A three-phase, 50Hz transmission line with a length of "240" is given. It has values of “27” MVA, 0.8 reverse power coefficient and phase voltage “134” kV (phase-phase) for the end of line. Transmission line conductors are placed “3.2” meters apart. The conductors are known to have a resistance of 0.11ohm/km and a diameter of 1.6cm. Neglecting the leaks and using the π equivalent circuit; ( ε0=8.854*10^(-12) F/m, μ0=4*π*10^(-7) H/m) 1) Find the total impedance value of the line, the end of line current, the line voltage at the end of the line, the line head phase and the line beginning line voltage?

A three-phase, 50Hz transmission line with a length of "240" is given. It has values of “27” MVA, 0.8 reverse power coefficient and phase voltage “134” kV (phase-phase) for the end of line. Transmission line conductors are placed “3.2” meters apart. The conductors are known to have a resistance of 0.11ohm/km and a diameter of 1.6cm. Neglecting the leaks and using the π equivalent circuit; ( ε0=8.85410^(-12) F/m, μ0=4π*10^(-7) H/m) 1) Find the total impedance value of the line, the end of line current, the line voltage at the end of the line, the line head phase and the line beginning line voltage?

Power System Analysis and Design (MindTap Course List)

6th Edition

ISBN:9781305632134

Author:J. Duncan Glover, Thomas Overbye, Mulukutla S. Sarma

Publisher:J. Duncan Glover, Thomas Overbye, Mulukutla S. Sarma

Chapter4: Transmission Line Parameters

Section: Chapter Questions

Problem 4.27P: Figure 4.34 shows double-circuit conductors' relative positions in segment I of transposition of a...

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Concept explainers

Short Transmission Line

A short transmission line is a transmission line that has a length less than 80 kilometers, an operating voltage level of less than 20 kV, and zero capacitance effect.

Power Flow Analysis

Power flow analysis is a topic in power engineering. It is the flow of electric power in a system. The power flow analysis is preliminary used for the various components of Alternating Current (AC) power, such as the voltage, current, real power, reactive power, and voltage angles under given load conditions and is often known as a load flow study or load flow analysis.

Complex Form

A power system is defined as the connection or network of the various components that convert the non-electrical energy into the electric form and supply the electric form of energy from the source to the load. The power system is an important parameter in power engineering and the electrical engineering profession. The powers in the power system are primarily categorized into two types- active power and reactive power.

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Step 1: The parameter of the three phase transmission line are given as

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Step 2: Calculation of the Inductance per km

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Step 3: Calculation of the Capacitance per km

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Step 4: Calculation of Total ohmic resistance of line

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Step 5: Calculation of Total Inductive Reactance of line

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Step 6: Total Impedance of the transmission line and calculation of load end line current

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Step 7: Calculation of load end line voltage

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Step 8: Calculation of line current

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Step 9: Calculation of line beginning line voltage

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