KR20090011919A - Head cover for a hermetic compressor and working-fluid discharging apparatus using the same - Google Patents

Abstract

A head cover of a hermetic compressor and a working fluid discharge device using the same are provided to minimize vibration generated in a working fluid pipe of a heat exchange cycle. A suction indent part(52) is formed on a surface of a body part(51) to secure a side of a suction muffler. A discharge indent part(54) is formed on the surface of the body part and has first and second outlet chambers(58,64) for compressed and discharged working fluid to temporarily stay, wherein the first and second outlet chambers are connected to each other by a connection path.

Description

Head Cover for A Hermetic Compressor and Working-fluid Discharging Apparatus Using the same}

1 is a cross-sectional view showing the internal configuration of a hermetic compressor according to the prior art.

Figure 2 is a perspective view showing the configuration of the head cover and the valve assembly according to the prior art.

Figure 3 is an exploded perspective view showing a preferred embodiment of the head cover and the working fluid discharge device using the same according to the present invention.

Figure 4 is a perspective view showing the configuration of the head cover constituting the embodiment of the present invention.

Figure 5 is an operating state showing the working fluid flows in the head cover constituting an embodiment of the present invention.

Figure 6a is a graph showing the noise reduction effect of the embodiment of the present invention.

Figure 6b is a graph showing the noise-related content of the prior art.

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

20: cylinder block 22: compression chamber

30: valve assembly 31: valve plate

32: suction hole 33: discharge hole

34: euro ball 36: suction valve plate

38: suction valve 40: flow path

42: discharge valve 44: gasket

45: window 50: head cover

51: body 52: suction groove

54 discharge groove 56 partition wall

58: first discharge 60: communication flow

62: entrance 64: second discharge chamber

The present invention relates to a hermetic compressor, and more particularly, to a head cover having a discharge chamber in which a compressed working fluid is discharged and temporarily stays in a compression chamber, and a working fluid discharge device using the same.

Figure 1 shows the internal configuration of a conventional hermetic compressor according to the prior art. According to this, the sealed container 1 consists of an upper container 1t and a lower container 1b, and a frame 2 is installed inside the sealed container. The frame 2 is supported inside the sealed container 1 by a spring 2S, and the stator 3 is fixed to the lower part of the frame 2. The crankshaft 5 is provided through the center of the frame 2. The crankshaft (5) is integrally provided with a rotor (4) located through the center of the stator (3), the rotor (4) by the electromagnetic interaction with the stator (3) Rotate together with the crankshaft (5).

An eccentric pin 5b is provided at the upper end of the crankshaft 5. The eccentric pin 5b is eccentrically installed at the center of rotation of the crankshaft 5. A counterweight 5c is formed on the opposite side in the longitudinal direction at the point where the eccentric pin 5b is installed. In FIG. 1, a passage formed inside the crankshaft 5 for supplying oil L is indicated by reference numeral 5a, and an oil piece for pumping oil L into the passage 5a is indicated by reference numeral. It is marked 5d.

The frame 2 is provided with a cylinder block 6 having a compression chamber 6 'formed therein. A piston 7 is installed in the compression chamber 6 ', and the piston 7 is connected by an eccentric pin 5b of the crankshaft 5 and a connecting rod 8. At the front end of the cylinder block 6, a valve assembly 9 is installed to control the working fluid flowing into and out of the compression chamber 6 '. In the valve assembly 9, a head cover 10 having a space for compressing a working fluid is located on a surface opposite to a surface on which the front end of the cylinder block 6 is located. In addition, a suction silencer 11 is connected to the head cover 10 to reduce noise generated by the working fluid.

Here, the configuration of the head cover 10 will be described in detail with reference to FIG. 2. The head cover 10 is installed in the cylinder block 6 together with the valve assembly 9 to transfer the working fluid to the valve assembly 9 and to receive the working fluid compressed from the compression chamber 6 '. It serves to deliver the discharge silencer (not shown).

A surface facing the cylinder block 6 of the head cover 10 is recessed in a predetermined shape to form a discharge chamber 10a. The discharge chamber 10a is a space where the compressed working fluid is discharged from the compression chamber 6 'for the first time. The other side of the head cover 10 is formed with a silencer seating portion (10b) recessed to correspond to the shape of one side of the suction silencer (11). A discharge part (not shown) of the suction silencer 11 is seated in the silencer seating part 10b and a working fluid flows into the compression chamber 6 'through the inside of the suction silencer 11.

However, the hermetic compressor according to the related art as described above has the following problems.

The discharge chamber 10a formed in the head cover 10 is a space in which the working fluid compressed in the compression chamber 6 'is discharged and stays for the first time. The working fluid compressed by the control of the valve assembly 9 flows into the discharge chamber 10a, and the working fluid is discharged through a flow path formed through the valve assembly and the cylinder block 6 as a discharge silencer. It is configured to be.

At this time, the valve assembly for transmitting the working fluid from the discharge chamber 10a to the discharge silencer and the flow path formed in the cylinder block 6 communicate with the discharge chamber 10a at one end of the discharge chamber 10a. Since the portion where the discharge silencer side and the discharge chamber 10a communicate with each other is at one end of the discharge chamber 10a, the path through which the working fluid flows in the discharge chamber 10a becomes very short, and the discharge chamber 10a The other end is a space that is rarely used in the flow of the working fluid.

As such, when the flow distance within the head cover 10 becomes relatively short while the working fluid compressed and discharged in the compression chamber 6 'is flowed, the pulsation and noise of the working fluid become relatively large. Is generated.

The present invention is to solve such a conventional problem, the object of the present invention is to maximize the flow distance of the working fluid in the head cover.

According to a feature of the present invention for achieving the above object, the present invention is a body portion; A suction recess groove formed on one surface of the body portion and having one side of the suction silencer seated thereon; It is formed to be indented on one surface of the body portion formed with the suction groove portion, the first discharge chamber and the first discharge chamber in which the compressed and discharged working fluid temporarily stays and the first discharge chamber and the second discharge chamber in which the working fluid temporarily stays and the first And a discharge groove having a communication flow path communicating with the second discharge chamber.

A partition wall is formed in the discharge groove to partition the first discharge chamber, the second discharge chamber, and the communication flow path.

The inlet of the communication flow passage partitioned by the partition wall is formed on the opposite side to which the second discharge chamber is provided.

According to another feature of the invention, the present invention is a valve assembly is provided with a suction valve and a discharge valve on the surface of the valve plate is formed in each of the suction hole and the discharge hole communicating with the compression chamber and the suction hole and the suction hole, A suction cover is formed in which the suction fluid is passed and the discharge groove is compressed in the compression chamber and the fluid flows through the discharge hole. The head cover is fastened to the cylinder block in which the compression chamber is formed together with the valve assembly. And the inside of the discharge groove is partitioned into a first discharge chamber, a communication passage and a second discharge chamber by a partition wall so that the working fluid exiting the compression chamber is the first discharge chamber, the communication passage and the second discharge chamber. Passes through the discharge chamber one after another.

The inlet of the communication flow passage partitioned by the partition wall is formed on the opposite side to which the second discharge chamber is provided.

The first discharge chamber is formed at a position where the discharge hole is selectively communicated with the discharge valve, and the second discharge chamber communicates with a flow path hole formed in the valve plate communicating with a flow path formed through the cylinder block. Formed in position.

According to the present invention having such a configuration, since the working fluid compressed and discharged from the compression chamber has a relatively long flow distance in the discharge chamber inside the head cover, the pulsation and noise of the working fluid are relatively reduced.

Hereinafter, a preferred embodiment of a head cover of a hermetic compressor according to the present invention and a working fluid discharge device using the same will be described in detail with reference to the accompanying drawings.

3 is an exploded perspective view showing a preferred embodiment of the head cover and the working fluid discharge device using the same according to the present invention, Figure 4 is a perspective view of the configuration of the head cover constituting an embodiment of the present invention.

As shown in these figures, the cylinder block 20 is formed with the compression chamber 22 penetrating back and forth. In the compression chamber 22, a piston (not shown) compresses the working fluid while linearly reciprocating. Fastening holes 20 ′ for fastening the valve assembly 30 and the head cover 50 are perforated at four corners of the cylinder block 20 on which the valve assembly 30 to be described below is mounted.

The valve assembly 30 controls the flow of the working fluid into and out of the compression chamber 22. To this end, the valve assembly 30 is provided with a valve plate 31. The valve plate 31 has a rectangular plate shape, and fastening holes 31 'corresponding to the fastening holes 20' are drilled at four corners thereof.

In the valve plate 31, the suction hole 32, the discharge hole 33, and the flow path hole 34 are drilled, respectively. The suction hole 32 is a path through which the working fluid flows into the compression chamber 22. The discharge hole 33 is a path through which the working fluid compressed in the compression chamber 22 is discharged from the compression chamber 22. The flow path hole 34 forms a flow path for communicating the discharge silencer with the discharge groove portion 54 side of the head cover 50 to be described below.

A suction valve plate 36 is provided to be positioned between the valve plate 31 and the cylinder block 20. The suction valve plate 36 is made of spring steel in a rectangular plate shape. An intake valve 38 is formed in the intake valve plate 36, and the intake valve 38 opens and closes the intake hole 32 to control the inflow of the working fluid into the compression chamber 22. In the suction valve plate 36, a discharge hole 39 is formed at a position corresponding to the discharge hole 33, and a passage hole 40 is formed at a position corresponding to the passage hole 34. Reference numeral 36 'is a fastening hole.

Discharge valves 42 are provided on the opposite side of the valve plate 31 in contact with the suction valve plate 36. The discharge valve 42 opens and closes the discharge hole 33. The discharge valve 42 is installed in a groove (not shown) formed in one surface of the valve plate 31, and is fixed by a valve retainer (not shown) together with a valve spring (not shown). Of course, the discharge valve 42 may also be provided on the discharge valve plate having a similar configuration to the suction valve plate 36 to be in close contact with one surface of the valve plate 31.

A gasket 44 is installed in close contact with a surface of the valve plate 31 on which the discharge valve 42 is provided. The gasket 44 serves to prevent the leakage of the working fluid between the head cover 50 and the valve plate 31 to be described below. A window 45 having a predetermined shape penetrates the gasket 44. The window 45 has a shape corresponding to the discharge groove 54 of the head cover 50 to be described below. A suction hole 46 is formed in the gasket 44 to communicate with the suction hole 32 of the valve plate 31. Reference numeral 44 'is a fastening hole.

The head cover 50 is coupled to the cylinder block 20 together with the valve assembly 30 to form a path through which the working fluid flows into and out of the compression chamber 22 under the control of the valve assembly 30. do.

Body portion 51 forms the skeleton of the head cover 50, one side of the body portion 51, as shown in Figure 4, the suction groove 52 and the discharge groove 54 Each is formed to be concave. One side of the suction silencer is seated in the suction recess 52. A working fluid may be delivered to the compression chamber 22 through the suction holes 46 and 32 through one side of the suction silencer seated in the suction recess 52. The suction recess 52 is formed to extend from one of the center of the body portion 51 to one side edge.

The discharge recess 54 formed to be recessed on one side of the body 51 may cooperate with the valve assembly 30, in this embodiment, to form a closed space in cooperation with the valve plate 31.

A partition wall 56 is formed in the discharge recess 54. The partition wall 56 divides the interior of the discharge recess 54 into a first discharge chamber 58, a communication passage 60, and a second discharge chamber 64. The first discharge chamber 58 is formed near the center of the body portion 51 adjacent to the suction recess 52. Here, the partition wall 56 is preferably designed such that the length of the communication passage 60 connecting the first discharge chamber 58 and the second discharge chamber 64 is as long as possible.

To this end, in the present embodiment, the first discharge chamber 58 and the flow path hole 34 (indicated by the dotted line in FIG. 4) communicating with the discharge hole 33 (indicated by the dotted line in FIG. 4) of the valve plate 31. The second discharge chamber 64 in communication with each other) is partitioned from each other by the partition wall 56, and the inlet of the communication flow path 60 formed by the partition wall 56 is formed in the discharge recess 54. The second discharge chamber 64 was formed on the opposite side. That is, when the body portion 51 of the head cover 50 is viewed from the front, the partition wall 56 extends in the direction toward both ends of the discharge groove 54, and the second discharge chamber 64 On the opposite side of), the communication flow path 60 and the first discharge chamber 58 were allowed to communicate with each other.

In the figure, reference numeral 51 'is a fastening hole formed in the body portion 51 of the head cover 50, and a portion through which a bolt for fastening the head cover 50 together with the valve assembly 30 to the cylinder block 20 passes. to be.

Hereinafter will be described in detail the operation of the head cover of the hermetic compressor according to the present invention having the configuration as described above and the working fluid discharge device using the same.

In the present invention, the head cover 50 is fastened by bolts to the cylinder block 20 together with the valve assembly 30. At this time, one side of the suction silencer is seated in the suction recess 52 of the head cover 50. Thus, the outlet of the suction silencer and the suction holes 46 and 32 communicate with each other. The first discharge chamber 58 of the head cover 50 may be in communication with the discharge hole 33 when the discharge valve 42 is opened through the window 45.

When the compressor is driven and the piston is linearly reciprocated in the compression chamber 22, suction and compression of the working fluid proceed. That is, when the piston retreats backward from the inside of the compression chamber 22, the inside of the compression chamber 22 becomes low pressure, and the suction valve 38 elastically deforms, thereby opening the suction hole 32. Thus, a working fluid is sucked into the compression chamber 22 through the suction silencers and through the suction holes 46 and 32.

When the piston moves forward while the working fluid is sucked into the compression chamber 22, compression occurs in the compression chamber 22. By this operation, the suction valve 38 blocks the suction hole 32. . When the piston continues to move forward in the compression chamber 22, compression of the working fluid proceeds, and when a predetermined or more compression is performed, the discharge valve 42 is operated by the internal pressure of the compression chamber 22. The discharge hole 33 is opened.

When the discharge hole 33 is opened, the working fluid compressed in the compression chamber 22 is discharged to the first discharge chamber 58 through the discharge hole 33. The working fluid discharged to the first discharge chamber 58 moves toward the inlet 62 of the communication passage 60 as indicated by the arrow in FIG. 5. The working fluid is transferred to the communication passage 60 through the inlet 62, and the working fluid flowing along the communication passage 60 flows to the second discharge chamber 64.

The working fluid flowing into the second discharge chamber 64 passes through the flow path holes 34 and 40 to the flow path (not shown) formed through the cylinder block 20. The flow passage is in communication with the discharge silencer. Therefore, the working fluid delivered to the flow path is delivered to the discharge silencer and discharged to the outside of the compressor.

6A and 6B are graphs showing the degree of noise improvement in a compressor employing an embodiment of the present invention and a conventional compressor, where N is a reference value for relatively indicating the level of noise.

Looking at the graph above each figure, it can be seen that when the operating frequency is about 3kHz, the noise level is 2.9N dB in the present invention, 3.6N dB in the prior art. That is, it can be seen that the noise level is relatively low in the present invention. This reduction in noise level can also be seen in the graph below each figure.

The scope of the present invention is not limited to the embodiments described above, but is defined by the claims, and various changes and modifications can be made by those skilled in the art within the scope of the claims. It is self evident.

For example, the inlet 62 of the communication flow path 60 formed by the partition wall 56 is formed opposite the second discharge chamber 64 in the illustrated embodiment. However, this is a case where the flow distance of the working fluid in the discharge groove 54 is the longest. Thus, the inlet 62 may be formed about the middle of the partition wall 56. Of course, in this case, the noise and pulsation removal effect will be relatively low.

In addition, in the illustrated embodiment, the first discharge chamber 58, the communication passage 60, and the second discharge chamber 64 extend from one end of the discharge groove 54 to the other end of the inner wall of the discharge groove 54. It is partitioned into one partition wall 56 formed in parallel with, but is not necessarily so. The partition wall 56 may be bent and configured to have a plurality of lengths of the communication passage 60.

According to the head cover of the hermetic compressor according to the present invention as described above and the working fluid discharge device using the same, the following effects are expected.

First, in the present invention, the discharge recess groove formed to be recessed in the body portion of the head cover is partitioned into a communication passage connecting the first discharge chamber and the second discharge chamber and these discharge chambers through partition walls. Therefore, since the working fluid passes through the first discharge chamber, the communication passage, and the second discharge chamber, the pulsation and the noise are reduced while the flow distance is increased.

In particular, since the inlet of the communication passage connecting the discharge chambers is opposite to the second discharge chamber, the distance from which the working fluid moves from the first discharge chamber to the second discharge chamber becomes relatively far.

By minimizing the pulsation and noise before the working fluid exits the compression chamber and goes to the discharge silencer, the vibration generated in the working fluid pipe of the heat exchange cycle using the compressor employing the present invention can be minimized. In this state, noise can be minimized at low and high frequencies, respectively.

Claims (6)

A body part; A suction recess groove formed on one surface of the body portion and having one side of the suction silencer seated thereon; It is formed to be indented on one surface of the body portion formed with the suction groove portion, the first discharge chamber and the first discharge chamber in which the compressed and discharged working fluid temporarily stays and the first discharge chamber and the second discharge chamber in which the working fluid temporarily stays and the first And a discharge recess groove having a communication flow passage communicating with the second discharge chamber. The head cover of the hermetic compressor according to claim 1, wherein the discharge groove has a partition wall formed to partition the first discharge chamber, the second discharge chamber, and the communication passage. 3. The head cover of the hermetic compressor according to claim 2, wherein the inlet of the communication flow passage partitioned by the partition wall is formed on the opposite side of the second discharge chamber. A valve assembly for opening and closing the suction hole and the discharge hole by installing a suction valve and a discharge valve on a surface of the valve plate having suction and discharge holes communicating with the compression chamber, respectively; A suction groove portion through which the working fluid delivered to the suction hole passes and a discharge groove portion through which the working fluid from the discharge hole passes through the discharge hole is formed and is fastened to the cylinder block in which the compression chamber is formed together with the valve assembly. It is configured to include a head cover, The interior of the discharge groove is partitioned into a first discharge chamber, a communication passage and a second discharge chamber by partition walls so that the working fluid exiting the compression chamber passes through the first discharge chamber, the communication passage and the second discharge chamber in this order. Operating fluid discharge device of the hermetic compressor characterized in that the. 5. The working fluid discharge device of claim 4, wherein the inlet of the communication flow path partitioned by the partition wall is formed on the opposite side to the second discharge chamber. 6. The valve of claim 5, wherein the first discharge chamber is formed at a position in which the discharge chamber is selectively communicated with the discharge valve, and the second discharge chamber communicates with a flow path formed through the cylinder block. A working fluid discharge device of a hermetic compressor, characterized in that formed in a position in communication with the flow path formed in the plate.

Images