JP2018054213A - accumulator - Google Patents

Abstract

PROBLEM TO BE SOLVED: To devise a routing structure of an outlet pipe of an accumulator to reduce vibration noise due to vibration from a compressor.SOLUTION: An outlet pipe (25) of an accumulator (20) includes a first pipe part (25a), a second pipe part (25b), and a third pipe part (25c). The first pipe part (25a) vertically extends in a sealed container (21), and penetrates each of the upper part and lower part of the sealed container (21, and an upper end part thereof is connected to a suction side of a compressor (8). The second pipe part (25b) vertically extends in the sealed container (21), an upper end part thereof is opened to the inside of the sealed container (21), and a lower end part thereof penetrates the lower part of the sealed container (21). The third pipe part (25c) connects between the lower end part of the first pipe part (25a) and the lower end part of the second pipe part (25b).SELECTED DRAWING: Figure 2

Description

  The present invention relates to an accumulator.

  Conventionally, an accumulator that temporarily stores a refrigerant flowing through a refrigerant circuit is known (see, for example, Patent Document 1).

  Patent Document 1 discloses a configuration in which the outlet pipe of the accumulator is bent in a zigzag shape in order to attenuate the vibration transmitted from the compressor to the accumulator through the outlet pipe.

  However, in the configuration of Patent Document 1, since the entire length of the outlet pipe becomes long, generation of vibration sound due to vibration of the outlet pipe increases, and there is a concern about deterioration of the stress of the outlet pipe.

  Therefore, the inventors of the present application, as shown in FIG. 3, after the outlet pipe (25) of the accumulator (20) penetrates the lower part of the sealed container (21), the upper part along the outer surface of the sealed container (21) In the routing structure that is bent in a straight line, it was considered to attach a damping weight (40) in the middle of the outlet pipe (25). Thereby, the vibration transmitted from the compressor through the outlet pipe (25) is suppressed. The outlet pipe (25) is fastened and fixed to the sealed container (21) by a fastening band (41).

Japanese Utility Model Publication No. 1-19876

  By the way, the outlet pipe (25) of the accumulator (20) is generally composed of a copper pipe, and if the fastening force of the fastening band (41) is too strong, the copper pipe may be deformed. Therefore, the outlet pipe (25) is held in the sealed container (21) in a state where the tightening force of the fastening band (41) is set somewhat loose.

  Therefore, vibration cannot be reliably suppressed in the portion from the lower part of the accumulator (20) to the fastening band (41) in the outlet pipe (25), and vibration noise may be generated. 40) is installed.

  However, since it is costly to attach the weight (40) separately to the outlet pipe (25), a measure that can reduce the vibration noise of the outlet pipe (25) without using the weight (40) is desired. It was.

  This invention is made in view of this point, and the objective is to make it possible to reduce the vibration sound by the vibration from a compressor by devising the wiring structure of the outlet pipe of an accumulator. .

  The present invention provides a sealed container (21) for temporarily storing refrigerant before being sucked into the compressor (8), and the refrigerant in the sealed container (21) connected to the compressor (8). The following solution was taken for an accumulator equipped with an outlet pipe (25) that flows into the compressor (8).

That is, in the first invention, the outlet pipe (25)
A first pipe part (25a) extending vertically in the sealed container (21) and penetrating the upper and lower parts of the sealed container (21);
A second pipe portion (25b) that extends vertically in the sealed container (21) and whose upper end opens into the sealed container (21) and whose lower end penetrates the lower portion of the sealed container (21) When,
It has a 3rd pipe part (25c) which connects the lower end part of the said 1st pipe part (25a), and the lower end part of the said 2nd pipe part (25b), It is characterized by the above-mentioned.

  In the first invention, the outlet pipe (25) has a first pipe part (25a), a second pipe part (25b), and a third pipe part (25c). The first pipe portion (25a) extends vertically in the sealed container (21), and its upper end penetrates the upper portion of the sealed container (21) and is connected to the suction side of the compressor (8).

  Thus, by devising the arrangement structure of the outlet pipe (25) of the accumulator (20), it is possible to reduce vibration noise due to vibration from the compressor (8).

  Specifically, when the outlet pipe (25) has a shape bent upward along the outer surface of the sealed container (21) after passing through the lower part of the sealed container (21), the compressor (8 ) Is transmitted to the outlet pipe (25), and the portion of the outlet pipe (25) extending upward along the outer surface of the hermetic container (21) vibrates to generate vibration noise.

  On the other hand, in the present invention, the outlet pipe (25) is routed so as to pass through the sealed container (21) after being pulled out so as to penetrate the lower part of the sealed container (21), and the sealed container ( It is fixed to the upper part of 21) by brazing, for example.

  Thereby, the vibration transmitted from the compressor (8) through the outlet pipe (25) is cut off at the upper part of the sealed container (21), and the first pipe part routed in the sealed container (21). (25a) can be suppressed from vibrating. Even if the first pipe part (25a) vibrates, the first pipe part (25a) is accommodated in the sealed container (21), so that the sealed container (21) functions as a soundproof wall, It is possible to insulate the vibration sound of the first pipe part (25a) from leaking outside.

The second invention is as defined in claim 1,
An oil return pipe (28) for separating the oil separated from the refrigerant and stored in the lower part of the sealed container (21) into the outlet pipe (25);
An on-off valve (29) connected to the oil return pipe (28) to allow or block the flow of oil;
The oil return pipe (28) is connected so as to connect the lower part of the hermetic container (21) and the third pipe part (25c).

  In the second invention, the oil return pipe (28) communicates the lower part of the sealed container (21) with the third pipe part (25c) disposed below the lower part of the sealed container (21). Yes. As a result, when the on-off valve (29) is opened, the oil in the sealed container (21) flows out to the third pipe part (25c) by its own weight, and the oil is smoothly returned to the outlet pipe (25). Can do.

  ADVANTAGE OF THE INVENTION According to this invention, the vibration sound by the vibration from a compressor can be reduced by devising the wiring structure of the outlet pipe of an accumulator.

It is a refrigerant circuit figure of the air harmony device concerning this embodiment. It is a longitudinal cross-sectional view which shows the structure of an accumulator. It is a longitudinal cross-sectional view which shows the structure of the conventional accumulator.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. It should be noted that the following description of the preferred embodiment is merely illustrative in nature and is not intended to limit the present invention, its application, or its use.

<Configuration of air conditioner>
As shown in FIG. 1, the air conditioner (1) is a device capable of cooling and heating a room such as a building by performing a vapor compression refrigeration cycle. The air conditioner (1) is mainly configured by connecting a heat source unit (2) and two utilization units (3). In addition, the number of utilization units (3) is an example, and is not limited to this.

  Here, the heat source unit (2) and the two utilization units (3) are connected via the liquid refrigerant communication pipe (4) and the gas refrigerant communication pipe (5). That is, the vapor compression refrigerant circuit (6) of the air conditioner (1) includes a heat source unit (2) and a utilization unit (3), a liquid refrigerant communication pipe (4) and a gas refrigerant communication pipe (5). It is comprised by connecting via.

  The heat source unit (2) is installed outside the indoor space (the roof of the building, the vicinity of the wall of the building, or the machine room), and constitutes a part of the refrigerant circuit (6). The heat source unit (2) mainly includes a compressor (8), an oil separator (9), a four-way switching valve (10), a heat source side heat exchanger (11), and a heat source side expansion valve (12). And a liquid side closing valve (13), a gas side closing valve (14), a heat source side fan (15), and an accumulator (20).

  The compressor (8) is a fluid machine for compressing a refrigerant, and is constituted by, for example, a high-pressure dome type scroll compressor. The discharge pipe (16) of the compressor (8) is connected to the first port of the four-way switching valve (10). An oil separator (9) is connected in the middle of the discharge pipe (16). The oil separator (9) separates the refrigeration oil from the refrigerant discharged from the compressor (8). The refrigerating machine oil separated by the oil separator (9) is returned to the suction side of the compressor (8) through the capillary tube (9a).

  A suction pipe (hereinafter referred to as an outlet pipe (25) of the accumulator (20) in the present embodiment) of the compressor (8) is connected to the accumulator (20). The accumulator (20) temporarily stores the refrigerant before being sucked into the compressor (8). Details of the accumulator (20) will be described later.

  The four-way selector valve (10) includes a state in which the first port and the second port and the third port and the fourth port communicate with each other (a state indicated by a solid line in FIG. 1), a first port and a third port, The second port and the fourth port can be switched to a state in which the second port and the fourth port communicate with each other (a state indicated by a dotted line in FIG. 1), and the usage unit (3) is cooled or heated by switching the flow direction of the refrigerant. Let it run.

  The first port of the four-way selector valve (10) and the compressor (8) are connected by a discharge pipe (16). The second port of the four-way selector valve (10) and the heat source side heat exchanger (11) are connected by a gas pipe (17). The third port of the four-way selector valve (10) and the gas-side stop valve (14) are connected by a gas pipe (18). The fourth port of the four-way selector valve (10) and the accumulator (20) are connected by an inlet pipe (22).

  The heat source side heat exchanger (11) is composed of, for example, a cross fin type fin-and-tube heat exchanger. A heat source side fan (15) is provided in the vicinity of the heat source side heat exchanger (11). The heat source side heat exchanger (11) is configured such that the refrigerant exchanges heat with the air taken in by the heat source side fan (15).

  The heat source side heat exchanger (11) and the liquid side shut-off valve (13) are connected by a liquid pipe (19). A heat source side expansion valve (12) is connected in the middle of the liquid pipe (19). The heat source side expansion valve (12) is an electronic expansion valve.

  The utilization unit (3) is installed indoors (such as a living room or a ceiling space) and constitutes a part of the refrigerant circuit (6). The utilization unit (3) mainly has a utilization side expansion valve (31), a utilization side heat exchanger (32), and a utilization side fan (33).

  The liquid refrigerant communication pipe (4) and the gas refrigerant communication pipe (5) are refrigerant pipes that are constructed on site when the air conditioner (1) is installed at an installation location such as a building. One end of the liquid refrigerant communication pipe (4) is connected to the liquid side shutoff valve (13) of the heat source unit (2), and the other end of the liquid refrigerant communication pipe (4) is the usage side expansion valve of the usage unit (3). It is connected to the liquid side end of (31).

  One end of the gas refrigerant communication pipe (5) is connected to the gas side shut-off valve (14) of the heat source unit (2), and the other end of the gas refrigerant communication pipe (5) is used on the usage side heat exchange of the usage unit (3). Connected to the gas side end of the vessel (32).

  The use side heat exchanger (32) is constituted by, for example, a cross fin type fin-and-tube heat exchanger. The use side expansion valve (31) is an electronic expansion valve. A use side fan (33) is provided in the vicinity of the use side heat exchanger (32). And the utilization side heat exchanger (32) is comprised so that a refrigerant | coolant may heat-exchange with the air taken in by the utilization side fan (33).

  Each device and each valve of the heat source unit (2) and the utilization unit (3) are controlled by the controller (30).

<Structure of accumulator>
As shown in FIG. 2, the accumulator (20) includes a sealed container (21), an inlet pipe (22) through which the refrigerant flows into the sealed container (21), and an outlet pipe through which the refrigerant flows out from the sealed container (21). (25) and the refrigerating machine oil stored in the sealed container (21) is returned to the outlet pipe (25), and the oil return pipe (28) is smaller in diameter than the outlet pipe (25).

  The hermetic container (21) temporarily stores the refrigerant before being sucked into the compressor (8), and gas-liquid separates the liquid refrigerant and the refrigerating machine oil contained in the refrigerant gas. The sealed container (21) includes a vertical cylindrical portion (21a) extending in the vertical direction, an upper end plate (21b) that closes the upper opening of the cylindrical portion (21a), and a lower end plate that closes the lower opening of the cylindrical portion (21a). (21c).

  The lower end plate (21c) of the hermetic container (21) is provided with three support legs (23) at intervals in the circumferential direction. The sealed container (21) is supported above the floor surface by the support legs (23), and a gap is provided between the lower end plate (21c) and the floor surface.

  The inlet pipe (22) is constituted by a copper pipe, and an iron tubular body (26) is brazed to a part thereof. The hermetic container (21) is made of, for example, stainless steel. Then, the inlet pipe (22) is passed through the upper part of the sealed container (21), specifically, the substantially center position of the upper end plate (21b), and the cylindrical body (26) of the inlet pipe (22) is By brazing the end plate (21b), the inlet pipe (22) is attached to the upper part of the sealed container (21). The lower end of the inlet pipe (22) opens at a position closer to the upper part in the internal space (S) of the sealed container (21).

  The outlet pipe (25) is hermetically sealed with the first pipe part (25a) extending vertically in the sealed container (21) and penetrating the upper end plate (21b) and the lower end plate (21c) of the closed container (21). The container (21) extends vertically and its upper end opens into the internal space (S) of the sealed container (21) and its lower end penetrates the lower end plate (21c) of the sealed container (21). A second pipe part (25b) and a third pipe part (25c) arranged outside the sealed container (21) and connecting the lower end part of the first pipe part (25a) and the lower end part of the second pipe part (25b); Have

  The upper end of the first pipe part (25a) is connected to the suction side of the compressor (8). The upper end of the second pipe part (25b) opens at a position closer to the upper part in the inner space (S) of the sealed container (21), and the inner space (S of the sealed container (21) from the inlet pipe (22). ) The refrigerant that has flowed into the second pipe portion (25b) is sucked into the second pipe portion (25b). The third pipe portion (25c) is routed below the lower portion of the sealed container (21), that is, in the gap between the lower end plate (21c) lifted by the support leg (23) and the floor surface.

  In this embodiment, the first pipe part (25a), the second pipe part (25b), and the third pipe part (25c) are bent by bending one outlet pipe (25) into a U shape. The outlet pipe (25) is formed, but each may be constituted by separate members and combined, and may be integrally formed by brazing or the like.

  Similarly to the inlet pipe (22), the outlet pipe (25) is made of a copper pipe. The upper pipe and the lower part of the first pipe part (25a) and the lower part of the second pipe part (25b) are made of iron. The cylindrical body (26) is brazed. The outlet pipe (25) is attached to the sealed container (21) by brazing the cylindrical body (26) of the outlet pipe (25) to the upper end plate (21b) and the lower end plate (21c), respectively. .

  Thus, after the outlet pipe (25) is drawn out so as to penetrate the lower part of the sealed container (21), it is routed so as to pass through the sealed container (21) again, and the upper part of the sealed container (21). For example, since it is fixed by brazing, vibration noise due to vibration from the compressor (8) can be reduced.

  That is, the vibration transmitted from the compressor (8) through the outlet pipe (25) is cut off at the upper part of the sealed container (21), and the first pipe part (25a) routed in the sealed container (21). ) Can be suppressed. Even if the first pipe part (25a) vibrates, the first pipe part (25a) is accommodated in the sealed container (21), so that the sealed container (21) functions as a soundproof wall, It is possible to insulate the vibration sound of the first pipe part (25a) from leaking outside.

  As shown in FIG. 1, the oil return pipe (28) is provided at the lower part of the sealed container (21), specifically, at the substantially center position of the lower end plate (21c) and the third pipe part of the outlet pipe (25). (25c) is connected. In the middle of the oil return pipe (28), an on-off valve (29) that allows or blocks the flow of the refrigerating machine oil is connected. The on-off valve (29) may be constituted by an electronic expansion valve.

  Thus, by connecting the lower part of the sealed container (21) and the third pipe part (25c) arranged below the lower part of the sealed container (21) by the oil return pipe (28), When the on-off valve (29) is opened, the refrigeration oil in the sealed container (21) flows out to the third pipe (25c) by its own weight, and the refrigeration oil can be smoothly returned to the outlet pipe (25). it can.

  As described above, the present invention is extremely useful because it is possible to reduce the vibration noise caused by the vibration from the compressor by devising the arrangement structure of the outlet pipe of the accumulator. Industrial applicability is high.

8 Compressor
20 Accumulator
21 Airtight container
25 Outlet pipe
25a 1st pipe
25b Second pipe
25c 3rd pipe section
28 Oil return pipe
29 On-off valve

Claims (2)

A sealed container (21) for temporarily storing refrigerant before being sucked into the compressor (8), and the refrigerant in the sealed container (21) connected to the compressor (8) is transferred to the compressor (8 And an outlet pipe (25) to be discharged into the accumulator,
The outlet pipe (25)
A first pipe part (25a) extending vertically in the sealed container (21) and penetrating the upper and lower parts of the sealed container (21);
A second pipe portion (25b) that extends vertically in the sealed container (21) and whose upper end opens into the sealed container (21) and whose lower end penetrates the lower portion of the sealed container (21) When,
An accumulator having a third pipe part (25c) connecting the lower end part of the first pipe part (25a) and the lower end part of the second pipe part (25b). In claim 1,
An oil return pipe (28) for separating the oil separated from the refrigerant and stored in the lower part of the sealed container (21) into the outlet pipe (25);
An on-off valve (29) connected to the oil return pipe (28) to allow or block the flow of oil;
The accumulator is characterized in that the oil return pipe (28) is connected so as to connect the lower part of the sealed container (21) and the third pipe part (25c).

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