KR20030032337A - Apparatus for fixing piston of reciprocating compressor - Google Patents

Abstract

PURPOSE: An apparatus for fixing a piston of a reciprocating compressor is provided to miniaturize the compressor. CONSTITUTION: An apparatus comprises a reciprocating motor in which a mover linearly reciprocates; a piston(140) joined to the mover of the reciprocating motor to linearly reciprocate in a cylinder, and having a female screw part(141a) formed on an inside thereof; a spring support(171) interposed between the mover and the piston to be fixed, and supporting resonant springs inducing resonant movement of the mover and the piston; and a coupling member(200) having a head part(210) pressed on an inside of the mover, and a male screw part(220) passing the mover and the spring support and screwed to the piston.

Description

Piston fixture of reciprocating compressor {APPARATUS FOR FIXING PISTON OF RECIPROCATING COMPRESSOR}

The present invention relates to a piston fixing device of a reciprocating compressor, and more particularly, to a piston fixing device of a reciprocating compressor capable of easily and concentrically coupling a piston and a mover of a reciprocating motor.

In general, a reciprocating compressor (Linear Compressor) is coupled to the rotary motor to the piston to reciprocate in a straight line, or coupled to the reciprocating motor to the piston to reciprocate in a straight line to suck and compress the fluid and discharge, especially reciprocating When the piston is coupled to the motor, the concentricity of the two members as well as the spring inducing the resonant movement of the two members must be maintained together to maintain the concentricity of the compressor.

In the reciprocating compressor using such a reciprocating motor, the present invention looks at the counter reciprocating compressor as an example, as shown in FIG.

As shown in this figure, the opposite reciprocating compressor includes a casing 10 having a plurality of suction pipes SP and one discharge pipe DP, and reciprocating mounted on both sides of the casing 10, respectively. The reciprocating motors 20 and 20 are slidably inserted into the cylinders 30 and the cylinders 30 mounted between the synchronous motors 20 and 20 and both reciprocating motors 20 and 20. Pistons (40) and (40), which are coupled to the movers (23) and (23) of (), to form a compression space (S), and suction valve assemblies (50) mounted on the front end surfaces of both pistons (40) and (40). (50), discharge valve assemblies (60) and (60) for opening and closing the compression space (S) between both pistons (40) and (40), and the mover of the reciprocating motors (20, 20) ( It includes a spring assembly 70, 70 for elastically supporting the 23 and 23 and the piston 40 and 40 to induce a resonant motion.

The reciprocating motors 20 and 20 each have a cylindrical shape and are fixed to the casing 10 by the outer stators 21 and 21 and the inner stators 22 and 22, and the outer stators 21 and 21. And the movable members 23 and 23 which reciprocate in a straight line from side to side through an inner stator 22 and 22.

The movers 23 and 23 are coupled to the pistons 40 and 40, and magnet frames 23A and 23A positioned between the outer stators 21 and 21 and the inner stators 22 and 22, It consists of a plurality of magnets 23B and 23B which are mounted on the outer circumferential surface of the magnet frames 23A and 23A to induce induction magnetism.

As shown in FIG. 2, the magnet frames 23A and 23A are bent to form fixing parts 23a and 23a closely contacted between the pistons 40 and 40 and the spring supports 71 and 71 at one end thereof. Piston through-holes 23b and 23b through which the piston bodies 41 and 41 penetrate are formed in the center of the fixing parts 23a and 23a, and fastening bolts are formed at the edges of the fixing parts 23a and 23a. The bolt through holes 23c and 23c through which (B) and (B) pass are formed.

The pistons 40 and 40 are flanged 42 and 42 at the rear ends of the piston bodies 41 and 41 so as to be in close contact with the inner surfaces of the fixing portions 23a and 23a of the magnet frames 23A and 23A. Fastening bolts B and B which have passed through the spring supports 71 and 71 with the magnet frames 23A and 23A interposed therebetween. The bolt fastening holes 42a and 42a are formed.

The spring assemblies 70 and 70 are in close contact with the outer surfaces of the fixing portions 23a and 23a of the magnet frames 23A and 23A, and are coupled to the pistons 40 and 40 with the fastening bolts B and B. Several resonant springs 72 whose ends are supported at both ends of the spring supports 71 and 71 and both sides of the spring supports 71 and 71 and one side of the outer stator 21 and 21 corresponding thereto, respectively. It consists of 72 pieces.

Spring support (71) (71) is formed in the shape of a disc or disk shape deformed in the center of the bolt insertion groove (71a) (71a) to insert the head of the fastening bolt (B) (B) in the magnet frame ( It is formed to be recessed toward 23A and 23A, and a piston through hole 71b and 71b, through which piston bodies 41 and 41 pass, is formed in the center of the bolt insertion groove portions 71a and 71a. A plurality of bolt through holes 71c and 71c through which the fastening bolts B and B pass are formed outside the 71b and 71b.

In the drawings, reference numeral F denotes a suction flow path of the piston.

The conventional reciprocating compressor as described above operates as follows.

That is, when power is applied to both reciprocating motors 20 and 20, the respective pistons 40 and 40 linearly reciprocate in opposite directions within the cylinder 30, and at the same time the refrigerant gas It is sucked into the casing 10 through the suction pipes SP and thereafter, the refrigerant gas is introduced into the compression space S of the cylinder 30 by the continuous reciprocating motion of the pistons 40 and 40 and compressed. Then, a series of processes that are discharged to the system outside the casing 10 through the discharge pipe DP are repeated.

Here, the magnet frame, the piston and the spring support are assembled as shown in FIG.

First, spring supports 71 and 71 on the outer surfaces of the magnet frames 23A and 23A of the reciprocating motors 20 and 20 and the fixing parts 23a and 23a of the magnet frames 23A and 23A. The convex surfaces of the bolt insertion grooves 71b and 71b of the bolt contact each other.

Thereafter, the piston bodies 41 and 41 connect the piston through holes 23b and 23b of the magnet frames 23A and 23A and the piston through holes 71b and 71b of the spring supports 71 and 71. The flanges 42 and 42 of the pistons 40 and 40 are inserted into the magnet frame 23A while the piston bodies 41 and 41 are inserted from the inside of the magnet frames 23A and 23A to pass therethrough. It comes in close contact with the inner surface of the fixing parts 23a and 23a of 23A.

Subsequently, the fastening bolts B and B pass through the magnet frames 23A and 23A on the concave surface of the bolt insertion grooves 71a and 71a of the spring supports 71 and 71 so as to pass through the pistons 40 and 40. ) At this time, the bolt through holes 71c and 71c of the spring supports 71 and 71, the bolt through holes 23c and 23c of the magnet frames 23A and 23A, and the flange portions of the pistons 40 and 40. (42) The bolts (42a) (42a) provided in the (42) are aligned on the same axis, and then the bolts (B) toward the pistons (40) (40) from the outer surfaces of the spring supports (71) (71). (B) was passed through to screw the bolts into the bolting holes 42a and 42a of the pistons 40 and 40.

However, in the conventional reciprocating compressor as described above, as described above, the magnet frames 23A, 23A, the spring supports 71, 71, and the pistons 40, 40 are fastened to the fastening bolts (B) (B). Since the bolt seat is to be provided on each member as fastening, the diameter of each part is increased by the bolt seat, thereby increasing the size of the compressor.

In addition, when the magnet frames 23A, 23A, the spring supports 71, 71, and the pistons 40, 40 are fastened with the fastening bolts B and B, distortion occurs between the members. There was also a problem that it was difficult to match.

The present invention has been made in view of the above problems of the conventional reciprocating compressor, and the magnet frame, the spring support and the piston are formed to be small and easy to assemble so that the compactness of the compressor is easily matched with the concentricity between the members. SUMMARY OF THE INVENTION An object of the present invention is to provide a piston fixing device for a reciprocating compressor.

1 is a longitudinal sectional view showing an example of a conventional counter-reciprocating compressor.

Figure 2 is a longitudinal cross-sectional view showing a disassembled piston coupling structure in a conventional opposed reciprocating compressor.

Figure 3 is a longitudinal sectional view showing an example of the present invention opposed reciprocating compressor.

Figure 4 is an exploded longitudinal cross-sectional view showing a piston coupling structure in the present invention reciprocating compressor.

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

110: casing 120: reciprocating motor

123: mover 123A: magnet frame

123a: fixing part 123b: bolt through hole

140: piston 141: piston body

141a: female thread portion 142: support flange portion

150: suction valve assembly 160: discharge valve assembly

170: spring assembly 171: spring support

171a: piston mounting portion 171b: bolt through hole

171c: frame mounting protrusion 200: fastening member

210: head 220: male thread

230: gas passage S: compression space

In order to achieve the object of the present invention, a reciprocating motor in which the mover linearly reciprocates, a piston coupled to the mover of the reciprocating motor to reciprocate linearly in the cylinder and form a female thread therein; A spring support which is sandwiched and fixed between the chair and the piston and supports a resonant spring for inducing the resonant movement of the mover and the piston, and a head that is pressed against the inner surface of the mover and successively passed through the mover and the spring support. After the piston provides a piston fixing device of the reciprocating compressor, characterized in that the fastening member having a screw threaded to the piston.

Hereinafter, the piston fixing device of the reciprocating compressor according to the present invention will be described in detail based on the embodiment shown in the accompanying drawings.

Figure 3 is a longitudinal sectional view showing an example of the present invention reciprocating reciprocating compressor, Figure 4 is a longitudinal sectional view showing an exploded piston coupling structure in the present invention reciprocating compressor.

As shown in the drawing, the opposite reciprocating compressor including the piston fixing device according to the present invention is installed in the casing 110, and the movable members 123 and 123 reciprocate linearly. (120) 120 and the piston (140) (140) to slid into the through-hole 131 of the cylinder 130 by press-fitting into the movers (123, 123) of the reciprocating motor (120) (120). ), A bolt member 200 for screwing the pistons 123 and 123 to the movers 123 and 123 of the reciprocating motor 120 and 120, and the wires of both the pistons 140 and 140. Intake valve assembly 150, 150 mounted on the cross section, discharge valve assembly 160, 160 for opening and closing the compression space S between both pistons 140, 140, and a reciprocating motor Resonant spring assemblies 170 and 170 which are screwed to the movers 123 and 123 of the 120 and 120 to induce the resonant movement of the movers 123 and 123 and the pistons 140 and 140. ).

The movers 123 of the reciprocating motors 120 and 120 are magnet frames 123A and 123A which are inserted between the outer stator 121 and the inner stator 122 to reciprocate in a straight line, and the outer stator ( It consists of a plurality of magnets 123B and 123B mounted on the outer circumferential surface of the magnet frames 123A and 123A so as to correspond to the winding coils (not shown) of 121.

Magnet frame 123A (123A) is formed of a cylindrical shape using a non-conductive and non-magnetic material, such as engineer plastic, the front side of the inner surface is in close contact with the spring support 171 (171) to be described later, while the inner surface The bending parts 123a and 123a, which are caught by the heads 210 and 210 of the bolt members 200 and 200, are bent to form a bolt member (2) in the center of the fixing parts 123a and 123a. Bolt through holes 123b and 123b are formed to pass through the screw parts 220 and 220 of the 200 and 200.

The pistons 140 and 140 are formed in a cylindrical shape in which the front side is blocked by stainless steel or aluminum in consideration of abrasion or lubrication during the friction with the cylinder 130, and the bolt members 200 and 200 to be described later on the rear inner peripheral surface thereof. Female threaded portions 141a and 141a are formed at the inlet side of the suction flow path F so as to engage with the male threaded portions 220 and 220 of FIG.

The bolt member 200 forms heads 210 and 210 so that one end is caught by the inner surface of the fixing parts 123a and 123a of the magnet frames 123A and 123A, while the other end is a magnet frame. The male threaded portions 220 and 220 are formed to pass through the through holes 123b and 123b of the 123A and 123A to engage with the female threaded portions 141a and 141a of the piston 140 and 140. When the bolt members 200 and 200 are mounted on the front side of the piston 140 and 140 with the suction valve assemblies 150 and 150 in consideration of the suction flow paths F and F of the refrigerant gas, The through-holes 230 may be formed.

The spring assemblies 170 and 170 are spring supports 171 and 171 which are fastened to the magnet frames 123A and 123A of the reciprocating motors 120 and 120 and both sides of the spring supports 171 and 171. And a plurality of resonant springs 172 and 172 for supporting the magnet frames 123A and 123A and the pistons 140 and 140 to reciprocate linearly together.

The spring supports 171 and 171 have a piston mounting portion 171a and 171a which fit the support flange portions 142 and 142 of the piston 140 and 140 on one side to the magnet frames 123A and 123A. It is formed to be recessed, and in the center of the piston mounting portion (171a) (171a) to form a bolt through hole (171b) (171b) through which the threaded portion (220) 220 of the fastening member (200) (200), piston mounting portion The frame mounting protrusions 171c and 171c extend from the circumferential walls 171a and 171a toward the magnet frames 123A and 123A.

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

Reference numeral 141 in the figure denotes a piston body.

The process of assembling the magnet frame, the piston and the spring support using the piston fixing device of the present invention reciprocating compressor as described above is as follows.

First, the spring supports 171 and 171 are placed on the front side of the magnet frames 123A and 123A, and the magnet frames 123A and 171 are attached to the frame mounting protrusions 171c and 171c of the spring supports 171 and 171. 123A is fitted into the fitting, and at the same time, the support flanges 142 and 142 of the pistons 140 and 140 are inserted into the piston mounting portions 171a and 171a of the spring supports 171 and 171, respectively. do.

At this time, a male screw portion (not shown) is formed on the outer circumferential surface of the magnet frames 123A and 123A, and a female screw portion (not shown) is formed on the inner circumferential surface of the frame mounting protrusions 171c and 171c of the spring supports 171 and 171. By rotating the spring support 171, 171 may be combined.

Next, the piston 140 (with the piston mounting portions 171a and 171a of the spring supports 171 and 171 on the outer surfaces of the fixing portions 123a and 123a of the magnet frames 123A and 123A). The bolt members 200 are inserted from the inside of the magnet frames 123A and 123A to the support flange portions 142 and 142 of the 140.

At this time, since the support flanges 142 and 142 of the pistons 140 and 140 are inserted into and fixed to the piston mounting parts 171a and 171a of the spring supports 171 and 171, the pistons 140 and 140 The coupling force is further doubled and the magnet frames 123A and 123A are fixed to the frame mounting protrusions 171c and 171c of the spring supports 171 and 171 so that the coupling force of the magnet frames 123A and 123A is fixed. It also doubles.

In addition, the head portions 210 and 210 of the bolt members 200 and 200 are caught on the inner surfaces of the fixing portions 123a and 123a of the magnet frames 123A and 123A while the female thread portions of the piston body 141 are provided. Since the male threads 220 and 220 of the bolt members 200 and 200 engage with 141a, the more tightened the bolt members 200 and 200, the more magnet frames 123A and 123A and the piston 140 ( It is possible to more firmly fix the spring supports 171 and 171 sandwiched between the two members 140 by jade.

In this way, the magnet frame and the piston are crimped and fastened with a single bolt member with the spring support in between to reduce the number of parts and reduce the number of assembly labor compared to fastening the magnet frame, the piston and the spring support using multiple bolts. In addition, the compressor can be miniaturized by reducing the extra clearance such as the bolt seat.

In addition, by fastening the magnet frame and the piston with one bolt member, machining errors and assembly errors can be reduced, so that the concentricity of the magnet frame and the piston can be easily matched.

The piston fixing device of the reciprocating compressor according to the present invention forms a female screw portion inside the piston to closely contact the outer surface of the mover of the reciprocating motor, and reciprocates a bolt member having a male screw portion to fit into the female screw portion of the piston. By engaging the above-mentioned mover and the piston by hanging on the inner surface of the mover of the motor, it is possible to reduce the number of parts for assembling the magnet frame and the piston, as well as to reduce the number of assembly labor and the bolt seat. The compressor can be miniaturized by reducing the area.

In addition, by fastening the magnet frame and the piston with one bolt member, machining errors and assembly errors can be reduced, so that the concentricity of the magnet frame and the piston can be easily matched.

Claims (8)

A reciprocating motor in which the mover linearly reciprocates, A piston coupled to the mover of the reciprocating motor to linearly reciprocate in the cylinder and form a female thread therein; A spring support that is inserted between the mover and the piston and supports a resonant spring for inducing the resonant movement of the mover and the piston; A piston holding device for a reciprocating compressor comprising a fastening member having a head pressed against an inner surface of a mover, and a threaded portion screwed to a piston after successively passing the mover and the spring support. The method of claim 1, The piston is a piston fixing device of the reciprocating compressor, characterized in that for forming a passage through which the fluid flows in the piston movement direction. The method of claim 2, A piston fixing device for a reciprocating compressor, characterized in that the female screw portion is formed on one side inner circumferential surface with suction oil of the piston. The method of claim 3, The fastening member is a piston fixing device of the reciprocating compressor, characterized in that formed through the gas passage so as to communicate with the suction flow path of the piston from the head to the screw portion. The method of claim 1, Piston fixing device of the reciprocating compressor, characterized in that the one side of the piston support to form a piston mounting portion to be inserted and coupled to one side of the spring support. The method of claim 5, A piston fixing device for a reciprocating compressor, characterized in that at the end of the piston inserted into the piston mounting portion of the spring support, a support flange portion is formed so as to substantially correspond to the main surface of the piston mounting portion. The method of claim 1, The piston holding device of the reciprocating compressor, characterized in that the other side of the spring support to form a frame mounting protrusion for inserting the corresponding end of the mover. The method of claim 7, wherein Piston fixing device of the reciprocating compressor, characterized in that the screw threaded to form a threaded portion on the inner peripheral surface of the frame mounting protrusion and the outer peripheral surface of the mover corresponding thereto.