1. Repeat Example 4.2, parts (a) and (b), assuming a three-phase 34.5 kV wye-grounded feeder main that has 350 kcmil 19-strand copper conductors with an equivalent spacing of 37 in between phase conductors and a lagging-load power factor of 0.9.  K=3.5935 ×10-5 [%VD/KVA-mi]

Below attached image is for example 4.2

 

Transcribed Image Text:

from Table A-1 for 50°C and 60 Hz Example 4-2 Assume that the feeder shown in Fig. 4-22 has the same charac- from Table A-10 for 60 Hz and 37-inch spacing SOLUTION (r cos 0 + x sin 0)G x 1000) V,V. (a) From Eq. (4-77), pu v NL = , + x, = 0.7456 2/mi X, = 0.609 Q mi X = 0.1366 /mi cos 0 = 0.9, lagging V = V, = 2400 V, line-to-neutral voltage where r = 1.503 /mi from Table A-1 for 60 Hz Therefore the per unit voltage drop per kilovoltampere-mile i (1.503 x 0.9 + 0.7456 x 0.4359)G x 1000 24002 2 0.0001 VD/(k VA mi) or K= 0.01 % VD/(k VA mi) (b) From Fig. 4-17, the K constant for #4 copper conductors is K = 0.01 % VD/(kVA mi) which is the same as the one found in part a. teristics as the one in Example 4-1 and a lumped-sum load of 500 kVA wi. lagging-load power factor of 0.9 is connected at the end of a l-mi-long feed main. Calculate the percent voltage drop in the main. SOLUTION The percent voltage drop in the main is % VD = x K x S, = 1.0 mi x 0.01% VD/(kVA · mi) x 500 kVA = 5.0% S= = 1 mi # 4 copper D = 37 AVLL = 4.16 kV 500 kVA PF = 0.9 lag Figure 4-22