KR100593389B1 - Head Cover Assembly of Hermetic Compressor - Google Patents

Abstract

The present invention relates to a head cover assembly of a hermetic compressor. The present invention includes a discharge communication portion 33 communicating with the discharge side of the compression chamber, and communication holes 34, 35, and 36 communicating with the first and second discharge silencers 50, 50 'are respectively drilled at both ends thereof. Uneven channel for formation of a head plate 31 and a discharge flow path coupled to the head plate 31 to allow a working fluid to flow through the discharge silencers 50 and 50 'in order from the discharge communication part 33 ( 43 and 45 are provided, including the head cover plate 40. The head plate 31 and the head cover plate 40 are manufactured by sheet metal processing, and are then brazed and fastened. The uneven channels 43 and 45 are formed so that the surface facing the head plate 31 is recessed to form a discharge flow path in cooperation with the head plate 31. The discharge communication part 33 and the first discharge are formed. It comprises a first uneven channel 43 for connecting between the silencer 50 and a second uneven channel 45 for connecting between the first discharge silencer 50 and the second discharge silencer (50). According to the present invention having such a configuration, there is an advantage that the pulsation and noise are more reliably removed while the working fluid compressed and discharged in the compression chamber passes through the interior of the head cover assembly and two discharge silencers.

Hermetic compressor, head cover plate, head plate, pulsation

Description

A head-cover assembly for hermetic compressor

1 is an exploded perspective view showing the main configuration of the hermetic compressor according to the prior art.

Figure 2 is a block diagram showing the configuration of a head cover assembly with a pulsating pipe of a hermetic compressor according to the prior art.

Figure 3 is a perspective view showing the main configuration of the hermetic compressor provided with a head cover assembly according to the present invention.

Figure 4 is an exploded perspective view showing the configuration of the head cover assembly of the embodiment of the present invention.

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

Explanation of symbols on the main parts of the drawings

20: frame 22: motor portion

24: crankshaft 25: eccentric pin

26: connecting rod 28: cylinder

29: valve assembly 30: head cover assembly

31: Head plate 32: Fastener

33: discharge communication portion 34: first communication hole

35: second communication hole 36: third communication hole

38: Silencer Connection 40: Head Cover Plate

42: fastener 43: first uneven channel

45: second uneven channel 50,50 ': discharge silencer

55: suction silencer

The present invention relates to a hermetic compressor, and more particularly to a head cover assembly for forming a flow path through which the working fluid flowing into and out of the compression chamber passes.

The compressor serves to compress the working fluid used in the heat exchange cycle, and FIG. 1 shows a configuration for transferring the working fluid from the general compressor to the compression chamber and discharging the compressed working fluid.

As shown therein, a compression chamber 2 is formed in the cylinder block 1 in which the working fluid is compressed. The cylinder block 1 is provided with a valve assembly for suctioning the working fluid into the compression chamber 2 or discharging the compressed working fluid to the outside of the compression chamber 2.

The valve assembly comprises a suction valve 3, a valve plate 5, a discharge valve 6 and a gasket 7. The valve plate 5 is provided with a suction hole 5i for sucking the working fluid into the compression chamber 2 and a discharge hole 5e for discharging outside the compression chamber 2. A suction valve 3 for opening and closing the suction hole 5i is installed between the valve plate 5 and the cylinder block 1.

On the opposite side to which the suction valve 3 is installed, a discharge valve 6 is installed to be in close contact with the valve plate 5. The head plate 8p is provided in close contact with the discharge valve 6 on the opposite side in contact with the valve plate 5. A gasket 7 for preventing leakage is installed between the discharge valve 6 and the head plate 8p. Such components are assembled by bolts B passing through the bolt holes BH which are drilled at corresponding positions, respectively, and being fastened to the cylinder block 1.

On the other hand, the head plate (8p) is provided with a suction silencer (9) for reducing the noise when delivering the working fluid sucked from the outside through the suction hole (5i) to the compression chamber (2). Reference numeral 9 'is a suction pipe.

As shown in FIG. 2, the head cover plate 8 is blazed on the head plate 8p to form a discharge chamber 8 'therebetween. The discharge chamber 8 'is compressed in the compression chamber 2 and the working fluid discharged through the discharge hole 5e is located. A suction guide 8g is installed inside the discharge chamber 8 'to guide the working fluid from the suction silencer 9 to the compression chamber 2. The suction guide 8g is mounted to the head plate 8p to communicate the suction silencer 9 and the compression chamber 2 through the suction hole 5i.

 A discharge silencer 10 is provided in communication with the discharge chamber 8 ', and the discharge silencer 10 is in communication with the discharge chamber 8' by the pulsation pipe 11. The pulsating pipe 11 is wound many times in a coil shape. On the other hand, the discharge pipe 12 for delivering the working fluid delivered to the discharge silencer 10 to the outside is provided.

On the other hand, the configuration shown in FIG. 2 including the head plate 8p and the head cover plate 8 forms an assembly. This will be referred to as a head cover assembly. In the head cover assembly, the head plate 8p and the head cover plate 8 are attached by welding to form a discharge chamber 8 'therein, and a suction guide 8g for delivering a working fluid to the compression chamber 2. It is provided. In addition, a suction silencer 9 and a discharge silencer 10 are separately manufactured and attached to the head cover assembly by welding.

However, the conventional head cover assembly as described above has the following problems.

The working fluid compressed in the compression chamber 2 is discharged to the discharge chamber 8 'under the control of the discharge valve 6 of the valve assembly, and discharged through the pulsation pipe 11 from the discharge chamber 8'. The silencer 10 is delivered to the inside. At this time, since the working fluid is discharged by a predetermined amount at the end of one cycle in the compression chamber 2, pulsation occurs in the working fluid flowing from the discharge chamber 8 'to the discharge silencer 10.

However, in the conventional configuration, the length of the flow path from the compression chamber 2 to the discharge pipe 12 is relatively short, so that the working fluid flows in a state in which the pulsation is not removed, so that the pressure pulsation increases, and the discharge pipe 12 There is a problem that a lot of vibration and noise occurs while the shaking phenomenon occurs.

 Accordingly, an object of the present invention is to solve the conventional problems as described above, and to maximize the flow path of the working fluid compressed in the compression chamber out of the compressor.

According to a feature of the present invention for achieving the above object, the present invention is provided with a discharge communication portion communicating with the discharge side of the compression chamber formed in the cylinder of the frame and communicated with the first and second discharge silencers at both ends, respectively. A head cover plate having a concave-convex channel for forming a discharge passage through which a communication hole is drilled and mounted to a cylinder and coupled to the head plate so that a working fluid flows through the discharge silencer in order from the discharge communication portion. The head plate and the head cover plate are formed of sheet metal, and the uneven channel is formed to be recessed on one surface of the head cover plate facing the head plate by sheet metal processing to form a discharge flow path in cooperation with the head plate. do.

The head plate and the head cover plate are joined by blazing welding.

And a first uneven channel connecting the discharge communication unit and the first discharge silencer and a second uneven channel connecting the first discharge silencer and the second discharge silencer.

The discharge flow path formed by the second uneven channel and the head plate should have a length of at least 40 mm or more and a diameter of 5 mm or less.

The discharge communication portion is formed through the head plate, and the shape of one end of the first uneven channel is formed to correspond to the shape of the discharge communication portion.

According to the present invention having such a configuration, there is an advantage that the pulsation and noise are more reliably removed while the working fluid compressed and discharged in the compression chamber passes through the interior of the head cover assembly and two discharge silencers.

Hereinafter, a preferred embodiment of a head cover assembly of a hermetic compressor according to the present invention will be described in detail with reference to the accompanying drawings.

FIG. 3 is a perspective view of a main structure of a hermetic compressor equipped with a head cover assembly according to the present invention, and FIG. 4 is an exploded perspective view of the head cover assembly according to the embodiment of the present invention.

As shown in these drawings, the motor unit 22 is provided at the lower portion of the frame 20 provided in the sealed container. The motor unit 22 provides a rotational force to drive the compressor. The crankshaft 24 is provided to penetrate the center of the frame 20 up and down. The crankshaft 24 rotates integrally with the rotor of the motor unit 22.

An eccentric pin 25 is provided at an upper end of the crankshaft 24. The eccentric pin 25 is in an eccentric position at the center of rotation of the crankshaft 24. The connecting rod 26 is connected to the eccentric pin 25. The connecting rod 26 serves to convert the rotational movement of the crankshaft 24 into a linear reciprocating motion of the piston.

The cylinder 28 is provided on one side of the upper surface of the frame 20. Inside the cylinder 28 is provided a compression chamber (not shown) in which the piston is seated. In the compression chamber, the working fluid is compressed by the linear reciprocating motion of the piston.

The valve assembly 29 is provided on the front surface of the cylinder 28 to shield one side of the compression chamber. The valve assembly 29 controls the entry and exit of the working fluid in the compression chamber.

The head cover assembly 30 is provided to be coupled to the cylinder 28 together with the valve assembly 29. The head cover assembly 30 mainly serves to form a flow path through which the working fluid compressed in the compression chamber is discharged.

The head cover assembly 30 has a head plate 31. The head plate 31 is a metal plate having a predetermined thickness, and both ends thereof are formed to extend further than both ends of the valve assembly 29, and the discharge silencers 50 and 50 ', which will be described below, on the extended ends. Are respectively connected.

Fastening holes 32 are drilled in the head plate 31 at positions corresponding to four corners of the valve assembly 29. The fastening hole 32 is a portion through which a bolt for fastening the head cover assembly 30 and the valve assembly 29 to the cylinder 38 passes.

The head plate 31 is provided with a discharge communication portion 33 in a portion corresponding to the discharge portion of the valve assembly 29. The discharge communicating portion 33 formed in the head plate 31 forms a discharge chamber in which the working fluid compressed and discharged in the compression chamber temporarily stays. The discharge communicating portion 33 is in a region formed by a line connecting the fastening hole 32.

The head plate 31 has a plurality of communication holes 34, 35, 36. The communication holes 34, 35, 36 are outside the region formed by the lines connecting the fastening holes 32. First, the first communication hole 34 serves to communicate the first discharge silencer 50 and the discharge communication unit 33 to be described below.

A second communication hole 35 is formed through the head plate 31 adjacent to the first communication hole 34. The second communication hole 35 is a portion in which the working fluid exits the first discharge silencer 50. A third communication hole 36 is drilled at the other end of the head plate 31 on the opposite side where the first communication hole 34 and the second communication hole 35 are formed. The third communication hole 36 serves to deliver the working fluid exiting the second communication hole 35 to the second discharge silencer 50 '.

On the other hand, the head plate 31 is provided with a silencer connecting portion 38. The silencer connection portion 38 is a portion on which one side of the suction silencer 55 to be described below is seated. The silencer connecting portion 38 allows the suction silencer 55 to be coupled together when the head cover assembly 30 is fastened to the cylinder 28.

The head cover plate 40 is coupled to the head plate 31. The head cover plate 40 is preferably coupled to the head plate 31 by blazing welding. However, this is not necessarily the case, and the head cover assembly 30 may be fastened using a bolt that couples to the cylinder 28. In the head cover plate 40, a fastening hole 42 is drilled at the same position as that of the fastening hole 32 of the head plate 31.

The head cover plate 40 is formed with a first uneven channel 43 for communicating the discharge communication part 33 and the first communication hole 34. The first concave-convex channel 43 is formed to protrude from the opposite surface of the head cover plate 40 facing the head plate 31. The first uneven channel 43 is configured such that one end thereof has a shape and an area corresponding to the discharge communication portion 33, and the other end thereof communicates with the first communication hole 34.

The head cover plate 40 is also provided with a second uneven channel 45. The second concave-convex channel 45 is also formed to protrude in a concave and opposite surface in the surface facing the head plate 31. The second uneven channel 45 communicates between the second communication hole 35 and the third communication hole 36.

The length of the second uneven channel 45 is preferably at least 40mm. This is to set the flow path length through which the compressed and discharged working fluid flows. If the distance between the second communication hole 35 and the third communication hole 36 is not 40mm, the second uneven channel 45 may be formed to have a predetermined curvature rather than a straight line. For reference, the diameter of the flow path formed by the second uneven channel 45 and the head plate 31 is preferably 5 mm or less.

On the other hand, a silencer connecting portion 48 is formed at a position corresponding to the silencer connecting portion 38 of the head plate 31. The silencer connecting portions 38 and 39 have a structure in which one side of the suction silencer 55 is seated and fixed. Since this is not the gist of the present invention, the description is omitted.

In addition, the head plate 31 and the head cover plate 40 can be produced by sheet metal work. In particular, the uneven channels 43 and 45 of the head cover plate 40 can be easily and accurately formed by sheet metal work.

Both ends of the head plate 31 are provided with first and second discharge silencers 50 and 50 ', respectively, to which the cylinder 28 is provided. The first discharge silencer 50 is provided at a position that can be simultaneously communicated with the first communication hole 34 and the second communication hole 35. In addition, the second discharge silencer 50 ′ is provided at a position in communication with the third communication hole 36. In general, the discharge silencers 50 and 50 'are fastened to the head plate 31 by blazing welding.

For reference, the discharge silencers 50 and 50 'may have a pulsating pipe as described in the prior art. For example, a pulsation pipe may be placed inside the first discharge silencer 50 to be connected to an outlet of the first communication hole 34, and the third communication hole may be inside the second discharge silencer 50 ′. A pulsating pipe can be placed to be connected to the outlet of (36).

On the other hand, the suction silencer 55 serves to remove the noise of the working fluid delivered to the compression chamber, the head cover assembly 30 is mounted to the cylinder 28 together with the valve assembly 29, the silencer connecting portion ( 38, 48) to be fixed.

Hereinafter, the operation of the head cover assembly of the hermetic compressor according to the present invention having the configuration as described above will be described.

It will be described that the working fluid is compressed in the compressor of the present invention. When the motor unit 22 is driven, the crankshaft 24 rotates. The rotation of the crankshaft 24 causes the eccentric pin 25 to move in a circular motion, and one end of the connecting rod 26 connected thereto rotates together with the eccentric pin 25. A piston connected to the opposite side of the connecting rod 26 compresses the working fluid while linearly reciprocating in the compression chamber of the cylinder 28.

The working fluid is delivered to the compression chamber via the suction silencer 55. That is, the working fluid from which the noise is removed in the suction silencer 55 is sucked into the compression chamber under the control of the valve assembly 29.

The working fluid sucked into the compression chamber is compressed by moving the piston to the top dead center, and is discharged from the compression chamber under the control of the valve assembly 29 when the compression is completed. The working fluid discharged from the compression chamber flows through the discharge communicating portion 33 to the discharge flow path formed by the first uneven channel 43 and the head plate 31. The working fluid delivered to the first uneven channel 43 is delivered to the first discharge silencer 50 via the first communication hole 34.

The working fluid in which the pulsation and noise are removed to some extent from the first discharge silencer 50 is a discharge passage formed by the second uneven channel 45 and the head plate 31 through the second communication hole 35. Flows. The working fluid is delivered into the second discharge silencer 50 ′ through the third communication hole 36.

The working fluid in which the pulsation and noise are removed from the second discharge silencer 50 'is also transferred to the outside of the compressor through a discharge pipe and then to other elements constituting the heat exchange cycle. For reference, in FIG. 5, a path through which the working fluid discharged and compressed in the present invention flows is indicated by an arrow.

On the other hand, in the case where separate pulsation pipes are installed inside the first and second silencers 50 and 50 ', the length of the discharge passage is further increased by the pulsation pipe so that the pulsation and noise of the working fluid can be removed. do.

The rights of the present invention are not limited to the embodiments described above, but are 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.

The head cover assembly of the hermetic compressor according to the present invention as described in detail above has first and second discharge silencers at both ends thereof, and is formed by the uneven channel and the head plate of the head cover plate formed by plate processing therebetween. The working fluid was allowed to flow through the flow path. Therefore, the flow path until the working fluid compressed in the compression chamber is finally delivered to the discharge pipe becomes long, thereby minimizing noise and pulsation generated during the discharge of the working fluid.

Claims (5)

A head plate having a discharge communicating portion communicating with the discharge side of the compression chamber formed in the cylinder of the frame, and having a communication hole communicating with the first and second discharge silencers respectively at both ends thereof, and mounted to the cylinder; And a head cover plate coupled to the head plate, the head cover plate having a concave-convex channel for forming a discharge flow path for allowing a working fluid to flow through the discharge silencer in order from the discharge communication part. The head plate and the head cover plate is a sheet metal processing, the uneven channel is formed to be recessed on one surface of the head cover plate facing the head plate by the sheet metal processing to form a discharge flow path in cooperation with the head plate Head cover assembly of a hermetic compressor. The head cover assembly of claim 1, wherein the head plate and the head cover plate are joined by blazing welding. The method of claim 1 or 2, further comprising a first uneven channel for connecting between the discharge communicating portion and the first discharge silencer and a second uneven channel for connecting between the first discharge silencer and the second discharge silencer. Head cover assembly of a hermetic compressor characterized in that the configuration. The head cover assembly of claim 3, wherein the discharge flow path formed by the second uneven channel and the head plate has a length of at least 40 mm and a diameter of 5 mm or less. The head cover of the hermetic compressor of claim 1, wherein the discharge communication part is formed through the head plate, and one end of the first uneven channel is formed to correspond to the shape of the discharge communication part. Assembly.

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