4. A wind turbine has a blade length of 15 m. In a given day, average speed ofwind for 10 hours is 8 m/s, average speed of wind for another 5 hours is 11m/s and wind speed is not sufficient to rotate wind turbine for remaining timein a day. Take Air density o = 1.23 kg/m.Determine the following:a) Maximum possible power output of wind turbine for 10 hoursb) Maximum possible power output of wind turbine for 5 hoursc) Maximum possible energy output of turbine in a given day

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4. A wind turbine has a blade length of 15 m. In a given day, average speed of wind for 10 hours is 8 m/s, average speed of wind for another 5 hours is 11 m/s and wind speed is not sufficient to rotate wind turbine for remaining time in a day. Take Air density g = 1.23 kg/m. Determine the following: a) Maximum possible power output of wind turbine for 10 hours b) Maximum possible power output of wind turbine for 5 hours c) Maximum possible energy output of turbine in a given day

4. A wind turbine has a blade length of 15 m. In a given day, average speed of wind for 10 hours is 8 m/s, average speed of wind for another 5 hours is 11 m/s and wind speed is not sufficient to rotate wind turbine for remaining time in a day. Take Air density g = 1.23 kg/m. Determine the following: a) Maximum possible power output of wind turbine for 10 hours b) Maximum possible power output of wind turbine for 5 hours c) Maximum possible energy output of turbine in a given day

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 2.31P: Consider two interconnected voltage sources connected by a line of impedance Z=jX, as shown in...

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