A study of corona loss and electric field distribution in bundle conductors.

Jue, Shao-man.

January 1971

No description available.

Electricity

Corona (Electricity)

Electric conductors

A MATLAB based analysis tool for clearance and thermal violations in transmission power lines

Mabuza, Ndumiso Simon

January 2016

A research report submitted to the faculty of Engineering and the Built Environment, of the University of the Witwatersrand, Johannesburg, in partial fulfilment of the requirements for the degree of Master of Science in Engineering Johannesburg 2014 / Clearances are an important aspect of High Voltage (HV) transmission line design, construction and maintenance. A software tool that combines clearance violation analysis and optimum loading operating conditions for power lines could save power utilities the capital cost of refurbishing transmission power lines that marginally exceed maximum power line clearance distances. This can be achieved by operating the power lines at an optimum amperage level for any given set of weather conditions. This research project proposes a low cost MATLAB® based software tool that detects clearance violations and determines operational limits on transmission power lines using prevalent weather conditions as well as the power line amperage. Various power lines around the states of Missouri and Illinois in the United States of America are analysed to test the viability and functionality of the software. In order to validate the accuracy of the program, the results obtained were compared to results from PLSCADD ®. Key Words: conductor, clearance, sag, software, temperature / MB2016

MATLAB

Electric lines

Electric conductors

Software engineering

Optimization of bundle conductor configuration based upon the maximum surface voltage gradient

Torelli, Lido M. A.

January 1974

No description available.

Electric conductors.

Electric power distribution.

Optimization.

The effect of thermal-mechanical processing on the physical and mechanical properties of Al-Fe-Co electrical conductor alloy

Chia, Enrique Calixto

08 1900

No description available.

Aluminum-iron-copper alloys

Electric conductors

Transient temperature distributions in overhead fiber-optic ground wires

Wells, M. Glenn

05 1900

No description available.

Electric conductors

Overhead electric lines

Heat Conduction

Online in-situ estimation of network parameters under intermittent excitation conditions

Taylor, Jason Ashley, Halpin, S. Mark,

January 2008

Dissertation (Ph.D.)--Auburn University, / Abstract. Vita. Includes bibliographic references (p.150-157).

Optimization of bundle conductor configuration based upon the maximum surface voltage gradient

Torelli, Lido M. A.

January 1974

No description available.

Electric conductors.

Optimization.

Electric power distribution.

New aspects of physics in conjugated systems

Wong-Kuen-Fat, John Erik

January 1998

No description available.

547

Electromagnetic wave propagation on helical conductors

January 1951

Samuel Sensiper. / Based on the author's (Sc. D.) thesis, Dept. of Electrical Engineering, Massachusetts Institute of Technology, 1951.

TK7855.M41 R43 no.194

Electromagnetic waves

Electric conductors

Dynamic characteristics of bare conductors.

Eshiemogie, Ojo Evans.

January 2011

The dynamic characteristic of transmission line conductors is very important in designing and constructing a new line or upgrading an existing one. This concept is an impediment to line design and construction because it normally determines the tension at which the line is strung and this in respect affects the tower height and the span length. Investigations into the phenomenon of mechanical oscillation of power line conductors have been extensively looked into by many researchers using concepts from mechanics and aerodynamics to try and predict the conductor dynamic behaviour. Findings have shown that precise prediction of conductor windinduced vibration is very difficult i.e. non-linearity. Over the years, various analytical models have been developed by researchers to try and predict the mechanical vibration of transmission line conductors. The first part of this dissertation considers the analysis of the model describing the transverse vibration of a conductor as a long, slender, simply supported beam, isotropic in nature and subjected to a concentrated force. The solution of this beam equation was used to obtain the conductor natural frequencies and mode shapes. Conductor self-damping was obtained by the introduction of both external and internal damping models into the equation of motion for the beam. Next, also using the same beam concept was the application of the finite element method (FEM) for the dynamic analysis of transmission line conductors. A finite element formulation was done to present a weak form of the problem; Galerkin‟s method was then applied to derive the governing equations for the finite element. Assembly of these finite element equations, the equation of motion for the transverse vibration of the conductor is obtained. A one dimensional finite element simulation was done using ABAQUS software to simulate its transverse displacement. The eigenvalues and natural frequencies for the conductors were calculated at three different tensions for two different conductors. The damping behaviour of the conductors was evaluated using the proportional damping (Rayleigh damping) model. The results obtained were then compared with the results from the analytical model and the comparison showed a very good agreement. An electrical equivalent for the conductor was developed based on the concept of mechanicalelectrical analogy, using the discrete simply supported beam model. The developed electrical equivalent circuit was then used to formulate the transfer function for the conductor. Matlab software was used to simulate the free response of the developed transfer function. Finally, the experimental study was conducted to validate both the analytical model and the FEM. Tests were done on a single span conductor using two testing methods i.e. free and force vibration. The test results are valid only for Aeolian vibration. From the test results the conductor‟s natural frequencies and damping were determined. The experimental results, as compared with the analytical results were used to validate the finite element simulation results obtained from the ABAQUS simulation. / Thesis (M.Sc.Eng.)-University of KwaZulu-Natal, Durban, 2011.

Electric conductors.

Electric lines.

Electric power transmission.

Theses--Electrical engineering.