KR20060062837A - Hermetic rotary compressor - Google Patents

Abstract

The present invention relates to a main body eccentric prevention support device for a reciprocating compressor, the present invention comprises a sealed container, a drive motor and a compression unit and the like, the main body located inside the sealed container, the main body and the sealed container In a reciprocating compressor comprising springs mounted therebetween and elastically supporting the body, the springs are first springs positioned on a relatively heavy side of the body, and positioned on a relatively variable side of the body and elastically supported. It is composed of second springs whose coefficient is relatively smaller than the first springs. As a result, the main body located in the sealed container maintains a horizontal state, which facilitates the maintenance of the gap between the sealed container and the main body, and maintains a constant distance, thereby causing vibration or collision between components during movement of the compressor. This is to prevent the occurrence of abnormal behavior.

Description

Main body eccentric support device for reciprocating compressor {HERMETIC ROTARY COMPRESSOR}             

1 is a cross-sectional view showing a main body supporting structure of a conventional reciprocating compressor;

2 is a cross-sectional view showing an operating state of a main body supporting structure of the reciprocating compressor;

3 is a cross-sectional view showing a main body eccentric support device of the reciprocating compressor of the present invention.

<Description of the symbols for the main parts of the drawings>

100; Closed container 200; main body

210; Front frame 220; Drive motor

230; Intermediate frame 240; cylinder

250; Piston 260; Rear frame

60; First spring 70; Second spring

TECHNICAL FIELD The present invention relates to a reciprocating compressor, and more particularly to a body of a reciprocating compressor which not only maintains a constant distance between a sealed container and a body to be located in the sealed container, but also allows the body to be positioned horizontally with respect to the sealed container. It relates to a support device for preventing eccentricity.

Generally, a compressor converts electrical energy into kinetic energy and compresses refrigerant gas by the kinetic energy.

There are various types of compressors, such as rotary compressors, scroll compressors, and reciprocal compressors, depending on a compression mechanism for compressing a refrigerant.

The basic configuration of such compressors includes a sealed container, a drive motor positioned in the sealed container to generate a driving force, and a compression unit configured to compress the refrigerant by receiving the driving force of the driving motor.

In the reciprocating compressor, the driving motor generates a rotational force and receives the rotational force of the driving motor, converts the rotational force into a linear reciprocating motion in the compression unit to compress the refrigerant, and the driving motor generates a linear reciprocating driving force. There is a method of compressing the refrigerant in the compression unit by receiving the linear reciprocating driving force of the drive motor.

1 is a cross-sectional view showing an example of a reciprocating compressor in which the drive motor generates a linear reciprocating driving force.

As shown in the drawing, the reciprocating compressor includes a main body 200 including a drive motor, a compression unit, and the like inside the hermetic container 100, and a lower portion of the main body 200 and the hermetic container 100. Springs 30 are mounted between the bottoms of the blades. The springs 30 are coil springs having the same modulus of elasticity. The springs 30 are positioned at two spaces on the lower surface of the front side (left side) of the main body 200 at regular intervals, and two springs 30 are positioned on the lower surface of the rear side (right side of the body) at regular intervals. . Both sides of the spring 30 are coupled to the mounting portion 110 protruding from the inner bottom surface of the sealed container 100 and the mounting portion 201 protruding from the lower portion of the main body 200, respectively.

In addition, a suction pipe 140 through which gas is sucked and a discharge pipe 150 through which gas is discharged are respectively coupled to the sealed container 100, and a predetermined amount of oil supplied to the main body 200 is provided on a bottom surface of the sealed container 100. It is filled.

In addition, the reciprocating compressor not only reduces the size of the hermetically sealed container 100 in order to free its installation space, but also makes the main body 200 compact. In addition, the interval between the inner wall of the sealed container 100 and the main body 200 located in the sealed container 100 is also optimized to maintain an appropriate interval. When the distance between the inner wall of the sealed container 100 and the main body 200 is too close, excessive vibration occurs in the drive motor and the compression unit, the compressor is mounted on a refrigerator or an air conditioner, or a refrigerator or an air conditioner in which the compressor is mounted. When the position is moved, the drive motor and the compression unit collide with the hermetic container 100 to cause breakage of the parts and generate a collision noise.

Therefore, the main body 200 should be supported by the springs 30 while keeping the sealed container 100 and the main body 200 at regular intervals.

However, in the conventional structure as described above, the springs 30 supporting the main body 200 on both sides of the lower surface of the main body 200 have a constant elastic modulus and length, and also drive the main body 200. Since the weight of both sides of the main body 200 is different by the motor and the compression unit, the main body 200 is inclined to one side as shown in FIG. 2. Due to this, not only the horizontal space is not maintained between the sealed container 100 and the main body 200 but also the gap between the sealed container 100 and the main body 200 is not kept constant so that vibration occurs or the compressor is moved when the compressor is moved. There was a problem that a collision occurs between the container 100 and the main body 200.

SUMMARY OF THE INVENTION The present invention has been made in view of the above, and an object of the present invention is not only to maintain a constant distance between a sealed container and a body to be placed in the sealed container, but also to maintain the body horizontally with respect to the sealed container. The present invention provides a support device for preventing an eccentric body of a reciprocating compressor.

In order to achieve the object of the present invention as described above, a main body including an airtight container, a drive motor, a compression unit, and the like, which is located inside the airtight container, is mounted between the main body and the airtight container, A reciprocating compressor comprising elastically supporting springs, the springs comprising: first springs positioned on a relatively heavy side of the body; and relatively springs on a relatively variable side of the body, the elastic modulus of which is determined by the first spring. There is provided a support device for preventing the eccentric body of the reciprocating compressor, characterized in that it consists of second springs that are relatively smaller than the two.

EMBODIMENT OF THE INVENTION Hereinafter, the main body eccentric prevention support apparatus of the reciprocating compressor by this invention is demonstrated in detail according to the Example shown in an accompanying drawing.

3 is a cross-sectional view showing an embodiment of a main body eccentricity support device of the reciprocating compressor of the present invention. The same code | symbol is attached | subjected about the same part as before.

As shown in the drawing, the support device for preventing the main body eccentricity of the reciprocating compressor includes a sealed container 100, a main body 200 located inside the sealed container 100, the main body 200 and a sealed container ( It is configured to include a spring mounted between the 100 and elastically supporting the main body 200, the springs and the first spring 60, which is located on a relatively heavy side of the main body 200, and the main body 200 ) Is composed of second springs 70 which are positioned on a relatively variable side and whose elastic modulus are relatively smaller than the first springs 60.

The airtight container 100 has a predetermined airtight space formed therein, and a certain amount of oil is filled on the bottom surface thereof. One side of the sealed container 100 is coupled to the suction tube 140, the gas is sucked, and the discharge tube 150 is discharged to the other side is coupled.

The main body 200 is located at one side of the drive motor 220 and the drive motor 220 coupled to one side of the front frame 210 and the front frame 210 and driven together with the front frame 210. An intermediate frame 230 for fixing the motor 220, a cylinder 240 coupled to the front frame 210, a linear reciprocating motion inserted into the cylinder 240, and the drive motor 220. The piston 250 is connected, the rear frame 260 coupled to the front frame 210, the resonant springs 270 and the piston (elastically supporting the movement of the piston 250 to cause a resonant movement) It is configured to include a valve assembly 280 for controlling the intake and discharge of gas into the compression space of the cylinder 240 in accordance with the reciprocating motion of (250).

The cylinder 240, the piston 250, and the valve assembly 280 constitute a compression unit.

In general, the portion where the drive motor 220 is located among the main body 200 is the heaviest portion.

The first springs 60 and the second springs 70 are coil springs.

The first springs 60 are composed of two springs positioned at predetermined intervals, and the first springs 60 are positioned at a relatively heavy portion of the main body 200. The second spring 70 is composed of two springs positioned at predetermined intervals, and is positioned on the opposite side of the heavy portion of the main body 200.

A main body-side first mounting portion 211 protruding in a predetermined shape is formed under the heavy portion of the main body 200 and protrudes in a predetermined shape on a lower surface of the airtight container 100 facing the main body-side first mounting portion 211. The container side first mounting part 102 is formed. Two main body side first mounting portions 211 and two container side first mounting portions 102 are formed. One side of the first spring 60 is coupled to and supported by the body-side first mounting portion 211, and the other side of the first spring 60 is coupled to and supported by the container-side first mounting portion 102.

A main body side second mounting part 261 protruding in a predetermined shape is formed in a lower portion of the main body 200 positioned on an opposite side of the heavy part of the main body 200 and is sealed to face the main body side second mounting part 261. The container side 2nd mounting part 103 which protrudes in the predetermined shape is formed in the bottom face of the container 100. FIG. The main body side second mounting part 261 and the container side second mounting part 103 are each formed in two pieces. One side of the second spring 70 is coupled to and supported by the main body side second mounting part 261, and the other side of the second spring 70 is coupled to and supported by the container side second mounting part 103.

The first springs 60 are positioned on the side of the drive motor 220 constituting the main body 200, and the second springs 70 are located on the opposite side of the drive motor 220.

Preferably, the main body side first mounting part 211 is formed at the front frame 210, and the main body side second mounting part 261 is preferably formed at the rear frame 260.

The outer diameter of the first spring 60 is greater than the outer diameter of the wire of the second spring 70 so that the elastic modulus of the first spring 60 is larger than that of the second spring 70. At this time, the height of the main body-side first mounting portion 211 and the main body-side second mounting portion 2221 may be the same or different.

In addition, the first springs 60 are shorter than the second springs 70 so that the first springs 60 have a larger elastic modulus than the second springs 70. In order to support such a structure, a support surface of the main body 200 in which the first springs 60 are in contact with the main body 200 side is supported by the second springs 70 in contact with the main body 200 side. It will be lower than cotton. That is, the height of the main body side first mounting part 211 is lower than the height of the main body side second mounting part 261. At this time, the height of the container-side first mounting portion 102 and the container-side second mounting portion 103 may be the same or different.

Referring to the effect of the main body eccentricity support device of the reciprocating compressor as described above are as follows.

First, as the power is applied, the reciprocating compressor generates a linear reciprocating driving force by operating the driving motor 220. The driving force of the driving motor 220 is transmitted to the piston 250, so that the piston 250 is a cylinder ( The linear reciprocating motion is performed in the compression space of 240). As the piston 250 linearly reciprocates in the compression space of the cylinder 240, the gas is sucked, compressed and discharged by the pressure difference in the compression space of the cylinder 240.

In the above process, the vibration generated in the main body 200 is absorbed by the first springs 60 and the second springs 70 so that the vibration generated in the main body 200 is transmitted to the sealed container 100. Will be minimized.

In addition, since the main body 200 is elastically supported by the first springs 60 and the second springs 70 having different elastic modulus, the center of gravity of the main body 200 is located in the middle of the main body 200. Even if not, the main body 200 is supported to be positioned horizontally. That is, the first spring 60 having a relatively large modulus of elasticity is positioned on the heavier side of the body 200, and the second spring having a relatively smaller modulus of elasticity than the first springs 60 on the opposite side of the heavier weight. Since the 70 is installed, the main body 200 is positioned in a horizontal state.

Meanwhile, the length of the first springs 60 is smaller than the length of the second springs 70 so that the support surface of the main body 200 on which the first springs 60 are supported is supported by the second springs 70. Lower than the support surface of the main body 200 and thereby the main body 200 is positioned in a horizontal state.

As described above, the main body eccentric prevention device of the reciprocating compressor of the present invention supports the main body 200 located in the sealed container 100 with the springs corresponding to the partial weight of the main body 200 and the sealed Since the main body 200 located in the container 100 maintains a horizontal state, the interval between the sealed container 100 and the main body 200 is not only convenient, but also maintains a constant interval, thereby generating vibration or When moving, it is possible to suppress the occurrence of collision or abnormal behavior between the parts. As a result, it is possible to increase the reliability of the compressor by preventing damage to the parts.

Claims (6)

A sealed container, a front frame and an intermediate frame located in the sealed container, a drive motor coupled to the front frame and the intermediate frame, a rear frame coupled to the intermediate frame, a cylinder coupled to the front frame, and inserted into the cylinder And a piston connected to the drive motor and comprising a main body and springs mounted between the main body and the hermetic container and elastically supporting the main body, wherein the springs are relative to the main body. Main body eccentric of the reciprocating compressor comprising: first springs positioned on a heavy side and second springs positioned on a relatively variable side of the main body and whose elastic modulus is relatively smaller than the first springs; Preventive support device. 2. The apparatus of claim 1, wherein the length of the first springs is smaller than the length of the second springs. The support device for preventing eccentricity of the reciprocating compressor according to claim 1, wherein the supporting surface of the main body in which the first springs are in contact with the main body is lower than the supporting surface in which the second springs are in contact with the main body. The support device for preventing eccentric body of claim 1, wherein the wire outer diameter of the first springs is larger than the wire outer diameter of the second springs. 2. The support device for preventing eccentricity of the main body of claim 1, wherein the first springs are located on a side of a drive motor constituting the main body. A sealed container, a front frame and an intermediate frame located in the sealed container, a drive motor coupled to the front frame and the intermediate frame, a rear frame coupled to the intermediate frame, a cylinder coupled to the front frame, and inserted into the cylinder And a piston connected to the drive motor, the reciprocating compressor comprising a body and springs mounted between the main body and the sealed container to elastically support the main body, wherein the relatively heavy one of the main bodies A support device for preventing the eccentric body of the reciprocating compressor, characterized in that the supporting surface of the main body in which the springs are placed in contact with the main body is lower than the supporting surface of the main body in which the springs located on the variable cloud side of the main body are in contact with the main body.

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