From 7f60ea012dd2524dae921a2a35adbf7ef21f2bb6 Mon Sep 17 00:00:00 2001 From: prashantsinalkar Date: Tue, 10 Oct 2017 12:27:19 +0530 Subject: initial commit / add all books --- 3760/CH1/EX1.28/Ex1_28.sce | 51 ++++++++++++++++++++++++++++++++++++++++++++++ 1 file changed, 51 insertions(+) create mode 100644 3760/CH1/EX1.28/Ex1_28.sce (limited to '3760/CH1/EX1.28/Ex1_28.sce') diff --git a/3760/CH1/EX1.28/Ex1_28.sce b/3760/CH1/EX1.28/Ex1_28.sce new file mode 100644 index 000000000..8202e42a4 --- /dev/null +++ b/3760/CH1/EX1.28/Ex1_28.sce @@ -0,0 +1,51 @@ +clc; +P=10000; // rated power of transformer in VA +E1=2500; // primary side voltage +E2=250; // secondary side voltage +pf=0.8; // power factor +//initialising the results of open circuit test +vo=250; // open circuit voltage +io=0.8; //no load current +po=50; // open circuit voltage +// initialising the results of open circuit test +vsc=60; // short circuit voltage +isc=3; // short circuit current +psc=45; // power dissipated in test +ifl=P/E1; // full load current on primary side +poh=psc*(ifl/isc)^2; // ohmic losses at full load current +disp('case a(1)'); +n=(1-(po+(poh/4^2))/(po+(poh/4^2)+(P*pf)/4))*100; // efficiency at 1/4 load +printf('efficiency at 1/4 load is %f percent\n',n); +disp('case a(2)'); +n=(1-(po+(poh/2^2))/(po+(poh/2^2)+(P*pf)/2))*100; // efficiency at 1/2 load +printf('efficiency at 1/2 load is %f percent\n',n); +disp('case a(3)'); +n=(1-(po+(poh/1^2))/(po+(poh/1^2)+(P*pf)/1))*100; // efficiency at full load +printf('efficiency at full load is %f percent\n',n); +disp('case a(4)'); +n=(1-(po+((poh*5^2)/4^2))/(po+((poh*5^2)/4^2)+(P*pf*5)/4))*100; // efficiency at 1*1/4 load +printf('efficiency at 5/4 load is %f percent\n',n); +// let maximum efficiency occurs at x times the rated KVA +// maximum efficiency occurs when core loss becomes equal to ohmic losses +x=sqrt(po/poh); +nm=(x*P)/1000; // VA output at maximum +nmax=(1-(2*po)/(nm*1000*pf+2*po))*100; +printf('KVA load at which maximum efficiency occurs is %f KVA\n',nm); +printf('Maximum efficiency is %f percent\n',nmax); +// from short circuit test +reh=psc/isc^2; // total resistance referred to h v side +zeh=vsc/isc; // total impedance referred to h v side +xeh=sqrt(zeh^2-reh^2); // total leakage reactance referred to h v side +er=(ifl*reh)/E1; //p u resistance +ex=(ifl*xeh)/E1; // p u reactance +vr=(er*pf+ex*sqrt(1-pf^2))*100; // p u voltage regulation +printf(' p u voltage regulation for lagging power factor is %f percent\n',vr); +dv=E2*(vr/100); // voltage drop in series impedance +v2=E2-dv; +printf('secondary terminal voltage for lagging power factor of 0.8 is %f v\n',v2); +// voltaage regulation for leading power factor +vr=(er*pf-ex*sqrt(1-pf^2))*100; // p u voltage regulation +printf(' p u voltage regulation for leading power factor is %f percent\n',vr); +dv=E2*(vr/100); // voltage drop in series impedance +v2=E2-dv; +printf('secondary terminal voltage for leading power factor of 0.8 is %f v\n',v2); -- cgit