KR101270624B1 - Compressor - Google Patents

Abstract

The compressor of the present invention includes a shell; A suction pipe for guiding gas to the shell; A suction muffler located inside the shell and connected to a compression mechanism unit through which gas is compressed; A gas guide tube connected to the suction muffler and guiding the gas guided to the suction tube to the suction muffler, wherein the gas guide tube has a fallopian tube portion having a diameter extending toward the shell and a fallopian tube having a diameter larger than the diameter of the fallopian tube portion; The gas guiding tube and the shell are integral with the fallopian tube, including an outer sealing rib formed integrally with the protruding portion and an inner sealing rib spaced apart from the outer sealing rib and smaller in diameter than the diameter of the outer sealing rib and integrally protruding from the fallopian tube portion. Since the double sealing is formed by the outer sealing rib and the inner sealing rib formed to protrude into the gas, it is possible to minimize the flow of gas outside the gas guide tube between the gas guide tube and the shell, the gas outside the gas guide tube and the shell There is an advantage that can prevent the decrease in efficiency due to the flow in.

Description

Compressor

The present invention relates to a compressor, and more particularly, to a compressor in which a muffler is connected to a compression mechanism part for compressing a gas.

Generally, a compressor is a device that compresses gas by converting electrical energy into kinetic energy, and includes a rotary compressor, a reciprocating compressor, a scroll compressor, and the like according to a compression mechanism for compressing gas.

The compressor includes a shell, a compression mechanism portion provided inside the shell, a suction pipe for introducing gas into the shell, and a gas discharge pipe through which the gas compressed in the compression mechanism portion is discharged.

The compressor may be connected to the suction muffler to the compression mechanism, and a gas guide tube for guiding the gas sucked into the suction pipe to the suction muffler may be connected to the suction muffler.

The gas guide tube is connected to the suction muffler so as to be positioned between the suction muffler and the shell, and guides the gas to the suction muffler with the end contacting the shell.

When the compressor is driven, the compression mechanism part and the suction muffler vibrate, and a gap may be generated between the gas guide tube and the shell during vibration. When the hot gas inside the shell is sucked into the gas guide tube through the gap, the specific volume of gas This increases the efficiency.

KR 10-0677518 (2007.02.02)

The compressor according to the related art configured as described above may have a gap with the shell in a state where the wear preventing member is connected to the gas guide tube, or the gas guide tube may be spaced apart from the wear preventing member and have a gap with the wear preventing member, and the inside of the shell The hot gas has a problem of being easily sucked into the gas guide tube through the gap between the wear protection member and the shell or the gap between the gas guide tube and the wear protection member.

The present invention has been made to solve the above problems of the prior art, by providing a double seal between the gas guide tube and the shell, to provide a compressor that minimizes the intake of hot gas between the gas guide tube and the shell. There is this.

Compressor according to the present invention for solving the above problems is a shell; A suction pipe for guiding gas to the shell; A suction muffler located inside the shell and connected to a compression mechanism unit through which gas is compressed; A gas guide tube connected to the suction muffler and guiding the gas guided to the suction tube to the suction muffler, wherein the gas guide tube includes a fallopian tube part extending in diameter toward the shell and a diameter of the fallopian tube part; An outer sealing rib having a large diameter and integrally protruding from the fallopian tube part, and an inner sealing rib having a diameter smaller than the diameter of the outer sealing rib and integrally protruding from the fallopian tube part.

 The outer sealing rib may protrude to have an obtuse angle with the fallopian tube part, and the inner sealing rib may protrude with an acute inclination angle with the fallopian tube part.

 The outer sealing rib and the inner sealing rib may be formed to become thinner gradually in the fallopian tube part.

The outer sealing rib may protrude obliquely in a shape that opens toward the direction of the shell from the end of the fallopian tube part, and the inner sealing rib may protrude obliquely in a shape that protrudes toward the direction of the shell from the end of the fallopian tube part. .

  The gas guide tube may have a space formed between the outer sealing rib and the inner sealing rib.

The present invention can minimize the inflow of the gas outside the gas guide tube between the gas guide tube and the shell, there is an advantage that can prevent the decrease in efficiency by the gas outside the gas guide tube between the gas guide tube and the shell have.

1 is a partial cutaway cross-sectional view showing an embodiment of a compressor according to the present invention,
2 is an enlarged perspective view of the gas guide tube shown in FIG.
3 is an enlarged cross-sectional view of the outer sealing rib and the inner sealing rib shown in FIG. 2;
4 is an enlarged cross-sectional view before the gas guide tube shown in FIG. 1 contacts the shell;
FIG. 5 is an enlarged cross-sectional view when the gas guide tube shown in FIG. 1 is in close contact with the shell. FIG.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a partial cutaway sectional view showing one embodiment of a compressor according to the present invention.

Referring to FIG. 1, the compressor includes a shell 2 which forms an appearance. The shell 2 may include a lower shell 4 having an open upper surface and an upper shell 6 installed on an upper portion of the lower shell 4 and having an open lower surface.

Inside the shell 2, a compression mechanism 8 for sucking and compressing gas and then discharging the gas is disposed.

The compression mechanism 8 may include a cylinder 10 having a compression chamber in which gas is compressed, and a piston 12 reciprocating in the cylinder 10.

The cylinder 10 may be provided with a valve body 14 having an intake valve for regulating gas inflow into the cylinder 10 and a discharge valve for regulating gas outflow from the cylinder 10.

Inside the shell 2, a motor 16 for reciprocating the piston 12 may be arranged.

The motor 16 may be provided with a crankshaft 18 connected to the piston 12, and the motor 16 may be assembled with the compression mechanism 8 to be integrated with the compression mechanism 8.

The motor 16 may be connected to a spring unit 20 for supporting the motor 16 and the compression mechanism 8 to the shell 2.

On the other hand, a loop pipe 22 through which the high temperature and high pressure gas compressed by the compression mechanism 8 passes through the shell 2 may be disposed. The roof pipe 24 may be connected to the discharge tube 24 installed in the shell 2. The discharge tube 24 discharges the high temperature and high pressure gas compressed by the compressor to the outside of the compressor, and may be connected to a condenser (not shown) and a condenser connecting pipe, and the high temperature and high pressure compressed by the compressor and discharged to the discharge tube 24 is provided. Gas can be transferred to the condenser through the condenser connection pipe and condensed in the condenser.

The compressor may be arranged with a discharge muffler 26 to reduce noise between the compression mechanism 8 and the loop pipe 22. That is, the gas of the high temperature and high pressure compressed by the compression mechanism part 8 can pass through the discharge muffler 26, the loop pipe 22, and the discharge pipe 24 sequentially.

The compressor includes a suction pipe 30 for guiding gas to the shell 2, a suction muffler 32 disposed inside the shell 2 and connected to the compression mechanism 4, and a suction pipe 32 connected to the suction muffler 32. And a gas guide tube 34 for guiding the gas guided by 30 to the suction muffler 32.

The suction pipe 30 allows the gas to be sucked into the compressor, and may be connected to an evaporator (not shown) and an evaporator connecting pipe, and the low temperature low pressure gas evaporated from the evaporator may be sucked into the compressor through the suction pipe 30.

The suction pipe 30 is preferably made of a brass material having a lower thermal conductivity than the copper material so as to minimize the temperature of the gas passing through the suction pipe 30 by the heat transferred from the shell 2 to the suction pipe 30.

 The suction pipe 30 may be heated to a high temperature by the heat transmitted from the shell 2 when made of copper material, while the copper suction pipe 30 may be heated to a relatively low temperature than copper when the copper material is made of copper. The temperature rise is minimized when passing through 30, and the efficiency is increased because the temperature of the gas sucked into the compression mechanism 8 is relatively low.

The gas guide tube 34 is preferably made of a rubber material.

FIG. 2 is an enlarged perspective view of the gas guide tube shown in FIG. 1, FIG. 3 is an enlarged cross-sectional view of the outer sealing rib and the inner sealing rib shown in FIG. 2, and FIG. 4 is a gas guide tube shown in FIG. 5 is an enlarged cross-sectional view before contacting, and FIG. 5 is an enlarged cross-sectional view when the gas guide tube shown in FIG. 1 is in close contact with the shell.

The gas guide tube 34 may include a hollow cylindrical portion 40 in which a flow path through which gas passes, and a suction muffler coupling portion 42 formed in the hollow cylindrical portion 40 and coupled to the suction muffler 32. Can be.

The gas guide tube 34 includes a fallopian tube portion 44 whose diameter extends in the direction of the shell 2.

The fallopian tube part 44 is formed on the opposite side of the suction muffler coupling portion 42 of both ends of the hollow cylindrical portion 40, and is formed to expand in diameter toward the opposite direction of the suction muffler coupling portion 42.

Gas guide tube 34 has a diameter larger than the diameter of the fallopian tube portion 44 and is spaced apart from the outer sealing rib 46 and the outer sealing rib 46 protruded integrally from the fallopian tube portion 44 and the outer sealing rib ( It has a diameter smaller than the diameter of 46 and includes an inner sealing rib 48 protruded integrally from the fallopian tube part 44.

The outer sealing rib 46 and the inner sealing rib 48 may be formed in a ring shape as a whole.

The outer circumferential surface of the outer sealing rib 46 is in surface contact with the inner surface of the shell 2, and the outer circumferential surface of the outer sealing rib 46 is in surface contact with the inner surface of the shell 2.

 The outer sealing ribs 46 and the inner sealing ribs 48 are in surface contact with the inner surface of the shell 2 to seal between the fallopian tube part 44 and the shell 2, and the outer sealing ribs 46 and the inner sealing ribs are sealed. 48 double seals between the fallopian tube part 44 and the shell 2 in the radial direction.

That is, the hot gas inside the shell 2 is first restricted to the inside of the gas guide tube 34 by the outer sealing rib 46, and the gas is secondaryly guided by the inner sealing rib 48. Inflow into the tube 34 is secondarily restricted.

The outer sealing rib 46 and the inner sealing rib 48 may be formed in the fallopian tube part 44 to become thinner gradually.

The outer sealing rib 46 may protrude with the fallopian tube portion 44 and an obtuse angle of inclination (ie, an inclination angle greater than 90 ° and less than 180 °).

 The outer sealing rib 46 protrudes inclined from the outer circumferential surface of the end portion 45 of the fallopian tube part 44, and protrudes in a shape that opens toward the shell 2.

The inner sealing rib 46 protrudes with the fallopian tube part 44 at an acute angle of inclination (ie, an angle of inclination smaller than 90 °).

The inner sealing rib 46 protrudes inclined from the inner circumferential surface of the end portion 45 of the fallopian tube part 44, and protrudes in the shape of a constriction toward the shell 2.

The gas guide tube 34 has a space S formed between the outer sealing rib 46 and the inner sealing rib 48, and the space S is formed when the fallopian tube part 44 moves away from the shell 2. It becomes large and becomes small when the fallopian tube part 44 is close to the shell 2.

As shown in FIG. 4, the gas guide tube 34 has a triangular cross-sectional shape of the space S while the space S is generally annular before the gas guide tube 34 contacts the shell 2. 5, the space S is elastically deformed while the outer sealing rib 46 and the inner sealing rib 48 are elastically deformed when the gas guide tube 34 is in close contact with the shell 2 as shown in FIG. 5. Almost disappear, the contact area of the outer sealing rib 46 and the shell 2 and the contact area of the inner sealing rib 48 and the shell 2 are increased.

Hereinafter, the operation of the present invention will be described.

First, when the motor 16 is driven, the piston 10 reciprocates the inside of the cylinder 12, the suction force is generated in the suction muffler 32, the gas guide tube 34 and the suction tube 30, the suction tube The gas in 30 flows out to the end of the suction pipe 34. At this time, the gas guide tube 34 is in a state in which the outer sealing rib 46 and the inner sealing rib 48 are pressed into the shell 2 to be in surface contact with the inner surface of the shell 2 and the inner and outer double, and the suction pipe ( The gas flowing out to the end of 34 is introduced into the inner space of the fallopian tube part 44.

Gas introduced into the inner space of the fallopian tube part 44 flows into the suction muffler 32 through the hollow cylindrical part 40, and then flows into the cylinder 12. The gas introduced into the cylinder 12 is compressed by the piston 10 and then discharged through the discharge muffler 26, the roof pipe 22, and the discharge tube 24.

On the other hand, in the configuration of the compressor as described above, the gas outside the gas guide tube 34 is to be introduced between the shell 2 and the gas guide tube 34, the outer sealing rib 46 and the inner sealing rib 48 is Since it is pressed into the shell 2 and double-sealed, it minimizes the inflow between the shell 2 and the gas guide tube 34, and the gas outside the gas guide tube 34 is introduced into the shell 2 and the gas guide tube ( It is possible to minimize the decrease in efficiency due to the flow in between 34).

2: shell 3: hole
8: compression mechanism part 30: suction pipe
32: suction muffler 34: gas guide tube
44: fallopian tube part 46: outer sealing rib
48: inner sealing rib

Claims (5)

A shell;
A suction pipe for guiding gas to the shell;
A suction muffler located inside the shell and connected to a compression mechanism unit through which gas is compressed;
A gas guide tube connected to the suction muffler to guide the gas guided to the suction tube to the suction muffler,
The gas guide tube has a diameter of the fallopian tube portion extending in diameter toward the shell, an outer sealing rib having a diameter larger than that of the fallopian tube portion, and integrally protruding from the fallopian tube portion, and a diameter of the outer sealing rib. Small and includes an inner sealing rib protruding integrally from the fallopian tube,
The outer sealing rib protrudes inclined in a shape that opens toward the shell at the end of the fallopian tube part,
And the inner sealing rib protrudes obliquely in a shape that retracts from the end of the fallopian tube part toward the shell. The method of claim 1,
The outer sealing rib protrudes with an inclination angle of the fallopian tube portion and an obtuse angle,
And the inner sealing rib protrudes at an acute angle with the fallopian tube part. 3. The method of claim 2,
And the outer sealing ribs and the inner sealing ribs are gradually thinner in the fallopian tube part. delete The method of claim 1,
And the gas guide tube has a space formed between the outer sealing rib and the inner sealing rib.

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