POWER SYSTEM-I - B.Tech. 4th Semester Examination, 2018

Which of the following distribution systems is preferred for good efficiency and high economy?

1. Single-phase, 2-wire system
2. 2-phase, 3-wire system
3. 3-phase, 3-wire system
4. 3-phase, 4-wire system

The main drawback(s) of overhead system over underground system is/are

1. underground system is more flexible than overhead system
2. higher charging current
3. surge problem
4. high initial cost

The highest transmission voltage used in India is

1. 400 kV
2. 220 kV
3. 132 kV
4. 765 kV

The function of steel wire in an ACSR conductor is to

1. compensate for skin effect
2. take care of surges
3. provide additional mechanical strength
4. reduce inductance

Corona is accompanied by

1. violet visible discharge in darkness
2. hissing sound
3. power loss
4. All of the above

The conductor carries more current on the surface in comparison to its core. This phenomenon is called the

1. skin effect
2. corona
3. Ferranti effect
4. Lenz's effect

Ferranti effect happens in transmission line when the line is

1. short and loaded
2. long and loaded
3. long and unloaded
4. None of the above

A transmission line is distortionless if

1. \( RG = LC \)
2. \( RC = GL \)
3. \( R/C = G/L \)
4. \( R = G \)

The receiving-end voltage of a transmission line will be greater than the sending-end voltage if the load is

1. greater than SIL (surge impedance loading)
2. less than SIL
3. equal to SIL
4. None of the above

Capacitor grading of cable means

1. use of dielectrics in different concentrations
2. introduction of capacitances at various lengths of cable to counter the effect of inductance
3. use of dielectric of different permittivities
4. grading according to capacitance per km length of the cable

Explain 3-phase, 4-wire system of distribution of electrical power.

A 2-wire feeder ABC has a load of 100 Ampere at unity p.f. at C and 65 Ampere at p.f. 0.8 lagging at B. The impedance AB is \( (0.06+j0.08)\Omega \) and that of BC is \( (0.04+j0.12)\Omega \). If the voltage at the far end C is to be maintained at 230 V, determine the voltage (i) at A and (ii) at B.

Derive an expression for the capacitance of a single-phase overhead transmission line.

Find out capacitance of a single-phase line 30 km long consisting of two parallel wires each 15 mm diameter and 1.5 m apart.

A single-phase line has an impedance of \( 5 \angle 60^{\circ} \Omega \). It is supplying a load of 120 A, 33 kV at 0.8 p.f. lagging. Calculate its regulation.

In a 3-phase, 4-wire system, the line voltage is 400 V and non-inductive loads of 10, 8 and 5 kW are connected between the three line conductors and the neutral. Calculate (i) the current in each line and (ii) the current in the neutral conductor.

What are the sources of vibrations in a transmission line? Explain the methods used to damp out these vibrations.

Obtain an expression for the sag of a transmission line supported by towers of different heights at the ends.

Define regulation of a 3-phase a.c. transmission system and develop an expression for approximate voltage regulation.

Explain surge impedance loading with respect to an overhead transmission line.

An overhead 3-phase transmission line delivers 5 MW at 22 kV at 0.8 lagging power factor. The resistance and reactance of each conductor are 4 \( \Omega \) and 6 \( \Omega \) respectively. Determine: (a) Sending-end voltage (b) Percentage regulation (c) Total line losses (d) Transmission efficiency.

With the neat labelled diagram, show the various parts of a high-voltage single-core cable.

Explain briefly the following methods of grading of cables: (i) Capacitance grading (ii) Intersheath grading.

A 132 kV transmission line has the following data: Weight of conductor = 680 kg/km, Length of span = 260 m, Ultimate strength = 3100 kg, Safety factor = 2. Calculate the height above ground at which the conductor should be supported. Ground clearance required is 10 m.

The three conductors of a 3-phase transmission line are arranged in a horizontal plane and are 3 m apart. The diameter of each conductor is 4 cm. Determine the inductance per km of each phase. Assume balanced load and R, Y, B phase sequence.