KR101176453B1 - A Hermetic Compressor - Google Patents

Abstract

The present invention relates to a hermetic compressor, and in particular, to increase the flow rate of the refrigerant by increasing the flow rate of the refrigerant in the suction muffler by changing the flow path of the refrigerant and opening and closing of the suction valve to increase the compression efficiency of the compressor. A hermetic compressor.

The present invention for achieving the above object, the hermetic compressor including a compression chamber, a suction valve for intermitting the flow of the refrigerant sucked into the compression chamber, a suction chamber in which the suction valve is installed, and a suction muffler connected to the suction chamber. To

The suction muffler may be in communication with a casing forming the exterior, a first resonance chamber formed inside the casing, into which a refrigerant flows, a discharge tube provided in the casing, and guiding the refrigerant into the suction chamber, and in contact with the first resonance chamber. A hermetic compressor comprising a guide tube for transferring refrigerant to a discharge tube, and a second resonance chamber which is partitioned from the first resonance chamber and in communication with the guide tube to absorb pulsations generated by opening and closing of the suction valve. Providing.

Description

Hermetic Compressor

1 is a side view of a hermetic compressor according to the present invention.

2 is an exploded perspective view of a suction muffler installed in the hermetic compressor according to the present invention.

3 is a perspective view showing a first embodiment of a suction muffler installed in the hermetic compressor according to the present invention.

Figure 4 is a perspective view showing a second embodiment of the suction muffler installed in the hermetic compressor according to the present invention.

Description of the Related Art [0002]

25a: suction valve 50: suction muffler

55: casing 60: cover

66: guide 68: partition plate

69: first resonance room 70: second resonance room

The present invention relates to a hermetic compressor, and more particularly, to smooth the suction of the refrigerant by differentiating the refrigerant flow path of the suction muffler that reduces noise and the transmission path of the pulsation generated by opening and closing the suction valve. In order to reduce noise and improve the compression efficiency, a closed compressor is provided.

In general, a hermetic compressor is a device for compressing a refrigerant in an enclosed space and discharging it to the outside, and includes a compression unit for compressing the refrigerant and a driving unit for driving the refrigerant.

The compression unit includes a cylinder block having a compression chamber configured to compress the refrigerant, a cylinder head coupled to one side of the cylinder block and having a suction chamber and a discharge chamber configured to guide the suction and discharge of the refrigerant into the compression chamber, and a piston for linear reciprocating movement inside the compression chamber. It consists of.

The driving unit includes a stator configured to receive magnetic power to form a magnetic field, a rotor rotating in interaction with the stator, and a rotation shaft that is axially pressed into the center of the rotor and integrally rotates.

In addition, an eccentric part for eccentric rotation is provided on the rotating shaft, and a connecting rod for connecting them is provided between the eccentric part and the piston.

In addition, a suction muffler is installed in the suction chamber side of the cylinder head to reduce the compression noise generated in the compression chamber, such a suction muffler is provided with a resonance chamber therein to resonate the problem frequency of the noise to reduce the noise.

In the structure of the suction muffler, a casing forming the exterior of the suction muffler, a suction part formed on one side of the casing to suck the refrigerant, a guide to guide the refrigerant into the compression chamber, and a discharge part connected to the suction valve, and a connection between the suction part and the discharge part It is composed of a resonance chamber formed inside the tube and the casing to reduce noise.

However, when the suction valve is opened, the refrigerant passes through the suction valve through the suction part, the guide tube, and the discharge part in order to flow into the compression chamber. The pulsation is generated by the opening and closing action of the pulsation, and the pulsation is transmitted through a path opposite to the inflow path of the refrigerant.

Therefore, when the delivery direction of the pulsation due to the opening and closing of the intake valve and the inflow direction of the refrigerant collide with each other, the inflow of the refrigerant may be restricted by the pulsation, thereby reducing the inflow of the refrigerant and reducing the efficiency of the compressor.

The present invention is to solve such a problem, by preventing the refrigerant flow is not disturbed by the pulsation by the flow path of the pulsation and the delivery path of the pulsation caused by the opening and closing of the intake valve does not match the flow rate of the refrigerant. The purpose is to increase the compression efficiency of the compressor by increasing.

The present invention for achieving the above object, the hermetic type including a compression chamber, a suction valve for regulating the flow of the refrigerant sucked into the compression chamber, a suction chamber in which the suction valve is installed, and a suction muffler connected to the suction chamber. In the compressor,

The suction muffler may be in communication with a casing forming the exterior, a first resonance chamber formed inside the casing, into which a refrigerant flows, a discharge tube provided in the casing, and guiding the refrigerant into the suction chamber, and in contact with the first resonance chamber. And a second resonance chamber which is partitioned from the first resonance chamber and communicates with the guide tube to absorb pulsation generated by the opening and closing of the suction valve.

The guide tube is provided with a first opening portion communicating with the first resonance chamber and a second opening portion communicating with the second resonance chamber, and the first resonance chamber and the second resonance chamber are separated on the outer circumferential surface of the guide tube. A partition plate for partitioning is provided.

In addition, one surface of the casing is opened, the open portion is sealed by a cover connected to the outer circumferential surface of the discharge pipe, the one surface of the cover a plurality of protruding toward the first resonance chamber inside the casing A partition wall is installed, and the first resonance chamber is partitioned into a plurality of spaces by the partition wall, and each space is in communication with each other.

In addition, the guide tube extends through the first resonance chamber to the second resonance chamber, the first opening is formed on the outer peripheral surface of the guide tube, the second opening is located in the second resonance chamber It is formed in the end of the said guide tube.

The first resonance chamber and the second resonance chamber are characterized in that a part of the first resonance chamber and a second resonance chamber are separated by a partition plate.

Hereinafter, a preferred embodiment of the present invention will be described with reference to the accompanying drawings.

As shown in FIG. 1, the hermetic compressor according to the present invention has a cylindrical hermetically sealed container 10. The hermetic container 10 includes an upper container 10a and a lower container 10b. The inside of the sealed container 10 is provided with a compression unit 20 for compressing the refrigerant and a driving unit 30 for driving the compression unit 20.

The compression unit 20 includes a cylinder block 21 forming a compression chamber 21a through which a refrigerant is compressed, a cylinder head 23 sealing the cylinder block 21, the cylinder block 21, and the And a valve plate 24 interposed between the cylinder heads 23.

In addition, in the compression chamber 21a, a piston 22 which reciprocates to compress the refrigerant, and transmits power to the piston 22, converts the rotational movement of the rotating shaft 33 to be described later into a linear movement. The connecting rod 25 is provided.

The drive unit 30 is a stator 31 receiving a power source to form a magnetic field, a rotor 32 rotatably received by the stator 31 and rotating by interaction with the stator 31, And it is fitted to the center of the rotor 32 is provided with a rotating shaft 33 to rotate in accordance with the rotation of the rotor 32, the connecting rod 25 in the upper portion of the rotating shaft 33 And an eccentric shaft 33a which is coupled with the axial shaft 33.

The valve plate 24 disposed between the cylinder head 23 and the cylinder block 21 has an intake valve 25a for controlling a flow of refrigerant sucked into the compression chamber 21a, and the compression chamber ( A discharge valve 25b is provided to control the flow of the refrigerant discharged from 21a). In particular, the cylinder head 23 is provided with a suction muffler 50 capable of reducing noise caused by the flow and compression of the suction refrigerant. In addition, a refrigerant gas pipe 100 is installed in the suction part 57 of the suction muffler 50, and refrigerant is supplied to the refrigerant gas pipe 100 and the suction muffler 50 in accordance with the opening and closing action of the suction valve 25a. ) Is sucked into the compression chamber 21a via the suction valve 25a.

As shown in FIG. 2, the suction muffler 50 is provided with a casing 55 that forms an appearance and is open at an upper portion thereof, and a suction part to which the refrigerant gas pipe 100 is coupled to a side of the casing 55. A 57 is formed, and the suction part 57 has an oil inflow bump 59 and a refrigerant to prevent oil inside the sealed container (see FIG. 1 and 10) from penetrating into the suction muffler 50. A suction port 58 into which the gas pipe 100 is inserted is provided.

A cover 60 is provided at an upper portion of the casing 55 to seal an open position, and a refrigerant inside the suction muffler 50 is supplied to the suction valve (see FIG. 1 and 25a) at the center of the cover 60. A discharge tube 62 is provided to guide the discharge tube 62. A discharge hole 62a through which a refrigerant passes is formed at one end of the discharge tube 62, and a first resonance chamber (to be described later) is formed on the bottom surface of the cover 60. 3, a plurality of separation walls 64 partitioning 69 into a plurality of spaces are provided extending downward.

A guide tube 66 coupled to the discharge tube 62 to guide the refrigerant toward the discharge tube 62 is disposed below the cover 60, and the casing 55 is disposed on an outer circumferential surface of the guide tube 66. The partition plate 68 is divided into a first resonance chamber (see Fig. 3, 69) and a second resonance chamber (see Fig. 3, 70), which will be described later, and the partition plate 66 is the casing. It is preferable to be provided in the shape of a horizontal plate so that the inside of 55 may be divided up and down, and the said guide pipe 66 is appropriately arrange | positioned in the form which penetrates the said partition plate 68. FIG.

In addition, a locking step 56 is formed on an inner wall of the casing 55 so that the partition plate 68 can be stably placed inside the casing 55.

The guide tube 66 has a first opening 72 in communication with the first resonance chamber (FIGS. 3 and 69), a second opening 78 in communication with the second resonance chamber (FIGS. 3 and 70), In order to remove noise of a specific frequency band, a through hole 75 distributed on an outer circumferential surface of the guide tube 66 and a third opening 81 communicating with the discharge tube 62 are formed.

In addition, the upper surface of the partition plate 68 is provided with a suction pipe 84 for guiding the suction of the refrigerant, the suction pipe 84 is connected to the refrigerant gas pipe 100 coupled to the suction port 58 is connected to the refrigerant gas pipe ( The refrigerant flowing through 100 is introduced into the casing 55, specifically, into the first resonance chamber (see FIG. 3 and 69).

In addition, the outer peripheral surface of the suction pipe 84 is provided with a partition wall 87 for partitioning a part of the first resonance chamber to the left and right, the partition wall 87 is the inner wall of the guide tube 66 and the casing 55. It is provided between and installed so that the upper portion reaches the lower surface of the cover (60).

As shown in FIG. 3, when the suction muffler 50 is completely coupled, the upper surface of the casing 55 is sealed by the cover 60, and the casing 55 ) Is divided into a first resonance chamber 69 and a second resonance chamber 70 by the partition plate 68.

A discharge tube 62 penetrates the center of the cover 60 and is inserted into the first resonance chamber 69 by a predetermined length, and the discharge tube 62 penetrates the partition plate 68. It is connected to the guide tube 66, the discharge tube 62 is formed with a discharge hole (62a) connected to an intake valve (not shown) to control the suction of the refrigerant into the compression chamber.

In addition, a plurality of partition walls 64 extending downward are disposed on the bottom surface of the cover 60, and the partition walls 64 partition the inside of the first resonance chamber 69, whereby a refrigerant is formed. When passing through the first resonance chamber 69, the unit area passing through is changed.

The first opening 72 is formed at the side surface of the guide tube 66 so as to communicate with the first resonance chamber 69, and the second opening 78 is one end of the guide tube 66. Specifically, it is formed on the opposite side of the third opening portion 81 in communication with the discharge tube 62 and communicates with the second resonance chamber 70.

In addition, the suction pipe 84 disposed on the upper surface of the partition plate 68 and disposed to surround a part of the guide tube 66 is connected to the refrigerant gas pipe 100 to supply a refrigerant to the first resonance chamber ( 69 and a partition 87 installed on the outer circumferential surface of the suction pipe 84 is installed between the guide pipe 66 and the inner wall of the casing 55 to separate a part of the inside of the casing 55 from side to side. It plays a role.

In addition, a plurality of through-holes 75 are formed on the outer circumferential surface of the guide tube 66, and are mainly formed to communicate with the first resonance chamber 69, and noise of a specific frequency according to the flow of the refrigerant and the flow of pressure pulsation. It is designed to attenuate.

Figure 4 shows another embodiment of the present invention, the same components as those shown in the embodiment of Figure 3 will be described using the same reference numerals.

As shown in FIG. 4, the inside of the casing 55 is divided into the first resonance chamber 69 and the second resonance chamber 70 provided separately from the first resonance chamber 69. The first embodiment In the first resonance chamber 69 and the second resonance chamber 70 is completely separated by the partition plate 68, but is configured to communicate only by the guide tube 66, According to the second embodiment, a partition plate 68 'of another type is installed so that the first resonance chamber 69 and the second resonance chamber 70 can communicate without being guided by the guide tube 66. In addition, the partition plate 68 'of FIG. 4 has a shape in which a part of one side is slightly cut compared to the partition plate 68 disclosed in FIG. 3, so that the first resonance chamber 69 and the second resonance chamber are (70) is to communicate, thereby reducing the noise by changing the passage area of the sound waves due to the flow of refrigerant. To.

Hereinafter, an operation of the present invention will be described with reference to the accompanying drawings.

As shown in FIG. 1, when the cylinder 22 retreats inside the compression chamber 21a and the inside of the compression chamber 21a becomes a vacuum state, the suction valve 25a is opened. The refrigerant gas pipe 100 is sucked into the compression chamber 21a via the suction muffler 50.

 As shown in FIG. 3, the refrigerant guided by the refrigerant gas pipe 100 passes through the suction pipe 84 and enters the inside of the first resonance chamber 69, where a unit area through which the refrigerant flows. When a sudden change occurs and the pressure drops significantly, the noise generated by the inflow of the refrigerant is also significantly reduced, and the first resonance chamber 69 is also separated into a plurality of spaces by the partition wall 64. In addition, since the cross-sectional area through which the sound waves caused by the refrigerant and the refrigerant flowing in the first resonance chamber 69 are changed, the noise reduction effect is further enhanced.

As described above, the refrigerant flows through the first resonance chamber 69 as shown by the solid arrow, and then passes through the first opening 72 to receive the guide tube 66 and move to the discharge tube 62. After that, it is discharged outside the discharge hole 62a and moved to the compression chamber (see Fig. 1, 21a).

When the piston (see Figs. 1 and 22) is advanced in the compression chamber 21a and the refrigerant inside the compression chamber 21a is compressed, the suction valve (see Fig. 1 and 25a) is closed. Pulsation occurs as the intake valve 25a is closed, and the pulsation is transmitted through the discharge tube 62 and the guide tube 66, and the path of the pulsation is indicated by a dotted arrow.

In this case, a second opening 78 is formed at an end of the guide tube 66, and the second opening 78 communicates with the second resonance chamber 70 through the second opening 78. Since it is formed at a position substantially facing the discharge hole 62a of the discharge tube 62, the pulsation passing through the discharge hole 62a is transmitted toward the second opening 78 while being straight, and thus transmitted. The pulsation is introduced into the second resonance chamber (70).

Since the compression movement in the compression chamber 21a occurs several times in a short time, the opening and closing movement of the suction valve 25a also occurs several times in a short time, and thus the suction of refrigerant and the suction valve 25a are performed. The pulsation due to the opening and closing of the pulsation almost occurs at the same time. Thus, the suction path of the refrigerant and the transmission path of the pulsation are partially changed, thereby preventing the inflow of the refrigerant caused by the pulsation.

That is, the suction path of the refrigerant is formed in the order of the suction pipe 84, the first resonance chamber 69, the first opening 72, the guide tube 66, the discharge tube 62, the discharge port 62a, Since the transmission path is formed in the order of the discharge port 62a, the guide tube 66, the second opening 78, and the second resonance chamber 70, the paths are changed to reduce the interference of the pulsating refrigerant flow. It is possible to increase the amount of refrigerant flow per hour.

As shown in FIG. 4, although the first resonance chamber 69 and the second resonance chamber 70 are formed separately from each other, even when a portion thereof is in communication with each other, the suction path and the pulsation delivery path of the refrigerant are shown in FIG. It is the same as the first embodiment shown in 3.

However, since the first resonance chamber 69 and the second resonance chamber 70 communicate with each other, a change occurs in the passage area of the sound wave, thereby further improving the damping effect of the noise.

According to the present invention, the pulsation is transmitted in the opposite direction to the direction in which the refrigerant is introduced, thereby avoiding the coincidence of the passage of the refrigerant with the delivery path of the pulsation generated by the opening and closing of the intake valve. The effect which can prevent the reduction can be obtained.

Therefore, there is an advantage that the compression efficiency of the compressor can be increased by increasing the amount of the refrigerant flowing into the compression chamber compared to the conventional hermetic compressor.

Claims (5)

In a hermetic compressor comprising a compression chamber, a suction valve for intermitting a flow of refrigerant sucked into the compression chamber, a suction chamber in which the suction valve is installed, and a suction muffler connected to the suction chamber, The suction muffler may be in communication with a casing forming the exterior, a first resonance chamber formed inside the casing, into which a refrigerant flows, a discharge tube provided in the casing, and guiding the refrigerant into the suction chamber, and in contact with the first resonance chamber. A hermetic compressor comprising a guide tube for transferring refrigerant to a discharge tube, and a second resonance chamber which is partitioned from the first resonance chamber and in communication with the guide tube to absorb pulsations generated by opening and closing of the suction valve. . The method of claim 1, The guide tube is provided with a first opening in communication with the first resonance chamber and a second opening in communication with the second resonance chamber, and on the outer circumferential surface of the guide tube separates the first resonance chamber and the second resonance chamber. Hermetic compressor, characterized in that the partition plate is installed.  The method of claim 1,  One surface of the casing is opened, and the open portion is sealed by a cover connected to the outer circumferential surface of the discharge pipe, and one surface of the cover has a plurality of partition walls protruding toward the first resonance chamber inside the casing. Is installed, the first resonance chamber is partitioned into a plurality of spaces by the partition wall, each space is hermetic compressor characterized in that the communication. 3. The method of claim 2, The guide tube extends through the first resonance chamber to the second resonance chamber, wherein the first opening is formed on an outer circumferential surface of the guide tube, and the second opening is located in the second resonance chamber. A hermetic compressor, formed at the end of the tube. 3. The method of claim 2, The said 1st resonance chamber and the said 2nd resonance chamber are the one part separated division by the said partition board, The one part is hermetic compressor characterized by the communication.

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