KR100593846B1 - Suction Muffler for Compressor - Google Patents

Abstract

The present invention relates to a suction muffler for a compressor, and the object of the present invention is to effectively separate the refrigerant and oil in the liquid state contained in each inside to reduce the refrigerant suction noise of the compressor to improve the performance of the compressor It is to provide an air suction muffler.

To this end, a compressor muffler according to the present invention includes a main body provided to connect a suction pipe of a compressor, a refrigerant inlet chamber formed inside the main body and provided with a refrigerant received from the suction pipe to flow from an upper side to a lower side, a compression chamber of the compressor, and the refrigerant. A refrigerant outlet pipe connecting the inflow chamber, a resonance chamber provided to be partitioned from the refrigerant inlet chamber, a compartment configured to partition the resonance chamber and the refrigerant inlet chamber, and the compartment so that the refrigerant inlet chamber and the resonance chamber communicate with each other. It is comprised including the communication part provided in a part.

Description

A suction muffler for compressor

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

2 is a cross-sectional view showing the structure of a compressor suction muffler according to the first embodiment of the present invention.

3 is a cross-sectional view showing the structure of a compressor suction muffler according to a second embodiment of the present invention.

Figure 4 is a cross-sectional view showing the structure of a suction muffler for a compressor according to a third embodiment of the present invention from another point of view.

Explanation of symbols on the main parts of the drawings

1: airtight container 2: suction line

3: discharge tube 10: compression part

11a: compression chamber 13: cylinder head

13a: refrigerant discharge chamber 13b: refrigerant suction chamber

20: drive unit 30: suction muffler

40: main body 41: refrigerant inlet pipe

42: first body portion 42a: second discharge hole

43: second body portion 43a: the first discharge hole

50: refrigerant inlet passage 60: refrigerant inlet chamber

61: information room 70: resonance room

80: refrigerant outlet pipe 90,90 ', 90 ″: compartment

91,91 ', 91 ": Communication part 92,92', 92": Upper compartment member

93,93 ′, 93 ″: lower compartment member 94: auxiliary communication section

The present invention relates to a suction muffler for a compressor, and more particularly, a suction for a compressor provided to effectively separate the refrigerant and oil in a liquid state contained in the refrigerant from the inside to reduce the refrigerant suction noise of the compressor and to improve the performance of the compressor. It is about a muffler.

Generally, a refrigerating cycle employed in a refrigerator or an air conditioner includes a compressor for sucking and compressing a low pressure refrigerant and discharging the refrigerant at a high pressure, a condenser for condensing the refrigerant discharged from the compressor, and an expansion device for expanding the refrigerant condensed from the condenser. The evaporator, which exchanges heat with surrounding air while the refrigerant expanded in the expansion device is evaporated, is provided to form a closed circuit through the refrigerant pipe.

The dual compressor usually includes a compression unit for compressing a refrigerant, a driving unit for providing compression power according to the compression of the refrigerant, a sealed container for sealing the compression unit and the motor unit with the outside, and guides the external refrigerant into the sealed container. It consists of a suction tube and a discharge tube for discharging the refrigerant compressed in the compression unit to the outside of the sealed container.

In addition, the compression unit is a cylinder block in which a compression chamber is formed to compress the refrigerant, a piston for compressing the refrigerant in the compression chamber, a cylinder coupled to one side of the cylinder block to seal the compression chamber, and the refrigerant discharge chamber and the refrigerant suction chamber are partitioned cylinders. And a valve device for intermittent suction and discharge of the refrigerant sucked into or discharged from the compression chamber between the cylinder block and the cylinder head.

Meanwhile, a suction muffler is installed between the compression chamber and the suction pipe of the compressor to reduce the flow noise of the refrigerant sucked into the compression chamber.

The suction muffler is provided such that the suction pipe is connected to the main body, and the inner space forms a predetermined resonance space to reduce the flow noise of the suction refrigerant, and the inside of the main body and the cylinder head to transfer the refrigerant introduced into the main body to the compression chamber. It is provided with a refrigerant discharge pipe coupled to the main body so as to connect between the refrigerant suction chamber.

Therefore, the refrigerant introduced into the suction muffler main body from the suction pipe during the suction action of the compressor flows into the refrigerant suction chamber of the cylinder head along the refrigerant outlet pipe in a state where the flow noise is reduced while passing through the main body forming the resonance space of the suction muffler. After being delivered, it is continuously delivered to the compression chamber, and the refrigerant delivered to the compression chamber is pressurized by the pressure action of the piston and discharged to the outside of the compressor through the discharge pipe.

However, the suction muffler of the conventional compressor has a large amount of liquid refrigerant or oil contained in the refrigerant transferred into the main body through the suction pipe as the entire internal space of the main body is formed to form a resonance space together with the gaseous refrigerant. Since the refrigerant can flow into the refrigerant pipe, the suction noise of the refrigerant is increased while the mixed fluid of the liquid phase and the gaseous phase is transferred to the refrigerant suction chamber through the refrigerant discharge pipe, and the liquid refrigerant in the compression chamber is increased. There is a problem that is transmitted and degrades the performance of the compressor.

The present invention is to solve such a problem, an object of the present invention is to effectively separate the refrigerant and the oil in the liquid state contained in the refrigerant therein is provided to reduce the refrigerant suction noise of the compressor to improve the performance of the compressor It is to provide a suction muffler for the compressor.

Compressor suction muffler according to the present invention for achieving the above object is a main body provided to be connected to the suction pipe of the compressor, the refrigerant inlet chamber formed in the main body and the refrigerant received from the suction pipe flows from the upper side to the lower side, and the compressor A refrigerant outlet pipe connecting the compression chamber and the refrigerant inlet chamber of the chamber, a resonance chamber arranged to partition the refrigerant inlet chamber inside the main body, a partition unit arranged to partition the resonance chamber and the refrigerant inlet chamber, and the refrigerant inlet chamber and the resonance chamber. It characterized in that it comprises a communication unit provided in the partition so as to communicate.

And the coolant inlet chamber forms a lower space of the coolant inlet chamber and includes a guide chamber for guiding the coolant flowed under the coolant inlet chamber into the coolant outlet tube. It features.

The partition may include an upper partition member extending from an upper inner surface of the main body to a lower side, and a lower partition member extending from an lower inner surface of the main body to an upper side, and the communication unit may be provided between the upper and lower partition members. It features.

The upper compartment member and the lower compartment member are provided to be spaced apart from each other in an intersecting state, and an end of the lower compartment member intersecting with the upper compartment member is more than an end of the upper compartment member intersected with the lower compartment member. It is characterized in that it is provided adjacent to the refrigerant inlet chamber.

In addition, the auxiliary chamber between the lower compartment member and the main body side of the guide chamber is characterized in that the auxiliary communication unit for communicating the resonance chamber and the resonance chamber is provided.

In addition, the auxiliary communication unit is characterized in that it is provided along the longitudinal direction of the lower compartment member to communicate with the communication unit.

In addition, the resonance chamber side body is characterized in that the first discharge hole for discharging the liquid refrigerant and the oil in the liquid state to the outside of the main body is provided.

In addition, the guide chamber side body is characterized in that the second discharge hole for discharging the liquid refrigerant and the oil in the refrigerant state to the outside of the main body is provided.

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

As shown in FIG. 1, the compressor according to the present invention includes an airtight container 1 formed by combining an upper container 1a and a lower container 1b, and a refrigerant that is provided inside the sealed container 1. It includes a compression unit 10 to perform the compression, and a drive unit 20 for providing the compression power in accordance with the compression of the refrigerant, one side and the other side of the sealed container (1) to the external refrigerant into the sealed container (1) A discharge pipe 3 for discharging the refrigerant compressed by the guide suction pipe 2 and the compression unit 10 to the outside of the sealed container 1 is provided.

The double compression unit 10 includes a cylinder block 11 in which a compression chamber 11a is formed to compress the refrigerant, a piston 12 linearly reciprocating in the compression chamber 11a to perform a compression action of the refrigerant, and compression A cylinder head 13 coupled to one side of the cylinder block 11 to seal the chamber 11a and having a refrigerant discharge chamber 13a and a refrigerant suction chamber 13b partitioned therein, and the cylinder block 11 and the cylinder head 13. And a valve device 14 for intermittent flow of the refrigerant sucked into the compression chamber 11a from the refrigerant suction chamber 13b or discharged from the compression chamber 11a to the refrigerant discharge chamber 13a. .

In addition, the drive unit 20 provides a driving force to allow the piston 12 to reciprocate in the compression chamber 11a. The stator 21 and the stator 21 fixed inside the sealed container 1 are provided. It is provided with a rotor 22 spaced apart from the inside of the stator 21 and the electromagnetic interaction. And the center of the rotor 22 is provided with a rotating shaft 23 so as to be interlocked with the rotor 22, the upper portion of the rotary shaft 23 of the eccentric portion 24 and the eccentric portion 24 for eccentric rotation One end is rotatably coupled to the eccentric portion 24 so that the eccentric rotation can be converted into a linear movement, and the other end is provided with a connecting rod 25 installed to rotate and linearly move the piston 12.

On the other hand, between the compression chamber (11a) and the suction pipe (2) is provided with a suction muffler (30) for reducing the flow noise of the refrigerant sucked from the suction pipe (2) into the compression chamber (11a), such a suction muffler (30) 1 and 2, the refrigerant inlet pipe 41 to which the suction pipe 2 is connected to form the refrigerant inflow path 50, and the internal space of the refrigerant in direct communication with the refrigerant inflow path 50. A first body part 42 provided to form the inlet chamber 60 and a resonant chamber 70 are provided to be spaced apart from the refrigerant inlet passage 50 by a predetermined interval and the internal space is partitioned from the refrigerant inlet chamber 60. The second body 43 is provided so as to have a main body 40 formed integrally.

Here, the suction pipe 2 is coupled to the inlet of the refrigerant inlet tube 41, and the outlet of the refrigerant inlet tube 41, which serves as the inlet of the refrigerant inlet chamber 60, is one side of the upper side of the refrigerant inlet chamber 60. Located in the refrigerant inlet chamber 60, the refrigerant inlet chamber 60 and the cylinder head 13 to deliver the refrigerant delivered to the refrigerant inlet chamber 60 through the refrigerant inlet pipe (41) to the compression chamber (11a). Coolant outlet pipe (80) connecting between the refrigerant suction chamber (13b) of the () is provided. At this time, the outlet of the refrigerant outlet pipe 80 is extended to the upper portion of the first body 42 is coupled to the refrigerant suction chamber 13b of the cylinder head 13, the lower portion of the refrigerant outlet pipe 80 in which the inlet is formed The predetermined distance extends below the inlet pipe 41 through the inlet of the refrigerant inlet chamber 60.

In addition, the partition portion formed along the vertical length direction of the main body 40 to partition the resonance chamber 70 and the refrigerant inlet chamber 60 in the main body 40 between the resonance chamber 70 and the refrigerant inlet chamber 60. 90 is provided. The refrigerant introduced into the refrigerant inlet chamber 60 from the refrigerant inlet tube 41 through the partition unit 90 of the refrigerant inlet chamber 60 is formed along the inner surface of the refrigerant inlet chamber 60. It flows from the top to the bottom side.

In addition, the refrigerant inlet chamber 60 forms a lower space of the refrigerant inlet chamber 60 and includes a guide chamber 61 for guiding the refrigerant flowing into the lower portion of the refrigerant inlet chamber 60 into the refrigerant outlet pipe 80. The guide chamber 61 is provided to have a substantially hemispherical shape through the lower end of the first body 42 formed convexly downward, and flows from the upper side to the lower side along the inner surface of the refrigerant inlet chamber 60 through this structure. The flowed coolant is guided to the guide chamber 61 and flows into the inlet of the coolant outlet pipe 80.

In addition, the compartment 90 is provided with a communication unit 91 for communicating the resonance chamber 70 and the refrigerant inlet chamber 60, and the communication unit 91 is a compartment 90 at the upper side of the guide chamber 61. It is provided in the), which is introduced into the refrigerant inlet chamber 60, the portion of the refrigerant flowing from the upper side to the lower side along the inner surface of the refrigerant inlet chamber 60 is guided to such a communication unit 91 before being guided to the guide chamber 61 To be introduced into the resonance chamber 70 through. Therefore, the liquid refrigerant and oil in the refrigerant introduced into the resonance chamber 70 are accumulated in the resonance chamber 70, and the refrigerant in the gas state flows back into the refrigerant inlet chamber 60 through the communication unit 91 again. After being introduced into the resonance chamber 70 with the refrigerant not introduced into the guide chamber 61 and introduced into the refrigerant outlet pipe 80, through which a substantial amount of the refrigerant contained in the refrigerant introduced into the refrigerant inlet chamber 60 The liquid refrigerant and the oil may be separated into the resonance chamber 70. In addition, the first discharge hole 43a is formed at the lower end of the second body 43 so that the liquid refrigerant and oil accumulated in the resonance chamber 70 can be discharged to the outside of the main body 40, and the refrigerant inlet chamber ( A second discharge hole 42a is formed at the lower end of the first body 42 on the side of the guide chamber 61 so that the predetermined liquid refrigerant and oil may be discharged to the outside of the main body 40 through the 60.

In addition, the partition 90 includes an upper partition member 92 extending from the upper inner surface of the main body 40 to the lower side, and a lower partition member 93 extending from the lower inner surface of the main body 40 to the upper side. The communication part 91 is formed through a spaced space between the upper compartment member 92 and the lower compartment member 93.

In addition, FIG. 3 shows a partition 90 'according to another embodiment of a suction muffler for another compressor of the present invention, in which a greater amount of liquid refrigerant and oil than the first embodiment are suction mufflers 30. It can be separated into the resonance chamber 70 therein.

That is, as shown in Figure 3, in the suction muffler 30 according to another embodiment of the present invention, the partition portion 90 'is an upper compartment member extending from the upper inner surface of the main body 40 to the lower side ( 92 ') and a lower partition member 93' extending from the lower inner surface of the main body 40 to the upper side, and the upper partition member 92 'and the lower partition member 93' are spaced apart from each other in an intersecting state. The communication unit 91 'is provided between each end of the upper partition member 92' and the lower partition member 93 'that cross each other. The end of the lower compartment member 93 'that intersects the upper compartment member 92' is closer to the refrigerant inlet chamber 60 than the end of the upper compartment member 92 'that intersects the lower compartment member 93'. Is placed. Therefore, at this time, most of the refrigerant flowing downward along the inner surface of the refrigerant inlet chamber 60 on the upper side of the communicating portion 91 'is caught by the end of the lower compartment member 93' and resonates through the communicating portion 91 '. Since the liquid 70 is introduced into the chamber 70, more liquid refrigerant and oil may be separated into the resonance chamber 70 inside the body 40.

In this case, since most of the refrigerant passes through the communication portion 91 ′ before being guided to the guide chamber 61, the coolant supply speed to the compression chamber 11a may be lowered as the flow force of the refrigerant decreases. In consideration of this matter, the partition of the suction muffler 30 may be formed as shown in FIG. 4.

That is, as shown in Figure 4, in the suction muffler 30 according to another embodiment of the present invention, the partition portion 90 ″ is the upper compartment member 92 extending from the upper inner surface of the main body 40 to the lower side ″) And a lower partition member 93 ″ extending from the lower inner surface of the main body 40 to the upper side, wherein the upper partition member 92 ″ and the lower partition member 93 ″ are in the longitudinal direction of the main body 40. It is provided so as to be spaced apart from each other, the communication portion 91 "is formed through the spaced space between the upper compartment member 92" and the lower compartment member 93 ".

In the partition 90 ″, one side end of the lower partition member 93 ″ on the side of the guide chamber 61 connects the refrigerant inlet chamber 60 and the resonance chamber 70 between the inner surface of the main body 40. It is provided to be spaced apart from the inner surface of the main body 40 so that the auxiliary communication portion 94 for communicating.

Therefore, at this time, a smaller amount of refrigerant is separated into the resonance chamber 70 in the process of flowing from the upper side to the lower side along the inner surface of the refrigerant inlet chamber 60 than in the case where the partition 90 'according to the second embodiment is formed. On the other hand, the supply speed of the refrigerant to the compression chamber 11a is increased, and a predetermined amount of the liquid state of the refrigerant guided directly to the guide chamber 61 is not introduced into the resonance chamber 70 through the communication unit 90 ″. Refrigerant and oil are also guided to the guide chamber 61 and at the same time can be separated into the resonance chamber 70 directly through the auxiliary communication section 94, so that a somewhat larger amount of liquid refrigerant and than in the first embodiment Allow oil to separate into resonance chamber 70.

In this case, the auxiliary communication unit 94 may be formed long along the vertical direction of the lower partition member 93 ″ to communicate with the communication unit 91 ″, as shown in FIG. Refrigerant introduced into the 61 as well as a predetermined amount of the refrigerant before flowing into the guide chamber 61 through the communication unit 90 ″ can be separated into the resonance chamber 70 through the upper portion of the secondary communication unit 94. do.

Next will be described the operation of the compressor equipped with a muffler for the compressor according to the present invention and the resulting effects.

First, when the rotating shaft 23 rotates together with the rotor 22 by the electrical interaction between the stator 21 and the rotor 22 according to the power application, the eccentric portion 24 and the connecting rod 25 are rotated. The piston 12 connected through the linear reciprocating motion in the compression chamber (11a), through which the refrigerant outside the sealed container (1) passing through the suction muffler (30) from the suction pipe (2) is somewhat reduced noise After entering the refrigerant suction chamber 13b of the cylinder head 13 in a state, it is delivered to the compression chamber 11a and compressed in the compression chamber 11a, and the refrigerant compressed in the compression chamber 11a is again a cylinder. After the discharge to the refrigerant discharge chamber (13a) of the head 13 is discharged to the outside of the sealed container 1 through the discharge pipe (3), this process is repeated and the compression of the refrigerant through the compressor is performed.

In the main body 40 of the suction muffler 30 in which the partitions 90, 90 ′, 90 ″ and the communication units 91, 91 ′, 91 ″ are formed during the refrigerant compression process of the compressor, the liquid contained in the refrigerant is included. An operation of separating the refrigerant and the oil in the resonance chamber 70 is performed. First, a refrigerant separation operation of the suction muffler 30 according to the first embodiment of the present invention will be described.

As shown in FIG. 2, some of the refrigerant flowing from the suction pipe 2 into the refrigerant inlet chamber 60 and flowing from the upper side to the lower side along the inner surface of the refrigerant inlet chamber 60 is guided to the guide chamber 61. The refrigerant inflow chamber 60 and the resonance chamber 70 are introduced into the resonance chamber 70 through the communication unit 91 provided in the partition unit 90 so as to communicate with each other. The liquid refrigerant and oil in the refrigerant introduced into the resonance chamber 70 are accumulated in the resonance chamber 70, and the refrigerant in the gas state flows back into the refrigerant inlet chamber 60 through the communication unit 91. After being guided to the guide chamber 61 with the refrigerant not introduced into the resonance chamber 70 is introduced into the refrigerant outlet pipe 80, through which a significant amount of the refrigerant contained in the first refrigerant inlet chamber 60 The liquid refrigerant and the oil may be separated into the resonance chamber 70. In this case, the liquid refrigerant and the oil accumulated in the resonance chamber 70 are discharged to the outside of the main body 40 through the first discharge hole 43a, and formed in the guide chamber 61 side of the refrigerant inlet chamber 60. A predetermined amount of liquid refrigerant and oil are also discharged to the outside of the main body 40 through the second discharge hole 42a.

In addition, the refrigerant separation operation of the suction muffler 30 according to the second embodiment of the present invention will be described. In this case, as shown in FIG. 3, the inner surface of the refrigerant inlet chamber 60 on the upper side of the communication unit 91 ′ is shown. Most of the refrigerant flowing to the lower part is caught at the end of the lower compartment member 93 'on the communication part 91' and flows into the resonance chamber 70 through the communication part 91 '. More liquid refrigerant and oil can be separated into the resonance chamber 70 inside the body 40.

In addition, as shown in Figure 4, the suction muffler 30 according to the third embodiment of the present invention, rather than the case where the compartment 90 'according to the second embodiment of the refrigerant is introduced into the refrigerant In the process of flowing from the upper side to the lower side along the inner surface of the chamber 60 is separated into the resonance chamber 70, while the refrigerant supply speed to the compression chamber (11a) is increased, and the resonance through the communication portion 91 ″ Refrigerant and oil of a predetermined amount of the liquid state of the refrigerant guided directly to the guide chamber 61 without being introduced into the chamber 70 is guided to the guide chamber 61 through the auxiliary communication section 94 and at the same time the resonance chamber 70 As a result, the liquid refrigerant and oil in a somewhat larger amount can be separated into the resonance chamber 70 than in the first embodiment.

Therefore, the refrigerant in the liquid state and the oil contained in the refrigerant transferred from the suction pipe 2 to the suction muffler 30 through the suction muffler 30 according to each of these embodiments together with the refrigerant in the gaseous state compression chamber 11a. To be effectively prevented.

As described above in detail, the compressor suction muffler according to the present invention can effectively suppress the transfer of the liquid refrigerant and the oil in the refrigerant together with the gaseous refrigerant into the compression chamber through the configuration of the compartment and the communication unit. As a result, the refrigerant suction noise of the compressor is reduced, as well as the performance of the compressor is further improved.

Claims (8)

A main body provided to connect the suction pipe of the compressor, a refrigerant inlet chamber formed inside the main body and provided with a refrigerant flowing from the suction pipe to an upper side to a lower side, and the refrigerant inlet to connect the compression chamber of the compressor and the refrigerant inlet chamber A refrigerant outlet tube installed to extend through the upper part of the chamber and extending into the lower part of the refrigerant inlet chamber, and having a lower side opened therein; a resonance chamber provided to be partitioned from the refrigerant inlet chamber in the main body; and the resonance chamber and the refrigerant inlet chamber. And a communicating unit provided in the compartment so that the provided compartment and the refrigerant inlet chamber and the resonance chamber communicate with each other. The coolant inlet chamber of claim 1, wherein the coolant inlet chamber forms a lower space of the coolant inlet chamber and includes a guide chamber for guiding a coolant flowed under the coolant inlet chamber into the coolant outlet tube. Suction muffler for compressor, characterized in that provided in the partition. The method of claim 2, The partition part includes an upper compartment member extending from the upper inner surface of the main body to the lower side, and a lower compartment member extending from the lower inner surface of the main body to the upper side, and the communication unit is provided between the upper and lower compartment members. Suction muffler for compressor. The method of claim 3, wherein The upper compartment member and the lower compartment member are provided to be spaced apart from each other in an intersecting state, and an end of the lower compartment member intersecting the upper compartment member is introduced into the refrigerant rather than an end of the upper compartment member intersected with the lower compartment member. Suction muffler for compressor, characterized in that provided adjacent to the seal. The method of claim 3, wherein Suction muffler for compressor, characterized in that the auxiliary communication portion for communicating the refrigerant inlet chamber and the resonance chamber between the lower compartment member and the main body side of the guide chamber. The method of claim 5, The auxiliary communication unit is a suction muffler for the compressor, characterized in that provided along the longitudinal direction of the lower partition member to communicate with the communication unit. The method of claim 1, The resonance chamber side main body has a first discharge hole for discharging the liquid refrigerant and oil contained in the refrigerant to the outside of the main body is provided with a compressor muffler. The method of claim 7, wherein The guide chamber side main body has a second discharge hole for discharging the liquid refrigerant and oil contained in the refrigerant to the outside of the main body is provided with a compressor muffler.

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