14. Three resistances, each of 500 2 are connected in star to a 400-V, 50-Hz, 3-phase supply. If three capacitors, when connected in delta to the same supply, take the same line currents, calculate the capacitance of each capacitor and the line current. [2.123 µ F, 0.653 A] (London Univ.) 15 A factory takes the following balanced loads ffrom a 440.V 3-phase 50-Hz supply:
14. Three resistances, each of 500 2 are connected in star to a 400-V, 50-Hz, 3-phase supply. If three capacitors, when connected in delta to the same supply, take the same line currents, calculate the capacitance of each capacitor and the line current. [2.123 µ F, 0.653 A] (London Univ.) 15 A factory takes the following balanced loads ffrom a 440.V 3-phase 50-Hz supply:
Power System Analysis and Design (MindTap Course List)
6th Edition
ISBN:9781305632134
Author:J. Duncan Glover, Thomas Overbye, Mulukutla S. Sarma
Publisher:J. Duncan Glover, Thomas Overbye, Mulukutla S. Sarma
Chapter3: Power Transformers
Section: Chapter Questions
Problem 3.33P: Consider the three single-phase two-winding transformers shown in Figure 3.37. The high-voltage...
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![8. A 415-V, 3-phase, 4-wire system supplies power to three non-inductive loads. The loads are
25 kW between red and neutral, 30 kW between yellow and neutral and 12 kW between blue and neutral.
Calculate (a) the current in each-line wire and (b) the current in the neutral conductor.
[(a) 104.2 A, 125 A, 50 A (b) 67 A] (London Univ.)
9. Non-inductive loads of 10, 6 and 4 kW are connected between the neutral and the red, yellow and
blue phases respectively of a three-phase, four-wire system. The line voltage is 400 V. Find the current in
each line conductor and in the neutral.
[(a) 43.3 A, 26A, 173. A, 22.9] (App. Elect. London Univ.)
10. A three-phase, star-connected alternator supplies a delta-connected load, each phase of which
has a resistance of 20 Q and a reactance of 10 Q Calculate (a) the current supplied by the alternator (b) the
output of the alternator in kW and kVA, neglecting the losses in the lines between the alternator and the
load. The line voltage is 400 V.
11. Three non-inductive resistances, each of 100 Q, are connected in star to 3-phase, 440-V supply.
Three equal choking coils each of reactance 100 2 are also connected in delta to the same supply.
Calculate:
[(a) 30.95 A (b) 19.2 kW, 21.45 kVA]
(a) line current
(b) p.f. of the system.
[(a) 8.04 A (b) 0.3156] (I.E.E. London)
12. In a 3-phase, 4-wire system, there is a balanced 3-phase motor load taking 200 kW at a power
factor of 0.8 lagging, while lamps connected between phase conductors and the neutral take 50, 70 and 100
kW respectively. The voltage between phase conductors is 430 V. Calculate the current in each phase and
in the neutral wire of the feeder supplying the load.
[512 A, 5.87 A, 699 A; 213.3 A] (Elect. Power, London Univ.)
13. A 440-V, 50-Hz induction motor takes a line current of 45 A at a power factor of 0.8 (lagging).
Three A-connected capacitors are installed to improve the power factor to 0.95 (lagging). Calculate the
kVA of the capacitor bank and the capacitance of each capacitor. [11.45 kVA, 62.7 µF] (I.E.E. London)
14. Three resistances, each of 500 Q are connected in star to a 400-V, 50-Hz, 3-phase supply. If
three capacitors, when connected in delta to the same supply, take the same line currents, calculate the
capacitance of each capacitor and the line current.
15. A factory takes the following balanced loads from a 440-V, 3-phase, 50-Hz supply:
(a) a lighting load of 20 kW
(c) an intermittent welding load of 30 kVA at 0.5 p.f. lagging.
Calculate the kVA rating of the capacitor bank required to improve the power factor of loads (a) and
(b) together to unity. Give also the value of capacitor required in each phase if a star-connected bank is
employed.
What is the new overall p.f. if, after correction has been applied, the welding load is switched on.
[2.123 µ F, 0.653 A] (London Univ.)
(b) a continuous motor load of 30 kVA at 0.5 p.f. lagging.
[30 KVAR; 490µ F; 0.945 kg]
16. A three-wire, three-phase system, with 400 V between the line wires, supplies a balanced delta-
connected load taking a total power of 30 kW at 0.8 power factor lagging. Calculate (i) the resistance and
(ii) the reactance of each branch of the load and sketch a vector diagram showing the line voltages and line
currents. If the power factor of the system is to be raised to 0.95 lagging by means of three delta-connected
capacitors, calculate (ii) the capacitance of each branch assuming the supply frequency to be 50 Hz.
[() 10.24 A (i) 7.68 2 (ii) 83.2 µF] (London Univ.)](/v2/_next/image?url=https%3A%2F%2Fcontent.bartleby.com%2Fqna-images%2Fquestion%2Fa8372b82-a1de-4948-a27b-cbb86b7c5c76%2Fd953fb58-a4c3-46d9-a15f-a1ea2e88fd3f%2Fjvkxz4_processed.jpeg&w=3840&q=75)
Transcribed Image Text:8. A 415-V, 3-phase, 4-wire system supplies power to three non-inductive loads. The loads are
25 kW between red and neutral, 30 kW between yellow and neutral and 12 kW between blue and neutral.
Calculate (a) the current in each-line wire and (b) the current in the neutral conductor.
[(a) 104.2 A, 125 A, 50 A (b) 67 A] (London Univ.)
9. Non-inductive loads of 10, 6 and 4 kW are connected between the neutral and the red, yellow and
blue phases respectively of a three-phase, four-wire system. The line voltage is 400 V. Find the current in
each line conductor and in the neutral.
[(a) 43.3 A, 26A, 173. A, 22.9] (App. Elect. London Univ.)
10. A three-phase, star-connected alternator supplies a delta-connected load, each phase of which
has a resistance of 20 Q and a reactance of 10 Q Calculate (a) the current supplied by the alternator (b) the
output of the alternator in kW and kVA, neglecting the losses in the lines between the alternator and the
load. The line voltage is 400 V.
11. Three non-inductive resistances, each of 100 Q, are connected in star to 3-phase, 440-V supply.
Three equal choking coils each of reactance 100 2 are also connected in delta to the same supply.
Calculate:
[(a) 30.95 A (b) 19.2 kW, 21.45 kVA]
(a) line current
(b) p.f. of the system.
[(a) 8.04 A (b) 0.3156] (I.E.E. London)
12. In a 3-phase, 4-wire system, there is a balanced 3-phase motor load taking 200 kW at a power
factor of 0.8 lagging, while lamps connected between phase conductors and the neutral take 50, 70 and 100
kW respectively. The voltage between phase conductors is 430 V. Calculate the current in each phase and
in the neutral wire of the feeder supplying the load.
[512 A, 5.87 A, 699 A; 213.3 A] (Elect. Power, London Univ.)
13. A 440-V, 50-Hz induction motor takes a line current of 45 A at a power factor of 0.8 (lagging).
Three A-connected capacitors are installed to improve the power factor to 0.95 (lagging). Calculate the
kVA of the capacitor bank and the capacitance of each capacitor. [11.45 kVA, 62.7 µF] (I.E.E. London)
14. Three resistances, each of 500 Q are connected in star to a 400-V, 50-Hz, 3-phase supply. If
three capacitors, when connected in delta to the same supply, take the same line currents, calculate the
capacitance of each capacitor and the line current.
15. A factory takes the following balanced loads from a 440-V, 3-phase, 50-Hz supply:
(a) a lighting load of 20 kW
(c) an intermittent welding load of 30 kVA at 0.5 p.f. lagging.
Calculate the kVA rating of the capacitor bank required to improve the power factor of loads (a) and
(b) together to unity. Give also the value of capacitor required in each phase if a star-connected bank is
employed.
What is the new overall p.f. if, after correction has been applied, the welding load is switched on.
[2.123 µ F, 0.653 A] (London Univ.)
(b) a continuous motor load of 30 kVA at 0.5 p.f. lagging.
[30 KVAR; 490µ F; 0.945 kg]
16. A three-wire, three-phase system, with 400 V between the line wires, supplies a balanced delta-
connected load taking a total power of 30 kW at 0.8 power factor lagging. Calculate (i) the resistance and
(ii) the reactance of each branch of the load and sketch a vector diagram showing the line voltages and line
currents. If the power factor of the system is to be raised to 0.95 lagging by means of three delta-connected
capacitors, calculate (ii) the capacitance of each branch assuming the supply frequency to be 50 Hz.
[() 10.24 A (i) 7.68 2 (ii) 83.2 µF] (London Univ.)
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