KR100850593B1 - Linear compressor - Google Patents

Abstract

A linear compressor is provided to enhance spatial efficiency inside a shell by installing a dynamic vibration absorber outside the shell. A linear compressor comprises a shell(100), a compressor body, a mount(200), a clamp(250) and a dynamic vibration absorber including a first vibration absorber(301) and a second vibration absorber(302). The compressor body is installed in the shell and compresses refrigerant using a piston, which reciprocates by a linear motor. The mount is installed under the shell along the reciprocation direction of the piston and fixes the shell. The dynamic vibration absorber includes a center part which is fixed by the clamp, and two free ends which absorb vibration of the shell.

Description

Linear Compressor {LINEAR COMPRESSOR}

1 shows an example of a conventional linear compressor;

2 is a side view of a linear compressor having a dynamic reducer according to an embodiment of the present invention;

3 is a plan view of a linear compressor having a copper reducer according to an embodiment of the present invention.

The present invention relates to a linear compressor. More specifically, the present invention relates to a linear compressor including a configuration capable of reducing vibration.

In general, a compressor is a mechanical device that increases pressure by receiving power from a power generator such as an electric motor or a turbine to compress air, refrigerant, or various other working gases. It is widely used throughout.

These compressors are classified into reciprocating compressors that compress the refrigerant while the piston reciprocates linearly inside the cylinder by forming a compression space in which the working gas is absorbed and discharged between the piston and the cylinder. Rotary compressor that compresses the refrigerant while the roller is eccentrically rotated along the inner wall of the cylinder so that a compression space for absorbing and discharging the working gas is formed between the compressor and the eccentrically rotating roller and the cylinder. And a scroll compressor for compressing the refrigerant while the turning scroll is rotated along the fixed scroll to form a compressed space in which the working gas is sucked and discharged between the orbiting scroll and the fixed scroll. Divided into

Recently, among the reciprocating compressors, in particular, a piston is directly connected to a reciprocating linear motion drive motor, so that there is no mechanical loss due to the motion conversion, thereby improving the compression efficiency, and a simple linear compressor has been developed.

1 shows an example of a linear compressor. In general, the linear compressor is configured to suck, compress and then discharge the refrigerant while the piston 4 moves reciprocally linearly in the cylinder 2 by the linear motor 10 inside the closed shell 1. The linear motor 10 includes an inner stator 12, an outer stator 14, and a permanent magnet 16. The permanent magnet 16 linearly reciprocates between the inner stator 12 and the outer stator 14 by mutual electromagnetic force. As the permanent magnet 16 is driven while being connected to the piston 4, the piston 4 sucks and compresses the refrigerant while reciprocating linearly inside the cylinder 2, and then discharges the refrigerant.

The linear compressor also includes a frame 3 on which the cylinder 2 is mounted. In addition, the motor cover 5 is further provided with a frame 3 and bolt assembly. The linear motor 10 is installed between the frame 3 and the motor cover 5. In addition, the motor cover 5 is provided with a back cover 6 to support one end of the spring (7) connected to the piston (4).

Hereinafter, in order to simplify the vibration system of the linear compressor, the cylinder 2, the piston 4, the frame 3, the motor cover 5, the back cover 6, the spring 7, the linear motor 10 The flow path through which the refrigerant passes and the members used for the compression of the refrigerant are collectively referred to as the linear compressor main body 20.

In general, the compressor main body 20 is installed spaced apart from the bottom of the shell 1 so that the vibration generated from the movement of the piston 4 is not transmitted directly to the shell 1. The compressor main body 20 is supported by the elastic member 9 and is spaced apart from the bottom of the shell 1. The elastic member 9 is generally provided with four pairs, one pair at the front of the compressor main body 20 and one pair at the rear of the compressor main body 20.

Reaction force is applied to the elastic member 9 due to the weight of the compressor main body 20. In addition, the center of gravity of the compressor main body 2 exists at a predetermined position inside the compressor main body 20. Therefore, since the installation point of the elastic member 9 is separated from the center of gravity of the compressor main body 20 by a predetermined distance r, a rotation moment is generated in the elastic member 9 due to the movement of the piston 4. When the birth member 9 vibrates by the rotation moment, the compressor main body 20 supported by the elastic member 9 also vibrates. Therefore, not only the vibration and noise of the entire linear compressor are increased, but also the vibration is transmitted to the mount 30 for mounting the linear compressor to the mechanism. In addition, vibration is also transmitted to a device equipped with a linear compressor, thereby increasing the vibration and noise of the device itself.

An object of the present invention is to reduce vibration and noise of a linear compressor.

In addition, an object of the present invention is to provide a linear compressor with a simple structure and easy installation and removal of a copper reducer.

The shell, which is installed inside the shell and compresses the refrigerant using a piston driven by a linear motor, is mounted on the bottom of the shell, mounted on the bottom of the shell, and mounted by clamps and clamps that engage the mount. Provided is a linear compressor comprising a copper reducer for absorbing vibration. Through such a configuration, since the dynamic absorber absorbs the vibration of the shell outside the shell, the linear compressor structure may not be changed inside the shell, and the installation of the copper reducer by the clamp is easy.

The present invention also provides a linear compressor, characterized in that the copper reducer includes an elastic member having a mass and an elastic modulus adjusted to resonate at an operating frequency of the compressor main body. Through this configuration, since the elastic member itself serves as a copper reducer, there is an advantage that the configuration is simple. For example, if the natural frequency of the copper reducer is adjusted to match the operating frequency of the compressor main body by adjusting the mass and stiffness of the copper reducer, the dynamic reducer vibrates instead of the compressor during operation of the compressor main body, thereby reducing the vibration of the compressor. .

In another aspect, the present invention provides a linear compressor characterized in that the mount is installed in the front and rear directions of the shell, the copper reducer, the center is fixed by the clamp, both ends of the free end is vibrated to reduce the vibration of the shell. do. Through this configuration, the copper reducer, which is an elastic member, is compressed and stretched in the main elastic direction, and both ends rotate in front and rear directions and vibrate. Therefore, the main vibration of the linear compressor can be effectively reduced.

In addition, the present invention is installed in the shell, the shell, the compressor body for compressing the refrigerant, mounted on the bottom of the shell, the mount for fixing the shell, one end is fixed by the clamp and the clamp coupled to the mount, the vibration of the shell Provided is a linear compressor comprising a plurality of copper reducers for absorbing. For example, two or more copper reducers are installed in one clamp, one end of the copper reducer is fixed to the clamp, and the other end is a free end. This configuration can reduce the vibration of the linear compressor while the free end is vibrating.

Hereinafter, the present invention will be described in more detail with reference to the accompanying drawings.

Figure 2 is a side view showing an example of a linear compressor having a copper reducer according to an embodiment of the present invention. In addition, Figure 3 is a plan view showing an example of a linear compressor having a copper reducer according to an embodiment of the present invention.

2 and 3, a linear compressor according to an embodiment of the present invention includes a piston, a cylinder, and a linear motor, and includes a shell 100 and a shell 100 in which a compressor body compresses a refrigerant. The mount 200 for installation in the instrument, the copper reducer 300 installed on the mount 200 and the clamp 250 fixed to the copper reducer 300 and the mount 200 for the installation of the copper reducer 300 Include. When the copper reducer 300 is installed using the clamp 250, the installation structure of the copper reducer 300 is not only simple, but also has an advantage of being easily detachable to the mount 200.

Here, the copper reducer 300 is an elastic member having an effective mass and elasticity. When using a coil spring widely used as an elastic member, it is possible to reduce manufacturing time and manufacturing cost. The effective mass and elasticity of the dynamic reducer 300 are adjusted such that the operating frequency of the linear compressor and the natural frequency of the dynamic reducer 300 coincide. The operating frequency of the linear compressor is generally adjusted to match the natural frequency of the linear compressor to increase the efficiency of the linear compressor. Here, the natural frequency of the linear compressor is measured while the components of the compressor body are completely coupled and the compressor body is installed in the shell 100. When the operating frequencies of the dynamic reducer 300 and the linear compressor match, the dynamic reducer 300 vibrates instead of the linear compressor while reducing the vibration of the linear compressor.

The clamp 250 connects the mount 200 and the copper reducer 300, and serves to transfer the vibration transmitted from the shell 100 to the mount 200 to the copper reducer 300. The clamp 250 is not limited in shape as long as it can be firmly coupled to the copper reducer 300. The clamp 250 may have a pincer shape corresponding to the shape of the copper reducer 300, and the copper reducer 300 and the clamp 250 may be welded to each other to be coupled to each other. In addition, the clamp 250 and the mount 200 may also be firmly coupled to each other by welding, or may be coupled to be detachable such as bolt coupling.

The copper reducer 300 installed by the clamp 250 and absorbing the vibration of the shell 100 may be fixed to the center portion by the clamp 250, and both ends thereof may be free ends to vibrate. At this time, if the copper reducer 300 is a coil spring, while rotating relative to the fixed center portion, it is possible to effectively reduce the vibration of the shell 100 in various directions while being compressed and tensioned in the main deformation direction of the coil spring.

In addition, two or more copper reducers 300 fixed by one clamp 250 may be provided. In this case, the copper reducer 300 includes first and second copper reducers 301 and 302, one end of which is fixed by the clamp 250, and the other end of which is a free end, which rotates, vibrates, compresses, and tensions. .

Preferably, the mount 200 is installed in the front and rear directions of the shell 100. Here, the front and rear directions of the shell 100 are linear axis directions in which the piston reciprocates linearly by a linear motor, and are directions in which the refrigerant is compressed. In addition, the clamp 250 is fixed so that the longitudinal direction of the clamp 250 is the front and rear directions of the shell 100 to the mount 200. One end of the clamp 250 is coupled to the mount 200, and the other end is provided with a copper reducer 300. The copper reducer 300 is fixed by the clamp 250 and is installed in the left and right directions. The copper reducer 300 may reduce vibrations in the left and right directions of the compressor while being compressed and stretched in the left and right directions. In addition, the free end of the copper reducer 300 can reduce the front and rear vibration of the compressor while rotating by a predetermined angle in the front, rear direction. In addition, since the free end of the copper reducer 300 can also vibrate in the up and down directions, the up and down vibrations of the compressor can also be reduced. The vibration reduction effect of the copper reducer 300 includes a plurality of copper including the first and second copper reducers 301 and 302 as well as a case in which one copper reducer 300 is installed in one clamp 250. The same applies to the case where the reducer 300 is provided.

In addition, the clamp 250 and the copper reducer 300 may be installed only in any one of the two mounts 200 installed in the shell 100, or may be installed in both mounts 200. When the clamp 250 and the copper reducer 300 are installed in both mounts 200, the mass and the rigidity of all the copper reducers 300 installed in the two mounts 200 are reduced in order to reduce vibration of the compressor. It is considered to be connected and must be adjusted.

In the linear compressor according to the present invention, a copper reducer is installed outside the shell, so that the space inside the shell can be efficiently used, and the installation is convenient.

In addition, the linear compressor according to the present invention, since the copper reducer is installed on the mount through the clamp, it is easy to install and detach.

In addition, the linear compressor according to the present invention can be efficiently reduced by the front, rear, vertical and horizontal vibrations of the shell by the front, rear, vertical and horizontal vibrations of the dynamic reducer.

In the linear compressor according to the present invention, since the vibration of the compressor main body is not reduced because the copper reducer is installed outside the shell, the vibration of the shell can be reduced while lubricating the piston and the cylinder using the vibration of the compressor main body. .

Claims (4)

Shell; A compressor body installed inside the shell and compressing the refrigerant using a piston reciprocating by a linear motor; Mounted along the reciprocating direction of the piston at the bottom of the shell, fixing the shell; A clamp to engage the mount; And And a dynamic reducer having a central portion fixed by the clamp and absorbing vibrations of the shell while both ends being free ends vibrate. The method of claim 1, The clamp has a longitudinal direction coincident with the mounting direction of the mount, and the copper reducer is fixed to the clamp at a right angle to the clamp. The method according to claim 1 or 2, The dynamic reducer includes a elastic member having a mass and an elastic modulus. The method of claim 3, The elastic member is a linear compressor, characterized in that resonating at the operating frequency of the compressor main body.

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