CN217952771U - Efficient liquid storage device with heat regeneration function - Google Patents

Abstract

The utility model provides a take high-efficient reservoir of backheat belongs to reservoir technical field, includes barrel, closing cap, support frame, pipette, filter screen and heat exchange tube. The utility model discloses set up the heat exchange tube in the accumulator jar internal, the partial heat in the liquid refrigerant can be taken away to the gaseous state refrigerant in the heat exchange tube, makes the liquid refrigerant temperature lower, makes driver's cabin refrigeration efficiency higher after getting into the evaporimeter, and the temperature is lower, and refrigeration effect is better. The gaseous refrigerant absorbs a part of the heat, so that the dryness of the gaseous refrigerant is better, and the liquid impact of the compressor is avoided. The heat energy converted mutually can be fully utilized during heating so as to improve the efficiency of the heat pump system.

Description

Efficient liquid storage device with heat regeneration function

Technical Field

The utility model belongs to the technical field of the reservoir, especially, relate to a take high-efficient reservoir of backheat.

Background

The liquid storage device is assembled between the air conditioner condenser and the expansion valve and has the functions of liquid storage, filtration and water absorption. The existing liquid storage devices have no heat exchange function and do not fully utilize waste heat, so that the refrigeration and heating efficiency is very low.

Therefore, there is a need in the art for a new solution to solve this problem.

SUMMERY OF THE UTILITY MODEL

The utility model aims to solve the technical problem that: the utility model provides a high-efficient reservoir of taking backheat is used for solving current reservoir and all does not have the heat transfer function, therefore heat pump system's the technical problem of inefficiency.

A high-efficiency liquid accumulator with heat recovery comprises a cylinder body, a sealing cover, a supporting frame, a liquid suction pipe, a filter screen and a heat exchange pipe, wherein an upper opening of the cylinder body is fixedly connected with the sealing cover, and a gaseous refrigerant outlet is formed in the bottom of the cylinder body; the sealing cover is provided with a gas-liquid refrigerant inlet, a liquid refrigerant outlet and a gaseous refrigerant inlet; the support frame is fixedly arranged in the barrel body, and a hollow structure and a part mounting hole are formed in the support frame; the upper port of the pipette is inserted into the seal cover and is fixedly connected with the liquid refrigerant outlet, the lower end of the pipette is sleeved with the filter screen and then is abutted against the part mounting hole of the support frame, and the lower port of the pipette is communicated with the inside of the barrel; the upper port of the heat exchange tube is inserted into the sealing cover and fixedly connected with the gaseous refrigerant inlet, the lower port of the heat exchange tube is inserted into the bottom of the barrel and fixedly connected with the gaseous refrigerant outlet, and the tube body of the heat exchange tube penetrates through the component mounting hole of the support frame.

And sealing rings are arranged at the splicing part of the heat exchange tube and the sealing cover and the splicing part of the heat exchange tube and the barrel.

And the outer wall of the heat exchange tube is bundled with a molecular sieve.

Fins are arranged on the side wall of the heat exchange tube along the radial direction.

Through the above design scheme, the utility model discloses following beneficial effect can be brought:

1. the utility model discloses set up the heat exchange tube in the accumulator jar internal, the partial heat in the liquid refrigerant can be taken away to the gaseous state refrigerant in the heat exchange tube, makes the liquid refrigerant temperature lower, makes driver's cabin refrigeration efficiency higher after getting into the evaporimeter, and the temperature is lower, and refrigeration effect is better.

2. The gaseous refrigerant absorbs a part of heat, so that the dryness of the gaseous refrigerant is better, and the liquid impact of the compressor is avoided.

3. The heat energy converted mutually can be fully utilized during heating so as to improve the efficiency of the heat pump system.

Drawings

The invention is further described with reference to the following drawings and detailed description:

fig. 1 is a schematic structural view of the regenerative efficient liquid storage device of the present invention.

Fig. 2 is the structure schematic diagram of the utility model relates to a take high-efficient reservoir middle barrel of backheating.

Fig. 3 is a schematic view of the overlooking structure of the drum body in the regenerative high-efficiency liquid accumulator of the present invention.

Fig. 4 is a schematic structural diagram of the support frame in the high-efficiency regenerative liquid storage device of the present invention.

Fig. 5 is a schematic view of the top-view structure of the support frame in the regenerative high-efficiency liquid storage device of the present invention.

Fig. 6 is a schematic structural diagram of a heat exchange tube in a regenerative high-efficiency liquid reservoir of the present invention.

Fig. 7 is a schematic view of the overlooking structure of the heat exchange tube in the regenerative high-efficiency liquid storage device of the utility model.

Fig. 8 is a schematic structural view of the sealing cover in the regenerative efficient liquid storage device of the present invention.

Fig. 9 is a schematic top view of the capping in the regenerative high-efficiency reservoir of the present invention.

Fig. 10 is a schematic structural diagram of a pipette in the regenerative efficient liquid storage device of the present invention.

In the figure, 1-cylinder, 2-sealing cover, 3-supporting frame, 4-pipette, 5-filter screen, 6-heat exchange tube, 7-sealing ring, 8-molecular sieve, 9-fin, 101-gaseous refrigerant outlet, 201-gas-liquid refrigerant inlet, 202-liquid refrigerant outlet, 203-gaseous refrigerant inlet, 301-hollow structure and 302-part mounting hole.

Detailed Description

As shown in the figure, the high-efficiency liquid accumulator with the heat recovery function comprises a cylinder body 1, a sealing cover 2, a support frame 3, a liquid suction pipe 4, a filter screen 5 and a heat exchange pipe 6, wherein an opening at the upper part of the cylinder body 1 is fixedly connected with the sealing cover 2, and a gaseous refrigerant outlet 101 is formed in the bottom of the cylinder body 1; the cover 2 is provided with a gas-liquid refrigerant inlet 201, a liquid refrigerant outlet 202 and a gas refrigerant inlet 203; the support frame 3 is fixedly arranged inside the cylinder body 1, and a hollow structure 301 and a component mounting hole 302 are arranged on the support frame 3; the upper port of the pipette 4 is inserted into the seal cover 2 and fixedly connected with the liquid refrigerant outlet 202, the lower end of the pipette 4 is sleeved with the filter screen 5 and then abutted against the part mounting hole 302 of the support frame 3, the lower port of the pipette 4 is communicated with the inside of the barrel 1, and two ends of the pipette 4 are provided with bulges for fixing; the upper port of the heat exchange tube 6 is inserted into the sealing cover 2 and fixedly connected with the gaseous refrigerant inlet 203, the lower port of the heat exchange tube 6 is inserted into the bottom of the cylinder 1 and fixedly connected with the gaseous refrigerant outlet 101, and the tube body of the heat exchange tube 6 penetrates through the component mounting hole 302 of the support frame 3.

And sealing rings 7 are arranged at the splicing part of the heat exchange tube 6 and the sealing cover 2 and the splicing part of the heat exchange tube 6 and the barrel 1.

The molecular sieve 8 is bound on the outer wall of the heat exchange tube 6, and the molecular sieve 8 has a water absorption effect, so that the moisture in an air conditioning system is prevented from being frozen to cause 'ice blockage'. The binding belt is tied to a certain height, and can absorb water in gas and liquid at the same time.

The side wall of the heat exchange tube 6 is uniformly provided with fins 9 along the radial direction, so that the heat exchange area is increased, and the heat exchange efficiency is improved.

The working principle is as follows:

the gas-liquid mixed refrigerant enters the cylinder 1 from the gas-liquid refrigerant inlet 201, and after oscillation, the liquid exists at the bottom of the cylinder 1, passes through the filter screen 5, then enters the evaporator through the liquid suction pipe 4 and the liquid refrigerant outlet 202 through the expansion valve, and the high-efficiency refrigeration is completed.

The gaseous refrigerant enters the heat exchange tube 6 through the gaseous refrigerant inlet 203, takes away part of heat of the liquid refrigerant, enables the gaseous refrigerant to be gasified better, enters the compressor, and prolongs the service life of the compressor.

Claims (4)

1. The utility model provides a high-efficient reservoir of area backheat which characterized by: the heat exchange tube comprises a tube body (1), a sealing cover (2), a support frame (3), a liquid suction tube (4), a filter screen (5) and a heat exchange tube (6), wherein an upper opening of the tube body (1) is fixedly connected with the sealing cover (2), and a gaseous refrigerant outlet (101) is formed in the bottom of the tube body (1); the sealing cover (2) is provided with a gas-liquid refrigerant inlet (201), a liquid refrigerant outlet (202) and a gas refrigerant inlet (203); the support frame (3) is fixedly arranged inside the barrel body (1), and a hollow structure and a component mounting hole are formed in the support frame (3); the upper port of the pipette (4) is inserted into the sealing cover (2) and is fixedly connected with the liquid refrigerant outlet (202), the filter screen (5) is sleeved outside the lower end of the pipette (4) and then is abutted against the part mounting hole of the support frame (3), and the lower port of the pipette (4) is communicated with the inside of the barrel (1); the upper port of the heat exchange tube (6) is inserted into the sealing cover (2) and fixedly connected with the gaseous refrigerant inlet (203), the lower port of the heat exchange tube (6) is inserted into the bottom of the barrel (1) and fixedly connected with the gaseous refrigerant outlet (101), and the tube body of the heat exchange tube (6) penetrates through the component mounting hole of the support frame (3).

2. The regenerative efficient accumulator of claim 1, wherein: and sealing rings (7) are arranged at the splicing parts of the heat exchange tube (6) and the sealing cover (2) and the splicing parts of the heat exchange tube (6) and the barrel body (1).

3. The regenerative efficient accumulator of claim 1, wherein: and the outer wall of the heat exchange tube (6) is bundled with a molecular sieve (8).

4. The regenerative efficient accumulator of claim 1, wherein: and fins (9) are arranged on the side wall of the heat exchange tube (6) along the radial direction.

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