KR100539755B1 - Regenerator assembly structure for stirling refrigerator - Google Patents

Abstract

The present invention relates to a regenerator assembly structure of the cryogenic refrigerator, the present invention is coupled to the actuator of the drive motor and the piston reciprocating linearly in the interior of the cylinder, while slidingly inserted into one side of the cylinder interlocked with the piston A displacer for compressing / expanding the working gas, a cold finger tube having a cryogenic portion by sealingly coupled to one side of the cylinder, and accumulating thermal energy of the working gas while reciprocating inside the cold finger tube by being coupled to one side of the displacer. In a cryogenic freezer comprising a regenerator having a heat storage material for discharging, the regenerator is formed of a cylinder to receive the heat storage material and a coupling body to form a coupling groove on the inner circumferential surface thereof, and a coupling protrusion to engage the coupling groove of the housing body. The housing cover for covering the cold finger tube end of the housing body By eliminating the use of adhesives, the performance of the refrigerating unit can be prevented in advance, and the assembly of the regenerator can be easily and quickly performed, thereby increasing the productivity of the regenerator.

Description

Regenerator assembly structure of cryogenic freezer {REGENERATOR ASSEMBLY STRUCTURE FOR STIRLING REFRIGERATOR}

1 is a cross-sectional view showing an example of a conventional sterling refrigerator,

Figure 2 is a perspective view showing the decomposition of the regenerator in the conventional sterling refrigerator,

Figure 3 is a perspective view showing the decomposition of the regenerator in the present invention sterling refrigerator,

Figure 4 is a cross-sectional view showing the assembly of the regenerator in the present invention sterling refrigerator.

** Description of symbols for the main parts of the drawing **

110: housing 111: housing body

111a: engagement groove 111b: inclined guide surface

112: housing cover 112a: second gas through hole

112b: engaging protrusion 112c: inclined sliding surface

112d: incision

The present invention relates to a regenerator of a cryogenic freezer, and more particularly, to a regenerator of a cryogenic freezer, in which the housing body and the housing cover can be easily assembled without an adhesive.

In general, the regenerator is a key component of the regeneration cycle, and is a device that accumulates / discharges thermal energy while exchanging heat with working gas flowing between the freezing section and the compression section. Such regenerators mainly use stainless steel thin fibers of relatively large heat exchange area as heat storage material for smooth heat exchange with working gas, and use them by cutting the net or woven fabric in the shape of net or The cotton in its initial state is pressed and used as it is.

1 is a cross-sectional view illustrating an example of a conventional sterling refrigerator, and FIG. 2 is a perspective view of the conventional sterling refrigerator in which the regenerator is disassembled.

As shown in the drawing, a conventional sterling refrigerator includes a sealed container 10 having a predetermined internal space and a sealed container 10 inside the sealed container 10, in which the mover 23 reciprocates linearly. ), A cylinder 30 fixed to the sealed container 10 to fill a working gas therein, and a mover 23 of the reciprocating motor 20, and reciprocated in a straight line to one side of the cylinder 30. Inserted so as to be able to move the piston 40 for pumping the operating gas of the cylinder 30, and the other side of the cylinder 30 is inserted to have a fine air gap and the refrigerant gas while interlocking with the piston 40 Connected to the displacer 50 for compressing / expanding, the support spring 60 fixed to the sealed container 10 so as to elastically support one side of the displacer 50 to maintain concentricity, and the outlet side of the cylinder 30. Cold-Finger Tube (70) having a cryogenic portion (71) by sealing coupling De is inserted so as to have a fine pore on a finger tube (70) a regenerator (80) for storing / releasing the heat energy of the working gas which combines the displacer (50).

The regenerator 80 has a predetermined inner space and is coupled to the body portion 51 of the displacer 50 and inserted into the inner space of the housing 81 to accumulate / discharge thermal energy of the working gas. It consists of a heat storage material (82).

The housing 81 covers the housing body 83 formed as a hollow body of the cylinder and one side of the housing body 83, and forms a plurality of second gas through holes 84a to form the inside of the cold finger tube 70 and the above. It consists of a housing cover 84 which communicates the inner space of the housing body (83).

The housing body 83 has an open structure on the displacer 50 side so as to communicate with the first gas through hole 51a provided in the body portion 51 of the displacer 50.

The housing cover 84 is inserted into the end of the housing body 83 so that the housing body 83 has a minute gap with the inner circumferential surface of the cold finger tube 70 and fixed with an adhesive or the like.

The heat storage material 82 is made of stainless fiber in the form of cotton or woven fabric is inserted and coupled to the inside of the housing 81.

In the drawings, reference numeral 31 denotes a gas passage, 52 a displacer rod, 91 an inner heat dissipation unit, 92 an outer heat dissipation unit, S1 a compression space, and S2 an expansion space.

The conventional sterling freezer as described above operates as follows.

That is, when power is applied to the reciprocating motor 20, the piston 40 moves forward with the actuator 23 of the reciprocating motor 20 to compress the working gas in the compression space (S1), The working gas compressed in S1 is introduced into the housing 81 of the regenerator 80 through the gas passage 31 of the cylinder 30 and the first gas through hole 51a of the displacer 50. After passing through the heat storage material 82 of the regenerator 80 accumulates thermal energy in the heat storage material 82 is discharged to the opposite expansion space (S2), the displacer 50 is expanded space along the piston 40 When the piston 40 moves backward (S2) and moves backward, it moves back toward the compression space S1 by the pressure of the expansion space S2 and the restoring force of the support spring 60. At this time, the working gas of the expansion space (S2) is rapidly expanded while cooling the cryogenic portion 71 of the cold finger tube (70).

Next, the working gas of the expansion space (S2) is introduced into the housing 81 through the second gas through hole (84a) of the regenerator 80, the working gas again to the heat storage material 82 inside the housing 81 While passing through the heat energy was transferred to the compression space (S1) of the cylinder 30 was to repeat a series of processes to be compressed again when the piston 40 moves forward.

However, in the conventional sterling refrigerator as described above, a slot (not shown) was processed in the housing cover 84, and an adhesive was applied to the processed portion thereof, and then inserted into the housing body 83 to harden. In vulnerable cryogenic freezers, a large amount of residual gas contained in the adhesive is released over time, freezing in the freezing section, leading to deterioration, etc., as well as applying the adhesive to the narrow housing cover 84 is difficult and difficult to apply. There was a problem that the productivity is reduced as the time to harden additionally.

The present invention has been made in view of the above problems of the regenerator of the conventional sterling refrigerator, it is an object of the present invention to provide an assembly structure of a regenerator for a sterling refrigerator that can be easily assembled to the housing body.

In order to achieve the object of the present invention, the piston coupled to the mover of the drive motor to reciprocate linearly in the interior of the cylinder, and is inserted into one side of the cylinder by sliding to interlock with the piston to compress / expand the working gas The displacer, a cold finger tube having a cryogenic portion by sealingly coupled to one side of the cylinder, and a heat storage material coupled to one side of the displacer to accumulate / discharge thermal energy of the working gas while reciprocating inside the cold finger tube. In the cryogenic freezer including a regenerator, the regenerator is formed of a tubular body to accommodate the heat storage material and a coupling groove formed on the inner circumferential surface thereof, and a coupling protrusion to be engaged with the coupling groove of the housing body to form a cold finger of the housing body. Extremely low, characterized in that consisting of a housing cover for covering the tube end It provides player mounting structure of the refrigerator.

Hereinafter, the regenerator assembly structure of the cryogenic freezer according to the present invention will be described in detail based on the embodiment shown in the accompanying drawings.

Figure 3 is a perspective view showing the regenerator disassembled in the present invention sterling refrigerator, Figure 4 is a cross-sectional view showing the assembly of the regenerator in the present invention sterling refrigerator.

As shown therein, the regenerator of the sterling refrigerator of the present invention includes a housing 110 coupled to the body 51 of the displacer (shown in FIG. 1) with a predetermined internal space, and the housing ( Inserted into the internal space of the 110 is configured as a heat storage material 120 to accumulate / discharge the thermal energy of the working gas.

The housing 110 has a housing body 111 formed of a cylindrical hollow body and a cold finger tube (shown in FIG. 1) by covering one side of the housing body 111 and forming a plurality of second gas through holes 112a ( It consists of a housing cover 112 for communicating the interior of the housing 70 and the inner space of the housing (111).

The housing body 111 negatively forms the coupling groove 111a to be inserted into the coupling protrusion 112b of the housing cover 112, which will be described later, on one side inner circumferential surface coupled with the housing cover 112. In addition, the inclined guide surface 111b is formed at the opening side end of the housing body 111 so as to extend outward so that the engaging protrusion 112b of the housing cover 112 can be inserted smoothly.

The housing cover 112 is formed in a 'cup' shape to be inserted and coupled to one end of the housing body 111, but is inserted into and coupled to the coupling groove 111a of the housing body 111 on the outer circumferential surface thereof. The coupling protrusion 112b is formed as much as possible. Coupling protrusion 112b is preferably to form an inclined sliding surface (112c) to be inserted into the housing body 111 smoothly.

In addition, the opening side of the housing cover 112 is a longitudinal direction of several incisions (112d) along the circumferential direction so that the coupling protrusion (112b) when the insertion protrusion 112b is inserted into the housing body 111 and unfolded to some extent It is preferable to form long.

The heat storage material 120 is manufactured by forming a stainless fiber in the form of cotton or fabric as described above, and inserts into the interior of the housing.

Regenerator assembly structure of the present invention sterling refrigerator as described above has the following effects.

That is, in order to assemble the regenerator, first, the housing cover 112 is pushed into the end of the housing body 111, and the engaging protrusion 112b of the housing cover 112 is coupled to the coupling groove 111a of the housing body 111. To lock it in place.

At this time, the opening side of the housing cover 112 is formed by several incisions 112d, and when the housing cover 112 is pushed and inserted into the housing body 111, the opening side of the housing cover 112 is slightly retracted. As the diameter of the opening side becomes narrow along the part 112d, the housing cover 112 can be inserted easily.

In addition, the housing cover 112 is further formed by forming the inclined guide surface 111b at the end of the housing body 111 and the inclined sliding surface 112c at the engaging protrusion 112b of the housing cover 112 opposite thereto. Easy to insert

In this way, by fitting the housing cover to the housing body forming the regenerator, it is possible to eliminate the use of adhesive to prevent the deterioration of the freezing part due to residual gas and to simplify the assembly operation of the regenerator. It can be performed and additional processes such as hardening after assembly can be omitted, thus simplifying the assembly work and increasing productivity.

 The regenerator assembly structure of the cryogenic freezer according to the present invention, by assembling the housing body for accommodating the heat storage material and the housing cover for covering it, thereby eliminating the use of adhesive to prevent the deterioration of the freezing part due to residual gas in advance. In addition, the assembly of the regenerator can be easily and quickly performed to increase the productivity of the regenerator.

Claims (4)

A piston coupled to the mover of the drive motor to linearly reciprocate in the cylinder, a displacer that slides into one side of the cylinder and is interlocked with the piston to compress / expand the working gas and seals to one side of the cylinder. In the cryogenic freezer including a cold finger tube having a cryogenic portion coupled to, and a regenerator having a heat storage material to accumulate / discharge the heat energy of the working gas while reciprocating inside the cold finger tube coupled to one side of the displacer, The regenerator is formed of a tubular body to receive the heat storage material, and a housing body for forming a coupling groove in the inner circumferential surface thereof, and a coupling protrusion for engaging with the coupling groove of the housing body to cover the cold finger tube side end of the housing body. Regenerator assembly structure of the cryogenic freezer, characterized in that consisting of. The method of claim 1, The coupling protrusion is a regenerator assembly structure of the cryogenic freezer, characterized in that to form the inclined insertion direction on the housing body. The method of claim 2, End of the housing body is a regenerator assembly structure of the cryogenic freezer, characterized in that the coupling protrusion of the housing cover is formed to be inclined so as to slide. The method according to any one of claims 1 to 3, The housing cover is a regenerator assembly structure of the cryogenic freezer, characterized in that to form several cuts in the longitudinal direction on the rim.

Images