As the load on a transformer is increased, the core losses
            (a) decrease slightly     (b) increase slightly     
             (c) remain constant         (d) may increase or decrease slightly depending upon the nature of load
19. Can a 50 Hz transformer be used for 25 Hz, if the input voltage is maintained constant at the rated value corresponding to 50 Hz?
(a) Yes. Since the voltage is constant, current levels will not change
(b) No. Flux will be doubled which will drive the core to excessive saturation
(c) No. Owing to decreased reactance of transformer, input current will be doubled at load
(d) Yes. At constant voltage, insulation will not be overstressed
20. In a transformer, if primary leakage impedance is neglected then
1. magnetizing current lags the applied voltage V1 by 900
2. Core loss current lags V1 by 900
3. Exciting current lags V1 by 900
4.core loss current is in phase with V1
5.Exciting current lags V1 by about 800
6. Magnetizing current lags V1 by about 800
From these, the correct statements are
(a)    1,4,5    (b) 3,4,6           (c) 1,4              (d) 1,2,6
21. A transformer secondary is connected to pure resistive load. The power factor on the primary side will be
(a)    Near about .95 lead                 (b) near about .095 lag                        (c) zero             (d) unity
22. A 50 Hz transformer having equal hysteresis and eddy current losses at rated excitation is operated at 45 Hz at 90% of rated voltage compared to rated operating point, the core loss under this condition
(a) reduces by 10%      (b) reduces by 19%     (c) reduces by 14.5%   (d)Remains unchanged
23. In a 1-phase transformer, the magnitude of leakage reactance is twice that of resistance of both primary and secondary. With secondary short circuited, the input p.f is
(a) 1/√2                        (b) 1/√5                        (c) 2/√5                        (d) 1/√3
24. A multimeter, for measuring resistance is connected to one terminal of primary and the other terminal of secondary. The multimeter reading would be
(a) zero                        (b) infinity                   (c) zero or infinity       (d) equal to the resistance of the windings
25. For given base voltage and base volt amperes, the per unit leakage impedance of a transformer is x. What will be the per unit leakage impedance of this transformer when the voltage and volt-ampere bases are both doubled?
(a) 0.5x                        (b) 2x               (c) 4x               (d) x
26. At 50 Hz operation, a single phase transformer has hysteresis loss of 200 W and eddy current loss of 100 W. Its core loss at 60 Hz operation will be
(a) 432 W        (b) 408 W                    (c) 384 W                    (d) 360 W
27. In a transformer, eddy current loss is 100 W which is half of the total core loss. If both the thickness of laminations and frequency are increased by 10%, the new core loss would be
(a) 256.41 W               (b) 231 W                    (c) 267.41 W               (d) 242 W
28. A 220 V, 50 Hz transformer with 0.35 mm thick laminations has eddy current loss of 120 W which is two third of the total core loss at no load. If this transformer is built with 0.7 mm thick laminations and is worked from 110 V, 25 Hz, then total no load loss would be
(a) 150 W                    (b) 510 W                    (c) 200 W                    (d) 45 W
29. A transformer fed from an alternator at 230 V, 50 Hz has eddy current loss of 50 W and hysteresis loss of 100 W. If the speed of the prime mover driving the alternator drops to 80% of its previous speed, then eddy current and hysteresis losses in the transformer would be
(a) 40 W, 80 W                        (b) 32 W, 80 W                                    (c) 32 W, 64 W                        (d) 40 W, 64 W
30. Two windings of a transformer are indicated by terminals AB and CD as shown in fig. When a voltage of 110 V is applied across AB with CD short circuited, a voltage of 200 V appears across AC. The turns ratio from CD to AB is
(a) 3                 (b) 1                 (c) 3 or 1                      (d) 2 or 1
31. A 400V/200/200V, 50Hz three winding transformer is connected as shown fig. The reading of the voltmeter V will be
(a) 0V                (b) 400V            (c) 600V                        (d) 800V
32. A transformer has leakage impedance of Ze= re+jxe. Its maximum voltage regulation occurs at a power factor of
(a) re/xe leading    (b)re/ze lagging  (c) xe/ze leading      (d)re/ze leading
33.A transformer has leakage impedance of Ze= re+jxe. Zero voltage regulation for this transformer occurs at a power factor of
(a) re/xe leading    (b)re/ze lagging  (c) xe/ze leading      (d)re/ze leading
34.A 1-phase transformer has p.u. leakage impedance of 0.02+j0.04. Its regulation at power factor 0.8 lagging and 0.8 leading are respectively
(a) 4%, 0.8%       (b) 4%, -0.8%      (c) 2.4%,-0.8%             (d) 4%,-1%
35.The voltage regulation of transformer is mainly influenced by
(a) no-load current and load power factor       (b) winding resistance and load power factor  
(c) leakage fluxes and load power factor        (d) winding resistance and core loss
36.A 1-phase transformer has a maximum efficiency of 90% at full load unity p.f. Efficiency at half load at the same p.f is
(a) 86.7%     (b) 88.26%      (c) 88.9%           (d) 87.8%
37. full-load voltage regulation of a power transformer is zero when power factor of the load is near
(a)unity and leading                       (b) zero and leading
(c) Zero and lagging                       (d) unity and lagging
38. The voltage regulation of transformer at full load 0.8 pf lagging is 4%.Its voltage regulation at full-load 0.8pf leading
(a) will be positive     (b) will be negative  (c) may be positive   (d)may be negative
39. The voltage regulation of transformer depend on its
1. Equivalent reactance             2.equivalent resistance                 3. Load power factor
4. transformer size                    5.load current
From these, the correct answer is
(a)    1 , 2 ,3 ,5                   (b)1, 2, 3, 4, 5         (c) 1,  2,  4,  5   (d) 1,  2,  3,  4
40. The voltage regulation of a transformer at full load and 0.8 pf lagging is 2.5%.The voltage regulation at full load 0.8 leading will be
(a) -2.5%               (b) zero         (c) -0.9%             (d) 2.5%
41.The efficiency of a transformer at full load and 0.8 pf lag is 90%.its efficiency at full load 0.8 pf leading will be
(a) Somewhat less than 90% (b) somewhat more than 90%
(c) 90%                                 (d) 91%
42.Transformer maximum efficiency ,for a constant load current, occurs at
(a) at unity               (b)zero pf leading       (c) zero pf lagging   (d) unity pf
43. Transformer at no –load behaves like
(a) a resistor, pf=0                                        (b) an inductive reactor, pf=0.2lagging
(c) a capacitive reactor, pf=0.2 leading        (d) an inductive reactor, pf=0.8 lagging
44.which of the following statements are incorrect
1. Maximum voltage regulation of a transformer occurs at leading power factor
2. voltage regulation of a transformer is the maximum when load power factor (lagging) angle has the same value as the angle of equivalent impedance
3. voltage regulation of a transformer at zero power factor is always zero
4.voltage regulation of a transformer can be negative at leading power factor
Select the correct answer using the code given bellow:
(a) 1 and 3       (b) 2 and 3       (c) 2and 4     (d) 1 and 4
45.A transformer designed for operation of 60Hz supply is worked on 50Hz supply system without change its voltage and current ratings. When compared with full load efficiency at 60Hz, the transformer efficiency on full load at 50Hz will
(a)increases marginally           (b) increases by a factor of 1.2  
(c) remain unaltered                (d) decreases marginally

Sunday, 2 October 2011

BRAINWAVE





The power to make you an IITian






You can download complete details of BRAINWAVE – Nalgonda from the following website

Electric Motors and Drives

Electric Motors and Drives Technical Manual




Table of Contents


Section Title Page
Motor Specifications
1.1 Nameplate 1
1.2 Insulation Class 3
1.3 Enclosure Type 11
1.4 Temperature Class 19
1.5 Mounting 30
1.6 Manufacturer’s Identification Number 51
1.7 Terminal Markings 55
1.8 Motor Design 67
1.9 Types of Duty 76
General Characteristics
2.1 System Nominal Voltage 103
2.2 Voltage 104
2.3 Power Factor 112
2.4 Efficiency 113
2.5 Speed 118
2.6 Vibration Characteristics and Balancing 119
2.7 Bearings 141
2.8 Torque 170
Asynchronous Motor Starting Systems
3.1 Starting Methods 175
3.2 Single-phase Motor Starting 187
Motor Protection and Coordination
4.1 Motors Protection 193
4.2 Protection Against Short Circuits 194
4.3 Protection Against Overload 203
4.4 Multifunction Relays 212
4.5 Motor Circuit Breakers 215
Motor Starter Co-ordination
5.1 Concepts 219
5.2 Solutions 220
5.3 Motor Overload Protection 229
5.4 Terminology 241
Motor Efficiency
6.1 Repair-Replace Decision Model 246
6.2 Premium EfficiencyMotors 262
Installation, Testing, and Maintenance
7.1 Installation and Maintenance 273
7.2 Description of Routine Tests 309
7.3 Recommended Winding Tests 321
7.4 Other Tests 322
7.5 Motor Starting Capabilities and Considerations 323
7.6 Maintenance and Reliability 328
7.7 Maintenance Programs 332
7.8 Machinery Condition Monitoring 334
7.9 Maintenance Planning 338



Power Transformer

2010 Edition Power Transformers Technical Manual



Table of Contents
Introduction
Transformer Core
Transformer Winding
Transformer Insulation (Solid)
Transformer Insulation (Fluid)
Transformer Tanks & Accessories
Transformer Specifications
Reading and Applying Nameplate Information
Transformer Connections
Over current Protection
Overvoltage Protection
Protective Relays
Philippine Electrical Code Provisions on Transformer
Protection
Field testing of Power Transformers
Factory Acceptance Testing of Power Transformers
Appendix
A Comparative Study of IEC 76 and ANSI C57.12
On Transformers


Handbook of Photovoltaic Science and Engineering



Handbook of Photovoltaic Science and Engineering






Engineering Electromagnetism

Engineering Electromagnetics


Contents

1. Vector Analysis 1

2. Coulomb’s Law and Electric Field Intensity 26

3. Electric Flux Density, Gauss’s Law, and Divergence 48

4. Energy and Potential 75

5. Conductors and Dielectrics 109

6. Capacitance 143

7. The Steady Magnetic Field 180

8. Magnetic Forces, Materials, and Inductance 230

9. Time-Varying Fields and Maxwell’s Equations 277

10. Transmission Lines 301

11. The Uniform Plane Wave 367

12. Plane Wave Reflection and Dispersion 406

13. Guided Waves 453

14. Electromagnetic Radiation and Antennas 511

Appendix A Vector Analysis 553

Appendix B Units 557

Appendix C Material Constants 562

Appendix D The Uniqueness Theorem 565

Appendix E Origins of the Complex Permittivity 567

Appendix F Answers to Odd-Numbered Problems 574

Index 580



Tuesday, 31 May 2011

The art and science of protective relaying

The art and science of protective relaying

Contents

1. The philosophy of protective relaying
What is protective relaying?
The function of protective relaying
Fundamental principles of protective relaying
- primary relaying
- back-up relaying
- protection against other abnormal conditions
Functional characteristics of protective relaying
- sensitivity, selectivity, and speed
- reliability
How do protective relays operate?
2. Fundamental relay-operating principles and characteristics
General considerations
- operating principles
- definitions of operation
- operation indicators
- seal-in and holding coils, and seal-in relays
- adjustment of pickup or reset
- time delay and its definitions
Single-quantity relays of the electromagnetic-attraction type
- operating principle
- ratio of reset to pickup
- tendency toward vibration
Directional relays of the electromagnetic attraction type
- operating principle
- efficiency
- ratio of continuous thermal capacity to pickup
Induction-type relays–general operating principles
- the production of actuating force
- types of actuating structure
Single-quantity induction relays
- torque control
- effect of frequency
- effect of d-c offset
- ratio of reset to pickup
Directional induction relays
- torque relations in terms of actuating quantities
- the significance of the term “directional”
- the polarizing quantity of a directional relay
- the operating characteristic of a directional relay
- the “constant-product” characteristic
- effect of d-c offset and other transients
The universal relay-torque equation
3. Current, voltage, directional, current (or voltage)-balance, and differential relays
General protective-relay features
Overcurrent, undercurrent, overvoltage, and undervoltage relays
D-C directional relays
A-C directional relays
Current (or voltage) – balance relays
Differential relays
4. Distance relays
The impedance-type distance relay
The modified impedance-type distance relay
The reactance-type distance relay
The mho-type distance relay
General considerations applicable to all distance relays
5. Wire-pilot relays
Why current-differential relaying is not used
Purpose of a pilot
Tripping and blocking pilots
D-C wire-pilot relaying
Additional fundamental considerations
A-C wire-pilot relaying
6. Carrier-current-pilot and microwave-pilot relays
The carrier-current pilot
The microwave pilot
Phase-comparison relaying
Directional-comparison relaying
Looking ahead
7. Current transformers
Types of current transformers
Calculation of ct accuracy
Polarity and connections
8. Voltage transformers
Accuracy of potential transformers
Capacitance potential devices
The use of low-tension voltage
Polarity and connections
9. Methods for analyzing generalizing, and visualizing relay response
The R-X diagram
Short circuits
Power swings and loss of synchronism
Response of polyphase directional relays to positive- and negative-phase-sequence volt-amperes
Response of single-phase directional relays to short circuits
Phase-sequence filters
10 A.C generator and motor protection
Generator protection
11. Transformer protection
Power transformers and power auto transformers
Step voltage regulators
Grounding transformers
Electric arc-furnace transformers
Power-rectifier transformers
12 bus protection
Protection by back-up relays
The fault bus1
Directional-comparison relaying
Current-differential relaying with over current relays
Partial-differential relaying
Current-differential relaying with percentage-differential relays
Voltage-differential relaying with “linear couplers”
Current-differential relaying with over voltage relays
Combined power-transformer and bus protection
The value of bus sectionalizing
Back-up protection for bus faults
Grounding the secondaries of differentially connected ct’s
Once-a-shift testing of differential-relaying equipment
13. Line protection with over current relays
How to set inverse-time-over current relays for coordination
Arc and ground resistance
Effect of loop circuits on over current relay adjustments
Effect of system on choice of inverseness of relay characteristic
The use of instantaneous over current relays
An incidental advantage of instantaneous over current relaying
Overreach of instantaneous over current relays
The directional feature
Use of two versus three relays for phase-fault protection
Single-phase versus poly phase directional-over current relays
How to prevent single-phase directional over current-relay misoperation during ground faults
Adjustment of ground versus phase relays
Effect of limiting the magnitude of ground-fault current
Transient ct errors
Detection of ground faults in ungrounded systems
Effect of ground-fault neutralizers on line relaying
The effect of open phases not accompanied by a short circuit
The effect of open phases accompanied by short circuits
Polarizing the directional units of ground relays
Negative-phase-sequence directional units for ground-fault relaying
Current-balance and power-balance relaying
Automatic reclosing
Restoration of service to distribution feeders after prolonged outages
Coordinating with fusesA-C and capacitor tripping
14. Line protection with distance relays
The choice between impedance, reactance, or mho
The adjustment of distance relays
The effect of arcs on distance-relay operation
The effect of intermediate current sources on distance-relay operation
Overreach because of offset current waves
Overreach of ground distance relays for phase faults
Use of low-tension voltage
Use of low-tension current
Effect of power-transformer magnetizing-current inrush on distance-relay operation
The connections of ground distance relays
Operation when PT fuses blow
Purposeful tripping on loss of synchronism
Blocking tripping on loss of synchronism
Automatic reclosing
Effect of presence of expulsion protective gaps
Effect of a series capacitor
Cost-reduction schemes for distance relaying
Electronic distance relays
15. Line protection with pilot relays
Wire-pilot relaying
Obtaining adequate sensitivity
The protection of multiterminal lines
Current-transformer requirements
Back-up protection
Carrier-current-pilot relaying
Phase comparison
Directional comparison
Combined phase and directional comparison
All-electronic directional-comparison equipment
High-speed reclosing