KR100227494B1 - Compressor - Google Patents

Abstract

The present invention provides a structure of a compressor, in particular a flapper discharge valve assembly.

The structure of the flapper discharge valve assembly of the compressor includes a valve plate member 35 having a discharge port 38 formed therein, a discharge valve 34 which opens and closes to discharge high pressure gas, and an opening / closing area of the discharge valve 34. In the compressor comprising a backing spring (33) for defining a restriction, and a stopper member (31) for fixing the discharge valve 34 and the backing spring 33, the discharge valve on the upper surface of the valve plate member (35) An accommodating part 37 is formed to accommodate the 34 and the backing spring 33, and a free space 41 is formed in the accommodating part 37 so that the discharge valve is opened and closed smoothly at the lower end of the accommodating part 37. And an end portion protrudes around the discharge port 38 to match the height of the accommodating portion 37 at a predetermined position of the free space 41 to minimize the volume of the discharge port 38. On the upper surface of the valve plate member 35, the stopper member 31 has two ribs. Characterized in that 32 to lock the two ends of the stopper member 31.

Accordingly, the volume of the discharge port is reduced, thereby improving the performance of the compressor, improving the assemblability of the valve valve and the stability or reliability of the opening and closing operation of the valve, and reducing noise and vibration. There is an effect such as.

Description

compressor

The present invention relates to a compressor, and more particularly, to a compressor having a flapper discharge valve assembly, in which a simple structure minimizes the volume of the discharge port, thereby improving the performance of the compressor, and further improving assembly performance and opening / closing operation of the valve. The flapper discharge valve assembly structure of the compressor.

Compressors typically convert mechanical energy into compressive energy of a compressive fluid, which are reciprocating, rotary and turbo. When such a compressor is used for a refrigerator, the saturated steam of a low boiling point refrigerant having the inside of the refrigerator as a low heat source and the outside as a high heat source is compressed to a high pressure and flowed to a condenser. In the condenser, latent heat of evaporation is released from the high-pressure and high-temperature refrigerant to a high-heat source outside the refrigerator, causing a phase change to a liquid refrigerant, and the liquid refrigerant is throttled to low pressure and low temperature through an expansion valve. It enters the evaporator. The low pressure and low temperature refrigerant in the evaporator absorbs latent heat from the low heat source inside the refrigerator in the liquid phase, thereby causing a phase change to the saturated steam refrigerant, and then flowing into the compressor described above to form a refrigeration cycle. In the middle of repeating such a refrigeration cycle, the inside of the refrigerator is continuously supplied with cold air to bring about the desired refrigeration (long) effect.

Normally, the compressor for a domestic refrigerator is mainly installed in the lower part of the refrigerator, sealed in a case together with its driving electric motor, mainly in a single-stage reciprocating type, and the internal structure in a state where the upper case is removed in FIG. 1 is shown in plan view.

In the reciprocating compressor 10, the electric motor and the compressor are hermetically housed in the upper and lower cases 12 and 11 for soundproofing and dustproofing, and the upper and lower cases 12 and 11 are predetermined. At intervals of, it is supported by means of suitable dust and soundproofing means, for example compression springs or leaf springs, via the frame 24 at the bottom or side of the upper and lower cases 12, 11.

The above-mentioned reciprocating compressor consists of a cylinder block 13 fixed to the upper part of the frame 24 horizontally in FIG. 1 and a piston 14 reciprocally inserted into a cylinder therein (see FIG. 2). By the reciprocating motion of the piston 14, low pressure and low temperature refrigerant gas is sucked through the suction and discharge valves 15 provided at the left end of the cylinder block 13, and high pressure and high temperature refrigerant gas is discharged. . The suction and discharge valve 15 is composed of a flapper or reed type thin plate structure which is usually elastic for miniaturization, and the flapper or lead type suction and discharge valve 15 acts on both sides. It is opened and closed passively by the pressure difference.

In the reciprocating compressor configured as described above, during the backward movement of the piston 14, the low-pressure, low-temperature refrigerant gas is sealed and fixed to the upper or lower cases (12, 11) (22) And a high pressure and high temperature discharged from an external evaporator (not shown) to the suction lead valve of the suction and discharge valve 15 through the suction muffler 16 and discharged from the compressor during the forward movement of the piston 14. Refrigerant gas from the intake and discharge valves 15 through the discharge pipe 23 'and the discharge pipe connecting pipe 23 fixedly sealed to the upper or lower cases 12 and 11, the external condenser It is sent out (not shown). The refrigerant filling pipe 22 'is hermetically fixed to the lower case 11 and initially filled with refrigerant gas, and then sealed.

In addition, the compressor noise, which occupies most of the operation noise of the refrigerator, is generated by the reciprocating motion of the piston 14, the opening and closing shock of the suction and discharge valve 15, the pulsation of the suction gas and the discharge pressure, and the like. In order to reduce noise caused by the pulsation of the suction and discharge pressures, the refrigerant gas introduced into the suction pipe (connecting pipe) 22 is filled in the upper and lower cases 12 and 11, and through the suction muffler 16. The refrigerant sucked into the cylinder 13 and compressed in the cylinder 13 is discharged to the discharge pipe 23 ′ through the discharge muffler 17.

On the other hand, the electric motor is composed of a stator 18 fixedly installed at the lower part of the frame 24, and a rotor 19 rotating with a gap between the stator 18 (see FIG. 2). The electrons 19 are rotatably supported on the frame 24 so as to be fixed to the rotation shaft 20 and rotate together. By forming the eccentric shaft 21 at the end of the rotating shaft 20 of the electric motor to the upper portion of the frame 24 to connect the piston 14 to the eccentric shaft 21 through the connecting rod and the number of shafts, The piston 14 reciprocates by the amount of eccentric rotation of the eccentric shaft 21. In addition, an external power source is applied to the winding coil of the stator 18 of the electric motor via the external terminal 18 'which is hermetically fixed to the upper and lower cases 12 and 11.

In order to smoothly operate the compressor and the driving motor operating as described above, the refrigerator oil storage tank 25 in which the refrigerator oil is stored is formed at the bottom of the lower case 11, and the lubricating oil supply groove 20 'of the rotating shaft 20 is formed. As it is sucked into the upper portion, the refrigerant oil is supplied to each lubrication part to perform lubrication.

3 and 4 show an example of the structure of a conventional flapper discharge valve in detail. The flapper discharge valve system includes a valve plate member 110, a discharge valve 123, a backing spring 122, and a stopper member 121.

A discharge port 114 is formed in the singer valve plate member 110 to the inside of the cylinder 103, and the discharge valve 123 is installed at the upper portion of the discharge port 14 so as to be opened and closed for discharge of the high pressure gas. The backing spring 122 is installed on the upper part of the discharge valve 123 to elastically limit the opening and closing area thereof, and the stopper member 121 moves the discharge valve 123 and the backing spring 122 into position. Restrict to maintain

On the upper surface of the valve plate member 110, a first accommodating portion 111 formed to accommodate the stopper member 121, and the backing spring 122 and the discharge under the first accommodating portion 111 A second receiving part 112 formed to receive the valve 123, a support space 113 formed to open and close the discharge valve 123 smoothly under the second receiving part 112, and the support space A discharge port 114 having an end portion protruding to correspond to the height of the second accommodating part 112 is formed at a predetermined position of the 113 to be configured to minimize the volume of the discharge port 114. 3 and 4, protrusions 125 and 124 are protruded from one end of the discharge valve 123 and the backing spring 122, respectively, and the second accommodating portion 112 is formed in the discharge valve 123 and the backing spring 122, respectively. The support 116 is formed to accommodate the protrusions 125 and 124 protruding from the discharge valve 123 and the backing spring 122, respectively, so that the discharge valve 123 and the backing spring 122 flow. It is configured to work without.

However, as described above, the first accommodating part 111, the second accommodating part 112, the support space 113, and the discharge port 114 are formed on the upper surface of the valve plate member 110 in a stepped manner. Therefore, the airtightness and strength at the time of compression and the minimum thickness required for sintering molding are required, and when formed in the step shape as described above, the minimum thickness is determined by the support space 113 according to the airtightness and strength at the time of compression and sintering molding. There is a problem that the lower limit of the volume of the discharge port 114 is limited.

In addition, in the above-described structure, the stopper member 121 is elastically inserted and fixed to the first accommodating portion 111 in the lateral direction of both ends, so that the stopper member 121 is not only highly detachable, but also easily flows, and thus the backing spring 122 and the ejection. Since the valve 123 cannot be stably maintained, the stability or reliability of the valve opening and closing operation is lowered, and there are problems such as generating noise and vibration or affecting the life of the valve. In addition, the material surface is limited to an elastic material, and the slits formed at both ends have a width of about 1 mm, so that in the press work, repair or breakage due to cutting of the punch punch or abrasion of the punch during press work is frequently performed. There is also a problem of deterioration.

Accordingly, the present invention is to solve the above-mentioned problems, the flapper discharge valve assembly of the compressor to improve the performance of the compressor by minimizing the volume of the discharge port with a simple structure and further improved the assembly and opening and closing operation of the valve The purpose is to provide a structure.

1 is a plan view showing the internal structure of a hermetic reciprocating compressor.

2 is a cross-sectional view taken along line 2-2 of FIG. 1 showing the internal structure of the hermetic compressor.

3 is a partially enlarged cross-sectional view showing the structure of a flapper discharge valve assembly of a conventional compressor.

4 is an exploded perspective view of the discharge valve assembly of FIG.

5 is a partially enlarged cross-sectional view of a flapper discharge valve assembly of the compressor of the present invention.

6 is a top plan view of the discharge valve assembly of FIG.

7 is an exploded perspective view of the discharge valve assembly of FIG.

* Explanation of symbols for main parts of the drawings

10 compressor 11 lower case

12: upper case 13: cylinder

14 piston 15 suction and discharge valve assembly

16: suction muffler 17: discharge muffler

18: stator (stator) 19: rotor (rotor)

20: axis of rotation 21: eccentric shaft

22: suction pipe (connecting pipe) 23: discharge pipe connecting pipe

23: discharge pipe 24: frame

25: refrigerator oil storage tank 31: stopper member

32: rivet 33: backing spring

34: discharge valve 35: valve plate

36: stone tongue 37: receiving portion

38 discharge port 40 side wall

In order to achieve the above object, the present invention provides a valve plate member having a discharge port, a discharge valve that opens and closes to discharge high pressure gas, a backing spring that defines an opening and closing area of the discharge valve, and fixes the discharge valve and the backing spring. In the compressor consisting of a stopper member, a receiving portion for receiving the discharge valve and the backing spring is formed on the upper surface of the valve plate member, free space in the receiving portion so that the discharge valve is opened and closed smoothly at the lower end of the receiving portion And an end portion protrudes around the discharge port at a predetermined position of the free space to match the height of the receiving portion, and the stopper member is fixed to both ends of the stopper member by two rivets on the upper surface of the valve plate member. It provides a compressor, characterized in that configured.

In addition, the discharge valve and the backing spring can be maintained firmly and stably, and the stopper member is configured to be riveted to the valve plate member at both ends in a horseshoe shape, so that it can be simply configured without discharge resistance, In addition, protrusions may be formed at both ends of the stopper member to prevent excessive movement of the discharge valve and the backing spring. The backing spring is formed by bending toward the upper surface of the valve plate member.

In addition, an asymmetrical protrusion may be formed at one end of the discharge valve and the backing spring to prevent the disassembly of the discharge valve and the backing spring, and an asymmetrical protrusion may be formed at the other end of the backing spring. have. In this case, it is preferable that the support portions are formed at both ends of the accommodation portion to accommodate the asymmetric protrusions of the discharge valve and the backing spring so as to prevent misassembly and the discharge valve and the backing spring from flowing.

Hereinafter, with reference to the accompanying drawings will be described in detail the configuration and operation of the embodiment of the present invention.

5 to 7 show the structure of the flapper discharge valve assembly of the compressor according to the invention in detail.

5 to 7, the flapper discharge valve system is composed of a valve plate member 35, a flapper discharge valve 34, a backing spring 33 and a stopper member 31. As shown in FIG.

The valve plate member 35 is arranged to be closed on the upper surface of the cylinder 13, as shown in FIG. 5, and at least one discharge port 38 for communicating the cylinder 13 with the discharge chamber is formed, A receiving portion 37 is formed around the discharge port 38.

In the receiving portion 37, a discharge valve 34 and a backing spring 33 are inserted, and a stopper member 31 is formed thereon so that the rivet hole 32 'of the stopper member 31 is opened by the rivet 32 on the upper surface thereof. It is fixed through. The stopper member 31 has a horseshoe shape and is fixed to the valve plate member 35 by rivets 32 at both ends thereof. In addition, protrusions 36 are formed at both ends of the stopper member 31 to prevent excessive movement of the discharge valve 34 and the backing spring 33 inserted into the receiving portion 37.

The backing spring 33 is bent toward the upper surface of the valve plate member 35, thereby primarily limiting the improvement of the discharge valve 34, and quickly discharging the valve 34 when closed by the elastic spring. Act to close.

In addition, a valve seat portion is formed around the discharge port 38 in the accommodation portion 37 to seal the discharge valve, and a free space 41 is formed to open and close the discharge valve 34 smoothly. That is, an end portion protrudes around the discharge port 38 to correspond to the height of the accommodating portion 37 at a predetermined position of the free space 41 to form a valve seat portion.

A side wall portion 40 is formed on the side wall of the free space 41 to form an inclined flow path so as to smoothly open and close the discharge valve and discharge the refrigerant gas discharged smoothly. The stopper member 31 and the backing spring 33 may be formed asymmetrically with respect to the center of the discharge port 38 in order not to obstruct the flow path to the side wall portion 40.

In addition, the discharge valve 34 and the backing spring 33 has asymmetrical protrusions 42 and 43 protruding at one end thereof to prevent the disassembly of the discharge valve 34 and the backing spring 33. In the case of the backing spring 33, an asymmetrical protrusion 45 for preventing misassembly and flow may be formed at the other end thereof.

In this case, support portions 44 are formed at both ends of the accommodating portion 37 to accommodate the asymmetrical protrusions 42, 43, 45 of the discharge valve 34 and the backing spring 33, respectively. Incorrect assembly and the discharge valve 34 and the backing spring 33 is configured so that there is no flow. As shown in FIG. 7, a flapper type suction valve 50 may be disposed between the valve plate member 35 and the cylinder 13.

The detailed operation of the flapper-type discharge valve assembly structure of the compressor according to the embodiment of the present invention configured as described above will be described with reference to FIGS. 5 to 7.

The discharge valve 34 and the backing spring 33 are accommodated in the receiving portion 37 formed on the upper surface of the valve plate member 35, and the stopper member 31 is fixed to the rivet hole 32 ′. The assembly is assembled. When the piston 14 rises, the pressure of the refrigerant is increased to discharge the refrigerant compressed through the discharge valve 34. At this time, the side wall portion 40 in the discharging direction is formed to be inclined as shown, and the stopper member 31 and the backing spring 33 are formed asymmetrically with respect to the center of the discharge port 38 so that the side wall portion ( The flow path to 40) is not obstructed and the discharge resistance is minimized.

In addition, only one end is formed between the accommodating portion 37 and the free space 41, and an end portion protrudes around the discharge port 38 to coincide with the height of the accommodating portion 37. 41) can be narrowly formed, and the airtightness and strength at the time of compression and the minimum thickness required for sintering molding can be made smaller than before, so that the volume of the discharge port 38 can be made smaller than before and the discharge However, the recompression rate of the refrigerant remaining in the discharge port 38 is reduced, thereby greatly improving the performance of the compressor.

In addition, the height of the side wall portion 40 around the discharge port 38 can be reduced by the one receiving portion 37 and the free space 41, and the side wall portion 40 is inclined as described above to discharge the discharge. It is possible to greatly reduce the discharge resistance of the compressed refrigerant is to be further improved the performance of the compressor.

In addition, in the above-described structure, the stopper member 31 is fixed by the rivet 32 so that the backing spring 33 or the discharge valve 34 can be stably inserted into the receiving portion 37 so that there is no possibility of detachment. The backing spring 33 or the discharge valve 34 is stably maintained by the protrusion 36 of the stopper member 31, thereby improving stability and reliability of the valve opening and closing operation, and improving noise and The vibration is reduced, and the life of the valve is also improved. In addition, also in the material surface, the stopper member 31 is not limited to the elastic material, and as shown in FIGS. 3 and 4, the slitting process becomes unnecessary, and furthermore, the airtightness and strength during compression and the sintering molding The minimum thickness required can be made smaller than before.

According to the configuration and function of the structure of the flapper valve assembly of the compressor according to the present invention as described above, the height of the accommodating portion 37 and the height of the valve seat portion around the discharge port 38 are the same and the accommodating portion ( 37) By fixing the stopper member 31 on the upper surface of the outer valve plate member 35 and holding the back kangaroo spring 33 and the discharge valve 34 stably by the protrusion 36 of the stopper member 31. By reducing the volume of the discharge port 38, the performance of the compressor is improved, the assembly and the opening and closing operation of the valve valve are improved, the stability or reliability is improved, and the noise and vibration are reduced.

Claims (7)

A valve plate member 35 having a discharge port 38 formed therein, a discharge valve 34 which opens and closes so as to discharge high pressure gas, a backing spring 33 defining an opening / closing area of the discharge valve 34, and the discharge valve In the compressor consisting of a stopper member (31) for fixing the (34) and the backing spring (33). An accommodating portion 37 in which the discharge valve 34 and the backing spring 33 are received is formed on an upper surface of the valve plate member 35; A free space (41) is formed in the accommodation portion (37) to smoothly open and close the discharge valve at the bottom of the accommodation portion (37); An end portion protrudes around the discharge port 38 at a predetermined position of the free space 41 so as to minimize the volume of the discharge port 38 so as to match the height of the accommodating part 37; Compressor, characterized in that the stopper member (31) is fixed to both ends of the stopper member (31) by two rivets (32) on the upper surface of the valve plate member (35). The side wall portion 40 of the free space 41 is inclined to smoothly open and close the discharge valve and at the same time to discharge the refrigerant gas discharged smoothly, and the stopper member 31 and the backing spring. (33) is characterized in that it is formed asymmetrically with respect to the center of the discharge port (38) so as not to obstruct the flow path to the side wall portion (40). 2. The compressor as claimed in claim 1, wherein the stopper member (31) is of a horseshoe shape and configured to rivet to the valve plate member (35) at both ends thereof. 2. The compressor as claimed in claim 1, wherein protrusions (36) are formed at both ends of the stopper member (31) to prevent excessive movement of the discharge valve (34) and the backing spring (33). The asymmetry according to any one of claims 1 to 4, wherein the discharge valve (34) and the backing spring (33) have an asymmetry for preventing the disassembly of the discharge valve (34) and the backing spring (33) at one end thereof. Compressor, characterized in that the protrusions 42, 43 are protruding. 6. The compressor as set forth in claim 5, wherein an asymmetrical protrusion (45) is formed at the other end of the backing spring (33) to prevent misassembly and flow. The support 44 is formed at both ends of the receiving portion 37, so that the asymmetrical protrusions 42, 43, 45 of the discharge valve 34 and the backing spring 33, respectively. Compressor is operated so as to accommodate the misassembly and the discharge valve (34) and the backing spring (33) is not flowed.

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