KR20070014706A - Rotary compressor - Google Patents

Abstract

A rotary compressor is provided to support a maximum load applied to a coupling element by a welding portion, thereby reducing vibration generated during operation of the same. A rotary compressor includes a case formed with a sealed inner space and mounted with a cylinder(31) inside, wherein the cylinder has an inner space. A rotation shaft(23) penetrates the cylinder. A roller(33) is mounted in the cylinder to rotate eccentrically for compressing working fluid. A flange(35) seals the cylinder and supports the rotation shaft. A coupling element(50) couples the cylinder with the flange. A first fixing part(X) among a plurality of fixing parts such as welding portions, which are formed on an outer periphery of the coupling element to fix the coupling element to the case, is formed at a position where the coupling element is applied with a maximum load by repulsive force generated when the roller compresses the working fluid in the cylinder.

Description

Rotary compressor

1 is a cross-sectional view showing the overall appearance of a rotary compressor according to an embodiment of the present invention.

2 is a view showing a load direction acting on the roller of the rotary compressor of FIG.

3 is a graph showing a change in the load received by the roller as the roller rotates.

4 is a view showing a direction in which the fixing portion is formed in the assembly formed by coupling the cylinder and the upper flange.

* Description of symbols on the main parts of the drawings *

10: case 23: rotating shaft

31: cylinder 32: eccentric cam

33: roller 35: upper flange

41: inlet 42; Outlet

50: binder θ: rotation angle

X, Y, Z: Fixed part O: Center of rotation axis

O ': center of roller

The present invention relates to a rotary compressor, and more particularly, to a fixing part of a case and a cylinder and an upper flange coupled to seal the inside of the rotary compressor.

In general, a compressor receives power from a driving device such as an electric motor, compresses by applying pressure to a fluid such as air or a refrigerant, and discharges the compressed fluid, and is used in many products such as an air conditioner and a refrigerator.

One such compressor is a rotary compressor in which fluid is compressed by a roller rotating in an eccentric state inside a cylinder, and Japanese Patent Laid-Open No. 60-201095 discloses an example of such a rotary compressor.

As disclosed in the above document, a rotary compressor is a space in which a refrigerant is compressed in a sealed case, a rotating shaft penetrating the cylinder and rotated by a driving motor, and eccentrically rotated by the rotating shaft to compress the refrigerant inside the cylinder. The roller is coupled to the cylinder to seal the cylinder and at the same time comprises a flange for supporting the rotating shaft.

In the rotary compressor configured as described above, the cylinder and the flange are mostly joined by bolts to form an assembly, and the joint is fixed to the case by forming a plurality of welds on the flange and joining the case.

In the conventional rotary compressor, when the roller inside the cylinder rotates to compress the refrigerant, the compressed refrigerant exerts a load on the roller, and the load is transmitted to the flange supporting the rotating shaft through the rotating shaft to be in the radial direction of the assembly. The load is borne by the weld of the flange and the case.

However, the load received by the roller by the refrigerant compressed in the cylinder is not constant, but varies depending on the rotation angle of the roller. In the conventional rotary compressor, the welding part is formed at an arbitrary position, and the welding part receives the maximum load of the roller. At the moment of receipt, it could not properly support the maximum load acting on the assembly. Therefore, the assembly is momentarily oriented in the direction of the maximum load acting on the assembly, and vibration occurs. When the vibration coincides with the resonance frequency of the rotating shaft, the vibration amplifies.

The present invention is to solve the above problems, it is an object of the present invention to provide a rotary compressor that can significantly reduce the vibration generated during the operation of the compressor.

In order to achieve the above object, a rotary compressor according to the present invention includes a case forming a sealed inner space, a cylinder provided inside the case and having an inner space, a rotating shaft rotating through the cylinder, and the cylinder. A roller provided therein and compressing a working fluid while rotating eccentrically, a flange for sealing the cylinder and supporting the rotating shaft, and an assembly in which the cylinder and the flange are coupled to each other, and provided in an outer circumference of the assembly. The first fixing part of the plurality of fixing parts fixed to the case is provided at a position where the load received by the assembly is maximized by the reaction force generated when the roller compresses the working fluid inside the cylinder.

In addition, three fixing parts for fixing the assembly to the case are formed, and the two angles each formed with the second and third fixing parts of the first fixing part as the vertex of the rotation axis are all obtuse angles.

In addition, the second and third fixing parts are symmetrical to each other in a straight line connecting the center of the first fixing part and the rotating shaft, and are provided to form an isosceles triangle when the three fixing parts are connected.

In addition, the plurality of fixing parts are formed by welding, and are provided on an upper flange to fix the assembly to the case.

Hereinafter, a rotary compressor according to an exemplary embodiment of the present invention will be described in detail with reference to the accompanying drawings.

As shown in FIG. 1, a rotary compressor according to an exemplary embodiment of the present invention includes a case 10 forming an external shape, a driving unit 20, and a compression unit 30 located inside the case 10. . One side of the case 10 is connected to the suction pipe 12 for supplying a working fluid from the accumulator 11 for filtering the liquid refrigerant to the compression unit 30.

The upper part of the case 10 is provided with a discharge tube 13 through which the compressed fluid is discharged, and a lower amount of the lubricating oil 14 is filled in the lower part of the case 10 for lubrication and cooling of the friction moving member.

The driving unit 20 includes a stator 21 fixed to the case 10, a rotor 22 rotatably supported inside the stator 21, and a rotation shaft 23 press-fitted to the rotor 22. . When power is applied to the stator 21, the rotor 22 rotates by electromagnetic force, and the rotary shaft 23 press-fitted to the rotor 22 transmits the rotational force to the compression unit 30.

The compression unit 30 is an eccentric cam 32 and an eccentric cam (32) fixed to be eccentrically positioned on the cylinder (31) and the rotating shaft (23), each of which is formed inside the cylinder 31 so that the working fluid is largely compressed. It is composed of a roller 33 is pressed into the outer peripheral surface of 32 to compress the working fluid. In addition, the upper flange 35 at the upper portion of the cylinder 31 and the lower flange 36 at the lower portion of the cylinder are respectively coupled by bolts 37 to seal the upper and lower surfaces of the cylinder 31 and at the same time rotate the shaft 23. ) Is rotatably supported.

2 shows the direction of the load acting on the roller 33 when the working fluid inside the cylinder 31 is compressed.

As shown in FIG. 2, the cylinder 31 is connected to a suction pipe 12 connected to the accumulator 11 and an inlet port 41 for receiving a working fluid and a discharge port for discharging the compressed refrigerant inside the cylinder 31. 42) is formed.

A groove 43 is formed between the suction port 41 and the discharge port 42 of the cylinder 31 to extend a predetermined depth from the inner circumference thereof, and the groove 43 is continuously elastically contacted with the outer circumferential surface of the roller 33. (31) A vane 45 is provided which partitions an inner space into a suction space 31a into which the working fluid is sucked and a compression space 31b into which the working fluid is compressed, and the groove 43 is provided with the vane 45. The compression spring 44 is accommodated in the groove 43 so as to elastically support the vane 45.

On the other hand, the eccentric cam 32 accommodated in the cylinder 31 is eccentric so that the center (O ') is spaced apart from the center (O) of the rotation shaft 23 by a predetermined distance, and coupled to the rotation shaft 23, roller 33 ) Is pressed into the outer circumference of the eccentric cam 32 is coupled.

Such a roller 33 contacts the vane 45 to form the first contact point A, and contacts the inner circumferential surface of the cylinder 31 to form the second contact point B. FIG. In this way, the roller 33 contacts the vanes 45 and the inner circumferential surfaces of the cylinder 31 to form two contacts A and B, thereby making the inner space of the cylinder 31 a suction space 31 a and a compression space. By partitioning to 31b, it is possible to prevent the working fluid of the suction space 31a from mixing with the working fluid of the compression space 31b.

When the rotary shaft 23 rotates in the clockwise direction by the driving of the driving unit 20 in the rotary compressor configured as described above, as shown in FIG. 2, the roller 33 moves along the inner surface of the cylinder 31 in the cylinder 31. The working fluid is sucked into the cylinder 31 through the suction port 41 while rotating clockwise. At this time, the suction valve (not shown) is closed by the working fluid flowing toward the discharge port 42, and the working fluid is compressed in the compression space 31b in the forward direction of the roller 33, and the compressed working fluid When the pressure reaches a predetermined value or more, it is discharged through the discharge port 42.

When the working fluid is compressed in the compression space 31b as described above, the roller 33 compressing the working fluid receives a reaction force f 'by the compressed working fluid. As indicated by the black arrows, the working fluid inside the compression space 31b exerts a reaction force f 'on the roller 33 in the direction of the center O' of the roller 33, and thus on the roller 33. The reaction forces applied (f) are combined to act as a load F 'as indicated by the white arrow, the direction of the load (F') acting on the roller 33 is the center (O ') of the roller 33 Passing in the vertical direction to the straight line (C) connecting the first contact point (A) and the second contact point (B).

3 is a graph showing a change in the load F 'received by the roller 33 according to the rotation angle θ of the roller 33 when the R22 refrigerant is used as the working fluid.

Here, the rotation angle θ is the center of the roller (O ') as a vertex, the center of the roller (O') and the clockwise direction from the straight line connecting the center of the roller (O ') and the first contact (A) It is an angle formed by a straight line connecting the two contacts B to the center. As shown in FIG. 3, the load F 'received by the roller 33 starts to increase gradually from the point where the rotation angle θ is approximately 90 degrees, and becomes maximum at approximately 212 degrees. When the load F 'received by the roller 33 becomes maximum (rotation angle θ of 212 degrees), the refrigerant inside the compression space 31b is compressed and discharged through the discharge port 42, that is, compression The pressure inside the space 31b is equal to the discharge pressure, and the discharge pressure at that time is 21.1 kg / cm ² G.

FIG. 4 is a view in which fixing parts X, Y, and Z are formed to fix the assembly 50 to which the cylinder 31 and the upper flange 35 are coupled to the case 10.

As shown in FIG. 4, the cylinder 31 and the flanges 35 and 36 are combined to form a combined body 50, and a plurality of fixing parts X, Y, and Z are formed on the outer circumferential surface of the combined body 50. It is fixed to the case 10. There are a number of ways to form the fixing portion (X, Y, Z) It is preferable to form by welding which can be joined firmly and seamlessly.

In addition, it is preferable that a plurality of fixing parts X, Y, and Z are provided on the upper flange 35 to fix the combination 50 to the case 10.

As described above, when the roller 33 inside the cylinder 31 rotates to compress the refrigerant, the compressed refrigerant exerts a load F ′ on the roller 33, and the load F ′ is a rotation shaft ( It is transmitted to the flanges 35 and 36 supporting the rotating shaft 23 through the 23 to act in the radial direction of the assembly 50 to which the cylinder 31 and the flanges 35 and 36 are coupled.

As the load F 'received by the roller 33 is changed according to the rotation angle θ of the roller 33, the load acting on the assembly 50 is also changed, and the roller 33 has the maximum load F' _MAX. ), The assembly 50 also receives the maximum load (F _MAX ). The maximum load F _MAX applied to the assembly 50 acts in a direction substantially parallel to the maximum load F _'MAX applied to the roller 33 and acts in a direction passing through the center of the rotation shaft 23.

In order to effectively support the maximum load (F _MAX ) applied to the assembly 50, three fixing parts (X, Y, Z) are formed to fix the assembly 50 to the case 10. Among the fixing parts (X, Y, Z), the first fixing part (X) is preferably prepared at a position where the assembly 50 receives the maximum load (F _MAX ). The second and third fixing parts (Y, Z) are symmetrical to each other in a straight line connecting the first fixing part (X) and the center (O) of the rotation axis 23, and the three fixing parts (X, Y, Z) ) Is connected to each other is preferably provided to form an isosceles triangle. This is because when the first fixing part X receives the maximum load, the second and third fixing parts Y and Z support the assembly 50 symmetrically with each other on the first fixing part X so that both fixing parts ( To balance the vibration of the compressor To reduce.

In this case, the second and third fixing parts (X, Z) are the first fixing part (X) provided at the position receiving the maximum load (F _MAX ), and the second and third fixing parts (X) have the center (O) of the rotation axis (23) as a vertex. ∠XOY and ∠XOZ respectively formed with the fixed portions Y and Z are oblique angles. At this time, by setting the angles of XXOY and XXOZ to 120 degrees, respectively, connecting the three welded portions X, Y and Z, the second and third fixing portions Y and Z may be positioned to form an approximately equilateral triangle.

As such, by providing the first fixing part X at the position where the assembly 50 receives the maximum load (F _MAX ), the fixing part X can support the assembly 50. Vibration is reduced during the operation of, and the effect will be greater in the twin rotary compressor that compresses the refrigerant in two compression units arranged up and down.

In the above description, the assembly is fixed to the case by three fixing parts, but the present invention is not limited thereto and may be implemented in a rotary compressor having a plurality of fixing parts.

In addition, it has been described that there is only one cylinder, but it can be implemented in a twin rotary compressor that compresses refrigerant in two compression units.

As described above, according to the rotary compressor according to the present invention, one welding portion is provided at a position where the combination of the cylinder and the upper flange receives the maximum load when the roller is rotated, and the welding portion can support the maximum load applied to the assembly. By doing so, the vibration generated during the operation of the rotary compressor can be significantly reduced.

Claims (8)

A case forming a sealed inner space, A cylinder provided inside the case and having an inner space; A rotating shaft rotating through the cylinder, A roller provided inside the cylinder and compressing a working fluid while eccentrically rotating; A flange for sealing the cylinder and supporting the rotating shaft; It includes a combination coupled to the cylinder and the flange, The first fixing part of the plurality of fixing parts provided on the outer periphery of the assembly to fix the assembly to the case is a position where the load received by the assembly is maximized by the reaction force generated when the roller compresses the working fluid inside the cylinder. Rotary compressor, characterized in that provided in. The method of claim 1, Rotary compressor characterized in that three fixing parts for fixing the combination to the case. The method of claim 2, And two angles each of which the first fixing part is formed with the second and third fixing parts by using the center of the rotation axis as a vertex are both obtuse angles. The method of claim 3, The second and third fixing parts are symmetrical to each other in a straight line connecting the center of the first fixing part and the rotating shaft, and when the three fixing parts are connected, the rotary compressor is provided to form an isosceles triangle. The method of claim 4, wherein The second and third fixing parts are configured to form an equilateral triangle when the three fixing parts are connected. The method of claim 1, The plurality of fixed parts of the rotary compressor, characterized in that formed by welding. The method of claim 1, Wherein the plurality of fixing parts are provided on an upper flange to fix the assembly to the case. The method of claim 1, And said cylinder and said flange are joined by bolts to form an assembly.

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