Answer:
Step-by-step explanation:
a)
Apparent power|S0| of the original load:
|S0|=P0/0.8=1600000/0.8
|S0|=2000kvA
P0 is the average power of the original load.
To determine the relative power Q0 of the original load :
Q0=√|S0|^2-P0^2
=√(2000000^2)-(1600000)^2=1200kVAR
Complex power of the original load S0:
S0=P0+jQ0
=1600+j1200kvA
After the additional power factor load, the final power Pf is :
Pf=1600000+320000=1920kw
Therefore the final apparent power |Sf| of the load will be:
|Sf |=Pf/0.96
|Sf|=1920000/0.96=2000kvA
Hence, the reactive power (Qf) of the composite Load:
Qf=√|Sf|^2-P^2
Qf=√(2000000)^2-(1920000)^2=560kVAR
Now, the final complex power(Sf) associated with the composite load is:
Q(add)=Qf-Q0
Q(add)=560000-1200000
=-640kVAR
b) Yes, since the reactive power value of the added load is negative, the added load delivers magnetizing vars:
c) Complex power S(add) of the added load:
S(add)=P(add) + jQ(add)
S(add)=320000-j640000
S(add)=715541.753<-63.435
The phase difference between the added load voltage and current is:
Qv-Qi=-63.435
The power factor Pf of the added load :
Pf=cos(-63.435)=0.447
Therefore, the added load current leads the voltage, the power of the additional load or adjustable power factor is leading by:
Pf=0.447leading
d) the current into the factory (I) before adding the power factor load is:
I=S0/2400
I=1600000-j1200000/2400
I=666.667-j500
I=833.33<-36.87A(rms)
rms magnitude of the current into the factory| I| before adding the power factor load is given as:
|I|=833.33A(rms)
e) current into the factory ,I, after adding the power factor load :
I=Sf*/2400
I=1920000-j560000/2400
I=833.33<-16.25•(rms)
Therefore, rms magnitude of the current into the factory |I| after adding the power factor load is :
|I|=833.33A(rms)
Finally ,adding the capacitor has not changed the current rms magnitude but it's phase only.