KR100314025B1 - Structure for fixing spring of lubricationless pulse tube refrigerator - Google Patents

Abstract

The present invention relates to a spring fixing structure of the non-lubricated pulsating tube refrigerator, the inner circumferential surface of the casing is formed with a fixed jaw portion is fixed to the elastic member, the spacer is interposed between the fixed jaw portion and the elastic member in the appropriate place A fastening hole having an insertion groove is formed to protrude from the upper surface of the fixed jaw portion to a predetermined height, and the fastening hole is fastened to the fastening hole of the fixing jaw at the center of the spacer and the outer circumference of the elastic member corresponding to the fastening hole of the fixed jaw portion. Through-holes and through-holes are formed to pass through the fastening bolts respectively, so that the springs are fixed, so that spacers interposed between the springs and the fixing jaw portions are press-fitted into the fastening holes of the fixing jaw portions at the time of assembling the respective springs so as to always maintain their positions. Therefore, bolting is easy and productivity is improved.

Description

STRUCTURE FOR FIXING SPRING OF LUBRICATIONLESS PULSE TUBE REFRIGERATOR}

The present invention relates to a spring fixing structure of the non-lubricated pulsating tube refrigerator, and more particularly, to a spring fixing structure of a lubricating pulsating tube refrigerator suitable for fixing a spring for inducing the resonant and straight movement of the piston to the casing of the drive unit.

In general, cryogenic freezer is a low vibration high reliability freezer used for cooling small electronic parts or superconductor, mainly Stirling Refrigerator, GM Refrigerator or Joule-Thomson Refrigerator. This is widely known. These refrigerators have to be lubricated for high speed operation as well as to reduce lubrication at the time of operation. Therefore, in recent years, the refrigerators are maintained in high speed operation and do not require long-term maintenance. Cryogenic freezers are required, and one of such cryogenic freezers is a lubricationless pulse tube refrigerator.

1 is a schematic view showing an example of a conventional non-lubricated pulsating tube refrigerator, as shown in the related art. It is composed of a refrigeration unit (20) having a cryogenic portion by the thermodynamic cycle of the working gas reciprocating in the tube while being pumped by (10).

The drive unit 10 includes a casing 11 having a cylinder 10a, a linear drive motor 12 mounted inside the casing 11, and a drive shaft coupled to the drive motor 12. 13, a piston 14 connected to the drive shaft 13 and inserted into the cylinder 10a, and an upper plate 15 and a lower plate spring 16 coupled to upper and lower ends of the drive shaft 13, respectively. )

On the inner circumferential surface of the casing 11, a fixing jaw portion 11a on which the upper plate spring 15 and the lower plate spring 16 are seated is precisely formed, and the spring 15, A fastening hole 11a-1 for fastening 16 is formed.

The upper leaf spring 15 and the lower leaf spring 16 are formed by overlapping several leaf springs formed in a spiral type, and fastening holes of the fixing jaw portion 11a are formed at the outer circumference of the leaf springs 15 and 16. The through holes 15a and 16a are formed so as to correspond to 11a-1. The outer circumferential surface of each spring 15, 16 in close contact with the inner circumferential surface of the casing 11 is precisely processed.

A washer spacer 17 is disposed between the fixing jaw portion 11a of the casing 11 and one side of each of the springs 15 and 16 opposite to each other so that the respective springs 15 and 16 maintain the horizontality. It is mounted on one fixed jaw part 11a.

In the drawings, reference numeral 17a denotes a through hole of the spacer, 21 precooler, 22 regenerator, 23 pulsation tube, 23A cold side heat exchanger, 23B on side heat exchanger, 24 on orifice, 25 on storage vessel, 26 Freezing side sealing shell, B is a fastening bolt.

The process of assembling the drive unit in the conventional non-lubricated pulsating tube refrigerator configured as described above is as follows.

First, the stator of the drive motor 12 is fixed inside the casing 11, the mover is inserted into the cavity of the stator, and then the drive shaft 13 is integrally fastened to the mover, and the drive shaft 13 Fastening the upper plate spring 15 and the lower plate spring (16) fixed to the casing (11) to the top and bottom of each.

At this time, several fastening holes 11a-1 are formed in the fixing jaw portion 11a of the casing 11 so that the through holes 17a of the spacers 17 coincide with the fastening holes 11a-1. The two spacers 17 on the fixed jaw portion 11a, and the through holes 115a and 16a of the upper spring 15 and the lower spring 16 pass through the through holes 17a of the spacers 17, respectively. The through holes 15a and 16a of the upper plate spring 15 and the lower plate spring 16 and the through holes 17a of the spacer 17 in a state in which they are aligned with the fastening holes 17a-1 of the fixing jaw portion 11a. The springs 15 and 16 are fixed to the fixing jaw portion 11a of the casing 11 by a separate fastening bolt B fastened to the fastening holes 17a-1 of the fixing jaw portion 11a.

Next, the piston 14 is coupled to the upper end of the drive shaft 13, and the casing 11 is covered with the upper frame (unsigned) of the casing 11 so that the piston 14 is inserted parallel to the cylinder 10a. The remaining parts of 11 were sealed and assembled so that the refrigeration unit 20 communicated with the cylinder 10a of the drive unit 10.

When power is applied to the drive motor 12 of the conventional non-lubricated pulsating tube refrigerator assembled as described above, the drive shaft 13 is linearly reciprocated by the upper plate spring 15, and integrated into the drive shaft 13. Piston 14 coupled to the reciprocating movement in a straight line in the cylinder (10a) to pump the operating gas of the refrigeration unit 20 was to form the cryogenic portion on the cold side heat exchanger 22 side of the pulsating tube (21).

However, in the spring fixing structure of the conventional non-lubricated pulsating tube refrigerator, the springs 17 and 16 are put back on the upper surface of the fixing jaw portion 11a and fastened to the fixing bolts B by the spacers 17. In this process, the spacer 17 slides from the fixed jaw portion 11a in position, and the through hole 17a of the spacer 17 passes through the through holes 15a and 16a of the springs 15 and 16, respectively. ) And the fastening holes 11a-1 of the fixing jaw portion 11a, there is a problem that the assembly is cumbersome because the position of the spacer 17 needs to be adjusted again.

The present invention has been made in view of the problems of the spring fixing structure of the conventional non-lubricated pulsating tube refrigerator as described above, to provide a spring fixing structure of the non-lubricating pulsating tube refrigerator easy to assemble the upper plate and the lower plate spring. There is a purpose.

1 is a longitudinal sectional view showing an example of a conventional non-lubricated pulsating tube refrigerator.

Figure 2 is a partial perspective view showing an exploded fastening structure of the leaf spring in the conventional non-lubricated pulsating tube refrigerator.

Figure 3 is a longitudinal sectional view showing an example of the present invention a non-lubricated pulsating tube refrigerator.

Figure 4 is a partial perspective view showing an exploded fastening structure of the leaf spring in the present invention a non-lubricated pulsating tube refrigerator.

Figure 5 is a longitudinal cross-sectional view showing a modification of the fastening structure of the leaf spring in the present invention lubrication-free pulsating tube refrigerator.

** Explanation of symbols for the main parts of the drawings **

110: casing 111: upper frame

111a: fixing jaw portion 111a-1: fastening hole

111a-2: spacer insert groove 120: drive motor

130: drive shaft 140: piston

150,160: Upper plate and lower plate spring 151: Through hole

170: spacer 171: through hole

B: Tightening Bolt N: Tightening Nut

In order to achieve the object of the present invention, the piston of the drive unit for pumping the operating gas of the refrigeration unit is coupled to the drive shaft in a linear motion is inserted into the cylinder, coupled to both ends of the drive shaft and the drive motor of the drive shaft An elastic member for inducing a resonance motion and a straight motion is fixed to the casing of the drive unit,

An inner circumferential surface of the casing is provided with a fixed jaw portion fixed with an elastic member mounted thereon, and a spacer interposed between the fixed jaw portion and the elastic member protrudes from an upper surface of the fixed jaw portion at an appropriate height in an appropriate position of the fixed jaw portion, and is inserted therein. A fastening hole having a fastening hole is formed, and through-holes and through-holes are formed at the axial center of the spacer corresponding to the fastening hole of the fixing jaw and the outer periphery of the elastic member so that the fastening bolt fastened to the fastening hole of the fixing jaw is formed. A spring fixing structure of a lubrication free pulsating tube refrigerator is provided.

Hereinafter, the spring fixing structure of the non-lubricating pulsating tube refrigerator according to the present invention will be described in detail based on the embodiment shown in the accompanying drawings.

Figure 3 is a longitudinal cross-sectional view showing an example of the present invention a non-lubricated pulsating tube freezer, Figure 4 is a partial perspective view showing an exploded fastening structure of the leaf spring in the non-lubricated pulsating tube refrigerator.

As shown therein, the non-lubricated pulsating tube refrigerator provided with the spring fixing structure according to the present invention includes a drive unit 100 for generating a reciprocating motion of the working gas, and a pump unit reciprocating in the tube while being pumped by the drive unit 100. It consists of a refrigeration unit (20) having a cryogenic portion by a thermodynamic cycle of the working working gas.

The drive unit is coupled to the casing 110, the linear drive motor 120 mounted inside the casing 110, and the drive motor 120 is provided with a cylinder (110a) for linear reciprocating motion Drive shaft 130, the piston assembly 140 coupled to the drive shaft 130 and inserted into the interior of the cylinder (110a), and the upper and lower springs 150 and the lower plate spring coupled to the upper and lower ends of the drive shaft 130, respectively ( 160).

The casing 110 is the upper frame 111, the cylinder (110a) is formed, the stopping frame 112 is fastened to the upper frame 111, the drive motor 120 is mounted, and the stopping frame 112 The lower frame 113 is fastened to be fixed to, and the interrupting frame 112 and the lower frame 113 is accommodated in the sealing shell 114 is sealed to the upper frame 111.

On the inner circumferential surfaces of the upper frame 111 and the lower frame 113, fixing jaw portions 111a (unsigned) to which the upper plate spring 150 and the lower plate spring 160 are mounted are formed, and each of the fixing jaw portions 111a. In the appropriate portion of the, unsigned) is formed a fastening hole (111a-1, unsigned) for fastening the respective springs (150, 160).

In addition, the spacer 170, which will be described later, is inserted into the fastening hole 111a-1 (not shown) of the fixing jaw portion 111a (not shown) so as to protrude from the upper surface of the fixing jaw portion 111a (not shown) to a certain height and press-fit the spacer. Insertion groove 111a-2 (not shown) is formed stepped, the fastening hole (111a-1, unsigned) through holes (151, unsigned) and the through hole of the spacer 170 of each spring 150,160 A screw portion is formed so that the fastening bolt B passing through 171 is screwed, or the fastening bolt B is fastened to the fixing jaw portion 111a (not shown) as shown in FIG. 5. It may be screwed into the fastening nut (N) from the other side through 1).

The spacer 170 is formed of an elastic member so that its outer diameter is somewhat larger than the diameter of the spacer insertion groove 111a-2 (unsigned) of the fixing jaw portion 111a (not shown), and its height is also higher than the spacer insertion groove 111a-. 2, unsigned) is formed somewhat higher than the depth of the spacer 170, the through hole (151, unsigned) of the spring 150, 160 and the fastening hole (111a, unsigned) of the fastening hole (111a-) A through hole 171 perpendicular to 1, unsigned is formed.

In the drawings, the same reference numerals are given to the same parts as in the prior art.

The process of fastening each spring to the casing in the non-lubricated pulsating tube refrigerator according to the present invention as described above is as follows.

First, each spacer 170 is press-fitted into the spacer insertion groove 111a-2 (not shown) of each of the fastening holes 111a-1 (not shown) formed in the fixing jaw portion 111a (not shown) of the casing 110. Then, the respective through holes 151 (not shown) formed at the outer periphery of the springs 150 and 160 coincide with the through holes 171 of the spacers 170, and each spring is placed on the upper surface of the spacer 170. Put on (150,160).

Subsequently, through the through holes 151 (unsigned) from the upper surface of each of the springs 150 and 160, and through the through holes 171 of the spacer 170, the fastening holes 111a-1 of the fixing jaw portions 111a and unsigned. Using the fastening bolt (B) to reach the unsigned) to each spring 150, 160 is fastened to the fixing jaw portion (111a, unsigned) of the casing 110.

At this time, if the threaded portion is formed in the fastening hole 111a-1 (not shown) of the fixing jaw portion (111a, unsigned), the fixing bolt (B) directly to the threaded portion of the fastening hole (111a-1, unsigned) When the fixing bolt (B) passes through the fastening hole (111a-1, unsigned) of the fixing jaw portion (111a, unsigned), the fixing bolt (B) is fastened to the fastening hole (111a-1, unmarked). By using a separate fastening nut (N) on the outer surface of the reference) to complete the fixing work of each spring (150, 160).

In this way, a spacer is interposed between the fixing jaw of the casing and the upper plate spring and the lower plate spring, and the spacer is pre-injected into the spacer insertion groove of the fixing jaw so that the through holes of the spacer coincide with the respective fastening holes of the fixing jaw. When each spring is fixed to the fastening bolt, the assembly of the respective springs is facilitated by preventing the spacers from being pushed by the respective springs when the upper and lower springs are assembled.

Spring fixing structure of the non-lubricated pulsating tube refrigerator according to the present invention, the inner peripheral surface of the casing is formed with a fixing jaw to which the elastic member is mounted and fixed, the spacer is interposed between the fixing jaw and the elastic member in the appropriate place A fastening hole having an insertion groove is formed to protrude from the upper surface of the fixed jaw portion to a predetermined height, and the fastening hole is fastened to the fastening hole of the fixing jaw at the center of the spacer and the outer circumference of the elastic member corresponding to the fastening hole of the fixed jaw portion. Through-holes and through-holes are formed to pass through the fastening bolts respectively, so that the springs are fixed, so that spacers interposed between the springs and the fixing jaw portions are press-fitted into the fastening holes of the fixing jaw portions at the time of assembling the respective springs so as to always maintain their positions. Therefore, bolting is easy and productivity is improved.

Claims (1)

The piston of the drive unit for pumping the working gas of the refrigerating unit is coupled to the drive shaft for linear movement, inserted into the cylinder, and coupled to both ends of the drive shaft and elastic to induce the resonant and straight movement of the drive shaft together with the drive motor. The member is fixed to the casing of the drive unit described above, An inner circumferential surface of the casing is provided with a fixed jaw portion fixed with an elastic member mounted thereon, and a spacer interposed between the fixed jaw portion and the elastic member protrudes from an upper surface of the fixed jaw portion at an appropriate height in an appropriate position of the fixed jaw portion, and is inserted therein. A fastening hole having a fastening hole is formed, and through-holes and through-holes are formed at the axial center of the spacer corresponding to the fastening hole of the fixing jaw and the outer periphery of the elastic member so that the fastening bolt fastened to the fastening hole of the fixing jaw is formed. Spring fixed structure of the non-lubricating pulsating tube refrigerator.