FIELD INTEGRATED PULSE TUBE CRYOCOOLER WITH SADA Il COMPATIBILITY

TECHNICAL FIELD

The present invention relates to a coldfinger cryocooler for cooling electronic components such as infrared sensors. More particularly, the present invention relates to a unitary pulse tube cryocooler that is configured as a drop-in replacement for a Stirling displacer-type expander in a coldfinger cryocooler.

BACKGROUND OF THE INVENTION

Many electronic components (e.g., infrared sensors) must be cooled to cryogenic temperatures to operate. Infrared sensors and associated electronics are often contained in a vacuum sealed housing commonly known as a Dewar assembly. The cryocooler assembly includes a "coldfinger" which has heat exchangers defining a cold end and an opposite warm end, and an expander removably positioned and extending between the warm and cold ends of the coldfinger. The expander includes a regenerator which operates to transfer heat from the cold end region to the warm end region of the expander while the cryocooler operates.

Standard Advanced Dewar Assembly Il (SADA II) is a military standard that requires a coldfinger type cryocooler to have a specific geometry to allow "in-the field" integration into a Dewar assembly (e.g. at the Dewar/sensor manufacturer's facility). The expander must therefore be unitary to allow it to be "dropped-in" to the coldfinger by the Dewar/sensor manufacturer. Dewar/sensor manufacturers therefore often require cryocooler manufacturers to provide cryocoolers that are compliant with the SADA Il standard.

One technology used in cryocoolers is known as a split Stirling cryocooler which comprises a rigid cylinder with an internal moving regenerator component that oscillates through a fixed quantity of working gas within the cylinder in response to pressure oscillations from an external

compressor. As the regenerator component moves, gas is alternately compressed and expanded with the heat of compression being transferred from a "cold" heat exchanger located at the cold end of the expander to "hot" heat exchangers located at the warm end of the expander. When the cryocooler is installed in a Dewar assembly, the cold end is positioned closely adjacent or against the sensor to be cooled. Heat is removed from the cryocooler system at the "hot" heat exchangers in the warm end region of the pulse tube expander.

The Stirling regenerator and cold end heat exchanger are encased in a rigid cylinder to provide a unitary, self contained, cylindrical expander. The "warm end" of the expander attaches to the cooling head which includes the appropriate connections and tubing leading to a cryocooler compressor and buffer. The "cold end" of the expander extends outwardly therefrom and is inserted into the SADA Il coldfinger which thereby completes the cryocooler assembly for shipment to the Dewar/sensor manufacturer. The coldfinger closes off the cryocooler unit to the ambient allowing the cryocooler unit to be charged with an inert gas which keeps the cryocooler clean during handling and shipment to the Dewar/sensor manufacturer.

It is common practice for the Dewar/sensor manufacturer to have already welded a SADA Il coldfinger into their Dewar housing. Thus, upon receiving the cryocooler from the cryocooler manufacturer, the Dewar/sensor manufacturer must first remove the SADA Il coldfinger from the cryocooler unit as shipped prior to attachment to the coldfinger/Dewar assembly. With the "shipped" SADA Il coldfinger removed, the Dewar/sensor manufacturer inserts the now exposed expander cold end into the SADA Il coldfinger which has been previously welded into the Dewar. The SADA Il coldfinger which came attached to the cryocooler is shipped back to the cryocooler manufacturer for re-use.

While Stirling type expanders benefit from the fact they are unitary, the fact that their regenerator is a moving component is undesirable in that the movement can create unwanted system vibrations and potential mechanical failure points. It would therefore be desirable to have a unitary pulse tube

expander with no moving parts that can act as a drop-in replacement for Stirling expanders in a SADA Il coldfinger.

SUMMARY OF THE INVENTION

The present invention addresses the above need by providing a uniquely configured pulse tube expander with no moving parts which may be used as a drop-in replacement for a Stirling type expander in a SADA Il coldfinger. By "drop-in replacement", it is meant that the pulse tube expander of the present invention may removably attach to a SADA Il coldfinger in the same manner and with the same ease as a Stirling type expander. Before the present invention, this has not been possible due to the fact that pulse tube expanders are typically "built-up" and not available in unitary form.

The inventive pulse tube expander includes a cylindrical pulse tube having an inner diameter that defines a central bore and an outer diameter upon which a regenerator (e.g., comprising a stack of punched discs) is mounted. The regenerator is mounted in contacting, coaxial relationship about the pulse tube.

A regenerator sleeve is placed in preferably coaxial relationship about the regenerator. The pulse tube expander further includes a cold cap mounted to a cold end of the pulse tube which is located opposite a warm end thereof. The cold cap covers the opening defined by the edges of the regenerator sleeve to enclose the regenerator and tube and thereby form a rigid, cylindrically shaped pulse tube body having outer surfaces defined by the regenerator sleeve, the cold cap, and the warm end region of the expander to which the pulse tube is connected. Thus, a unitary, rigid, pulse tube expander is formed for drop-in insertion into a SADA Il coldfinger.

The pulse tube expander of the present invention may thus operate as a drop-in replacement for a Stirling type expander in a coldfinger in the field. The functionality of field integration, together with no moving parts and adherence to mechanical tolerances specified by the military standard SADA

II, renders the pulse tube expander of the present invention as a desirable drop-in replacement for Stirling type expanders in SADA Il coldfingers and Dewar assemblies.

BRIEF DESCRIPTION OF THE DRAWINGS

The present invention will be better understood by referring to the drawings wherein;

FIG. 1 is a cross sectional view of a prior art SADA Il coldfinger

FIG. 2 is a cross sectional view of a prior art Stirling expander;

FIG. 3 is a cross sectional view the prior art Stirling expander of FIG. 2 incorporated into the SADA Il coldfinger of FIG. 1 and Dewar assembly;

FIG. 4 is a cross sectional view of an embodiment of a pulse tube expander in accordance with an embodiment of the present invention; and

FIG. 5 is a cross sectional view of the pulse tube expander of FIG. 4 incorporated into a SADA Il coldfinger and Dewar assembly.

DETAILED DESCRIPTION OF A PREFERRED EMBODIMENT OF THE INVENTION

Referring now to the drawings, there is seen in FIG. 1 a prior art SADA Il coldfinger 10 having a warm end 12 and a cold end cap 14. The SADA Il coldfinger is configured with SADA Il military standard dimensions to permit attachment to an expander such as the prior art Stirling expander 20 seen in FIGS. 2 and 3. As explained above, the Dewar/sensor manufacturer typically welds a SADA Il coldfinger 10 to the Dewar 30 adjacent the electronics 32 to be cooled (Fig. 3). Upon receiving the cryocooler from the cryocooler manufacturer, the Dewar/sensor manufacturer removes the SADA Il coldfinger which was shipped with the cryocooler. With the SADA Il coldfinger

thus removed, the now exposed expander is then inserted into the SADA Il coldfinger in the Dewar 30

As known to those skilled in the art, Stirling expander 20 includes a moving regenerator 21 , a clearance seal 22, and spring 23. When attached to the coldfinger 10, an expansion space 24 is created adjacent coldfinger cold end 14 and a compression space 25 is created adjacent spring 23. A transfer line 26 is connected to a compressor (not shown) to drive the cooler. Pressure oscillations from the compressor induce phased oscillations in the moving regenerator 21. With the proper phase relationship in place, cooling is created by the expanding gas in expansion space 24, and heat is rejected by the compressed gas in the compression space 25.

As explained above, a Stirling type expander as shown in FIGS. 2 and 3 has drawbacks due to the presence of moving regenerator 21 which creates the need for clearance seals which must have tight tolerances and kept free of contamination. The moving regenerator is also a source of vibration and a point for mechanical fatigue and failure.

As seen in Figures 4 and 5, pulse tube expander 40 generally includes a warm end region 42, a central region 44, and a cold end region 46. Warm end region 42 includes a connector portion 48 that extends through coldfinger warm end 12 to communicate along line 52 with a buffer volume which contains a reservoir of working fluid (e.g., helium). Warm end region 42 may also include hot heat exchangers 54 which operate to remove heat from warm end region 42 while cryocooler unit 50 is in operation as is well understood by those skilled in the art.

Central region 44 includes a cylindrical pulse tube 56 having first and second ends 56a, 56b, respectively. Hot heat exchanger 54 is disposed at first end 56a adjacent warm end region 42 of pulse tube expander 40 and a "cold" heat exchanger 60 is disposed at second end 56b adjacent cold end region 46 of pulse tube expander 40.

An annular regenerator 62 having an inner diameter ID1 is sized to coaxially mount to and contact an outer surface 64 having an outer diameter

OD1 of pulse tube 56. Regenerator 62 generally extends from warm end region 42 to cold end region 46 of pulse tube expander 40. Regenerator 62 preferably comprises a plurality of stacked metallic, mesh discs 62, each having a central hole which align to define a bore through which pulse tube 56 axially extends, although other types and configurations of regenerators are of course possible.

A regenerator sleeve 66 having an inner diameter ID2 is sized to coaxially mount to and contact an outer diameter OD2 of regenerator 62. Sleeve 66 preferably extends from warm end region 42 to cold end region 46 to a distance slightly beyond pulse tube 56. A cold cap 68 is positioned over an opening defined at end 66a of regenerator sleeve 66 to thereby encase pulse tube 56 and regenerator 62 and define a unitary body which may then be simply attached to a SADA Il coldfinger 10 in the same manner as a Stirling expander 20. This is made possible by forming the outer surfaces at warm end region 42 of pulse tube expander 40 to match the internal geometry of cold finger cold end 12. Furthermore, the regenerator sleeve 66 provides a very reproducible outer diameter dimension that is easily matched to the SADA Il geometry requirements. As such, expander 40 may be removably attached to and extend between coldfinger cold end 12 and cold end cap 14 to form cryocooler unit 50. Unit 50 may then be charged with an inert gas for safe shipment to the Dewar/sensor manufacturer. Once received, the Dewar/sensor manufacturer removes the SADA Il coldfinger shipped with the unit 50 and inserts the now exposed expander 40 into the SADA Il coldfinger previously welded into the Dewar 30 as seen in Figure 5.

It will thus be appreciated the invention provides a unitary pulse tube type expander which may be easily attached to a SADA Il coldfinger in the same manner as Stirling-type expanders. While the invention has been described herein with reference to preferred embodiments thereof, it will be appreciated that modifications may be made thereto without departing from the full spirit and scope of the invention as defined by the claims which follow.