AN ANALYTICAL ALGORITHM TO DETERMINE ALLOWABLE AMPACITIES OF HORIZONTALLY INSTALLED RECTANGULAR BUS BARS

Abstract

The main objective of this paper is to propose an algorithm for the determination of the allowable ampacities of single rectangular-section bus bars without the occurrence of correction factors. Without correction factors, the ampacity computation of the copper and aluminium bus bars is fully automatized. The analytical algorithm has been implemented in a computer program code that along with the allowable ampacity can compute the bus bar temperature and the individual heat transfer coefficient for each side of the bus bar, as well as their corresponding power losses. Natural and forced convection correlations for rectangular bus bars are applied. Effects of the solar radiation and radiation heat losses from the bus bar surface are taken into consideration as well. The finite element method (FEM) has been used for the linear/non-linear steady-state thermal analysis, i.e. for validation of the analytical algorithm. All FEM-based numerical computations were carried out using the COMSOL Heat Transfer Module.

Dates

  • Submission Date2014-08-29
  • Revision Date2014-10-24
  • Acceptance Date2014-10-27
  • Online Date2014-11-08

DOI Reference

10.2298/TSCI140829127K

References

  1. ***, Chapter 13: Conductor materials and accessories for switchgear installations, in: ABB switchgear manual, 12th edition, ABB AG, Mannheim, Germany, 2007
  2. Heuck, K., Dettmann, K.-D., Schulz, D., Elektrische Energieversorgung: Erzeugung, Übertragung und Verteilung elektrischer Energie für Studium und Praxis, 9. aktualisierte und korrigierte Auflage, Springer Vieweg, Deutschland, 2013
  3. Coneybeer, R. T., Black, W. Z., Bush, R. A., Steady-state and transient ampacity of bus bar, IEEE Transactions on Power Delivery 9 (1994), 4, pp. 1822-1829.
  4. Klimenta, D., Perović, B., Anđelković, D., Todorović, A., An analytical algorithm to determine the continuously permissible loads of horizontal bus bars with a rectangular cross-section, Proceedings, XII International Scientific - Professional Symposium INFOTEH Jahorina 2013, Bosnia and Herzegovina, 2013, Vol. 12, pp. 148-153.
  5. Klimenta, D., Termički procesi u elektroenergetici: opšti deo (in English: Heat transfer in power engineering: general part), Faculty of Technical Sciences in Kosovska Mitrovica, K. Mitrovica, Serbia, 2012
  6. Incropera, F. P., DeWitt, D. P., Bergman, T. L., Lavine, A. S., Fundamentals of heat and mass transfer, 6th edition, John Wiley & Sons Inc., New York, USA, 2007
  7. Arpaci, V. S., Selamet, A., Kao, S.-H., Introduction to Heat Transfer, Prentice Hall Inc., New Jersey, USA, 2000
  8. Holman, J. P., Heat transfer, 8th edition, McGraw-Hill International Editions, Mechanical Engineering Series, Singapore, 1999
  9. Kreith, F., Manglik, R. M., Bohn, M. S., Principles of heat transfer, 7th edition, Cengage Learning, USA, 2011
  10. Yovanovich, M. M., Teertstra, P., Laminar forced convection modeling of isothermal rectangular plates, Journal of Thermophysics and Heat Transfer 15 (2001), 2, pp. 205-211.
  11. ***, Chapter 13: Bus conductor design and application, in: Aluminum electrical conductor handbook, 3rd edition, Aluminum Association Inc., Washington D.C., USA, 1989