JP2014129940A - Stirling refrigerator - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a Stirling refrigerator in which the leakage of actuation gas is suppressed.SOLUTION: A Stirling refrigerator includes: a yoke 21 having a coolant gas space for charging coolant gas which is made of a material having a first linear expansion coefficient α and generates frigidness on an inner part, into the coolant space; an adaptor 80A which is made of a material having a linear expansion coefficient different from that of the yoke 21 and is fastened to the yoke 21; and a metal seal 50 which seals the yoke 21 and the adaptor 80A to each other. Therein, an opposite part 91A, 92A which comprises first opposite surfaces 71A, 72A formed so as to be extended in the direction (Z1, Z2 direction) fastened to the yoke 21 and second opposite surfaces 81A, 82A formed so as to be extended in the direction (Z1, Z2 direction) fastened to the adaptor 80A, the first opposite surfaces 71A, 72A being opposite to the second opposite surfaces 81A, 82A is provided such that the member having a larger linear expansion coefficient, of the yoke 21 and the adaptor 80A is located on the inner side.

Description

  The present invention relates to a Stirling refrigerator having a metal seal.

  In general, a Stirling refrigerator using a Stirling cycle is known as a kind of cryogenic refrigerator. This Stirling refrigerator is configured to include a compressor and an expander.

  In this Stirling refrigerator, a compressor and an expander are connected by a capillary tube. Therefore, it is necessary to perform sealing in order to prevent leakage of the working gas at the connection position between the compressor and the capillary tube and the connection position between the expander and the capillary tube. In addition, in other parts of the compressor and the expander, it is necessary to seal a part where the working gas may be leaked.

  On the other hand, in a refrigerator having a relatively small internal volume, such as a small Stirling refrigerator, when the gas pressure of the working gas is reduced, the refrigeration performance is greatly reduced. Further, in the case of a Stirling refrigerator using resonance, the working gas functions as a gas spring together with the piston spring. Therefore, the piston driving is affected by the leakage of the working gas, which also reduces the refrigeration performance. For this reason, a metal seal that can keep the leak rate small is used as the seal member (see Patent Document 1).

JP 2000-266420 A

  By the way, the Stirling refrigerator is used in a wide temperature range of -60 ° C to 150 ° C. Further, the metal seal requires a certain degree of softness when trying to maintain the adhesion at the seal portion. Furthermore, the linear expansion coefficient of the metal seal may be larger than that of a seal mounting member that sandwiches the metal seal.

  For this reason, when a Stirling refrigerator is used in a high temperature environment and a thermal shock is applied to the metal seal, creep occurs in the metal seal. Specifically, the metal seal is deformed by thermal expansion larger than the gap between the members in the gap between the members sandwiching the metal seal.

  When a Stirling refrigerator is used in a low-temperature environment after creep has occurred, the heat shrinkage of the metal seal is larger than that of the seal mounting member, and a gap is generated between the metal seal and the above metal mounting member. The working gas may leak from the site.

  This invention is made | formed in view of said point, and it aims at providing the Stirling refrigerator which suppressed the leak of working gas.

In order to solve the above problems, a Stirling refrigerator that is one embodiment of the present invention,
A first member having a first coefficient of linear expansion and having a refrigerant gas space in which a refrigerant gas for generating cold is loaded;
A second member having a linear expansion coefficient different from that of the first member and fastened to the first member;
A Stirling refrigerator having a metal seal that seals between the first member and the second member,
The first opposing surface is configured by a first opposing surface formed to extend in the fastening direction on the first member and a second opposing surface formed to extend in the fastening direction on the second member. And the second facing surface are opposed to each other so that a member having a large linear expansion coefficient is located inside the first member and the second member.

  According to the disclosed Stirling refrigerator, since the deformation of the metal seal at a high temperature is regulated by the facing portion, the occurrence of leakage can be suppressed.

FIG. 1 is a cross-sectional view of a Stirling refrigerator that is a first embodiment of the present invention. FIG. 2 is an enlarged view showing the sealing mechanism of the Stirling refrigerator according to the first embodiment of the present invention, wherein (A) is a cross-sectional view showing a state at a low temperature, and (B) shows a state at a high temperature. It is sectional drawing. FIG. 3 is an enlarged view showing a sealing mechanism of a Stirling refrigerator according to the second embodiment of the present invention. FIG. 3A is a cross-sectional view showing a state at a low temperature, and FIG. 3B shows a state at a high temperature. It is sectional drawing. FIG. 4 is an enlarged cross-sectional view showing a low temperature state of the seal mechanism of the Stirling refrigerator that is the third embodiment of the present invention. FIG. 5 is an enlarged view showing a high temperature state of the seal mechanism of the Stirling refrigerator according to the third embodiment of the present invention. FIG. 5A shows a case where the linear expansion coefficient of the adapter is larger than the linear expansion coefficient of the yoke. (B) is a cross-sectional view showing a case where the linear expansion coefficient of the adapter is smaller than the linear expansion coefficient of the yoke.

  Next, embodiments of the present invention will be described with reference to the drawings.

  FIG. 1 shows a Stirling refrigerator 10 according to the first embodiment of the present invention. The Stirling refrigerator 10 includes a compressor 11, a cold head (expander) 12, a capillary tube 13, a seal mechanism 40A, and the like.

  The compressor 11 includes a yoke 21, a pressure holding container 22, a compression piston 23, a piston control spring 24, and the like. The yoke 21 (corresponding to the first member recited in the claims) functions as a cylinder of the compression piston 23. The yoke 21 includes an annular groove into which a movable coil 25 fixed to the compression piston 23 is inserted, and a permanent magnet 26 embedded outside the groove.

  The pressure holding container 22 is fixed to the yoke 21. The pressure holding container 22 and the yoke 21 form a pressure holding space in which the compression piston 23 is accommodated and filled with a working gas (for example, helium). The pressure holding container 22 is provided with an airtight power supply terminal (not shown), and the movable coil 25 is connected to an external power supply (AC power supply) through the airtight power supply terminal.

  Further, a piston control spring 24, which is a mechanical spring, is connected between the compression piston 23 and the pressure holding container 22 so as to connect the compression piston 23 and the pressure holding container 22 (so that the compression piston 23 can be kept at a neutral point). Is provided.

  The cold head 12 includes a housing portion 31, a displacer 32, a displacer control spring 33, a lid 35, and the like. The housing portion 31 functions as a cylinder in its internal space.

  The displacer 32 stores therein a cold storage material for heat exchange. The displacer control spring 33 is provided in the housing portion 31 and functions to keep the displacer 32 at a neutral point. The lid 35 closes the left end of the internal space of the housing portion 31 in the figure.

  The Stirling refrigerator 10 having the above-described configuration is controlled such that the compression piston 23 reciprocates (moves in the left-right direction in the figure) by supplying an alternating current to the movable coil 25 via an airtight power supply terminal. . The high-pressure working gas generated in the compression space 28 by the reciprocating motion of the compression piston 23 is supplied to the cold head 12 through the capillary tube 13. As a result, cold is generated by the expansion of the working gas in the expansion space 34 of the cold head 12, thereby cooling the object to be cooled connected to the cold head 12.

  By the way, as described above, in a refrigerator having a relatively small internal volume, such as the Stirling refrigerator 1, when the gas pressure of the working gas is lowered, the refrigeration performance is greatly lowered. For this reason, the connection position between the capillary tube 13 and the compressor 11 (specifically, the yoke 21), the connection position between the capillary tube 13 and the displacer control spring 33 (position surrounded by a broken line indicated by arrow A1 in FIG. 1), A sealing mechanism 40A that prevents the working gas from leaking is provided at a mounting position (a position surrounded by a broken line indicated by an arrow A2 in FIG. 1) where the lid 35 is mounted on the housing portion 31.

  In FIG. 1, for convenience of illustration, only the sealing mechanism 40A provided at the connection position between the capillary tube 13 and the yoke 21 is shown, and the sealing mechanisms at the other positions A1 and A2 are not shown.

  Next, the sealing mechanism 40A provided in the Stirling refrigerator 10 having the above-described configuration will be described. FIG. 2 is an enlarged sectional view showing the sealing mechanism 40A. The seal mechanism 40A includes a metal seal 50, a fastening portion 70A, an adapter 80A, and the like.

  The metal seal 50 has no permeation phenomenon and has high durability, heat resistance, and sealing performance as compared with a soft gasket using rubber or the like. Therefore, it is suitable as a gasket for a refrigerator that achieves extremely low temperatures where leakage and contamination are problematic.

  For example, various metals such as solder and indium are used as the metal seal. In this embodiment, a solder having a certain degree of softness is used as a material for the metal seal 50 in order to maintain adhesion to the contact surface. Yes. The metal seal 50 has an annular shape (a donut shape) when viewed from above.

  The fastening portion 70 </ b> A is formed on the yoke 21. The fastening portion 70 </ b> A is connected to the upper end portion of the gas flow passage 74 whose lower end is connected to the compression space 28.

  The capillary tube 13 is connected to the fastening portion 70A. Therefore, the compression space 28 is connected to the cold head 12 via the gas flow passage 74 and the capillary tube 13.

  The fastening portion 70 </ b> A has a first facing surface 71 </ b> A, a first facing surface 72 </ b> A, and a seal mounting surface 73. The first facing surface 71 </ b> A is provided at an inner position with respect to the seal mounting surface 73, and the first facing surface 72 </ b> A is provided at an outer position with respect to the seal mounting surface 73.

  In the following description, the side closer to the central axis of the fastening portion 70A (the one-dot chain line indicated by the arrow X in FIG. 2) is referred to as the inner side, and the side far from the central axis X is referred to as the outer side.

  The first opposing surfaces 71A, 72A are configured to extend along the direction of fastening to the fastening portion 70A of the adapter 80A described later (indicated by an arrow Z2 in FIG. 2). Therefore, the first facing surfaces 71A and 72A are concentric with the central axis X, and are parallel when viewed in cross section. The first opposed surfaces 71A and 72A have a circular shape in plan view, and the circle of the first opposed surface 71A is located inside and the circle of the first opposed surface 72A is located outside.

  The seal mounting surface 73 is formed between the first facing surface 71A and the first facing surface 72A. The seal mounting surface 73 is a surface on which the metal seal 50 is mounted, and is formed to extend in a direction orthogonal to the fastening direction (Z2 direction) of the adapter 80A. Accordingly, the first facing surface 71A, the seal mounting surface 73, the first facing surface 72A, and the upper surface of the yoke 21 form a step.

  The seal mounting surface 73 has an annular shape (a donut shape) when seen in a plan view.

  The capillary tube 13 is connected to the adapter 80A (corresponding to the second member recited in the claims). The adapter 80A is configured such that a small diameter portion 87, a medium diameter portion 88, and a large diameter portion 89 are integrally formed from the lower side in the drawing. Therefore, the adapter 80A forms a step, and this step is configured to correspond to the step formed in the fastening portion 70A.

  The adapter 80 </ b> A has a second facing surface 81 </ b> A, a second facing surface 82 </ b> A, and a seal mounting surface 83. 81 A of 2nd opposing surfaces are the outer peripheral surfaces of the small diameter part 87, and are located inside the seal mounting surface 83. FIG. The second facing surface 82 </ b> A is an outer peripheral surface of the medium diameter portion 88 and is located on the outer side with respect to the seal mounting surface 83.

  The second facing surfaces 81A and 82A are configured to extend along the direction Z2 in the fastening direction to the fastening portion 70A of the adapter 80A. Therefore, the second facing surfaces 81A and 82A are concentric with the central axis X, and are parallel when viewed in cross section. The second opposing surfaces 81A and 82A have a circular shape when viewed from the bottom, with the circle of the second opposing surface 81A positioned on the inner side and the circle of the second opposing surface 82A positioned on the outer side.

  The seal mounting surface 83 is formed between the second facing surface 81A and the second facing surface 82A. The seal mounting surface 83 is a surface pressed against the metal seal 50 and is formed to extend in a direction perpendicular to the fastening direction (Z2 direction) of the adapter 80A.

  The seal mounting surface 83 is formed with a recess 83a for temporarily fixing the metal seal 50. The metal seal 50 is press-fitted between the seal mounting surfaces 73 and 83 in a state in which movement between the seal mounting surfaces 73 and 83 is regulated to some extent by being fitted in the recess 83a.

  Bolt holes 84 are formed in the large diameter portion 89. The bolt hole 84 is a hole that penetrates the large-diameter portion 89 in the Z1 and Z2 directions. A bolt hole 75 is formed at a position corresponding to the bolt hole 84 of the yoke 21.

  Next, the assembly procedure of the seal mechanism 40A will be described. It is assumed that the capillary tube 13 is airtightly fixed to the adapter 80A in advance.

  In order to assemble the seal mechanism 40A, first, the metal seal 50 is placed in the recess 83a of the seal mounting surface 83 constituting the fastening portion 70A. The metal seal 50 at this time has a donut shape.

  When the metal seal 50 is mounted on the seal mounting surface 83, the adapter 80A is inserted into the fastening portion 70A. As described above, since the step of the fastening portion 70A and the step of the adapter 80A are configured to correspond to each other, the adapter 80A is easily inserted into the fastening portion 70A. In addition, the metal seal 50 is sandwiched and pressed between the seal mounting surface 73 and the seal mounting surface 83 in a state where the adapter 80A is inserted into the fastening portion 70A.

  When the adapter 80A is inserted into the fastening portion 70A, the adapter 80A is subsequently fastened to the fastening portion 70A (yoke 21) by the fastening bolt 60. The adapter 80A is fastened to the fastening portion 70A (yoke 21) by the screwing force of the fastening bolt 60.

  The fastening force with which the adapter 80A is fastened to the fastening portion 70A is also applied to the metal seal 50. That is, the fastening force with which the adapter 80A is fastened to the fastening portion 70A acts as a force that presses (holds) the metal seal 50 between the seal mounting surface 73 and the seal mounting surface 83. With this fastening force, the metal seal 50 is deformed and is in close contact with the seal mounting surface 73 and the seal mounting surface 83. As a result, the space between the seal mounting surface 73 and the seal mounting surface 83 is hermetically sealed by the metal seal 50.

  Here, attention is paid to the facing surfaces 71A, 72A, 81A, and 82A in a state where the adapter 80A is fastened to the fastening portion 70A.

  In a state where the adapter 80A is fastened to the fastening portion 70A, the first facing surface 71A and the second facing surface 81A face each other to form a facing portion 91A, and the first facing surface 72A and the second facing surface 82A face each other. Thus, the facing portion 92A is formed.

  Further, the facing portion 91A has a configuration in which the first facing surface 71A is located on the outside and the second facing surface 81A is located on the inside. Further, in the facing portion 92A, the first facing surface 72A is positioned on the outside, and the second facing surface 82A is positioned on the inside.

  In the present embodiment, the facing portion 91A is provided so as to extend downward (Z2 direction) from the inner end portion of the mounting position of the metal seal 50, and the facing portion 92A is the outer end portion of the mounting position of the metal seal 50. It is provided so as to extend upward (Z1 direction). That is, in this embodiment, the opposing portions 91A and 92A are provided on both sides of the metal seal 50.

  Next, the operation of the sealing mechanism 40A configured as described above will be described.

  Now, the linear expansion coefficient of the adapter 80A is α, and the linear expansion coefficient of the yoke 21 is β. In the present embodiment, it is assumed that the linear expansion coefficient α of the adapter 80A is larger than the linear expansion coefficient β of the yoke 21 (α> β). Accordingly, in each of the facing portions 91A and 92A, the yoke 31 is located on the outside and the adapter 80A is located on the inside.

  Further, as described above, the linear expansion coefficient of the metal seal 50 is larger than the linear expansion coefficient of the fastening bolt 60, and further larger than the linear expansion coefficient α of the adapter 80A and the linear expansion coefficient β of the yoke 21.

  FIG. 2A shows the sealing mechanism 40A when the Stirling refrigerator 10 is placed in a low temperature environment (for example, a room temperature environment).

  In this state, as shown in the figure, between the first opposing surface 71A and the second opposing surface 81A constituting the opposing portion 91A, and the first opposing surface 72A and the second opposing surface 82A constituting the opposing portion 92A. A gap of ΔX is formed between.

  However, since the metal seal 50 made of solder is not greatly deformed by heat at room temperature, the metal seal 50 is unlikely to advance into the gaps formed in the facing portions 91A and 92A.

  On the other hand, FIG. 2 (B) shows the seal mechanism 40A when the Stirling refrigerator 10 is placed in a high temperature environment (for example, 60 ° C.).

As the environmental temperature in which the Stirling refrigerator 10 is placed rises, each element constituting the Stirling refrigerator 10 performs thermal expansion. The fastening portion 70A (yoke 21) constituting the seal mechanism 40A expands outward with the central axis X as the center. The expansion of the fastening portion 70A (yoke 21) is indicated by an arrow _Fβ in FIG.

Further, the adapter 80A constituting the seal mechanism 40A also expands outward about the central axis X. In FIG. 2 (B), shows an expansion of the adapter 80A by the arrow F _alpha.

As described above, in this embodiment, the linear expansion coefficient α of the adapter 80A is larger than the linear expansion coefficient β of the yoke 21 (α> β). Therefore, the expansion F _{α of the} adapter 80A is larger than the expansion F _β of the fastening portion 70A (yoke 21) (F _α > F _β ).

  In the facing portion 91A, the first facing surface 71A and the second facing surface 81A face each other, and in the facing portion 92A, the first facing surface 72A and the second facing surface 82A face each other. The opposing surfaces 71A, 72A, 81A, and 82A also move outward as the yoke 21 and the adapter 80A expand due to an increase in environmental temperature.

At this time, since the expansion F _alpha adapter 80A is greater than the expansion F _beta of the fastening portion 70A (the yoke 21), the second opposing face 81A, the amount of movement of the outer 82A, the first opposing face 71A, the outer 72A It becomes larger than the amount of movement to. Therefore, in a high temperature environment, the first facing surfaces 71A and 72A and the second facing surfaces 81A and 82A are in contact with each other at the facing portions 91A and 92A (ΔX = 0).

  On the other hand, when the Stirling refrigerator 10 is placed in a high temperature environment, a thermal shock due to a temperature rise is applied to the metal seal 50. Since the linear expansion coefficient of the metal seal 50 is larger than the linear expansion coefficient of the fastening bolt 60, the metal seal 50 tends to spread between the seal mounting surfaces 73 and 83 facing each other.

  However, the first facing surface 71A and the second facing surface 81A are in contact with each other at the facing portion 91A located inside the arrangement position of the metal seal 50, and the first facing surface 72A is also at the facing portion 92A located outside. And the second facing surface 82A are in contact with each other. Each of the facing portions 91A and 92A serves as a resistance for an operation in which the metal seal 50 tries to spread.

  Thus, in this embodiment, it is the structure provided with opposing part 91A, 92A which functions as a resistance which controls the operation | movement which the metal seal 50 tends to spread. Therefore, according to this embodiment, even when the Stirling refrigerator 10 is placed in a high temperature environment, thermal deformation (creep) generated in the metal seal 50 can be reduced. Thereby, the thickness of the metal seal between the seal mounting surfaces 73 and 83 can be secured, and the axial force of the fastening bolt 60 necessary for sealing can be maintained. As a result, the sealing performance in the sealing mechanism 40A can be maintained, and the leakage of the working gas can be reduced at the position where the metal seal 50 is disposed.

  In the above-described embodiment, the facing portions 91A and 92A are provided on both sides of the position where the metal seal 50 is disposed. However, the facing portion is provided only on either the inside or the outside of the position where the metal seal 50 is disposed. It is possible to improve a certain sealing property even if it is provided in the configuration.

  Next, a second embodiment of the present invention will be described.

  FIG. 3 shows an enlarged view of the Stirling refrigerator sealing mechanism 40B according to the second embodiment of the present invention. The Stirling refrigerator according to this embodiment has the same configuration as the Stirling refrigerator 10 according to the first embodiment shown in FIG. 1 except for the configuration of the seal mechanism 40B.

  For this reason, only the sealing mechanism 40B is shown in FIG. 3, and illustration and description of the overall configuration of the Stirling refrigerator are omitted. In FIG. 3, the same reference numerals are given to the components corresponding to those shown in FIGS. 1 and 2, and the description thereof is omitted.

  FIG. 3 shows a state where the adapter 80 </ b> B is fastened to the fastening portion 70 </ b> B formed on the yoke 21. Also in the present embodiment, the fastening portion 70B has first opposing surfaces 71B and 72B and a seal mounting surface 73, and the adapter 80B has second opposing surfaces 81B and 82B and a seal mounting surface 83.

  Further, in a state where the adapter 80B is fastened to the fastening portion 70B, the first facing surface 71B and the second facing surface 81B face each other to form a facing portion 91B, and the first facing surface 72B and the second facing surface 82B By facing each other, a facing portion 92B is formed.

  In the present embodiment, the yoke 21 is located on the inner side and the adapter 80B is located on the outer side in the facing portions 91B and 92B. Accordingly, in the facing portion 91B, the first facing surface 71B is located on the inner side and the second facing surface 81B is located on the outer side. Further, in the facing portion 92B, the first facing surface 72B is located on the inner side and the second facing surface 82B is located on the outer side. Thus, in the present embodiment, the opposing sides of the first facing surfaces 71B and 72B and the second facing surfaces 81B and 82B are opposite to those in the first embodiment.

  The facing portion 91B configured as described above is provided so as to extend upward (in the Z1 direction) from the inner end portion of the mounting position of the metal seal 50, and the facing portion 92B is the outer end portion of the mounting position of the metal seal 50. It is provided so as to extend downward (Z2 direction). Therefore, also in this embodiment, it is set as the structure by which the opposing parts 91B and 92B were provided in the both sides of the metal seal 50. FIG.

  Next, the operation of the sealing mechanism 40B configured as described above will be described.

  Also in this embodiment, the linear expansion coefficient of the adapter 80B is α, and the linear expansion coefficient of the yoke 21 is β. In the present embodiment, it is assumed that the linear expansion coefficient α of the adapter 80B is smaller than the linear expansion coefficient β of the yoke 21 (α <β). It is to be noted that the linear expansion coefficient of the metal seal 50 is larger than the linear expansion coefficient of the fastening bolt 60 and larger than the linear expansion coefficient α of the adapter 80B and the linear expansion coefficient β of the yoke 21 as in the first embodiment. is there.

  FIG. 3A shows the sealing mechanism 40B when the Stirling refrigerator is placed in a low temperature environment (for example, a room temperature environment).

  In this state, as shown in the figure, between the first opposing surface 71B and the second opposing surface 81B constituting the opposing portion 91B, and the first opposing surface 72B and the second opposing surface 82B constituting the opposing portion 92B. A gap of ΔX is formed between.

  However, since the metal seal 50 is not greatly deformed by heat at room temperature, it is difficult for the metal seal 50 to advance into the gaps formed in the facing portions 91B and 92B as described above.

  On the other hand, FIG. 3 (B) shows the sealing mechanism 40B when the Stirling refrigerator is placed in a high temperature environment (for example, 60 ° C.).

As the environmental temperature in which the Stirling refrigerator 10 is placed rises, the fastening portion 70B (yoke 21) constituting the seal mechanism 40B expands outward with the central axis X as the center (FIG. 3B shows this expansion). together is indicated by arrow F _beta), the adapter 80B also expand outwardly about a central axis X (FIG. 3 (B) shows this expansion by the arrow F _alpha).

In the present embodiment, unlike the first embodiment, the linear expansion coefficient α of the adapter 80B is set smaller than the linear expansion coefficient β of the yoke 21 (α <β). Therefore, the expansion F _β of the fastening portion 70B (yoke 21) is larger than the expansion F _{α of the} adapter 80B (F _α <F _β ).

  Also in the present embodiment, the first facing surface 71B and the second facing surface 81B face each other in the facing portion 91B, and the first facing surface 72B and the second facing surface 82B face each other in the facing portion 92B. Each of the opposing surfaces 71B, 72B, 81B, and 82B moves outward as the yoke 21 and the adapter 80B expand due to a rise in environmental temperature.

At this time, since the expansion F _beta fastening portions 70B (the yoke 21) is greater than the expansion F _alpha adapter 80B, the first opposing surface 71B, the amount of movement of the outer 72B is the second opposing face 81B, outer 82B It becomes larger than the amount of movement to. Therefore, also in the present embodiment, by placing the Stirling refrigerator in a high temperature environment, the first facing surface 71B and the second facing surface 81B come into contact with each other at the facing portion 91B, and the first facing surface 72B and the second facing surface 92B come into contact with each other at the facing portion 92B. 2 The opposed surface 82B comes into contact (ΔX = 0).

  As described above, also in the present embodiment, since the opposing portions 91B and 92B serving as the resistance of the operation in which the metal seal 50 tries to spread are provided, the Stirling refrigerator 10 is placed in a high temperature environment. Even in this case, thermal deformation (creep) generated in the metal seal 50 can be reduced. Thereby, the thickness of the metal seal between the seal mounting surfaces 73 and 83 can be secured, and the axial force of the fastening bolt 60 necessary for sealing can be maintained. As a result, the sealing performance in the sealing mechanism 40B can be maintained, and the working gas can be prevented from leaking at the position where the metal seal 50 is disposed.

  In the embodiment described above, the opposing portions 91B and 92B are provided on both sides of the position where the metal seal 50 is disposed. However, the facing portion is provided only on either the inside or the outside of the position where the metal seal 50 is disposed. It is possible to improve a certain sealing property even if it is provided in the configuration.

  Next, a third embodiment of the present invention will be described.

  FIG. 4 shows an enlarged left half of a Stirling refrigerator sealing mechanism 40C according to a third embodiment of the present invention.

  The Stirling refrigerator according to this embodiment has the same configuration as the Stirling refrigerator 10 according to the first embodiment shown in FIG. 1 except for the configuration of the seal mechanism 40C. For this reason, only the sealing mechanism 40C is shown in FIG. 4, and illustration and description of the overall configuration of the Stirling refrigerator are omitted. Also, in FIG. 4 and FIG. 5 used for the description to be described later, the same reference numerals are given to the components corresponding to those shown in FIGS.

  The adapter 80C of the present embodiment is disposed with the metal seal 50 disposed therebetween, and is provided with a pair of convex portions 85A and 85B that project downward (in the direction indicated by the arrow Z2 in FIG. 4). . 85 A of 1st convex parts are provided in the outer side with respect to the arrangement position of the metal seal 50, and 85 B of 2nd convex parts are provided in the inner side with respect to the arrangement position of the metal seal 50.

  Further, the fastening portion 70C of the present embodiment is disposed with the metal seal 50 disposed therebetween, and is provided with a pair of recesses 86A and 86B protruding downward (in the direction of arrow Z2). The first recess 86 </ b> A is provided on the outer side with respect to the arrangement position of the metal seal 50, and the second recess 86 </ b> B is provided on the inner side with respect to the arrangement position of the metal seal 50.

  FIG. 4 shows a state where the adapter 80 </ b> C is fastened to the fastening portion 70 </ b> C formed on the yoke 21. In this fastened state, the first convex portion 85A is inserted into the first concave portion 86A, and the second convex portion 85B is inserted into the second concave portion 86B.

  Here, attention is paid to the surface formed by the convex portions 85A and 85B of the adapter 80C and the surface formed by the concave portions 86A and 86B of the fastening portion 70C.

  The first convex portion 85A forms the first outer facing surface 101A on the outer side and the first inner facing surface 102A on the inner side. Further, the second convex portion 85B forms the first outer facing surface 101B on the outer side and the first inner facing surface 102B on the inner side.

  The first recess 86A forms the second outer facing surface 111A on the outer side and the second inner facing surface 112A on the inner side. Further, the second recess 86B forms a second outer facing surface 111B on the outer side and a second inner facing surface 112B on the inner side.

  The first outer facing surfaces 101A and 101B, the first inner facing surfaces 102A and 102B, the second outer facing surfaces 111A and 111B, and the second inner facing surfaces 112A and 112B are all fastened to the fastening portion 70C of the adapter 80C. It is comprised so that it may extend along the direction Z2. Therefore, each of the surfaces 101A, 101B, 102A, 102B, 111A, 111B, 112A, and 112B is a surface concentric with the central axis X, and is a surface parallel to the sectional view.

  Further, in a state where the adapter 80C is fastened to the fastening portion 70C, the first outer facing surface 101A and the second outer facing surface 111A face each other to form a first facing portion 121A, and the first inner facing surface 102A and the second inner facing surface 102A The facing surface 112A faces to form a second facing portion 122A. Similarly, the first outer facing surface 101B and the second outer facing surface 111B face each other to form a first facing portion 121B, and the first inner facing surface 102B and the second inner facing surface 112B face each other to form a second facing portion. 122B is formed.

  Further, the first facing portion 121 </ b> A and the second facing portion 122 </ b> A are located on the outer side with respect to the mounting position of the metal seal 50. Further, the first facing portion 121A is configured to be located outside the second facing portion 122A.

  Further, the first facing portion 121 </ b> B and the second facing portion 122 </ b> B are located on the inner side with respect to the mounting position of the metal seal 50. Further, the second facing portion 122B is configured to be located inside the first facing portion 121B.

  Therefore, also in this embodiment, it is set as the structure by which facing part 121A, 122A and facing part 121B, 122B were provided in the both sides of the arrangement | positioning position of the metal seal 50. FIG.

  Next, the operation of the sealing mechanism 40C configured as described above will be described.

  In the present embodiment, the following description will be given assuming that the linear expansion coefficient of the adapter 80C is α and the linear expansion coefficient of the yoke 21 is β.

  First, the case where the linear expansion coefficient α of the adapter 80C is larger than the linear expansion coefficient β of the yoke 21 (α> β) will be described. Further, it is assumed that the linear expansion coefficient of the metal seal 50 is larger than the linear expansion coefficients of the fastening bolt 60, the adapter 80C, and the yoke 21.

  FIG. 4 shows a sealing mechanism 40C when the Stirling refrigerator is placed in a low temperature environment (for example, a room temperature environment).

  In this state, as shown in the figure, a gap ΔX1 is formed between the first outer facing surface 101A and the second outer facing surface 111A constituting the first facing portion 121A, thereby constituting the second facing portion 122A. A gap ΔX2 is formed between the first inner facing surface 102A and the second inner facing surface 112A, and between the first outer facing surface 101B and the second outer facing surface 111B constituting the first facing portion 121B. A gap ΔX3 is formed, and a gap ΔX4 is formed between the first inner facing surface 102B and the second inner facing surface 112B constituting the second facing portion 122B.

  However, since the metal seal 50 is not greatly deformed by heat at room temperature, the metal seal 50 is unlikely to advance in the gaps ΔX1 to ΔX4 formed in the facing portions 121A, 121B, 122A, 122B.

  On the other hand, FIG. 5A shows the sealing mechanism 40C when the Stirling refrigerator is placed in a high temperature environment (for example, 60 ° C.).

By environmental temperature rises, the fastening portion 70C constituting the seal mechanism 40C (yoke 21) expands outwardly about a central axis X (in FIG. 5 (A) shows this expansion by the arrow F _beta) The adapter 80C also expands outward with the central axis X as a center (indicated by an arrow _Fα in FIG. 5A).

In the embodiment shown in FIG. 5A, since the linear expansion coefficient α of the adapter 80C is larger than the linear expansion coefficient β of the fastening portion 70C (yoke 21) (α> β), the expansion F _{α of the} adapter 80C is the fastening portion. 70C (yoke 21) is greater than the expansion _F β of (F α> F _β).

  Here, attention is focused on the first facing portion 121A and the first facing portion 121B.

  In the first facing portion 121A, the first outer facing surface 101A and the second outer facing surface 111A face each other, and in the first facing portion 121B, the first outer facing surface 101B and the second outer facing surface 111B face each other. Each of the facing surfaces 101A, 111A, 101B, 111B also moves outward as the yoke 21 and the adapter 80C expand due to an increase in environmental temperature.

At this time, since the expansion F _alpha adapter 80C is greater than the expansion F _beta fastening portions 70C (yoke 21), the first outer facing surface 101A, the amount of movement of the outer 101B is a second outer facing surface 111A, 111B It becomes larger than the amount of movement to the outside. Therefore, in a high temperature environment, the first outer facing surface 101A and the second outer facing surface 111A, and the first outer facing surface 101B and the second outer facing surface 111B are in contact with each other in the first facing portions 121A and 121B. State (ΔX1 = ΔX3 = 0).

  Thus, in this embodiment, it is the structure provided with facing part 121A, 121B which functions as a resistance which controls the operation | movement which the metal seal 50 tries to spread. Therefore, according to this embodiment, even when the Stirling refrigerator 10 is placed in a high temperature environment, the occurrence of thermal deformation (creep) in the metal seal 50 can be reduced.

  That is, in the first facing portion 121A located outside the arrangement position of the metal seal 50, the first outside facing surface 101A and the second outside facing surface 111A abut, and also in the first facing portion 121B located inside. The first outer facing surface 101B and the second outer facing surface 111B abut. That is, the first facing portion 121A and the first facing portion 121B function as resistors that restrict the movement of the metal seal 50 to spread.

  Therefore, according to this embodiment, even when the Stirling refrigerator 10 is placed in a high temperature environment, thermal deformation (creep) generated in the metal seal 50 can be reduced. Thereby, the thickness of the metal seal between the seal mounting surfaces 73 and 83 can be secured, and the axial force of the fastening bolt 60 necessary for sealing can be maintained. Therefore, the sealing performance in the sealing mechanism 40C can be maintained, and the leakage of the working gas can be reduced at the position where the metal seal 50 is disposed.

  Note that the gap ΔX2 remains in the second facing portion 122A where the first inner facing surface 102A and the second inner facing surface 112A face each other, but one of the gap ΔX2 is the first facing portion 121A. It is a fine space closed by. Therefore, this gap ΔX2 does not become a problem.

  Next, the case where the linear expansion coefficient β of the yoke 21 is larger than the linear expansion coefficient α of the adapter 80C (α <β) will be described.

  Even when the linear expansion coefficient β of the yoke 21 is larger than the linear expansion coefficient α of the adapter 80C, the state when the Stirling refrigerator is placed in a low temperature environment (for example, a room temperature environment) is shown in FIG. Since it is the same as the state shown in FIG.

  FIG. 5B shows a state where the seal mechanism 40C in which the linear expansion coefficient β of the yoke 21 is set larger than the linear expansion coefficient α of the adapter 80C is placed in a high temperature environment (for example, 60 ° C.). .

By environmental temperature rises, the fastening portion 70C constituting the seal mechanism 40C (yoke 21) expands outwardly about a central axis X (in FIG. 5 (B) shows this expansion by the arrow F _beta) The adapter 80C also expands outward with the central axis X as a center (indicated by an arrow _Fα in FIG. 5B).

In the embodiment shown in FIG. 5B, since the linear expansion coefficient β of the fastening portion 70C (yoke 21) is larger than the linear expansion coefficient α of the adapter 80C (α <β), the expansion of the fastening portion 70C (yoke 21). F _β is larger than the expansion F _α of the adapter 80C (F _α <F _β ).

  Here, attention is focused on the second facing portion 122A and the second facing portion 122B.

  In the second facing portion 122A, the first inner facing surface 102A and the second inner facing surface 112A face each other, and in the second facing portion 122B, the first inner facing surface 102B and the second inner facing surface 112B face each other. Each of the facing surfaces 102A, 112A, 102B, and 112B also moves outward as the yoke 21 and the adapter 80C expand due to an increase in environmental temperature.

In the present embodiment, since the expansion F _beta fastening portions 70C (yoke 21) is greater than the expansion F _alpha adapter 80C, the second internal surface 112A, the amount of movement of the outer 112B is first internal surface 102A , 102B becomes larger than the amount of movement to the outside. Therefore, in a high temperature environment, the first inner facing surface 102A and the second inner facing surface 112A and the first inner facing surface 102B and the second inner facing surface 112B are in contact with each other in the second facing portions 122A and 122B. (ΔX2 = ΔX4 = 0).

  As described above, the first inner facing surface 102A and the second inner facing surface 112A are in contact with each other in the second facing portion 122A located outside the arrangement position of the metal seal 50, and in the second facing portion 122B located inside. In addition, since the first inner facing surface 102B and the second inner facing surface 112B are in contact with each other, the resistance of the operation that the metal seal 50 tries to spread is increased on both sides thereof.

  Therefore, even when the Stirling refrigerator 10 is placed in a high temperature environment, thermal deformation (creep) generated in the metal seal 50 can be reduced. Thereby, the thickness of the metal seal between the seal mounting surfaces 73 and 83 can be secured, and the axial force of the fastening bolt 60 necessary for sealing can be maintained. As a result, the sealing performance in the sealing mechanism 40C can be maintained, and the leakage of the working gas can be reduced at the position where the metal seal 50 is disposed.

  In the example shown in FIG. 5B as well, the gap ΔX3 remains in the first facing portion 121B where the first outer facing surface 101B and the second outer facing surface 111B face each other. The gap ΔX3 is a fine space that is closed by the second facing portion 122A. Therefore, this gap ΔX2 does not become a problem.

  In the above-described embodiment, the first opposing portions 121A and 121B are formed on both sides of the position where the metal seal 50 is disposed when α> β, and the position where the metal seal 50 is disposed when α <β. Although the second facing portions 122A and 122B are formed on both sides of the metal seal 50, even if the facing portion is provided only on either the inside or the outside of the arrangement position of the metal seal 50, a certain sealing property is obtained. It is possible to improve.

  In the example shown in FIGS. 4 and 5, the convex portions 85A and 85B are formed on the adapter 80C, and the concave portions 86A and 86B are formed on the yoke 21. However, a configuration may be adopted in which the concave portion is formed in the adapter and the convex portion is formed in the yoke.

  The preferred embodiments of the present invention have been described in detail above. However, the present invention is not limited to the specific embodiments described above, and various modifications are possible within the scope of the gist of the present invention described in the claims. It can be modified and changed.

DESCRIPTION OF SYMBOLS 10 Stirling refrigerator 11 Compressor 12 Cold head 13 Capillary tube 21 Yoke 22 Pressure holding container 23 Compression piston 24 Piston control spring 25 Movable coil 26 Permanent magnet 28 Compression space 31 Housing part 32 Displacer 33 Displacer control spring 34 Expansion space 40A, 40B , 40C Seal mechanism 50 Metal seal 60 Fastening bolts 70A, 70B, 70C Fastening portions 71A, 71B, 72A, 72B First facing surface 73 Seal mounting surfaces 80A, 80B, 80C Adapters 81A, 81B, 82A, 82B Second facing surface 83 Seal mounting surfaces 85A, 85B Convex portions 86A, 86B Concave portions 91A, 91B, 91C, 92A, 92B, 92C Opposing portions 101A, 101B First outer facing surfaces 102A, 102B First inner facing surfaces 111A, 11B second outer facing surface 112A, 112B second internal surface 121A, 121B first opposing portion 122A, 122B second opposing portions

Claims (8)

A first member having a first coefficient of linear expansion and having a refrigerant gas space in which a refrigerant gas for generating cold is loaded;
A second member having a linear expansion coefficient different from that of the first member and fastened to the first member;
A Stirling refrigerator having a metal seal that seals between the first member and the second member,
The first opposing surface is configured by a first opposing surface formed to extend in the fastening direction on the first member and a second opposing surface formed to extend in the fastening direction on the second member. The Stirling refrigerator, wherein the facing portion where the second facing surface faces is provided so that a member having a large linear expansion coefficient is located inside of the first member and the second member. The first member is a yoke functioning as a cylinder of a compression piston;
The second member is an adapter to which a capillary tube is connected;
A larger linear expansion coefficient of the second member than the linear expansion coefficient of the first member,
2. The Stirling refrigerator according to claim 1, wherein the opposing portion is configured such that the first opposing surface is located outside the second opposing surface.   The Stirling refrigerator according to claim 2, wherein the facing portions are provided on both sides of the metal seal placement position. The first member is a yoke functioning as a cylinder of a compression piston;
The second member is an adapter to which a capillary tube is connected;
A larger linear expansion coefficient of the first member than the linear expansion coefficient of the second member,
2. The Stirling refrigerator according to claim 1, wherein, in the facing portion, the first facing surface is positioned inside the second facing surface. 3.   The Stirling refrigerator according to claim 4, wherein the facing portions are provided on both sides of the metal seal arrangement position. Forming a convex portion having a first outer facing surface and a first inner facing surface extending in a fastening direction on either the first member or the second member;
A second outer facing surface and a second inner facing surface extending in a fastening direction on either the first member or the second member, and forming a recess into which the convex portion is inserted;
When the convex portion is inserted into the concave portion, a first opposing portion in which the first outer opposing surface and the second inner opposing surface oppose each other, and the first inner opposing surface and the second outer opposing surface are provided. The Stirling refrigerator according to claim 1, wherein a second opposing portion is formed.   The Stirling refrigerator according to claim 6, wherein the convex portion and the concave portion are provided on both sides of the arrangement position of the metal seal. A fastening member for fastening the first member and the second member;
The Stirling refrigerator according to any one of claims 1 to 7, wherein a linear expansion coefficient of the metal seal is larger than a linear expansion coefficient of the fastening member.

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