Regenerator for a Cryo-Cooler With Helium as a Working Gas and as a Heat-Storing Material

Abstract

A regenerator for a cryocooler includes a cell, a flow passage, a capillary and supporting elements. A cell wall encloses a cavity with sub-cavities. A connecting passage connects a first sub-cavity to a second sub-cavity. A first cell partition is disposed between the first and second sub-cavities. The flow passage is also disposed between the first and second sub-cavities. During operation of the regenerator, helium in the cavity functions as a heat-storing material, while helium that flows through the flow passage functions as a working gas. The capillary forms a pressure-equalizing opening in the cell wall and connects the helium that functions as the heat-storing material inside the cavity to the helium that functions as the working gas outside the cavity. The supporting elements are inside the first sub-cavity and separate the first cell partition from a second cell partition. The first and second cell partitions enclose the first sub-cavity.

Claims

1-16. (canceled)

17. A regenerator, comprising: a cell that includes a cell wall that encloses a cavity, wherein the cavity includes a first sub-cavity and a second sub-cavity, wherein the first sub-cavity is connected to the second sub-cavity via a connecting passage, wherein a first cell partition is disposed between the first sub-cavity and the second sub-cavity, and wherein the cavity is filled with helium that functions as a heat-storing material during operation of the regenerator; a flow passage disposed between the first sub-cavity and the second sub-cavity, wherein helium that functions as a working gas flows through the flow passage during operation of the regenerator; a capillary that forms a pressure-equalizing opening in the cell wall and that connects the helium that functions as the heat-storing material inside the cavity to the helium that functions as the working gas outside the cavity; and a plurality of supporting elements disposed inside the first sub-cavity, wherein the first cell partition is separated from a second cell partition by the supporting elements, wherein the supporting elements brace the first cell partition against the second cell partition, and wherein the first cell partition and the second cell partition enclose the first sub-cavity.

18. The regenerator of claim 17, wherein the first sub-cavity is tubular due to the shape of the cell wall and the first cell partition.

19. The regenerator of claim 17, wherein the first sub-cavity has an internal meander shape formed by the supporting elements and the first cell partition.

20. The regenerator of claim 17, wherein the supporting elements are strip-shaped and extend away from the cell wall into the first sub-cavity.

21. The regenerator of claim 20, wherein the strip-shaped supporting elements include holes through which the helium that functions as the working gas can pass.

22. The regenerator of claim 17, wherein the first cell partition is planar.

23. The regenerator of claim 17, wherein the first cell partition is cylindrical.

24. The regenerator of claim 17, wherein the first sub-cavity has a rectangular cross-section.

25. The regenerator of claim 17, wherein the first sub-cavity has a circular cross-section.

26. The regenerator of claim 17, wherein the flow passage has a rectangular cross-section.

27. The regenerator of claim 17, wherein the cell is cylindrical and has a circumference, and wherein the connecting passage is disposed around the circumference of the cell.

28. The regenerator of claim 17, wherein the capillary is formed as an artifact of 3D printing.

29. The regenerator of claim 17, wherein the first cell partition imparts a swirl structure to the flow passage.

30. A regenerator for a cryocooler, comprising: a cell that includes a cell wall that encloses a cavity, wherein the cavity comprises a plurality of sub-cavities that are interconnected by a connecting passage, wherein a first cell partition and a second cell partition enclose a first sub-cavity, and wherein the cavity is filled with helium that functions as a heat-storing material; a plurality of flow passages disposed between individual sub-cavities, wherein helium that functions as a working gas flows through the flow passages; a pressure-equalizing opening that penetrates the cell wall and forms a connection between the helium that functions as the working gas outside the cavity and the helium that functions as the heat-storing material inside the cavity; and a plurality of supporting elements disposed inside the sub-cavities, wherein the first cell partition is separated from the second cell partition by the supporting elements, and wherein the supporting elements brace the first cell partition against the second cell partition.

31. The regenerator of claim 30, wherein the first cell partition and the second cell partition impart a tubular shape to the first sub-cavity.

32. The regenerator of claim 30, wherein the first sub-cavity has an internal meander shape formed by the supporting elements, the first cell partition, and the second cell partition.

33. The regenerator of claim 30, wherein the supporting elements extend from the cell wall into the first sub-cavity.

34. The regenerator of claim 33, wherein the supporting elements include holes through which helium can pass.

35. The regenerator of claim 30, wherein the first cell partition is planar.

36. The regenerator of claim 30, wherein the first cell partition is cylindrical.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0015] The accompanying drawings, where like numerals indicate like components, illustrate embodiments of the invention.

[0016] FIG. 1 shows a perspective sectional view of a first embodiment of the regenerator.

[0017] FIG. 2 shows a perspective sectional view of a second embodiment.

DETAILED DESCRIPTION

[0018] Reference will now be made in detail to some embodiments of the invention, examples of which are illustrated in the accompanying drawings.

[0019] FIG. 1 is a cross-sectional view of a regenerator 1 comprising a cell 2. Due to a capillary 8 in the cell walls 4, the interior of the sub-cavities fills with helium as a heat-storing medium when the regenerator 1 is started up. Since comparable pressure conditions exist within the cavity 6 or sub-cavities 6-i during operation, the cell walls can be constructed to be comparatively thin. However, at least a minimum thickness of the cell walls is required so that they do not break or crack during the pressure fluctuations during operation of the regenerator. The fact that the sub-cavities have supporting elements in their interior means that the cell walls can be made even thinner because the thin cell walls are supported by the supporting elements. The thinner cell walls improve heat transfer through the cell walls. The ratio of cavity volume to opening area or outflow resistance of the capillary is selected in such a way that the pressure in the cavity or sub-cavities barely changes or at least only slightly changes in the operating frequency range of the cooler operation (approximately 1 to 60 Hz). This mode of operation is comparable to a capacitor at high frequencies, which is virtually unaffected by the change in voltage if the capacitance is high enough and the change in voltage is small. In a typical application, the pressure in the cell will always fluctuate around the medium pressure of the cooling system, typically around 16 bar. The stable pressure is important because otherwise the volume of the cavity or cavities would be a large contributor to the “dead volume” if its pressure fluctuated between, for example, 8 and 24 bar every period without contributing to cooling. The opening area or the outflow resistance of the pressure-equalizing opening is selected in such a way that helium enters the cavity or cavities before the regenerator is started up as well as during the start-up phase due to the prevailing pressure conditions. Due to the high outflow resistance of the pressure-equalizing opening, the “condenser effect” explained above results during the pressure fluctuations in the area of the regenerator with the operating frequency of a cooler. During the start-up phase of regenerator 1, the temperature of the helium working gas and also of the helium in the regenerator cavities decreases. Consequently, the volume of helium decreases, and helium continues to flow into the regenerator cavities via the pressure-equalizing opening. This means that helium has to be replenished during the start-up phase until the working temperatures and pressures have been established.

[0020] The cell 2 is interspersed with flow passages 10, which are bounded by the cell walls 4. This results in an increased heat exchange surface and thus improved heat transfer between the helium in the cavities and the working gas outside. The flow passages 10 are preferably in the form of slots. The slot-shaped flow passages for working gas preferably run in straight lines that are parallel to each other, on the one hand to minimize flow resistance and on the other hand to make the tubular cavities between them uniform. The straightness and parallelism result in an equal distance between two flow passages in a simple manner.

[0021] Optionally, the flow passages between the sub-cavities are arranged parallel to each other.

[0022] The pressure-equalizing opening may also be provided by leaks that occur during the manufacture of the cells.

[0023] In order to improve the heat exchange between the helium working gas and the helium heat-storing medium in the hollow body, the surfaces of the flow passages are provided with swirl structures.

[0024] In 3D printing processes, cuboid cavities or rounded cavities can be produced as a whole or in two steps from two components. Openings in the sub-cavities that are necessary for blowing out material after 3D printing can subsequently be closed. Since these openings have small cross-sectional areas, welding processes are suitable for this purpose. An opening in the cell wall that is an artifact of 3D printing can be used as a capillary through which helium that functions as a heat-storing medium enters the cavity when the regenerator starts operating.

[0025] Preferably, the supporting elements 14 are provided with slits in the form of blind holes that are accessible to the helium working gas. This allows thermal stresses occurring during 3D printing to be absorbed in the manner of an accordion so that cracks do not occur in the material.

[0026] The regenerators according to the present disclosure are particularly suitable for Stirling, Gifford-McMahon or pulse tube coolers in particular.

[0027] The entire regenerator preferably has a thickness of 5 mm to 100 mm in the direction of the flow of the working gas.

[0028] FIGS. 1 and 2 show two embodiments of the disclosure in the form of a cylindrical, column-shaped regenerator 1 with a circular cross-section, wherein only one half of the regenerator 1 is shown in each case. The regenerator 1 comprises a cell 2 with cell walls 4 that enclose a cavity 6 with sub-cavities 6-i. The cell walls 4 are penetrated by a pressure-equalizing opening in the form of a capillary 8. The cell 2 has a circular ring-shaped cross-section and is arranged in a tubular flow passage for the helium working gas. During operation, the interior of the cavity 6 is filled with helium as a heat-storing material. The sub-cavities 6-i form planar structures parallel to the longitudinal axis of the cell 2. Between the planar sub-cavities 6-i, parallel slot-shaped flow channels 10 are formed for helium as the working gas. The sub-cavities 6-i are interconnected in the rim region of the cylindrical regenerator 1 by a connecting passage 12. The sub-cavity 6-i together with the other sub-cavities 6-i form the cavity 6. The individual planar and parallel sub-cavities 6-i extend over the entire height or length of the column-shaped cell 2 and are formed by two spaced-apart, planar cell partitions 4-1, sealed in the rim region by strip-shaped cell walls 4-2. The slit-shaped flow passages 10 completely penetrate the cell 2 and are disposed between the individual sub-cavities 6-i.

[0029] Supporting elements 14 are provided inside the sub-cavities 6-i, which support the planar cell partitions 4-1 against each other. In the first embodiment according to FIG. 1, the supporting elements 14 are formed as small cuboids distributed over the interior of the sub-cavities 6-i. The supporting elements 14 may also be column-shaped or rounded and spherical.

[0030] In the second embodiment shown in FIG. 2, the supporting elements 14 are strip-shaped and extend away from the strip-shaped cell walls 4-2 so as to form a meandering passage. The strip-shaped supporting elements 14 support and reinforce the planar cell partitions 4-1. The strip-shaped supporting elements 14 are provided with slits in the form of blind holes, not shown, which are accessible to the helium working gas. This allows thermal stresses occurring during 3D printing to be absorbed in the manner of an accordion so that cracks do not develop in the material.

REFERENCE NUMERALS

[0031] 1 regenerator [0032] 2 cell [0033] 4 cell wall [0034] 4-1 planar cell partitions [0035] 4-2 strip-shaped cell walls [0036] 6 cavity [0037] 6-i sub-cavity [0038] 8 capillary [0039] 10 flow passage for working gas [0040] 12 circumferential connecting passage [0041] 14 supporting elements

[0042] Although the present invention has been described in connection with certain specific embodiments for instructional purposes, the present invention is not limited thereto. Accordingly, various modifications, adaptations, and combinations of various features of the described embodiments can be practiced without departing from the scope of the invention as set forth in the claims.