KR100524729B1 - Assembly structure for stirling refrigerator and method thereof - Google Patents

Abstract

The present invention relates to an assembly structure and a method of a cryogenic refrigerator, and the present invention is installed in the sealed container and the drive motor to reciprocate in a straight line and the mover, coupled to the mover of the drive motor in a straight line inside the cylinder A piston for reciprocating motion, a displacer which slides into one side of the cylinder and interlocks with the piston to compress / expand the working gas, a cold finger for sealingly coupled to one side of the sealed container, and housed inside the cold finger. In the cryogenic freezer comprising a regenerator having a heat storage material to accumulate / discharge the thermal energy of the working gas, and a cryogenic plate formed by sealingly coupled to one side of the cold finger to form a cryogenic portion, an insertion protrusion is formed on one side of the cryogenic plate The outer circumferential surface of the insertion protrusion of the plate and the inner circumferential surface of the cold finger are joined, while the other end of the cold finger is By bonding the interface between the side and the hermetically sealed container, to simplify the assembling process of the sealed container and the cold finger and the cryogenic cold finger plates it can further enhance the mass-productivity of the Stirling refrigerating machine. In addition, since the uprights of each member can be adjusted with a separate jig in the heating furnace, the failure rate during assembly can be effectively lowered.

Description

Assembly structure of cryogenic refrigerator and its method {ASSEMBLY STRUCTURE FOR STIRLING REFRIGERATOR AND METHOD THEREOF}

The present invention relates to a cold finger of the sterling refrigerator, and more particularly, to an assembly structure and a method of the sterling refrigerator that can be easily assembled cold finger.

In general, a cold finger is a core part of a cryogenic refrigerator, and is a device that generates a cryogenic part by accommodating a regenerator that accumulates / discharges heat energy while exchanging heat with a working gas flowing between the refrigeration part and the compression part. Such cold fingers are usually fixed to both ends of the compression section and the freezing section by using brazing welding.

1 is a cross-sectional view showing an example of a conventional sterling freezer, Figure 2 is a perspective view showing the decomposition of the cold finger in the conventional sterling freezer.

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 70 and the cold gap to the cold finger 70 to seal Regenerator 80 is inserted to have and coupled to the displacer 50 accumulates / discharges the thermal energy of the operating gas, and the cryogenic plate 90 is coupled to the other end of the cold finger 70 to form a cryogenic temperature, have.

Cold finger 70 is formed in a cylindrical shape as shown in Figs. 2 and 3 and one end is fixed in close contact with the airtight container 10 while the other end is fixed by inserting the cryogenic plate 90. To this end, as shown in FIG. 3, while one end of the cold finger 70 is in close contact with the sealed container 10, the blazing welding is performed along the edge of the cold finger 70 using a high frequency welding machine, while the cold finger ( The other end of 70) inserted the insertion protrusion 91 of the cryogenic plate 90 into the cold finger 70 described above, and fixed the other end interface of the cold finger 70 by blazing welding with a high frequency welder.

In the drawings, 21 is an outer stator, 22 is an inner stator, 23 is a movable member, 50a is a gas through hole, 80a is a gas through hole, 81 is a heat storage material, and S1 and S2 are compression and expansion spaces.

However, the conventional sterling refrigerator as described above, the cold finger 70 as described above was placed between the sealed container 10 and the cryogenic plate 90 to assemble by blazing welding both ends, which is blazing Since welding (w1, w2) has to be performed twice, there is a possibility that the defective rate will increase due to difficulty in securing shape tolerances such as squareness during welding as well as inferior productivity.

The present invention has been made in view of the problems of the conventional sterling refrigerator as described above, to provide an assembling structure and a method for assembling a cold finger and cryogenic plate easily and stably in a sealed container and an object of the present invention. There is this.

In order to achieve the object of the present invention, the drive motor is installed in the sealed container to move the reciprocating motion in a straight line, the piston coupled to the mover of the drive motor to reciprocate in a straight line in the cylinder, the cylinder A displacer that compresses / expands the working gas while interlocking with the piston by slidingly inserted at one side thereof, a cold finger sealingly coupled to one side of the sealed container, and stored / released thermal energy of the working gas contained inside the cold finger. In the cryogenic freezer including a regenerator having a heat storage material and a cryogenic plate which is sealed to one side of the cold finger to form a cryogenic portion, an insertion protrusion is formed on one side of the cryogenic plate to form the outer peripheral surface of the cryogenic plate and the cold finger. The other end of the cold finger joins the interface between the outer circumference of the cold finger and the sealed container. It provides an assembly structure of the cryogenic freezer, characterized in that.

In addition, by providing an insertion groove for inserting the cold finger on one side of the cryogenic plate provides an assembly structure of the cryogenic freezer, characterized in that the welding member sandwiched between the inner peripheral surface of the insertion groove of the cryogenic plate and the outer peripheral surface of the cold finger.

In addition, the welding member is inserted into the cold finger by inserting the welding member into the insertion protrusion or the insertion groove of the cryogenic plate at the same time, and the other welding member is arranged on the outer peripheral surface of the other end of the cold finger to arrange the welding member to be in close contact with the sealed container; Inserting a cold finger in a furnace (Furnance) and then heated to a predetermined temperature to perform the step of melting both the welding member and the cryogenic plate, the cold finger and the sealed container and the cold finger are bonded together It provides a method for assembling a cryogenic freezer.

Hereinafter, the assembling structure and method of the Stirling refrigerator according to the present invention will be described in detail based on the embodiment shown in the accompanying drawings.

Figure 4 is a perspective view showing the decomposition of the cold finger in the present invention sterling freezer, Figure 5 is a cross-sectional view of the assembled cold finger in the present invention sterling freezer, Figure 6 is a variant for the cold finger and cryogenic plate in the present invention sterling freezer An example is a half cross-sectional view of the assembly, Figure 7 is a block diagram showing a process of assembling a cold finger in the present invention sterling refrigerator.

Referring to FIG. 1, a sterling refrigerator of the present invention includes a sealed container 10 having a predetermined internal space and a reciprocating motor in which the mover 23 reciprocates in a straight line provided in the sealed container 10. 20), the cylinder 30 which is fixed to the sealed container 10 to fill the working gas therein, and the mover 23 of the reciprocating motor 20, is coupled to one side of the cylinder 30 in a straight line. A piston 40 for pumping the working gas of the cylinder 30 by inserting the reciprocating motion and a micro void in the other side of the cylinder 30 are inserted to interlock with the piston 40 to cool the refrigerant gas. A displacer 50 for compressing / expanding the support, a support spring 60 fixed to the closed container 10 so as to elastically support one side of the displacer 50 to maintain concentricity, and an outlet side of the cylinder 30. Cold finger 110 and the cold finger to connect and seal the fine pores 110 So as to insert comprises a cryogenic plate 120 forming the extremely low temperature by binding to the other end of the regenerator 80, and a cold finger 110, which binds to the displacer 50, the accumulation / discharge the thermal energy of the above-mentioned working gas.

Here, the cold finger 110 is formed in a cylindrical shape as shown in Figs. 4 and 5, one end thereof is in close contact with the sealed container 10 and fusion-fixed with the first welding ring 131 while the other end is described above. The cryogenic plate 120 is inserted to fix the fusion with the second welding ring 132.

To this end, one end of the cold finger 110 as shown in Figure 7 is inserted into the first welding ring 131 on the outer peripheral surface. In addition, the cryogenic plate 120 protrudes and forms the insertion protrusion 122 so as to have an outer diameter substantially equal to the inner diameter of the cold finger 110 described above in the center of the side of the cryogenic portion 121 formed in a disc shape. After inserting the second welding ring 132 into the 122, the insertion protrusion 122 is inserted into the cold finger 110. (S1) In this case, the second welding ring (2) is formed on the outer circumferential surface of the insertion protrusion 122. Forming the welding ring insertion groove 122a negatively by the thickness of 132 may facilitate preliminary assembly of the cold finger 110 and the cryogenic plate 120.

Thereafter, the cold finger 110 is placed in contact with the interface with the sealed container 10 is placed in the heating furnace. (S2)

Thereafter, the both welding rings 131 and 132 are fused by heating to a predetermined temperature to simultaneously bond the cold finger 110 and the closed container 10, and the cold finger 110 and the cryogenic plate 120 at the same time. (S3)

On the other hand, as shown in Figure 6 the insertion groove 123 to have an inner diameter almost the same as the outer diameter of the cold finger 110 to insert one end of the cold finger 110 in the center of one side of the cryogenic plate 120 Forming, but forming a welding ring insertion groove (123a) in the inner peripheral surface of the insertion groove 123 to insert the second welding ring 132, and then the outer peripheral surface of the cold finger 110 is the welding ring 132 The cold finger 110 is inserted into the insertion groove 123 of the cryogenic plate 120 to be in contact with the inner circumferential surface and heated to a predetermined temperature in a heating furnace to melt the second welding ring 132 while the cold finger ( The outer circumferential surface of the 110 and the inner circumferential surface of the insertion groove 123 of the cryogenic plate 120 may be bonded to each other.

In this way, when the cold finger is bonded to the airtight container and assembled, and the cold finger is joined to the cryogenic plate at the same time, the bonding process of the airtight container and the cold finger and the cold finger and the cryogenic plate can be simplified by joining both junctions at the same time. This can further increase the mass productivity of the sterling refrigerator.

In addition, when a separate jig is installed and joined in the heating furnace, shape tolerances such as the uprightness of each member can be easily secured, thereby effectively lowering the defective rate during assembly.

The assembly structure of the sterling refrigerator according to the present invention and the method, through the welding ring on the interface between the sealed container and the cold finger, and also to be fused at the same time in the heating furnace through the welding ring between the cold finger and the cryogenic plate, The production process of the sterling refrigerator can be further increased by simplifying the assembly process of the container, the cold finger, and the cold finger and the cryogenic plate.

In addition, since the uprights of each member can be adjusted with a separate jig in the heating furnace, the failure rate during assembly can be effectively lowered.

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 cold finger in the conventional sterling refrigerator,

3 is a half sectional view of assembling a cold finger in a conventional sterling refrigerator;

Figure 4 is a perspective view showing the decomposition of the cold finger in the present invention sterling refrigerator,

Figure 5 is a half sectional view of assembling a cold finger in the present invention sterling refrigerator,

Figure 6 is a cross-sectional view of the modified example for the cold finger and the cryogenic plate in the present invention sterling refrigerator,

Figure 7 is a block diagram showing a process of assembling a cold finger in the present invention sterling refrigerator.

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

10: sealed container 110: cold finger

120: cryogenic plate 121: cryogenic part

122: insertion protrusion 122a: welding ring insertion groove

123: insertion groove 123a: welding ring insertion groove

131,132: first and second welding ring

Claims (5)

A drive motor installed inside the sealed container to reciprocate linearly by the mover, a piston coupled to the mover of the drive motor to reciprocate linearly inside the cylinder, and a piston inserted to slide on one side of the cylinder and A regenerator including a displacer for compressing / expanding the working gas while interlocking together, a cold finger sealingly coupled to one side of the sealed container, and a heat storage material accommodated in the cold finger to accumulate / discharge thermal energy of the working gas; In the cryogenic freezer including a cryogenic plate sealingly coupled to one side of the cold finger to form a cryogenic portion, An assembly structure of a cryogenic freezer, characterized in that the insertion protrusions are formed on one side of the cryogenic plate and a welding member is inserted between the outer circumferential surface of the cryogenic plate and the inner circumferential surface of the cold finger. The method of claim 1, Cryogenic freezer assembly structure characterized in that the insertion projections of the cryogenic portion to form the welding member insertion groove to be inserted so as to insert the above welding member. A drive motor installed inside the sealed container to reciprocate linearly by the mover, a piston coupled to the mover of the drive motor to reciprocate linearly inside the cylinder, and a piston inserted to slide on one side of the cylinder and A regenerator including a displacer for compressing / expanding the working gas while interlocking together, a cold finger sealingly coupled to one side of the sealed container, and a heat storage material accommodated in the cold finger to accumulate / discharge thermal energy of the working gas; In the cryogenic freezer including a cryogenic plate sealingly coupled to one side of the cold finger to form a cryogenic portion, Assembling structure of the cryogenic freezer, characterized in that the insertion groove for inserting the cold finger on one side of the cryogenic plate is formed by joining the welding member between the inner peripheral surface of the insertion groove of the cryogenic plate and the outer peripheral surface of the cold finger. The method of claim 3, Cryogenic freezer assembly structure, characterized in that the insertion groove portion of the cryogenic portion to form the welding member insertion groove to be inserted so as to insert the welding member. And inserting a welding member into the cold finger of the cryogenic plate of claim 1 or 3 to insert the welding member into an outer peripheral surface of the other end of the cold finger and arranging the welding member to be in close contact with the sealed container; Inserting the pre-assembled cold finger into the furnace (Furnance) and then heated to a predetermined temperature to perform the step of bonding the cryogenic plate, the cold finger and the sealed container and the cold finger while melting both of the welding member described above. Assembling method of cryogenic freezer.