From b1f5c3f8d6671b4331cef1dcebdf63b7a43a3a2b Mon Sep 17 00:00:00 2001 From: priyanka Date: Wed, 24 Jun 2015 15:03:17 +0530 Subject: initial commit / add all books --- 1820/CH5/EX5.15/Example5_15.sce | 63 +++++++++++++++++++++++++++++++++++++++++ 1 file changed, 63 insertions(+) create mode 100755 1820/CH5/EX5.15/Example5_15.sce (limited to '1820/CH5/EX5.15/Example5_15.sce') diff --git a/1820/CH5/EX5.15/Example5_15.sce b/1820/CH5/EX5.15/Example5_15.sce new file mode 100755 index 000000000..95fe702ba --- /dev/null +++ b/1820/CH5/EX5.15/Example5_15.sce @@ -0,0 +1,63 @@ +// ELECTRIC POWER TRANSMISSION SYSTEM ENGINEERING ANALYSIS AND DESIGN +// TURAN GONEN +// CRC PRESS +// SECOND EDITION + +// CHAPTER : 5 : UNDERGROUND POWER TRANSMISSION AND GAS-INSULATED TRANSMISSION LINES + +// EXAMPLE : 5.15 : +clear ; clc ; close ; // Clear the work space and console + +// GIVEN DATA +L = 50 ; // length of transmission line in km +P_l_oh = 820 ; // Power loss at peak load for overhead transmission line in kW/km +P_l_g = 254 ; // Power loss at peak load for gas insulated transmission line in kW/km +cost_kwh = 0.10 // cost of electric energy in $ per kWh +lf_ann = 0.7 ; // Annual load factor +plf_ann = 0.7 ; // Annual Power loss factor +h_yr = 365*24 ; // Time in Hours for a year +total_invest = 200000000 ; // Investment cost of GIL in $ ( for case (j) ) + +// CALCULATIONS +// For case (a) +Power_loss_OHline = P_l_oh * L ; // Power loss of overhead line at peak load in kW + +// For case (b) +Power_loss_GILline = P_l_g * L ; // Power loss of gas-insulated transmission line at peak load in kW + +// For case (c) +energy_loss_OH = Power_loss_OHline * h_yr ; // Total annual energy loss of OH line at peak load in kWh/yr + +// For case (d) +energy_loss_GIL = Power_loss_GILline * h_yr ; // Total annual energy loss of GIL at peak load in kWh/yr + +// For case (e) +energy_ann_OH = lf_ann * energy_loss_OH ; // Average energy loss of OH line at peak load in kWh/yr + +// For case (f) +energy_ann_GIL = lf_ann * energy_loss_GIL ; // Average energy loss of GIL line at peak load in kWh/yr + +// For case (g) +cost_ann_OH = cost_kwh * energy_ann_OH ; // Average annual cost of losses of OH line in $ per year + +// For case (h) +cost_ann_GIL = cost_kwh * energy_ann_GIL ; // Average annual cost of losses of GIL line in $ per year + +// For case (i) +P_loss_ann = cost_ann_OH - cost_ann_GIL ; // Annual resultant savings of losses per yr + +// For case (j) +break_period = total_invest/P_loss_ann ; // Payback period if GIL alternative period is selected + +// DISPLAY RESULTS +disp("EXAMPLE : 5.15 : SOLUTION :-") ; +printf("\n (a) Power loss of Overhead line at peak load , (Power loss)_OH_line = %d kW \n",Power_loss_OHline) ; +printf("\n (b) Power loss of Gas-insulated transmission line , (Power loss)_GIL_line = %d kW \n",Power_loss_GILline) ; +printf("\n (c) Total annual energy loss of Overhead transmission line at peak load = %.4e kWh/yr \n",energy_loss_OH) ; +printf("\n (d) Total annual energy loss of Gas-insulated transmission line at peak load = %.5e kWh/yr \n",energy_loss_GIL); +printf("\n (e) Average energy loss of Overhead transmission line = %.5e kWh/yr \n",energy_ann_OH); +printf("\n (f) Average energy loss of Gas-insulated transmission line at peak load = %.5e kWh/yr \n",energy_ann_GIL); +printf("\n (g) Average annual cost of losses of Overhead transmission line = $ %.5e/yr \n",cost_ann_OH); +printf("\n (h) Average annual cost of losses of Gas-insulated transmission line = $ %.5e/yr \n",cost_ann_GIL); +printf("\n (i) Annual resultant savings in losses using Gas-insulated transmission line = $ %.6e/yr \n",P_loss_ann); +printf("\n (j) Breakeven period when GIL alternative is selected = %.1f years \n",break_period); -- cgit