ECE4762011_Lect6

# ECE4762011_Lect6 - ECE 476 POWER SYSTEM ANALYSIS Lecture 6...

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Lecture 6 Development of Transmission Line Models Professor Tom Overbye Department of Electrical and Computer Engineering ECE 476 POWER SYSTEM ANALYSIS

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2 Announcements For lectures 5 through 7 please be reading Chapter 4 we will not be covering sections 4.7, 4.11, and 4.12 in detail HW 2 is 4.10 (positive sequence is the same here as per phase), 4.18, 4.19, 4.23. Use Table A.4 values to determine the Geometric Mean Radius of the wires (i.e., the ninth column). Due September 15 in class. “Energy Tour” opportunity on Oct 1 from 9am to 9pm. Visit a coal power plant, a coal mine, a wind farm and a bio-diesel processing plant. Sponsored by Students for Environmental Concerns. Cost isn’t finalized, but should be between \$10 and \$20. Contact Rebecca Marcotte at [email protected] for more information or to sign up.
3 Two Conductor Line Inductance Key problem with the previous derivation is we assumed no return path for the current. Now consider the case of two wires, each carrying the same current I, but in opposite directions; assume the wires are separated by distance R. R Creates counter- clockwise field Creates a clockwise field To determine the inductance of each conductor we integrate as before. However now we get some field cancellation

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4 Two Conductor Case, cont’d R R Direction of integration Rp Key Point: As we integrate for the left line, at distance 2R from the left line the net flux linked due to the Right line is zero! Use superposition to get total flux linkage. 0 0 left For distance Rp, greater than 2R, from left line ln ln 2 ' 2 Rp Rp R I I r R μ λ π - = - ÷ Left Current Right Current
5 Two Conductor Inductance ( 29 0 left 0 0 0 0 Simplifying (with equal and opposite currents) ln ln 2 ' ln ln ' ln( ) ln 2 ln ln 2 ' ln as Rp 2 ' ln H/m 2 ' left Rp Rp R I r R I Rp r Rp R R R Rp I r Rp R R I r R L r μ λ π - = - ÷ ÷ = - - - + = + ÷ - = → ∞ ÷ = ÷

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6 Many-Conductor Case Now assume we now have k conductors, each with current i k , arranged in some specified geometry. We’d like to find flux linkages of each conductor. Each conductor’s flux
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## This note was uploaded on 11/17/2011 for the course ECE 476 taught by Professor Overbye,t during the Fall '08 term at University of Illinois, Urbana Champaign.

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ECE4762011_Lect6 - ECE 476 POWER SYSTEM ANALYSIS Lecture 6...

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