KR19990058920A - Vibration Noise Reduction Structure of Compressor - Google Patents

Abstract

The present invention relates to a structure for reducing vibration noise of a compressor. In the related art, vibration generated in a mass body in which parts such as a piston and a cylinder for compressing a refrigerant gas are coupled therein is acted in a horizontal direction and a longitudinal direction by a spring. The present invention has a disadvantage in that it is not effective to suppress the transmission of the vibration to the sealed container, the present invention is the main body case is open on both sides, and the refrigerant gas inside the compression, discharge time of each component such as cylinder and piston Is coupled to the inner container is inserted into the inside of the main body case, the leaf spring is fixed to the main body case and the elastic support for the inner container, and are coupled to both sides of the main body case and sealed together with the main body case In the process of compressing and discharging the refrigerant gas comprising a first cap and a second cap forming a container The vibration noise generated is alleviated through the leaf spring, and the vibration noise generated inside is minimized to the sealed container, thereby minimizing the transmission of vibration noise generated in the compressor to the outside, thereby improving the reliability of the compressor. It is to simplify the cost of materials.

Description

Vibration Noise Reduction Structure of Compressor

The present invention relates to a compressor, and more particularly, to a structure that reduces vibration noise of a compressor so that vibration noise generated during suction and compression of a refrigerant gas is transmitted to the outside and minimized.

In general, the compressor constituting the refrigeration cycle device is to compress the refrigerant flowing from the evaporator to be discharged in a state of high temperature and high pressure.

The compressor usually includes a drive motor for generating a driving force by a current applied to an inside of a sealed container having a predetermined internal volume, a piston reciprocating by the drive motor, a cylinder coupled to the piston, and into the cylinder. And a valve assembly configured to allow the refrigerant gas to be sucked and to discharge the compressed refrigerant gas. In addition, each component installed in the sealed container is combined with a main frame or an inner container installed inside the sealed container to form a mass.

In the compressor as described above, the driving motor is driven by the applied electric current, and the driving force of the driving motor is transmitted to the piston so that the piston reciprocates inside the cylinder, and the piston reciprocates the refrigerant gas into the cylinder through the valve assembly. Is sucked, compressed and discharged in a state of high temperature and high pressure.

On the other hand, the compressor generates a vibration noise in the process of inhaling, compressing and discharging the refrigerant while the piston reciprocates, the vibration noise is transmitted to the sealed container to the outside wavelength is mounted to the refrigerator or home appliances It gives the user a very unpleasant feeling.

1A, 1B, and 1C show the sealed container 10 constituting the compressor and each of the parts installed in the sealed container 1 as one real body 20, and generates the vibration noise. The structure in which the mass 20 is supported by the sealed container 10 is shown. As shown in the figure, a structure for reducing transmission of vibration noise generated in the conventional mass body 20 to the sealed container 10 has several coupling parts 21 formed on one side of the mass body 20, Several coupling parts 11 corresponding to the coupling part 21 formed on the mass body 20 are formed on the bottom surface of the airtight container 10, and the coupling part 21 and the sealing container of the mass body 20 ( The spring 30 is coupled between the coupling portions 11 of the 10 so that the mass body 20 is supported by the airtight container 10 by the spring 30.

The closed container 110 is formed by joining the upper cap 12 and the lower cap 13 formed in a hemispherical shape by welding, and the coupling portion 21 formed on the mass body 20 is formed to protrude in a conical shape. Coupling portion 21 is formed in each of the two on both sides of the four, the coupling portion 11 formed on the bottom surface of the sealed container 10 is also formed in four places so as to project in a conical shape. Both ends of the spring 30 are circular coil springs coupled to the coupling portion 21 of the mass body 20 and the coupling portion 11 of the hermetic container 10.

Reference numeral 40 denotes a suction tube, and reference numeral 50 denotes a discharge tube.

The structure generates a vibration noise in the process of compressing and discharging the refrigerant while the piston (not shown) constituting the mass 20 reciprocates inside the cylinder (not shown), the generated vibration noise is a spring (30) It is buffered by) to reduce the delivery to the sealed container (1).

However, in the conventional vibration noise reduction structure as described above, the vibration generated in the mass body 20 is acted in the transverse direction and the longitudinal direction by the spring 30 so that the vibration generated in the mass body 20 is closed. Not only do not effectively suppress the transmission to 10) but also the design of the spring (30) for supporting the mass 20 has a difficult disadvantage.

An object of the present invention devised in view of the above disadvantages is to provide a vibration noise reduction structure of the compressor to minimize the transmission of vibration noise generated by the refrigerant gas is sucked, compressed, discharged to the sealed container. .

Figure 1a is a front sectional view showing a vibration noise reduction structure of a conventional compressor,

Figure 1b is a side cross-sectional view showing a vibration noise reduction structure of a conventional compressor,

Figure 1c is a sectional plan view showing a vibration noise reduction structure of a conventional compressor,

Figure 2 is a front sectional view showing an exploded compressor vibration noise reduction structure of the present invention,

3 is a front view showing a leaf spring constituting the compressor vibration noise reduction structure of the present invention,

Figure 4 is a front sectional view showing a vibration noise reduction structure of the compressor of the present invention.

* Explanation of symbols for main parts of the drawings

20 ': inner container 110: body case

120: leaf spring 121: coupling hole

122: body 123: arm

In order to achieve the object of the present invention as described above, the main body case is open at both sides, and each component such as a cylinder and a piston for sucking, compressing, and discharging refrigerant gas therein are combined and inserted into the main body case. A container, a leaf spring fixed to the main body case and elastically supporting the inner container, and a first cap and a second cap coupled to both sides of the main body case to form an airtight container together with the main body case; Vibration noise reduction structure of the compressor, characterized in that configuration is provided.

The leaf spring is fixedly coupled to both sides of the main body case is provided with a vibration noise reduction structure of the compressor, characterized in that for supporting both ends of the inner container, respectively.

The leaf spring is provided with a vibration noise reduction structure of the compressor, characterized in that the coupling hole is formed in the center and has a predetermined area and a plurality of arms extending to the edge of the body portion.

The arm portion is formed to have an involute shape with a predetermined width, and four vibration portions are provided to reduce vibration noise of the body portion.

Hereinafter, the compressor vibration noise reduction structure of the present invention will be described according to the embodiment shown in the accompanying drawings.

Compressor vibration noise reduction structure of the present invention, as shown in Figure 2, is coupled to each component such as the main body case 110 having both sides open, the cylinder and piston for sucking and compressing and discharging the refrigerant gas therein An inner container 20 'inserted into the main body case 110, a leaf spring 120 fixed to the case 110 and elastically supporting the inner container 20', and the main body The first cap 130 and the second cap 140 are coupled to both sides of the case 110 to form a sealed container together with the body case 110.

The main body case 110 is formed to have a predetermined length with a cylindrical opening on both sides, the fixing protrusions 111 for supporting it when the leaf spring 120 is inserted into the inner inner circumferential surface of both ends. The inner container 20 'is formed in a cylindrical shape, one end is formed with an inlet 22 for guiding the introduction of refrigerant gas, and the inlet 22 is formed to protrude to have a predetermined diameter and the other end is The head cover 23 constituting the valve system protrudes. On one side of the inlet and the head cover 23, fixing protrusions 111 for supporting the leaf spring 12 () are formed. The first cap 130 is a cylindrical having a predetermined width, one end is opened, the other end is formed in a clogged shape and the diameter is formed into a diameter that is inserted into the body case 110. In addition, a suction pipe 40 through which refrigerant gas is sucked is coupled to the blocked surface. The second cap 140 is formed in the same shape as the first cap 130, the discharge pipe 50 for discharging the refrigerant gas compressed in the inner container 20 'is inserted into the blocked surface.

As shown in FIG. 3, the leaf spring 120 has a center coupling hole 121 formed therein, and a body portion 122 having a predetermined area and several arm portions formed at edges of the body portion 122. It is formed with 123. The arm portion 123 is formed to have an involute shape with a predetermined width, and four body parts 122 are formed at equal angles. The diameter of the circle extending from each end of the arm 123 is formed to be smaller than the inner diameter of the body case 110. The leaf springs 120 are fixedly coupled to both sides of the body case 110 to support both ends of the inner container 20 'inserted into the body case 110, respectively. The coupling hole 121 of the leaf spring 120 supporting the inlet portion 22 is formed to a diameter into which the inlet portion 22 can be inserted, and supports the head cover 23 of the inner container 20 '. The coupling hole 121 of the leaf spring 120 is formed to a diameter that the head cover 23 can be inserted.

Hereinafter, the operational effects of the compressor vibration noise reduction structure of the present invention will be described.

First, the coupling process of the compressor vibration noise reduction structure of the present invention, as shown in Figure 4, the inner container 20 'is inserted into the main body case 110. The coupling hole 121 of the leaf spring 120 is inserted into the inlet 22 of the inner container 20 'and the arm 123 is inserted into the body case 110 to be supported by the fixing protrusion 111. The leaf spring 120 is coupled by the. The coupling hole 121 of the other leaf spring 120 is inserted into the head cover 23 of the inner container 20 'and the arm 123 is inserted into the main body case 110 to the fixing protrusion 111. The other leaf spring 120 is coupled by being supported. In a state in which the inner spring 20 'inserted into the main body case 110 is inserted in both ends of the leaf spring 120, the first cap 130 is inserted into one side of the main body case 110. The leaf spring 120 is fixedly supported, and the second cap 140 is inserted into the other side of the main body case 110 and fixedly supports the leaf spring 120. The first and second caps 130 and 140 are coupled by welding in a state of being inserted into the body case 110.

The structure generates vibration noise in the process of compressing and discharging the refrigerant while the piston inserted into the inner container 20 'reciprocates the cylinder, and the vibration noise is transmitted to the inner container 20'. The vibration noise transmitted to the inner container 20 'is absorbed while moving left and right by the leaf springs 120 coupled to both ends of the inner container 20' so that the amount of vibration in the longitudinal direction is virtually eliminated. Therefore, noise is minimized.

In the present invention, the inner container 20 'positioned inside the sealed container has only left and right vibrations, so that the moving width of the inner container 20' becomes small, thereby simplifying the structure of the sealed container.

As described above, the vibration noise sensing structure of the compressor according to the present invention, the vibration noise generated in the process of sucking, compressing, and discharging the refrigerant gas is alleviated through the leaf spring, thereby minimizing the vibration noise transmitted to the sealed container. By minimizing the transmission of vibration noise generated in the outside to improve the reliability of the compressor, and also has the effect of reducing the material cost by simplifying the structure.

Claims (4)

An inner container inserted into the main body case by combining a main body case having both sides opened, cylinders and pistons for sucking, compressing, and discharging refrigerant gas therein, and being fixed to the main body case, Vibration noise reduction of the compressor, characterized in that it comprises a leaf spring for elastically supporting the container and the first cap and the second cap coupled to the side of the main body case to form a sealed container together with the main body case rescue. The vibration noise reduction structure of claim 1, wherein the leaf springs are fixedly coupled to both sides of the main body case to support both ends of the inner container. The vibration noise reduction structure of claim 1, wherein the leaf spring includes a body portion having a predetermined coupling hole, and a body portion having a predetermined area, and several arm portions extending from the edge of the body portion. The vibration noise reduction structure of claim 3, wherein the arm portion is formed to have an involute shape with a predetermined width, and four are formed in the body portion.