Two balanced three phase loads are connected in parallel, the loads are L1= 20 kW at 0.7 pflead, and L2= 12 kVA at 0.9 pf lag. The loads are fed from a distribution line with animpedance of 0.05+j0.2 Q/. The line to neutral voltage at the load end is 203 V and zerophase shift, the power factor of the loads is;A. 0.994 leadingO B. 0.897 leadingC. 0.994 laggingO D. 0.897 laggingO E. 0.203 leadingO F. 0.203 laggingO G. None

we will find total active power of load i.e. total active power to loads = active power of load…

Two balanced three phase loads are connected in parallel, the loads are L1= 20 kW at 0.7 pf lead, and L2= 12 kVA at 0.9 pf lag. The loads are fed from a distribution line with an impedance of 0.05+j0.2 Q/D. The line to neutral voltage at the load end is 203 V and zero phase shift, the power factor of the loads is; O A. 0.994 leading O B. 0.897 leading O C.0.994 lagging O D. 0.897 lagging O E. 0.203 leading O F. 0.203 lagging O G. None

Two balanced three phase loads are connected in parallel, the loads are L1= 20 kW at 0.7 pf lead, and L2= 12 kVA at 0.9 pf lag. The loads are fed from a distribution line with an impedance of 0.05+j0.2 Q/D. The line to neutral voltage at the load end is 203 V and zero phase shift, the power factor of the loads is; O A. 0.994 leading O B. 0.897 leading O C.0.994 lagging O D. 0.897 lagging O E. 0.203 leading O F. 0.203 lagging O G. None

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 2.19P: Consider a single-phase load with an applied voltage v(t)=150cos(t+10)volts and load current...

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