KR20030090004A - Structure for engaging frame in reciprocating compressor - Google Patents

Abstract

PURPOSE: A structure for coupling a frame for supporting a spring of a reciprocating compressor is provided to allow simple coupling work of a spring supporting frame supporting a resonant spring unit, and to reinforce the coupling. CONSTITUTION: A structure includes a fixed side middle frame(110) fixed and coupled to a reciprocating motor generating linear reciprocating driving force to support the reciprocating motor; a resonant spring unit elastically supporting a piston receiving linear reciprocating driving force of the reciprocating motor and linearly reciprocating in a cylinder; and a spring supporting frame(120) having a rotary engaging unit together with the fixed side middle frame to be coupled to or separated from the fixed side middle frame as the spring supporting frame is rotated, and supporting the resonant spring unit when coupled to the fixed side middle frame. The rotary engaging unit comprises a plurality of first engaging protrusions(114) formed between a plurality of first engaging opening grooves(113) by forming the first engaging opening grooves on a circumference of a penetrating hole(112) formed on an inside of the fixed side middle frame at regular intervals; and second engaging protrusions formed between a plurality of second engaging opening grooves(124) correspondingly with the first engaging opening grooves by forming the second engaging opening grooves on a circumference of a flange part(122) of the spring supporting frame correspondingly with the first engaging protrusions.

Description

STRUCTURE FOR ENGAGING FRAME IN RECIPROCATING COMPRESSOR}

The present invention relates to a frame coupling structure for the spring support of the reciprocating compressor, and in particular, the spring support of the reciprocating compressor not only to simplify the coupling operation of the spring support frame for supporting the resonant spring unit but also to strengthen the fastening force It relates to a frame coupling structure for.

Generally, a compressor is a device that compresses a fluid. The compressor may be of various types such as a rotary compressor, a scroll compressor, a reciprocating compressor, and the like according to a method of compressing a gas.

1 illustrates an example of a reciprocating compressor under the present applicant's research and development. As shown in FIG. 1, a reciprocating motor mounted inside the vessel 10 and the vessel 10 to generate a linear reciprocating driving force ( 20, the front frame 30 which covers one side of the motor 20 and the intermediate frame 40 which supports the other side of the reciprocating motor 20, and the inside of the reciprocating motor 20 The cylinder 50 is inserted and fixedly coupled to the front frame 30, and is connected to the reciprocating motor 20, and is inserted into the cylinder 50 to transmit the linear reciprocating driving force of the reciprocating motor 20. A piston (60) for receiving a linear reciprocating motion in the cylinder (50), a spring support rear frame (70) coupled to the motor (20) after the intermediate frame (40), and the cylinder (50). ) And the king of the piston 60 is coupled to the piston 60 Resonance for elastically supporting the linear reciprocating motion of the valve unit 80 and the reciprocating motor 20 and the piston 60 by suctioning and discharging gas into the cylinder 50 by the pressure difference generated by the movement. It is configured to include a spring unit (90).

The reciprocating motor 20 is formed in a cylindrical shape and has an outer stator 21 fixedly coupled to the front frame 30 and the intermediate frame 40 and an inner stator inserted into the outer stator 21 at regular intervals ( 22) and a winding coil (23) coupled to the outer stator (21) and a mover (A) inserted between the outer stator (21) and the inner stator (22) for linear reciprocating motion. .

The mover (A) is composed of a magnet holder 24 formed in a cylindrical shape and a plurality of permanent magnets 25 coupled to the magnet holder 24 at a predetermined interval, the magnet holder 24 is the piston It is connected with (60).

The valve unit 80 is located inside the discharge cover 81 for covering the compression space P of the cylinder 50 and the discharge cover 81 to open the compression space P of the cylinder 50. It is coupled to the discharge valve 82 for opening and closing, the valve spring 83 for elastically supporting the discharge valve 82 and the end of the piston 60 to open and close the suction flow path (F) formed in the piston (60) The suction valve 84 is comprised.

The resonant spring unit 90 has a front spring 91 inserted between one side of the front frame 30 and one side of the piston 60 and the other side of the piston 60 and the rear frame for supporting the spring ( It comprises a rear spring 92 is inserted between one side of the 70.

Reference numeral 1 is a suction pipe, and 2 is a discharge pipe.

Operation of the reciprocating compressor as described above is as follows.

When the power is supplied to the reciprocating motor 20 and current flows in the winding coil 23, the flux formed in the outer stator 21 and the inner stator 22 by the current flowing in the winding coil 23; By the interaction of the permanent magnet 25, the movable element A including the permanent magnet 25 is linearly reciprocated.

The linear reciprocating driving force of the mover A is transmitted to the piston 60 so that the piston 60 linearly reciprocates in the cylinder compression space P and at the same time the valve unit 80 is operated while gas flows into the cylinder. The process of being sucked into the compression space P, compressed and discharged is repeated.

In addition, the resonant spring unit 90 is a linear reciprocating motion of the piston 60, the front spring 91 and the rear spring 92 is tension contracted, the linear reciprocating force of the reciprocating motor 20 to the elastic energy In addition to storage and release, resonant motion is induced.

On the other hand, the coupling structure of the spring support rear frame 70 and the intermediate frame 40 fixedly coupled to the intermediate frame 40 to support the rear spring 92 of the resonant spring unit is shown in FIG. As described above, a plurality of threaded holes 41 are formed at predetermined intervals in the intermediate frame 40 and the plurality of threaded holes in the flange portion 71 of the rear frame 70 in contact with the intermediate frame 40. 72 is formed through. The fastening bolts 100 are fastened in a state where the screw holes 41 of the intermediate frame and the screw holes 72 of the rear frame are coincident with each other.

However, as described above, the rear frame 70 on which the rear spring 92 is supported is fixedly coupled to the intermediate frame 40 by a plurality of fastening bolts 100 so that the plurality of fastening bolts 100 may be fixed. The coupling process for fastening is cumbersome and cumbersome, the assembly productivity is lowered, and also there is a shortage of the fastening force of the intermediate frame 40 and the rear frame 70 or missing the fastening of the fastening bolt 100.

The object of the present invention devised in view of the above-mentioned point is not only to simplify the coupling operation of the spring support frame for supporting the resonant spring unit but also to engage the frame for the spring support of the reciprocating compressor to enhance the fastening force In providing a structure.

1 is a cross-sectional view showing a reciprocating compressor currently in development;

2 is a cross-sectional view showing a frame coupling structure of the reciprocating compressor;

Figure 3 is a cross-sectional view of a reciprocating compressor with an example of the frame coupling structure for the reciprocating compressor spring support of the present invention,

Figure 4 is a front view of the frame coupling structure for the reciprocating compressor spring support of the present invention,

Figure 5 is an exploded perspective view showing a frame coupling structure for the reciprocating compressor spring support of the present invention.

(Explanation of symbols for the main parts of the drawing)

20; Reciprocating motor 50; cylinder

60; Piston 90; Resonant Spring Unit

110; Fixed side intermediate frame 112; Frame through hole

113; First matching opening groove 114; 1st fitting protrusion

115; Seating groove 120; Spring support frame

124; Second matching opening groove 125; 2nd fitting protrusion

126; Seating process

In order to achieve the object of the present invention as described above, the fixed side frame is fixedly coupled to the reciprocating motor for generating a linear reciprocating driving force, and supports the reciprocating motor, and the linear reciprocating driving force of the reciprocating motor is received. And a resonant spring unit for elastically supporting the piston reciprocating linearly in rotation and a rotational mating coupling means together with the stationary side frame, thereby engaging or disassembling with the stationary side frame by rotating the stationary side frame. When coupled to the frame is provided a frame coupling structure for the spring support of the reciprocating compressor comprising a spring support frame for supporting the resonant spring unit.

Hereinafter, the frame coupling structure for the spring support of the reciprocating compressor of the present invention will be described according to the embodiment shown in the accompanying drawings.

3 and 4 illustrate a reciprocating compressor equipped with an example of a spring-supporting frame coupling structure of the reciprocating compressor of the present invention. Referring to this, first, the reciprocating compressor is a container having a predetermined internal space. A reciprocating motor 20 for generating a linear reciprocating driving force is mounted in the inside of the 10, and the front frame 30 and the fixed side intermediate frame 110 are coupled to both sides of the reciprocating motor 20, respectively.

The reciprocating motor 20 is formed in a cylindrical shape and is inserted into the outer stator 21 and the outer stator 21 fixedly coupled to the front frame 30 and the fixed side intermediate frame 110 at regular intervals. It comprises a winding coil 23 coupled to the stator 22 and the outer stator 21 and a mover A inserted in a linear reciprocating manner between the outer stator 21 and the inner stator 22. do.

The mover A is composed of a magnet holder 24 formed in a cylindrical shape and a plurality of permanent magnets 25 coupled to the magnet holder 24 at regular intervals.

The front frame 30 is formed to have an area of a predetermined shape and is provided with a cylinder insertion hole 31 formed therein to be coupled to the reciprocating motor 20. In addition, a cylinder 50 having a predetermined shape is coupled to the cylinder insertion hole 31 of the front frame, and a piston 60 is inserted into the cylinder 50. The piston 60 drives the reciprocating motor 20. It is connected with the magnet holder 24 of the movable member. The interior of the cylinder 50 into which the piston 60 is inserted forms a compression space P.

The fixed side intermediate frame 110 is provided with a through hole 112 in the frame body 111 formed to have a predetermined area.

Then, the spring support frame 120 having a predetermined shape is coupled to the fixed side intermediate frame 110. The spring support frame 120 has a cap portion 121 formed to have a predetermined internal space and a flange portion 122 and one surface of the cap portion 121 extending to have a predetermined area at the edge of the cap portion 121, That is, the passage hole 123 formed through the support surface is provided.

The fixed side intermediate frame 110 and the spring support frame 120 are detachably attached to each other by rotation-type coupling means provided at one side of the fixed side intermediate frame 110 and the spring support frame 120. Combined.

The rotatable joining means may include a first joining opening 113 having a predetermined shape formed at a predetermined interval at an edge of the through hole 112 formed through the inside of the fixed side intermediate frame 110. A plurality of first mating protrusions 114 are formed between the mating opening grooves 113 and correspond to the first mating protrusions 114 of the fixed side frame at the edge of the flange portion 122 of the spring support frame. As the plurality of second matching opening grooves 124 are formed, the second matching protrusions 125 corresponding to the first matching opening grooves 113 are formed between the second matching opening grooves 124. Is done. The first matching opening groove 113 and the second matching protrusion 125 formed corresponding thereto may be formed in a fan shape or a quadrangular shape.

In addition, although not shown in the drawing, a mounting groove (not shown) in which the second fitting protrusion 125 of the spring supporting frame may be seated on the inner wall of the first fitting protrusion 114 of the fixed side intermediate frame after rotation of the fitting. Even more preferably.

A mounting groove 115 having a predetermined shape is formed on the inner wall of the first fitting protrusion 114 of the fixed side intermediate frame, and the mounting groove 115 is formed on the inner wall of the second fitting protrusion 125 of the spring supporting frame. It is preferable that the seating protrusion 126 to be molded is formed.

And both sides of the piston (60) is provided with a resonator spring unit (90) for elastically supporting the mover (A) of the reciprocating motor (20) and the movement of the piston (60).

The resonant spring unit 90 has a front spring 91 inserted between one side of the front frame 30 and one side of the piston 60, the other side of the piston 60 and the spring support frame ( It is configured to include a rear spring 92 is inserted between one side of the 120. The front spring 91 and the rear spring 92 is preferably made of a coil spring.

In addition, a valve unit 80 which sucks and discharges gas into the cylinder 50 by the pressure difference generated by the linear reciprocating motion of the piston 60 inside the cylinder 50 includes the cylinder 50 and the piston. Coupled to 60.

The valve unit 80 is located inside the discharge cover 81 for covering the compression space P of the cylinder 50 and the discharge cover 81 to open the compression space P of the cylinder 50. It is coupled to the discharge valve 82 for opening and closing, the valve spring 83 for elastically supporting the discharge valve 82 and the end of the piston 60 to open and close the suction flow path (F) formed in the piston (60) It comprises a suction valve (84).

Reference numeral 1 is a suction pipe, and 2 is a discharge pipe.

Hereinafter, the operational effects of the spring-supporting frame coupling structure of the reciprocating compressor of the present invention will be described.

First, the operation of the reciprocating compressor is supplied with power to the reciprocating motor 20 so that a current flows in the winding coil 23. The outer stator 21 and the inner stator (by the current flowing in the winding coil 23) By the interaction between the flux formed in 22 and the permanent magnet 25, the movable element A including the permanent magnet 25 is linearly reciprocated.

The linear reciprocating driving force of the mover A is transmitted to the piston 60 so that the piston 60 linearly reciprocates in the cylinder compression space P and at the same time the valve unit 80 is operated while gas flows into the cylinder. The process of being sucked into the compression space P, compressed and discharged is repeated.

In addition, the resonant spring unit 90 is a linear reciprocating motion of the piston 60, the front spring 91 and the rear spring 92 is tension contracted, the linear reciprocating force of the reciprocating motor 20 to the elastic energy In addition to storage and release, resonant motion is induced.

On the other hand, the process of the spring support frame 120 for supporting the rear spring 92 of the resonant spring unit 90 is coupled to the fixed side intermediate frame 110, as shown in Figure 5, the fixed In the state in which the side intermediate frame 110 is fixedly coupled to the reciprocating motor 20, the second mating protrusions 125 of the spring supporting frame are inserted into the first mating opening grooves 113 of the stationary side intermediate frame. In accordance with this, the spring support frame 120 is pushed toward the reciprocating motor 20 to rotate at a predetermined angle. At this time, the second mating protrusions 125 of the spring support frame and the first mating protrusions 114 of the fixed side intermediate frame are folded to prevent the spring support frame 120 from being detached and the spring support thereof. Dragon frame 120 is elastically supported by the rear spring 92 is coupled to the fixed side intermediate frame 110. In addition, the seating protrusions formed on the rear surfaces of the second mating protrusions 125 in a state in which the second mating protrusions 125 of the spring support frame and the first mating protrusions 114 of the fixed side intermediate frame are coincident with each other. 126 and the seating groove 115 formed on the rear surface of the first fitting protrusions 114 are joined together to suppress movement by contact rotation between the spring supporting frame 120 and the fixed side intermediate frame 110.

When the spring supporting frame 120 is disassembled, the spring supporting frame 120 is pushed toward the reciprocating motor 20 to be fixed to the second mating protrusions 125 of the spring supporting frame in close contact with each other. The first matching protrusions 114 of the side intermediate frame are dropped. In this case, the seating protrusion 126 formed in the second mating protrusion 125 is separated from the seating recess 115 formed in the first mating protrusion 114. Then, the second fitting protrusions 125 and the first fitting protrusions 114 are dropped and then fixed with the second fitting protrusions 125 of the spring supporting frame while rotating the spring supporting frame 120. The first matching opening groove 113 of the side intermediate frame is coincident with the spring supporting frame 120 to be removed and separated.

The present invention is coupled to the reciprocating motor 20, the spring support for supporting the rear spring 92 of the resonant spring unit on a fixed side frame, that is, the fixed side intermediate frame 110 to support the reciprocating motor 20 By combining and rotating the frame 120 for joining or rotating two components to separate the two parts, the coupling or detachment operation of the fixed side intermediate frame 110 and the spring support frame 120 is simple and easy. . And since a part of the fixed side intermediate frame 110 and a portion of the spring support frame 120 are coupled to each other, the components according to the combination of the fixed side intermediate frame 110 and the spring support frame 120 is It becomes simple.

In addition, the first mating protrusions 114 of the fixed side intermediate frame and the second mating protrusions 125 of the spring support frame are elastically formed by the rear spring 92 of the resonant spring unit in a state where they are in contact with each other. The fixed side intermediate frame 110 and the spring support frame 120 are coupled to each other so that the fastening force is increased and the structural strength of the coupling structure is increased.

As described above, the spring-supporting frame coupling structure of the reciprocating compressor according to the present invention will be simple and easy to combine the fixed side frame for supporting the reciprocating motor and the spring support frame for supporting the resonant spring unit. In addition, the configuration according to the combination can be simplified to shorten the coupling process and time to separate the two parts to increase the productivity, and also increase the reliability by structurally strengthening the fastening force of the two parts.

Claims (4)

A fixed-side frame fixedly coupled to the reciprocating motor for generating a linear reciprocating drive force and supporting the reciprocating motor, and a resonant spring for elastically supporting a piston reciprocating linearly in the cylinder by receiving the linear reciprocating drive force of the reciprocating motor. The unit and the fixed side frame is provided with a rotational mating coupling means is coupled or disassembled with the fixed side frame by rotating the fixed side frame and the spring to support the resonant spring unit when coupled to the fixed side frame Frame support structure for the spring support of the reciprocating compressor, characterized in that it comprises a support frame. The method of claim 1, wherein the rotational joining means is formed between the first matching opening groove by the first matching opening groove having a predetermined shape is formed at a predetermined interval on the edge of the through-hole formed in the fixed side frame. A plurality of first matching protrusions are formed in the first fitting protrusion, and a plurality of second matching opening grooves having a shape corresponding to the first matching protrusions of the fixed side frame are formed at an outer edge of the spring supporting frame. The frame coupling structure for the spring support of the reciprocating compressor, characterized in that formed by forming the second matching protrusions corresponding to the opening groove. According to claim 2, wherein the mounting groove of a predetermined shape is formed on the inner wall of the first mating projection of the fixed side frame and the mounting protrusions are formed in the inner wall of the second mating projection of the spring support frame is formed in the mounting groove. Frame coupling structure for the spring support of the reciprocating compressor characterized in that. 3. The spring support of the reciprocating compressor according to claim 2, wherein a seating groove is formed on an inner wall of the first fitting protrusion of the fixed side frame to allow the second fitting protrusion of the spring supporting frame to be seated after the mating rotation. Frame coupling structure