The two loads in Figure 5 can be described as follows: Load 1 absorbs an average power
of 6 kW...
Engineering, 22.04.2020 01:46, stephliu721
The two loads in Figure 5 can be described as follows: Load 1 absorbs an average power
of 6 kW at a leading power factor of 0.7. Load 2 absorbs 18 kVA at a lagging power
factor of 0.55. Determine the following.
The real, net reactive and apparent power of each load.
Draw the power triangle for each load.
111)The current through each load
iv)The total apparent power of both loads.
v) The total current
vii) The resultant power factor of the two loads.
vii)
The power rating of the 0.05 N resistor.
viii) Given that power sources operates at 50Hz find the capacitance required to correct the power factor to a value of 1
Answers: 2
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Derive the correction factor formula for conical nozzle i=-(1+ cosa) and calculate the nozzle angle correction factor for a nozzle whose divergence hal-fangle is 13 (hint: assume that all the mass flow originates at the apex of the cone.
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Engineering, 04.07.2019 19:20, mariahmimibrooks
Liquid flows at steady state at a rate of 2 lb/'s through a pump, which operates to raise the elevation of the liquid 100 ft from control volume inlet to exit. the liquid specific enthalpy at the inlet is 40.09 btu/lb and at the exit is 40.94 btub. the pump requires 3 btu/s of power to operate. if kinetic energy effects are negligible and gravitational acceleration is 32.174 tt/s, the heat transfer rate associated with this steady state process is most closely 1)-2,02 btu/s from the liquid to the surroundings 2)-3.98 btu/s from the surroundings to the liquid. 3)-4.96 btu/s from the surroundings to the liquid. 4)-1.04 btu/s from the liquid to the surroundings.
Answers: 2
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