KR20010037804A - Noise reducing device of an enclosed reciprocating compressor having a side branch resonator formed on a valve plate - Google Patents

Abstract

PURPOSE: A noise reduction apparatus is provided to reduce noise at a specific frequency band from among the striking noise of a discharge valve or pulse noise caused during refrigerant compression, while occupying less space for installation of the side branch resonator. CONSTITUTION: A noise reduction apparatus comprises a discharge muffler(200) having a muffler plate with a refrigerant suction port, a refrigerant discharge port and a refrigerant outlet port, and a valve cover(206) formed by an inner panel and an outer panel; a gasket(210) having a bolt hole(214) and a refrigerant passage; a discharge valve plate(220) having a reed valve(226) and a bolt hole(222); and a valve plate(230) positioned at the inner surface of the discharge valve plate and which has an inlet hole(234) and an outlet hole(236). The valve plate has a side branch resonator(238) having a predetermined volume and which is formed in the vicinity of the outlet hole of the valve plate. The side branch resonator has a size sufficient to damp a predetermined frequency from among the noise produced from the compressor.

Description

Noise reduction device of hermetic reciprocating compressor having geodetic resonator formed on valve plate {NOISE REDUCING DEVICE OF AN ENCLOSED RECIPROCATING COMPRESSOR HAVING A SIDE BRANCH RESONATOR FORMED ON A VALVE PLATE}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a hermetic compressor for a refrigeration cycle of a refrigerator, and more particularly to a hermetic reciprocating compressor employing a side branch resonator to reduce the noise of a compressor, in particular, a specific frequency band. The noise reduction device of the present invention.

The compressor generally serves as a pump for sucking low-temperature and low-pressure refrigerant vapor evaporated to facilitate evaporation, compressing the absorbed vapor into high-temperature and high-pressure steam for easy condensation, and compressing the refrigerant with a compression force. It is a refrigerator component which performs the role which circulates continuously inside. Therefore, the compressor is used according to the pressure such as evaporation pressure and condensation pressure, and the compression ratio, piston output, type of refrigerant, temperature and flow state of air or water (condensing material) supplied to condense the refrigerant vapor compressed to high temperature and high pressure. There are many differences in the structure, form and method of operation.

This type of compressor includes a reciprocating compressor that compresses refrigerant gas through a reciprocating motion of a piston, a rotary compressor that rotates a rotor in a cylinder, and converts velocity energy into pressure energy using centrifugal force of an impeller. And a turbo compressor for compressing refrigerant gas.

FIG. 1A is a plan sectional view of a hermetic reciprocating compressor according to the prior art, and FIG. 1B is a front sectional view thereof.

In the illustrated compressor, a compressor body is built in upper and lower cases 10 and 20 sealed by welding. The compressor main body is largely provided with a frame 30, a motor unit 40 installed at a lower portion of the frame to rotate the shaft 60, which is a transmission medium, and a refrigerant gas sucked by converting the rotational movement of the shaft 60 into linear movement. It consists of a mechanical part 50 which compresses and discharges.

The frame 30 supports the entire motor portion 40 and the mechanical portion 50, and is supported by the upper and lower cases 10 and 20 through side stoppers 70 and coil springs 80, which are cushioning and noise preventing means, respectively. do.

The mechanical part 50 includes a cylinder 110 fixed to the upper end of the frame, a piston 120 inserted into the cylinder 110 to linearly reciprocate, and a crank part 61 of the piston 120 and the shaft 60. Is connected to the piston rod 130 is configured to convert the rotational movement of the shaft 60 to a linear movement. Thus, the shaft 120 rotated by the motor portion 40 reciprocates the piston rod 130 of the mechanical portion 50 through the crank portion 61 so that the piston 120 is linear in the cylinder 110. The reciprocating motion compresses and discharges the refrigerant gas sucked into the cylinder 110, and the refrigerant gas takes heat from the object to be cooled while circulating the refrigeration apparatus to achieve a predetermined refrigeration purpose.

In addition, a valve plate 140 having suction and discharge valves is installed at one side of the cylinder 110, and suction and discharge mufflers 150 and 160 which guide suction and discharge of refrigerant gas are installed outside the valve plate. The suction and discharge mufflers are connected to suction and discharge pipes 170 and 180, respectively. The discharge muffler 160 is installed on the discharge side through which the high-temperature / high-pressure refrigerant gas compressed from the cylinder 110 is discharged to reduce noise generated by the pulsation of the pressure during the discharge of the refrigerant gas.

2 is a schematic sectional plan view showing the structure of a conventional discharge muffler.

The discharge muffler 260 is coupled to the discharge side of the cylinder 110 together with the valve plate 140 and is in communication with the discharge plate and the muffler plate 270 having an inlet, an outlet, and an outlet for suction of refrigerant gas. A muffler cup 290 having a primary chamber and a valve cover 280 composed of an inner plate and an outer plate, a secondary chamber joined to the outlet side of the muffler plate 270 and communicating with the outlet, and a muffler cup 290. It is composed of a discharge pipe 180 is joined to the separate resonance type silencer 300 is connected to the side portion of the muffler cup 290 via a connecting pipe 310.

The discharge muffler 260 compresses the refrigerant gas in the cylinder 110 while the piston 120 of the mechanical part 50 reciprocates by the shaft 60. After the discharge port is discharged to the first direction of the valve cover 280, it is discharged again through the discharge port, the muffler cup 290 and the discharge pipe 180. At this time, the pulsation sound of the refrigerant gas and the blow sound of the valve generated during the discharge are attenuated by the transmission loss while passing through the resonance silencer 300 connected to the muffler cup 290 and the connection pipe 310.

However, since the noise structure of the hermetic reciprocating compressor as described above is simply attached to the muffler cup 290, the resonance type silencer 300 of the same type has a small amount of transmission loss due to resonance, and thus the blow sound of the discharge valve There is a weak point to attenuate the noise caused by refrigerant compression. That is, the blow and pulsation noises of the valve of the refrigerant gas generated at the time of discharging are not all attenuated by the muffler cup and the resonance silencer, but also require a large installation space.

The present invention has been made to solve the conventional problems as described above, while being able to attenuate the noise of a specific frequency band among the noise generated by the blow sound of the discharge valve or the refrigerant compression during operation of the hermetic reciprocating compressor, It is to provide a noise reduction device of a hermetic reciprocating compressor that occupies little.

In order to achieve the above object, the present invention provides a noise reduction device for a hermetic reciprocating compressor including a discharge muffler, a gasket, and a discharge valve plate.

Noise is characterized in that it comprises a valve plate which is fixed to the upper surface of the cylinder block and has a suction port and a discharge port, the geodetic resonator is formed on the discharge port side having a size capable of attenuating a predetermined frequency of the noise generated by the compressor Provide an abatement device.

1A and 1B are a plan sectional view and a front sectional view of a hermetic compressor according to the prior art,

2 is a plan sectional view of a discharge muffler according to the prior art,

3 is an exploded perspective view of a discharge muffler, a gasket, a discharge valve plate and a valve plate of the noise reduction device according to the present invention;

4A and 4B are a plan view and a bottom view of the valve plate of the noise reduction device according to the present invention, respectively,

4C is a side cross-sectional view taken along the line A-A of FIG. 4A.

<Description of the code | symbol about the principal part of drawing>

200: discharge muffler 206: valve cover

208: bolt accommodation 210: gasket

212: resonator connecting passage 214: bolt receiving ball

220: discharge valve plate 222: bolt receiving hole

224: geodetic resonator 226: flapper

230: valve plate 232: bolt receiving hole

234: suction port 236: discharge port

238: Geodetic Resonator

Such features of the present invention and the resulting effects thereof will become more apparent from the detailed description of the invention with reference to the accompanying drawings.

3 is an exploded perspective view of the discharge muffler 200, the gasket 210, the discharge valve 220 plate, and the valve plate 230 employed in the noise reduction device of the hermetic reciprocating compressor according to the present invention. It is.

The discharge muffler 200 has a muffler plate having a suction port for discharging refrigerant gas, a discharge port and a discharge port, and a valve cover 206 having a primary chamber (not shown) in communication with the discharge and discharge ports, and including an inner plate and an outer plate. It consists of). At the corner of the muffler plate 201, a bolt receiving hole 208 or the like for fastening a cylinder block (not shown) is formed.

The gasket 210 has a bolt receiving hole 214 and a refrigerant passage, and helps the valve assembly to be installed in the cylinder block (not shown) without leakage.

The discharge valve plate 220 includes a reed valve 226 having a reed structure having elasticity and a bolt receiving hole 222.

The valve plate 230 is located inside the discharge valve plate 220, that is, the cylinder block side, and includes a suction port 234 and a discharge port 236.

The noise reduction structure of the present invention is achieved by forming a side branch resonator 238 having a constant volume around the outlet 236 of the valve plate 230.

As shown in more detail in FIGS. 4A and 4C, the geodetic resonator 238 is formed to have a constant depth on the discharge port 236 side.

The length (l), width (a) and depth (h) of the geodetic resonator 238 are related to the frequency of the noise to be attenuated.

It can be expressed as Where f is the frequency to attenuate, C is the sound velocity (constant) of the refrigerant gas, l is the length of the resonator, and Vc is the volume of the resonance chamber. , a: width, h: depth.

The geodetic resonator of this configuration may be manufactured in a single process in the forging (or press) processing for processing the valve plate 230.

In the above, this invention is preferable. Although described in connection with the embodiment, those skilled in the art will understand that various changes may be made without departing from the spirit of the invention and the appended claims.

As described above, according to the noise reduction structure of the hermetic reciprocating compressor according to the present invention, a noise having a specific frequency among noises such as a blow sound of a valve or a pulsation sound during compression does not occupy a separate installation space. It can be removed using a geodetic resonator.

Claims (2)

In the noise reduction device of a hermetic reciprocating compressor comprising a discharge muffler, a gasket and a discharge valve plate, It is fixed to the upper surface of the cylinder block and has a suction port 234 and the discharge port 236, the valve having a geodetic resonator 238 has a size that can attenuate a predetermined frequency of the noise generated by the compressor on the discharge port side Noise reduction device comprising a plate (230). The noise reduction device according to claim 1, wherein the geodetic resonator (238) is formed on the valve plate by forging.