JP2006524307A - Heat storage agent - Google Patents

Abstract

As a heat storage agent for a low temperature region of less than 15 Kelvin, generally a granule made of a rare earth compound is used. The material cost of rare earth elements is expensive. Furthermore, rare earth elements are magnetic and are therefore not suitable for every application. The heat storage agent according to the present invention for the cryogenic region consists of a group (22) of hollow bodies (30) that can be supplied in bulk and are hermetically closed, and each hollow body (30) boils at a low temperature as a storage medium. The hollow body wall (32) is made of metal. This provides a relatively inexpensive heat storage agent whose physical, chemical, magnetic and mechanical properties can be adapted to the particular application by appropriate material selection.

Description

  The present invention relates to a heat storage agent for a low temperature region, a heat storage device for a low temperature refrigerator, and a low temperature refrigerator.

  A cryocooler is a generally multi-stage gas cooler that produces temperatures in the region of less than 15 Kelvin. Such gas coolers operate according to various methods such as the Gifford-McMahon method, the Stirling method or the pulse tube method. What is common to the refrigerators regardless of these operating methods is that the refrigerator has a volume through which the working fluid flows in the region of the “cold head” between the high temperature side and the low temperature side. This volume is filled with a heat storage agent and is called a heat storage. This regenerator acts as an intermediate accumulator for the heat that is alternated in two directions by the working fluid and absorbed by or supplied to the working fluid. That is, the heat accumulator is useful for thermally separating the working fluid in the low temperature chamber from the working fluid in the high temperature chamber on the compressor side. For this purpose, the regenerator needs to have a heat capacity as high as possible as compared with the flowing fluid. For temperatures up to 15 Kelvin, special steel, bronze, lead or another metal body can be used as the heat storage agent in the regenerator, but not for temperatures significantly lower than 15 Kelvin. This is because the specific heat of the metal is remarkably lowered downward from 30 Kelvin compared to the specific heat of helium, and approaches zero in the region of less than 5 Kelvin. Therefore, in a cryogenic region, that is, a region of less than 15 Kelvin, a bulk material made of a rare earth compound is used as a heat storage agent in a heat storage unit as described in, for example, European Patent No. 0411591. A drawback in the use of rare earth compounds lies in magnetism, which is a problem when used in a strong magnetic field such as in a nuclear spin tomography apparatus. Furthermore, rare earth compounds are sensitive to oxidation, tend to be destroyed when vibrations occur due to partial brittleness, and are expensive.

  As storage media for the cryogenic region, helium and other gases boiling at low temperatures are also suitable. For example, helium has a high specific heat with a maximum at about 9 Kelvin in relation to the pressure in the region below 15 Kelvin, and therefore this specific heat is significantly above the heat capacity of the metal in that temperature region. Yes. A regenerator known from DE 199 24 184, in which helium is used as a heat storage agent, is fixedly supported on a spiral tube or tube group in a heat storage casing, similar to a heat exchanger. Yes. Alternatively, the working fluid may flow through a pipe in the regenerator casing while the regenerator casing is filled with helium as the storage medium.

  However, in the test using the regenerator configured as described above, the target temperature of 4.2 Kelvin could not be obtained. This is due to high heat penetration through the metal swirl or tube material and extremely small contact surfaces.

  U.S. Pat. No. 4,359,872 describes a bulk consisting of glass spheres filled with helium as a heat storage agent. In order to have sufficient strength at the required internal pressure and low temperature, the thickness of the glass spheres must be relatively large.

  An object of the present invention is to provide a heat storage agent having a high heat capacity in a cryogenic region, a heat storage device having a high heat capacity heat storage agent for cryogenic temperatures, and a low-temperature refrigerator.

  This problem is solved by the configuration according to claim 1, 10, 11 or 12 according to the present invention.

  The heat storage agent according to the invention for the low temperature region, i.e. for temperatures below 15 Kelvin, consists of a group of hermetically closed hollow bodies that are permeable to working fluid, each hollow body boiling at a low temperature as a storage medium. It has a filling consisting of gas. A gas boiling at a low temperature is a gas having a boiling point of less than 30 Kelvin. This applies to gases such as hydrogen, helium, neon and all isotopes of these gases. A gas boiling at a low temperature naturally has a relatively high specific heat at low temperatures and is therefore well suited as a storage medium at temperatures below 30 Kelvin. The gas boiling at a low temperature may be enclosed in a hollow body having a hollow body wall of a relatively inexpensive and non-magnetic, mechanically suitable, non-oxidizing inexpensive material. That is, the thermal storage agent can be structurally adapted to the application with respect to its chemical, mechanical and magnetic properties. Furthermore, the hermetically closed hollow body has a surface that undergoes heat exchange that is significantly larger than a tube or spiral member. This significantly accelerates heat transfer.

Advantageously, the storage medium is a hollow body filling made of helium. A helium fill is understood to be a fill with a helium isotope such as ³ He or ⁴ He, for example. Helium as a storage medium has a relatively high specific heat at temperatures below 15 Kelvin and is therefore well suited as a storage medium at temperatures down to the 2 Kelvin range. Furthermore, helium is available at a low price.

  Advantageously, the helium filling has a pressure above 0.5 bar, in particular above the critical pressure, at a temperature of 4 Kelvin. At a pressure of helium filling above 0.5 bar, an absolute heat capacity is realized that allows the amount of heat generated to be stored in a relatively small regenerator. Such a regenerator is very compact compared to a metal regenerator.

  Advantageously, the material and wall thickness of the hollow body wall are selected such that the heat penetration depth is at least the value of said wall thickness. Thermal penetration depth μ is the equation

から得られる。この場合、ａは作業温度（例えば２ケルビン）における選択された中空体壁材料の熱伝導率であり、ｆ_ｍｏｄは作業ガスが蓄熱剤を周期的に交番通流する変調周波数である。この場合、作業周波数ｆ_ｍｏｄは低温冷凍機用に１．０〜１０．０Ｈｚが採用される。

Obtained from. In this case, a is the thermal conductivity of the selected hollow body wall material at the working temperature (e.g. 2 Kelvin) and f _mod is the modulation frequency at which the working gas periodically alternates the heat storage agent. In this case, the working frequency f _mod is 1.0 to 10.0 Hz for a low-temperature refrigerator.

  The wall of the hollow body is made of metal. Since metals and metal alloys also have good thermal conductivity and good mechanical properties, a small hollow body thickness can also be realized. The hollow body wall may be made of copper, aluminum, silver, brass, steel or another metal or metal alloy. The hollow body wall may alternatively be made of ceramic.

  By selecting a non-ferromagnetic metal for the hollow body wall, a heat storage agent suitable for use in, for example, a nuclear spin tomography apparatus or the like can be provided for use in a strong magnetic field without any other means.

  In an advantageous configuration, each hollow body has a diameter of less than 3.0 mm. For diameters of less than 3.0 mm, the hollow bodies have a volume specific surface that is sized to ensure sufficiently rapid heat absorption or supply. A typical diameter is 0.2-0.7 mm.

  Advantageously, each hollow body has a substantially spherical shape. By selecting a spherical shape, a defined ratio between the hollow body surface, the total hollow body volume, and the bulk volume is ensured in the hollow body bulk load, which is substantially constant over the entire bulk volume.

  The regenerator according to the invention has a casing filled with the heat storage agent described above. The low-temperature refrigerator according to the present invention has the above-mentioned heat accumulator and is formed as a regenerative circulation process, preferably as a Gifford McMahon refrigerator, a Stirling refrigerator or a pulse tube refrigerator, and helium as the working fluid Is used. That is, helium is used as a storage medium or as a working fluid separately.

  In the following, embodiments of the invention will be described in detail with reference to the drawings.

  The refrigerator 10 schematically shown in FIG. 1 has an expansion chamber 16 having a compressor 12, a heat accumulator 14, and a cryogenic head as important components. The compressor 12, the regenerator 14, and the expansion chamber 16 are connected to each other by conduits 18 and 20.

  The working fluid, preferably helium, is compressed by the compressor 12 and possibly precooled. Next, the compressed working fluid flows through the gas conduit 18 and the heat accumulator 14 and supplies heat to the heat accumulator in the heat accumulator 14. The working fluid further flows into the expansion chamber 16 where it is released. The working fluid to be cooled in this case absorbs heat from the surrounding environment, in particular via a cold surface, and then returns to the heat accumulator 14 again through the conduit 20. When the heat accumulator 14 flows, the working fluid absorbs the heat stored in the heat storage agent and is supplied to the compressor 12 again through the conduit 18. The regenerator 14 serves to thermally insulate between the compressor 12 and the expansion chamber 16.

  The refrigerator 10 may be formed as a Gifford McMahon refrigerator, a Stirling refrigerator or a pulse tube refrigerator, but can basically be operated by another regeneration cycle for intermediate heat storage in a low temperature region. A heat accumulator 14 is used. The low temperature region is understood to be a temperature of 0 to 15 Kelvin.

  The heat accumulator 14 shown in a longitudinal sectional view in FIG. 2 is formed by a substantially cylindrical or elliptical casing 24, and conduits 18, 20 are opened in casing walls 26, 27 on the lateral side of the casing 24. is doing. The heat accumulator casing 24 has a group 22 of hollow bodies 30 that can be supplied in bulk and are hermetically closed as a heat storage agent, which is gas permeable for working fluids. The heat accumulator 14 may be filled uniformly or with different layers of different heat storage agents.

  All the hollow bodies 30 are formed in substantially the same size and have a substantially spherical shape. However, the bulk goods may be formed from a mixture of hollow bodies of different diameters. The hollow body wall 32 is made of copper or another metal or metal alloy and has a wall thickness of about 0.2 mm or less than 0.2 mm. The diameter of the hollow body 30 is 0.2 to 2.0 mm, but may be larger than this and smaller than 3.0 mm. The hollow body 30 is hermetically closed and has a helium filling 34. This helium filling 34 has a pressure of about 200 bar at room temperature and a pressure of several bars at a temperature of 4 Kelvin. The hollow body 30 filled with the helium filling 34 may be formed, for example, by a fabrication method in which droplets of molten hollow body wall material travel through a cooling chamber filled with helium gas. The hollow body fill may be formed from a single helium isotope or a mixture of different helium isotopes, or a hydrogen or neon isotope, or a mixture of said elements. The material of the hollow body wall, the modulation frequency at which the working gas alternates through the regenerator and the wall thickness of the hollow body must be selected such that the penetration depth μ is at least one time the wall thickness. Penetration depth μ is the equation

から得られ、この場合、ａは作業温度（例えば４ケルビン）における選択された中空体壁材料の熱伝導率であり、ｆ_ｍｏｄは作業ガスが蓄熱剤を周期的に交番通流する変調周波数である。この場合、作業周波数ｆ_ｍｏｄは低温冷凍機において例えば約１．０Ｈｚが採用される。

Where a is the thermal conductivity of the selected hollow body wall material at the working temperature (eg 4 Kelvin), and f _mod is the modulation frequency at which the working gas periodically alternates the heat storage agent. is there. In this case, the working frequency f _mod is, for example, about 1.0 Hz in a low-temperature refrigerator.

  A heat storage agent formed by a hollow body 30 that is hermetically closed and has a helium filling is highly advanced in a very small volume, based on the high specific heat of helium in this very low temperature region, less than 15 Kelvin. Has heat storage capacity. By selecting an appropriate metal for the hollow body wall 32, the thermal storage material can be optimally adapted with respect to electrical, mechanical and chemical requirements for any application, for example for cooling in a nuclear spin tomography device. A non-magnetic material can be selected for the hollow body wall.

  In addition to the helium-filled hollow body 30, another heat storage element made of, for example, a rare earth alloy is present in the regenerator casing in a separate layer or mixed with the helium-filled hollow body 30. Also good.

It is the schematic of a refrigerator. It is sectional drawing of the heat exchanger for refrigerators provided with the filling which consists of a hollow body group with which helium was filled. It is sectional drawing of the hollow body with which helium was filled.

Claims (12)

A heat storage agent for a low temperature region, comprising a group (22) of bulk supply bodies, each of which is a hermetically closed hollow body (30), and each hollow body (30) In the form of having a filling (34) consisting of a gas boiling at low temperature as a storage medium,
A heat storage agent for a low temperature region, characterized in that the hollow body wall (32) is made of metal.   The heat storage agent according to claim 1, wherein the hollow body wall (32) is made of copper.   The heat storage agent according to claim 1 or 2, wherein the material and thickness of the hollow body wall (32) are selected such that the heat penetration depth is at least the value of the thickness.   The heat storage agent according to any one of claims 1 to 3, wherein the storage medium is a filling (34) made of helium.   The heat storage agent according to claim 4, wherein the helium filling (34) has a pressure of 0.5 bar or more at a temperature of 4K.   The heat storage agent according to claim 4 or 5, wherein the helium filling (34) has a pressure of approximately 200 bar at room temperature.   The heat storage agent according to any one of claims 1 to 6, wherein the wall thickness of the hollow body wall (32) is smaller than 1.0 mm.   The heat storage agent according to any one of claims 1 to 7, wherein the hollow body (30) has a substantially spherical shape.   The heat storage agent according to claim 8, wherein the hollow body (30) has a diameter smaller than 3.0 mm. A heat storage agent for a low temperature region, which is composed of a group (22) of bulk supply bodies, each of which is an airtightly closed hollow body (30), and each hollow body (30). In the form of having a filling (34) consisting of a gas boiling at low temperature as a storage medium,
A heat storage agent, wherein the hollow body wall (32) is made of ceramic.   Regenerator (14) for a low-temperature refrigerator (10), characterized in that it has a casing (24) filled with the heat storage agent (22) according to any one of claims 1 to 10. .   Low temperature refrigeration with a regenerator (14) according to claim 11, characterized in that it is formed as a Gifford McMahon refrigerator, a Stirling refrigerator or a pulse tube refrigerator, and helium gas is used as working fluid. Machine (10).

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