You are asked to design a small wind turbine (D-x+1.25 ft, where x is the last two digits of your student ID). Assume the wind speed is 15 mph at T-10°C and p = 0.9 bar. The efficiency of the turbine is n- 25%, meaning that 25% of the kinetic energy in the wind can be extracted. Calculate the power in watts that can be produced by your turbine. Scan the solution of the problem and upload in the vUWS before closing the vUWS or moving to other question. DO NOT EMAIL TO LECTURER. x=08

Please answer this NEATLY, COMPLETELY, and CORRECTLY for an UPVOTE. A 6-MW offshore wind turbine has a capacity factor of 40%. It has a height of 120 m, and 107-m long blades. The angular acceleration is 1.17 rad/s2. Assume that the distance from the center of the turbine to the connection with the blade is negligible, and that the turbine starts from rest. At t = 12 s, calculate the velocity and the acceleration for points (a) at half the length and (b) at the tip of the blade.

At the point of operation with maximum efficiency, a turbine indicated unit power of 12 units and unit speed of 98 units and operates with 3300 kgf/ s of flow. What is the speed in rpm and the specific speed of the machine respectively when its design head is 8.5m?

A turbine is rated at 600hp when the flow of water through it is 82cu.m/sec. Assuming an efficiency of 92%, what is the head acting on the turbine?

A tire dog (mass of approximate 1kg) does push-up by applying a force to elevate its center of mass by 6cm in order to do mere 0.6 Joule of work. If the tired dog does all this work in 3secs.. then determine the power.

Q6 A turbine develops 500 kW power under a head of 100 metres at 200 rpm .What would be its normal speed and output under a head of 81 m ?

A car has a frontal projected area of 1.6 2 m² and travels at 60km/hr. It has a drag coefficient of 0.35 based on frontal area. Calculate the power required in kW to overcome wind resistance by the car. 3 Density of air= 1.2 kg/m

A turbine produces 8000 kW of power at 500 rpm under a net head of 45 m with an overall efficiency of 85%. Determine the revolution per-minute (rpm), discharge and brake power of the same turbine under a net head of 60 m in homologous conditions.

1. Determine the power required to drive a centrifugal pump which discharges water at the rate of 200 liters per minute against a total head of 22m. Take overall efficiency of the pump as 70 %