Experimental Study of Linear Motor Direct-Driven Thermocompressor

Xiao Hua Wu; Lu Wei Yang; Jun Ling Yang; Wen Ye Lin

doi:10.4028/www.scientific.net/AMR.732-733.1147

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HomeAdvanced Materials ResearchAdvanced Materials Research Vols. 732-733Experimental Study of Linear Motor Direct-Driven...

Experimental Study of Linear Motor Direct-Driven Thermocompressor

Abstract:

A prototype thermocompressor driven by linear motor was setup and experimental tudied. Peak-peak pressure in the system was influenced by the regenerator, the heating temperature and the gap clearance between piston and cylinder. The optimal frequency of the system was determined by spring constant and total mass of piston, shaft and moving iron. The peak-peak pressure was found to change little with filling pressure when the heating temperature was lower than 250°C, employing with N2 or He4 as the working substance. But when the heating temperature was higher than 250°C, peak-peak pressure increased with filling pressure. Besides, Helium4 was found to perform better than Nitrogen as the working substance. For heating temperature of 650°C and cooling temperature of 40°C, the peak-peak pressure could reach 0.412MPa with pressure ratio of 1.13 when the filling pressure was 2.2MPa, which could be used to drive the pulse tube crycooler (PTC).

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Periodical:

Advanced Materials Research (Volumes 732-733)

Pages:

1147-1152

DOI:

https://doi.org/10.4028/www.scientific.net/AMR.732-733.1147

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Online since:

August 2013

Authors:

Xiao Hua Wu, Lu Wei Yang, Jun Ling Yang, Wen Ye Lin

Keywords:

Experimental Study, Linear Motor, Pulse Tube Crycooler (PTC), Thermocompressor

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