KR20050090632A - A compressor having an inlet muffler - Google Patents

Abstract

The present invention relates to a compressor, and more particularly to a compressor including a suction silencer for reducing the suction noise.

An object of the present invention is to provide a compressor having a passage chamber and a resonance chamber, the refrigerant guiding the main path through the passage chamber and the movement path of the sound through the resonance chamber to maximize the separation effect of the refrigerant and the movement path. It is.

The compressor according to the present invention has a suction silencer including an air inlet in which fluid is sucked, a flow path chamber in which the sucked fluid flows along a predetermined flow path, and a closed casing in which a discharge port through which the fluid passing through the flow path is discharged is formed. In the compressor, the inlet is formed on one side of the flow path chamber, the resonance chamber to cancel the flow path noise, characterized in that the guide portion to guide the fluid introduced from the suction port to the discharge port is formed.

Description

Compressor with suction silencer {A COMPRESSOR HAVING AN INLET MUFFLER}

The present invention relates to a compressor, and more particularly to a compressor including a suction silencer for reducing the suction noise.

A compressor refers to a device for compressing and supplying a working fluid such as a refrigerant. The compressor includes a transmission unit for generating rotational power by application of a current, and a compression unit for compressing a working fluid by the transmission unit.

In general, the compression unit seals a cylinder block having a compression chamber and a piston for compressing the refrigerant in the compression chamber and a compression chamber to pass through the compression chamber between the cylinder head and the cylinder block and the cylinder block in which the refrigerant discharge chamber and the refrigerant suction chamber are partitioned. It is composed of a valve device for controlling the suction and discharge of the refrigerant.

In addition, the compressor is provided with a suction silencer between the compression chamber and the suction pipe for reducing the flow noise of the refrigerant sucked into the compression chamber.

The silencer can be classified into a sound absorbing type using sound absorbing material and a reflection type silencer using the sound wave reflection and interference effect by attaching a resonator and rapidly expanding or reducing the surface of the flow path. A reflective silencer provided is used.

The inside of the reflective suction silencer is formed to reduce the noise while simplifying the flow path by differentiating the main path of the refrigerant and the movement path of the sound, and this suction silencer as disclosed in Korean Patent No. 0373455 forms a depression in the resonance chamber. Or by forming a partition wall in the resonance chamber, the main path of the refrigerant and the movement path of the sound are different from each other.

However, the conventional compressor forms a structure that separates the main path of the refrigerant and the movement path of the sound in the resonance chamber, so that the path of the refrigerant and the sound is locally separated in the resonance chamber, thereby reducing the noise reduction effect. there was.

The present invention is to solve this problem, an object of the present invention is provided with a passage chamber and a resonance chamber, the refrigerant is guided through the flow path chamber and the refrigerant path is guided through the resonance chamber, the refrigerant and sound It is to provide a compressor that maximizes the separation effect of the movement path.

The compressor according to the present invention for achieving the above object is a hermetic casing is formed in which the inlet port for the fluid is sucked, the flow path chamber is formed so that the sucked fluid flows along a certain flow path, the outlet port for discharging the fluid passing through the flow path chamber is formed. In the compressor having a suction silencer comprising: an inlet is formed on one side of the flow path chamber, the resonance chamber to cancel the flow path noise, characterized in that the guide portion to guide the fluid introduced from the suction port to the discharge port is formed.

The apparatus may further include an extension tube communicating with the discharge port and extending from the inner surface of the hermetic casing to the inside of the flow path chamber so that an end portion thereof is spaced apart from the inlet of the resonance chamber and the suction port by a predetermined distance. To guide to the inlet of the extension pipe.

In addition, the guide portion is characterized in that it comprises a partition wall formed to connect the outer surface of the extension tube and the inner wall of the hermetic casing.

In addition, a suction port through which the fluid is sucked, a flow path chamber in which the sucked fluid flows along a predetermined flow path, a resonance chamber installed at one side of the flow path chamber to cancel the flow path noise, and a fluid passing through the flow path chamber A compressor having an intake silencer including a closed casing in which a discharge port is discharged, the compressor comprising: a first flow passage communicating with the flow path chamber from the intake port to the discharge port in the flow path chamber and a predetermined distance spaced apart from the resonance chamber; A second flow passage communicating from the predetermined point to the discharge port, characterized in that the third flow passage communicating from the predetermined point to the inlet of the resonance chamber is formed.

In addition, the flow path chamber extends from the inner surface of the hermetic casing to the inside of the flow path chamber so that the second flow path is formed therein, and an inlet is formed at the predetermined point. Characterized in that it comprises a partition formed to divide into three euros.

In addition, the partition wall is characterized in that it is formed to connect the outer surface of the extension pipe and the inner wall of the hermetic casing.

In addition, the partition wall is characterized in that each formed on one side and the opposite side of the outside of the extension pipe.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. 1 is a cross-sectional view showing the overall structure of a compressor according to the present invention.

Referring to Figure 1, the compressor according to an embodiment of the present invention is provided with a drive unit 20 in the inner lower side of the casing 50 to seal the compressor to the outside. The compression unit 30 is installed above the driving unit 20 to drive the compression unit 30 by the driving unit 20. In addition, the refrigerant sucked through the suction tube 60 includes a suction tube 60 for guiding external refrigerant and a discharge tube (not shown) through which the refrigerant compressed by the compression unit 30 is discharged. After compressed in the discharge pipe (not shown) is discharged.

In addition, the compression unit 30 seals the cylinder block 31 having the compression chamber 31a and the compression chamber 31a in which the refrigerant is compressed, and the refrigerant discharge chamber 32a and the refrigerant suction chamber 32b. A valve device having a suction valve plate and a discharge valve plate to control the suction and discharge of the refrigerant passing through the compression chamber 31a between the cylinder head 32 and the cylinder block 31 and the cylinder head 32. And a piston assembly for compressing the refrigerant while reciprocating in the compression chamber 31a according to the driving of the drive unit 20. On the other hand, the suction silencer 40 to prevent the noise generated in the compression process of the refrigerant is transmitted to the outside is coupled to the refrigerant suction chamber (32b).

Referring to Figure 2 and 3 will be described in more detail with respect to the suction silencer 40 according to the present invention.

The suction silencer 40 according to the present invention has a closed casing structure made of a synthetic resin material having a suction port 41 through which a refrigerant is sucked in and a discharge port 49 through which the refrigerant is discharged. The suction port 41 of the suction silencer 40 is formed as a downward passage (41a) and the upper portion of the pipeline 41a is formed to be horizontally bent. In addition, the refrigerant discharged from the suction silencer 40 through the discharge port 49 is supplied into the compression chamber 31a through the cylinder head 32 (FIG. 1).

In addition, a flow path chamber 43 and a resonance chamber 47 are formed inside the suction silencer 40.

The flow path chamber 43 is formed with a flow path such that the refrigerant sucked into the suction silencer 40 through the suction port 41 moves along a predetermined path. This flow path is formed by the extension pipe 45 and the partition wall 45a formed in the flow path chamber 40. The extension pipe 45 is formed in a tubular shape extending downward from the sealed casing wall of the upper surface of the flow path chamber 43 and the upper end thereof is formed to communicate with the discharge port 49. In addition, the partition wall 45a extends to the side of the extension pipe 45 and the side wall of the flow path chamber 43 and is integrally formed with the extension pipe 45, which is formed on both sides of the extension pipe 45.

Therefore, the flow path chamber 43 has a first flow path 43a partitioned by the side wall of the suction port 41 side and the partition wall 45a of the extension pipe 45 and a second inside the extension pipe 45 as shown in FIG. 3. It is divided into a third passage 43c which is partitioned by the side wall of the resonance chamber 47 side of the flow passage 43b and the extension pipe 45 and the partition wall 45a and communicates with the resonance chamber inlet 47a. This complicated configuration inside the passage chamber 43 is to maximize the noise reduction effect by extending the radiation path of the noise as much as possible.

In addition, the resonance chamber 47 is formed on the opposite side of the suction port 41 on the basis of the flow path chamber 43, and the flow path chamber 43 and the resonance chamber 47 are formed through the flow path chamber inlet 47a formed on both sides thereof. Communicating. The resonance chamber 47 is formed as an empty space inside the noise chamber 47 so that the noise is canceled with each other to reduce the noise.

The path through which the refrigerant flows and the path through which the noise is transmitted in the suction silencer 40 of the compressor according to the present invention having such a configuration will be described below.

First, when the refrigerant is sucked into the suction silencer 40 through the suction port 41, the refrigerant flows horizontally while passing through the conduit 41a of the suction port 41 which is bent at a right angle as indicated by a solid line in FIG. 2. The refrigerant flowing horizontally for a predetermined period is guided downward through the first channel 43a partitioned by the side wall of the inlet port 41 and the partition wall 45a of the extension pipe 45 again by hitting the extension pipe 45 and the partition wall 45a. Will flow. Some of the refrigerant reaching the lower side of the passage chamber 43 is divided by the second passage 43b inside the extension pipe 45 and the side wall of the resonance chamber 47 side of the extension pipe 45 and the partition wall 45a. Branched to the third flow path (43c) in communication with the seal inlet (47a) is to flow. However, since the second passage 43b is in direct communication with the outlet 49 and the outlet 49 is in communication with the compression chamber 31a, the inside of the extension pipe 45 is lower than the resonance chamber 47 by the movement of the piston 34. Is maintained. Therefore, most of the refrigerant is guided and supplied to the compression chamber 31a through the second passage 43b in the extension pipe 45, and only a part of the refrigerant is supplied to the resonance chamber 47.

On the other hand, the noise generated in the compression unit 30 enters the suction silencer 40 through the discharge port 49 and exits to the suction port 41. The path of transmitting the noise is shown by a dotted line in FIG. First, the noise entered into the suction silencer 40 through the discharge port 49 is moved downward from the upper portion of the flow path chamber 43 through the second flow passage 43b inside the extension pipe 45. The noise transmitted to the lower portion of the flow path chamber 43 through the extension pipe 45 is separated along the first flow path 43a on the suction port 41 side and the third flow path 43c on the resonance chamber 47 side. At this time, the noise is different from the refrigerant, the transfer path is dependent on the internal shape of the suction silencer 40, not the difference in pressure, so that most of the refrigerant is supplied to the compression chamber 31a along the second passage 43b. It is transmitted to the resonance chamber 47 outside the suction silencer 40 and the third passage 43c through the first passage 43a without being biased to either side.

Therefore, the movement paths of the refrigerant and the noise are different, and the difference in the paths is not made in one chamber, but is made in a separate chamber through the passage chamber 43 and the resonance chamber 47 formed separately. It can be maximized.

 As described above in detail, in the compressor according to the present invention, only a part of the refrigerant enters the resonance chamber, while the noise is attenuated by entering the resonance chamber in a relatively large amount. Is improved. In particular, since the refrigerant is prevented from directly entering into the resonance chamber by the partition wall and is led to the end of the extension pipe, the path of noise is complicated, and the noise is effectively separated from the path of refrigerant, thereby maximizing the noise prevention effect.

1 is a cross-sectional view showing the overall structure of a compressor according to the present invention.

2 is a sectional perspective view showing a suction silencer of the compressor according to the present invention.

3 is a cross-sectional view showing a suction silencer of the compressor according to the present invention along the line A-A of FIG.

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

40: suction silencer, 41: suction port,

43: Eurosil, 45: Extension tube,

45a: bulkhead, 47: resonance chamber,

49: outlet.

Claims (7)

A compressor having a suction silencer including an inlet port through which a fluid is sucked, a flow path chamber in which a sucked fluid flows along a predetermined flow path, and a closed casing in which a discharge port through which the fluid passing through the flow path is discharged is formed. A resonance chamber installed at one side of the passage chamber to offset passage noise; Compressor having a suction silencer, characterized in that the guide portion for inducing the fluid introduced from the suction port to the discharge port is formed. The method of claim 1, And an extension tube communicating with the discharge port and extending from the inner surface of the hermetic casing into the flow path chamber so that an end portion thereof is spaced apart from the inlet of the resonance chamber and the suction port by a predetermined distance. The guide unit has a suction silencer, characterized in that for guiding the fluid introduced from the suction port to the inlet of the extension pipe. The method of claim 2, The guide unit has a suction silencer, characterized in that it comprises a partition wall formed to connect the outer surface of the extension tube and the inner wall of the hermetic casing. A suction port through which the fluid is sucked, a flow path chamber in which the sucked fluid flows along a certain flow path, a resonance chamber installed at one side of the flow path chamber to cancel the flow path noise, and the fluid passing through the flow path chamber is discharged In the compressor having a suction silencer comprising a closed casing, the outlet is formed, A first flow passage communicating with the flow passage chamber from the suction port to a predetermined point spaced apart from the discharge port and the resonance chamber in the flow passage chamber by a predetermined distance; A second passage communicating from the predetermined point to the outlet; And a third flow passage communicating from the predetermined point to the inlet of the resonance chamber. The method of claim 4, wherein The flow passage chamber includes an extension pipe extending from the inner surface of the hermetic casing to the inside of the flow passage chamber to form the second flow passage therein and having an inlet formed at the predetermined point; And a partition wall formed to divide the outside of the extension pipe into the first flow path and the third flow path. The method of claim 5, The partition wall is a compressor having a suction silencer, characterized in that it is formed so as to connect the outer surface of the extension pipe and the inner wall of the hermetic casing. The method of claim 6, The partition wall is a compressor having a suction silencer, characterized in that formed on one side and the other side of the outside of the extension pipe.