TY - GEN
T1 - Mixed-refrigerant joule-thomson (MR JT) mini-cryocoolers
AU - Tzabar, Nir
N1 - Publisher Copyright:
© 2014 AIP Publishing LLC.
PY - 2014
Y1 - 2014
N2 - This paper presents the progress in our ongoing research on Mixed-Refrigerant (MR) Joule-Thomson (JT) cryocoolers. The research begun by exploring different MRs and testing various compressors: oil-lubricated and oil-free, reciprocating and linear, custom-made and commercial. Closed-cycle JT cryocoolers benefit from the fact that the compressor might be located far from the cold-end and thus there are no moving parts, no vibrations, and no heat emission near the cold-end. As a consequence, the compressor may be located where there are no severe size limitations, its heat can be conveniently removed, and it can be easily maintained. However, in some applications there is still a demand for a small compressor to drive a JT cryocooler although it is located far from the cooled device. Recently, we have developed a miniature oil-free compressor for MR JT cryocoolers that weighs about 700 g and its volume equals about 300c. The cryocooler operates with a MR that contains Ne, N 2 , and Hydrocarbons. This MR has been widely investigated with different compressors and varying operating conditions and proved to be stable. The current research investigates the performances of MR JT mini-cryocooler operating with the MR mentioned above, driven with our miniature compressor, and a cold-finger prototype. A Dewar with heat load of about 230 mW is cooled to about 80 K at ambient temperatures between 0°C and 40°C. The experimental results obtained are stable and demonstrate the ability to control the cooling temperature by changing the rotation speed of the compressor.
AB - This paper presents the progress in our ongoing research on Mixed-Refrigerant (MR) Joule-Thomson (JT) cryocoolers. The research begun by exploring different MRs and testing various compressors: oil-lubricated and oil-free, reciprocating and linear, custom-made and commercial. Closed-cycle JT cryocoolers benefit from the fact that the compressor might be located far from the cold-end and thus there are no moving parts, no vibrations, and no heat emission near the cold-end. As a consequence, the compressor may be located where there are no severe size limitations, its heat can be conveniently removed, and it can be easily maintained. However, in some applications there is still a demand for a small compressor to drive a JT cryocooler although it is located far from the cooled device. Recently, we have developed a miniature oil-free compressor for MR JT cryocoolers that weighs about 700 g and its volume equals about 300c. The cryocooler operates with a MR that contains Ne, N 2 , and Hydrocarbons. This MR has been widely investigated with different compressors and varying operating conditions and proved to be stable. The current research investigates the performances of MR JT mini-cryocooler operating with the MR mentioned above, driven with our miniature compressor, and a cold-finger prototype. A Dewar with heat load of about 230 mW is cooled to about 80 K at ambient temperatures between 0°C and 40°C. The experimental results obtained are stable and demonstrate the ability to control the cooling temperature by changing the rotation speed of the compressor.
KW - Closed cycle cryocooling
KW - Cryocooler
KW - Joule-thomson
KW - Mixed refrigerant
UR - http://www.scopus.com/inward/record.url?scp=85063829488&partnerID=8YFLogxK
U2 - 10.1063/1.4860695
DO - 10.1063/1.4860695
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AN - SCOPUS:85063829488
T3 - AIP Conference Proceedings
SP - 148
EP - 154
BT - Advances in Cryogenic Engineering - Transactions of the Cryogenic Engineering Conference - CEC, Volume 59
A2 - Breon, Susan
A2 - Marquardt, Jennifer
A2 - Peterson, Thomas
A2 - DiPirro, Michael
A2 - Pfotenhauer, John
A2 - Demko, Jonathan
A2 - Fesmire, James
A2 - Klebaner, Arkadiy
A2 - Yuan, Sidney
A2 - Zeller, Al
A2 - Kittel, Peter
A2 - Nellis, Gregory
A2 - Zagarola, Mark
T2 - 2013 Joint Cryogenic Engineering and International Cryogenic Materials Conferences, CEC/ICMC 2013
Y2 - 17 June 2013 through 21 June 2013
ER -