Title :
Thermal simulation of bionic transpiration heat pipe system for high-power LED
Author :
Yongtao Liu ; Kai Dong ; Tao Dong
Author_Institution :
IMST-Dept. of Micro- & Nanosyst. Technol., Buskerud & Vestfold Univ. Coll., Kongsberg, Norway
Abstract :
Light-emitting diodes (LED) has been developing rapidly during recent years due to the advancement of technology driven by the global demand of reducing carbon dioxide emission to the atmosphere. Meanwhile, various kinds of corresponding LED products has been generated and widely used in many fields, e.g.. However, how to improve the luminous efficiency is the challenge in LED industry. And the problem is closely related to PN junction cooling, which becomes more prominent. To solve this problem, a new type of heat dissipation structure is proposed in this paper, which uses a new kind of heat pipe - bionic transpiration heat pipe with high thermal efficiency. In addition, the simulation used ANSYS Icepak on basis of this model will show the advantages of the system we design in details. Furthermore, the application of the present design can further broaden the application fields of LED in IT, military, machinery,aviation and so forth.
Keywords :
air pollution control; cooling; heat pipes; light emitting diodes; transpiration; ANSYS Icepak; PN junction cooling; bionic transpiration heat pipe system; carbon dioxide emission reduction; heat dissipation structure; high-power LED; light-emitting diodes; thermal simulation; Heat sinks; Heat transfer; Junctions; Light emitting diodes; Mathematical model; Resistance heating; ANSYS Icepak; Bionic Transpiration Heat Pipe; High Power LED; Simulation;
Conference_Titel :
Mechatronics - Mechatronika (ME), 2014 16th International Conference on
Conference_Location :
Brno
Print_ISBN :
978-80-214-4817-9
DOI :
10.1109/MECHATRONIKA.2014.7018344
