Introductory Circuit Analysis (13th Edition)
13th Edition
ISBN: 9780133923605
Author: Robert L. Boylestad
Publisher: PEARSON
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A dc short shunt compound generator delivers 20 kW to a load at 500 V. The armature, series field and shunt field resistances are 0.01 Ω, 0.05 Ω, and 100 Ω. Find the power developed in the armature
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- A seperately excited dc generator has the following data: armature resistance , 0.06 Ω; field resistance, 112 Ω, total core and mechanical losses, 966 W; votlage across the field , 230V. The generator supplies a load at a terminal voltage of 230V. Calcaulte the armature current at which the generator has a maximum efficiency.arrow_forwardA 480V synchronous generator. 200 kVA, 0.8 power factor lagging, 60 Hz, two poles. connected in Y. It has a synchronous reactance of 0.25Ω and an armature resistance of 0.04Ω at 60 Hz, its own friction losses and with the air are 6 kW and its core losses are 4 kW. The field circuit has a voltage of 200 V and the maximum Is is 10 A. The field resistance is adjustable in a range of 20 to 200 Ω. The generator occ is shown in the figure below.Assume that the field current of the generator from the problem in the previous task has been set to 4.5A.a) What will be the voltage at the terminals of the generator if it is connected to a load at A with an impedance of 5<30° Q?b) Draw the phasor diagram of this generator.c) What is the efficiency of the generator under these conditions?d) Suppose now that another charge at A, identical, is placed in parallel with the first one. What happens in the phasor diagram of the generator?e) What is the new terminal voltage after adding charge?…arrow_forwardA 480V synchronous generator. 200 kVA, 0.8 power factor lagging, 60 Hz, two poles. connected in Y. It has a synchronous reactance of 0.25Ω and an armature resistance of 0.04Ω at 60 Hz, its own friction losses and with the air are 6 kW and its core losses are 4 kW. The field circuit has a voltage of 200 V and the maximum Is is 10 A. The field resistance is adjustable in a range of 20 to 200 Ω. The generator occ is shown in the following figure…Assume that the field current of the generatoradjusts to achieve nominal 480V voltage under full load conditionsfor each of the questions below.a) What is the efficiency of the generator at nominal load?b) What is the voltage regulation of the generator if it is loaded with nominal KVAwith charges with a FP of 0.8 behind?c) What is the voltage regulation of the generator if it is loaded with nominal KVAwith charges with a FP of 0.8 in advance?d) What is the voltage regulation of the generator if it is loaded with nominal KVA with loads with a…arrow_forward
- The armature of a two-pole generator is rotating at 3600 r/min. The armature has a simplex lap winding with a total of 1504 conductors. Determine the generated voltage when the flux per pole is 600,000 x 10-8 Wb. 5.5arrow_forwardD2. When a generator's full-load output voltage is the same as its no-load output voltage it is said to be a) under-compounded b) flat-compounded c) over-compounded d) none of the above D3. The output of an overcompounded DC generator can be lowered by use of a a) rheostat connected in series with the series field b) rheostat connected in parallel with the series field c) rheostat connected in parallel with the shunt field d) none of the above D4. When might it be desirable to use an overcompounded generator? a) never b) always c) to compensate for line loss d) when you need a higher no-load voltage than your full-load voltagearrow_forward
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