Q2Figure Q2 below shows a manufacturing plant connected to three phase 3600V line of wye configuration operating at 50 Hz. The manufacturing plantdraws a total power of 415 kVA with power factor of 0.6.415 KVA3600 VPF = 0.6Figure Q2(a)Compute the impedance per phase of the manufacturing plant(b)Compute the capacitor per phase to improve the power factor of themanufacturing plant to 0.9. State the assumption that you made tocompute the value.

Given data: The source is wye (star) connected and operating frequency is f=50 Hz. Sending end line…

Figure Q2 below shows a manufacturing plant connected to three phase 3600 V line of wye configuration operating at 50 Hz. The manufacturing plant draws a total power of 415 kVA with power factor of 0.6. Q2 415 KVA 3600 V PF = 0.6 Figure Q2 (а) Compute the impedance per phase of the manufacturing plant Compute the capacitor per phase to improve the power factor of the manufacturing plant to 0.9. State the assumption that you made to compute the value. (b)

Figure Q2 below shows a manufacturing plant connected to three phase 3600 V line of wye configuration operating at 50 Hz. The manufacturing plant draws a total power of 415 kVA with power factor of 0.6. Q2 415 KVA 3600 V PF = 0.6 Figure Q2 (а) Compute the impedance per phase of the manufacturing plant Compute the capacitor per phase to improve the power factor of the manufacturing plant to 0.9. State the assumption that you made to compute the value. (b)

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

Chapter2: Fundamentals

Section: Chapter Questions

Problem 2.44P: Two balanced three-phase loads that are connected in parallel are fed by a three-phase line having a...

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