Title :
Computational analysis of Peltier current leads
Author :
Whitlow, L.W. ; Yamamoto, A. ; Ohta, T.
Author_Institution :
Electrotech. Lab., Tsukuba, Japan
Abstract :
Many superconducting magnets require current leads to carry hundreds or thousands of amperes. Unfortunately, these current leads are the largest source of heat leakage to the liquid helium system and a large energy expense. One proposal to improve this involves the use of a segmented current lead, composed of high-temperature superconducting material (HTSC) below 77 K, copper between 77 K and 200 K, and n- or p-type thermoelectric (TE) materials between 200 K and 273 K. By limiting heat leakage to a liquid nitrogen (LN) bath, large energy savings are predicted. We present calculated solutions to the TE heat flow equations between 77 and 273 K for various hybrid Peltier current leads. We find that, the total heat leakage into the liquid nitrogen bath can be minimized to 21 W/kA maximum current. In economic terms, this represents a modest improvement over more standard LN-techniques
Keywords :
Peltier effect; heat losses; heat transfer; wires (electric); 200 to 273 K; 77 to 200 K; Cu; Cu-Bi2Te3; HTSC; Peltier current leads; computational analysis; energy expense; heat flow equations; heat leakage; high-temperature superconducting material; hybrid current leads; liquid He system; liquid N bath; segmented current lead; superconducting magnets; thermoelectric materials; Copper; Equations; Helium; Magnetic analysis; Nitrogen; Proposals; Superconducting magnets; Superconducting materials; Tellurium; Thermoelectricity;
Conference_Titel :
Thermoelectrics, 1998. Proceedings ICT 98. XVII International Conference on
Conference_Location :
Nagoya
Print_ISBN :
0-7803-4907-5
DOI :
10.1109/ICT.1998.740319
