Performance improvement of multi-stage pulse tube cryocoolers with a self-precooled pulse tube.

Author(s) : QIU L. M., ZHI X. Q., HAN L., et al.

Type of article: Article

Summary

Reducing the pulse tube losses is significant for improving the cooling performance of pulse tube cryocoolers (PTCs) in particular for multi-stage ones, although ignored to a certain extent. A simple method called self-precooled pulse tube for multi-stage PTCs is comprehensively studied in order to reduce the entropy flow inside the pulse tube. Different from the complex multi-bypass or extra cryocooler or cryogens for precooling, the key of the idea is to directly precool some part of the lower stage pulse tube by using a small amount of cooling power from the upper stage through a thermal bridge. A two-stage separate Stirling PTC was chosen to demonstrate the effects of self-precooled pulse tube. Theoretical calculation showed that both the precooling temperature and position of the pulse tube affected the performance of the cryocooler. The experiment results showed that the cooling performance of the second stage with self-precooled pulse tube was remarkably improved as the bottom temperature decreased from 26.60 K to 18.02 K. The cooling power was notably increased with minor performance reduction of the first stage. By further optimizing the operation parameters, a no-load temperature of 15.87 K was achieved, which is the lowest temperature ever obtained by a two-stage Stirling PTC with only an inertance shifter. The study proves that the precooled pulse tube can help hot end heat exchanger reject the heat inside pulse tube, reduce the heat losses of the cold end and consequently improve the cooling performance of the cryocooler.

Details

  • Original title: Performance improvement of multi-stage pulse tube cryocoolers with a self-precooled pulse tube.
  • Record ID : 30005578
  • Languages: English
  • Source: Cryogenics - vol. 52 - n. 10
  • Publication date: 2012/10
  • DOI: http://dx.doi.org/10.1016/j.cryogenics.2012.05.002

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