Comparison of Air-Gap Thermal Models for MV Power Cables Inside Unfilled Conduit

This paper studies the effects of natural convection on longitudinal heat transfer and on the air-gap thermal resistance of cables inside conduit installations. Oversimplification of the physical placement of cables inside unfilled conduits is the main shortcoming in currently available thermal models. The study closely investigates the share of each heat-transfer mechanism and the effect of the natural placement of trefoil cables inside the conduit. Measurements from various installation setups are investigated for their impact on heat transfer. The installation-dependent convection correlations adopted in this study have broader applications for the dynamic thermal rating of underground cables inside conduit, troughs, and tunnels. Laboratory measurements are compared with numerical solutions from the IEC 60287 standards, Electra 143 methods, and FEA simulations.

[1]  K. Hollands,et al.  ANALYSIS OF HEAT TRANSFER BY NATURAL CONVECTION (OR FILM CONDENSATION) FOR THREE DIMENSIONAL FLOWS , 1978 .

[2]  B. M. Weedy,et al.  The Current Carrying Capacity of Power Cables in Tunnels , 1973 .

[3]  G. Anders,et al.  Increasing ampacity of cables by an application of ventilated pipes , 2004, Conference Record of the 2004 IEEE Industry Applications Conference, 2004. 39th IAS Annual Meeting..

[4]  Robert John Millar A comprehensive approach to real time power cable temperature prediction and rating in thermally unstable environments , 2006 .

[5]  Ranganathan Kumar,et al.  Laminar thermal convection between vertical coaxial isothermal cylinders , 1991 .

[6]  David Payne,et al.  Rating Independent Cable Circuits in Forced-Ventilated Cable Tunnels , 2010, IEEE Transactions on Power Delivery.

[7]  George J. Anders Rating of cables on riser poles, in trays, in tunnels and shafts-a review , 1996 .

[8]  Andrea Michiorri,et al.  Dynamic thermal rating and active control for improved distribution network utilisation , 2010 .

[9]  M. H. McGrath,et al.  The calculation of the temperature rise and load capability of cable systems , 1957, Transactions of the American Institute of Electrical Engineers. Part III: Power Apparatus and Systems.

[10]  K.G.T. Hollands,et al.  A General Method of Obtaining Approximate Solutions to Laminar and Turbulent Free Convection Problems , 1975 .

[11]  Y. T. Tsui,et al.  On Heat Transfer Between Cable and Its Surrounding Pipe or Duct Wall , 1983, IEEE Transactions on Power Apparatus and Systems.

[12]  G.J. Anders,et al.  Derating factor for cable crossings with consideration of longitudinal heat flow in cable screen , 2004, IEEE Transactions on Power Delivery.

[13]  K.F. Schoch Rating Of Electric Power Cables (Book Review) , 1998, IEEE Electrical Insulation Magazine.

[14]  K. Terpager Andersen,et al.  Theoretical considerations on natural ventilation by thermal buoyancy , 1995 .

[15]  S. Boetcher Natural Convection Heat Transfer From Inclined Cylinders , 2014 .

[16]  D. A. Douglass,et al.  Real-time monitoring and dynamic thermal rating of power transmission circuits , 1996 .

[17]  E. Dorison CURRENT RATING OF CABLES INSTALLED IN DEEP OR VENTI LATED TUNNELS , 2012 .

[18]  W. Z. Black,et al.  Refinements to the Neher-McGrath model for calculating the ampacity of underground cables , 1996 .

[19]  Andrzej Napieralski,et al.  Advanced modeling techniques for dynamic feeder rating systems , 2002 .

[20]  G. J. Anders,et al.  New Approach to Ampacity Evaluation of Cables in Ducts Using Finite Elemet Technique , 1987, IEEE Transactions on Power Delivery.

[21]  G J Anders,et al.  Ampacity Calculations for Cables in Shallow Troughs , 2010, IEEE Transactions on Power Delivery.