Pulse Tube Refrigerators (PTR's) are an effective method of producing cooling at cryogenic temperatures and can be applied to a diverse range of applications where cryogenic cooling is required. e.g. GB2310486. Single or multiple stage cooling devices can be used to assist conservation of liquid cryogens. In applications like MRI, NMR and other large scale uses of superconducting magnets it is desirable to reduce the consumption of the cryogenic liquid, usually liquid Helium cooling the magnet. Other cryogenic liquids are used for high temperature superconducting magnet systems. During operation of the PTR heat is extracted from the magnet system at the low temperature heat stations (cold end) and rejected at a higher temperature heat station (warm end) through heat exchangers. The principle of operation of PTR systems is comprehensively reported in technical literature e.g. GB 2318176. The heat exchanger located at high temperature, usually operates close to room temperature. In applications such as MRI where this heat rejection is considerable and can be typically 100W in the steady state under load or increased to 1000W during cooldown, significant temperature increase is evident at this heat exchanger. The mechanism is concerned with removing the considerable heat generated in MRI applications the size of the additional cooling area is provided as observed in experiments.
In accordance with the present invention, a pulse tube refrigerator comprises a cold head, wherein the cold head comprises at least one pulse tube and at least one regenerator; the cold head having a cold end and a warm end, each end being provided with respective heat exchangers; wherein refrigerant is supplied to the cold head; and wherein the warm end heat exchanger is provided with a secondary cooling mechanism to improve the efficiency of the PTR.
In general, a substantial secondary cooling mechanism is required and this provides additional efficiency and temperature control of the warm end. Reducing the temperature of the warm end without significantly affecting the cold end temperatures directly affects the Carnot efficiency of the PTR cycle, thereby making the system more efficient.
Preferably, the secondary cooling mechanism comprises fins and an air supply, such that the cooling is provided by airflow over the fins.
Alternatively, the secondary cooling mechanism comprises an additional heat exchanger.
In order to cool the additional heat exchanger, preferably the refrigerant is fed to the additional heat exchanger before being supplied to the cold head.
This uses the high pressure (HP) refrigerant from the compressor making the cooling circuit self contained. Using only the refrigerant flow from the compressor to effect the additional cooling, enables the system to be self contained.
Alternatively, a supplementary coolant is provided for the additional heat exchanger.
Preferably, the supplementary coolant is provided for the additional heat exchanger by bleeding a small flow of gas from the compressor high pressure side through the heat exchanger and back to the low pressure side of the compressor.
The present invention enables the high temperature heat station temperature to be controlled by providing additional cooling to the warm end heat exchangers, which thereby increases the efficiency of the PTR system.
An example of a pulse tube refrigerator according the present invention will now be described with reference to the accompanying drawings in which:
In a first example of the present invention in which the temperature of the warm end heat exchangers is controlled by means of additional active cooling, a secondary cooling mechanism is provided in which a surface cools the high temperature end using forced air or natural air convection around the PTR. As shown in
In a second example of the present invention, as shown in
Alternatively, if the main refrigerant from the compressor is not passed through the heat exchanger, but a supplementary coolant, water for example is used instead, then a separate flow circuit (not shown) is used to pass the fluid around-the heat exchanger 17. Any suitable fluid can be used. One such arrangement is to bleed a small amount of high pressure gas from the compressor through the heat exchanger and direct back to the compressor low pressure side entering the PTR.
The methods outlined here describe how a suitable supplementary heat exchanger is fixed as an integral or additive feature to the high temperature heat exchangers on a two stage PTR. The methods are generally applicable to a PTR with any number of stages.
Number | Date | Country | Kind |
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0301156.6 | Jan 2003 | GB | national |
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5791149 | Dean | Aug 1998 | A |
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6644038 | Acharya et al. | Nov 2003 | B1 |
Number | Date | Country |
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2310486 | Aug 1997 | GB |
Number | Date | Country | |
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20040221586 A1 | Nov 2004 | US |