KR100214833B1 - Condenser integrating receiver and dryer - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a receiver and drier integrated condenser (also referred to as a 'condenser') constituting an air conditioner for an automobile, comprising: refrigerant tubes arranged in parallel at predetermined intervals; A receiver and dryer-integrated condenser composed of heat dissipation fins arranged between the refrigerant tubes and inlet and outlet condenser heads respectively provided at both end portions of the refrigerant tube, wherein the receiver and dryer-integrated condenser comprises a predetermined center in the outlet condenser head. A coolant flow path having a predetermined length formed between the inner and outer intermediate partitions, the inner and outer intermediate partitions each having a pore group formed on the lower part and the upper part, respectively, and fixed at intervals of the inner and outer intermediate partitions A condenser head and a receiver and a dryer, respectively formed on both sides, and a filter and a desiccant therein. By including the receiver and dryer case housed in the bur and dryer unit, the heat of the outlet condenser head is transferred to the receiver and dryer with reduced heat, thereby realizing high heat exchange efficiency, and additional brazing and bolting operations By excluding the etc., the manufacturing process is more easily and easily contributed to the improvement of productivity.

Description

Receiver and dryer integrated condenser

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a condenser (referred to as a 'condenser') in which a receiver and a drier are integrally integrated in an air conditioner for lowering the vehicle's internal temperature and maintaining a comfortable environment in the vehicle. More specifically, the receiver end enables high heat exchange efficiency by transferring heat to the receiver and dryer in a state where the heat of the outlet condenser head is reduced, and also contributes to productivity improvement by making the manufacturing process simpler and easier. It relates to a dryer integrated capacitor.

Generally, a low heat source is required for cooling, but as a low heat source of an automotive air conditioner, a liquid called zircol ziflool methane is used to take heat away from the surroundings. When such a liquid is called a refrigerant | coolant, it is chosen that it is harmless, chemically stable, relatively inexpensive, and has a high ability to take heat away.

In order to continuously obtain a low heat source using a refrigerant, it is necessary to liquefy the vaporized refrigerant once again. For reference, the refrigeration cycle shown in FIG. 1, that is, the compressor (1) → condenser (2) → expansion valve (3). → The evaporator 4 → The method of repeating liquefaction and vaporization through the circulation path which consists of the compressor 1 is adopted. This approach is called a vapor compression refrigeration cycle.

2 is a diagram illustrating a refrigerant flow path of a refrigeration cycle applied to a typical vehicle, and FIG. 3 is a diagram illustrating a refrigerant cycle applied to a typical vehicle, in which 1 is a compressor, 2 is a condenser, and 3 is an expansion. A valve, 4 is an evaporator, 5 is a receiver and drier, respectively.

The compressor 1 sucks the refrigerant, compresses the refrigerant to high temperature and high pressure, and sends the refrigerant to the condenser 2.

The condenser 2 includes refrigerant tubes 21 arranged in parallel at predetermined intervals, heat dissipation fins 22 arranged between the refrigerant tubes 21, and both end portions of the refrigerant tubes 21. Condensation heads (23, 24) are respectively installed in the role to liquefy the refrigerant gas of high temperature, high pressure, and is usually installed on the front of the radiator, so as to be cooled by the air and radiator fan by the progress of the car It is.

The receiver and dryer 5 temporarily stores the refrigerant liquefied by the condenser 2 to remove moisture and dust in the liquid, and a filter and a moisture absorbent are enclosed therein.

The expansion valve (3) causes the liquid refrigerant flowing through the receiver and dryer (5) to be injected from the small hole to expand rapidly, and to convert to a low-temperature, low-pressure free phase refrigerant. It senses the temperature inside the car with a heat sink and increases or decreases the opening and closing of the valve.

In addition, the evaporator 4 causes the refrigerant passing through the expansion valve 3 to evaporate and vaporize, thereby depriving the surrounding air of heat. Therefore, passing the compartment air to the evaporator 4 performs the cooling and dehumidification.

Referring to the circulating action of the refrigerant by the refrigerating cycle as described above as follows.

First, the refrigerant gas is sucked from the evaporator 4 into the compressor 1, and is compressed by a normal compression action inside the compressor 1 to obtain a gas state of high temperature and high pressure (about 70 ° C., 15 kgf / cm ² ). It becomes

The high-temperature and high-pressure refrigerant gas is sent to the condenser 2, whereby it is forcedly cooled by the outside air, a radiator fan, and the like to liquefy.

Thereafter, the liquefied refrigerant flows into the receiver and dryer 5 to remove moisture and dust, and then collects the refrigerant condensed in the receiver and dryer 5 and flows into the expansion valve 3 in a liquid state.

In the expansion valve 3, the high-pressure liquid refrigerant rapidly expands, enters the evaporator 4 in a low temperature, low pressure fog state.

As such, the refrigerant introduced into the evaporator 4 takes heat from the surrounding air through the blower fan to cool the surroundings of the evaporator 4 as vaporization occurs, and the evaporator 4 from the misty refrigerant to the gas state. And exits and is sucked back into the compressor (1).

In this way, the refrigerant circulates through the refrigerant cycle and performs a cooling operation.

On the other hand, in recent years, in order to reduce the volume of the automobile engine room, reduce the number of manufacturing processes, and realize modularization of parts, as shown in FIG. 4, the receiver and dryer 70 is integrated on one side of the condenser 60. The technology that let you know is known.

According to the drawings, the condenser 60 includes a coolant tube 61 arranged in parallel at a predetermined interval, a heat dissipation fin 62 arranged between the coolant tube 61, and the coolant tube 61. The inlet and outlet side condenser heads 63 and 64 are respectively provided at both ends of the side wall, and the receiver and dryer 70 are integrally formed with the outlet side condenser head 64.

Although the outlet side condenser head 64 and the receiver and dryer 70 are not shown in detail in the drawings, they are formed separately, and after brazing welding, are firmly fixed to each other by welding and bolting operations.

In the intermediate plate 80 partitioning the outlet side condenser head 64 and the receiver and dryer 70, a plurality of through holes 81 are formed to enable the flow of the refrigerant, and the receiver and the dryer 70. The outlet pipe 71 is provided in the lower end part of), and is comprised so that it may be guided to an expansion valve through the outlet pipe 71. As shown in FIG.

Reference numeral 91 in the figure shows an inlet pipe installed on the inlet side condenser head 63.

The receiver and dryer integrated capacitor 60 according to the related art, which is configured as described above, has various advantages in that various types of designs are possible in addition to the advantages of reducing the volume of the automobile engine room, reducing the number of manufacturing processes, and realizing the modularization of parts. There is this.

According to the receiver and dryer integrated condenser 60 described above, since the receiver and dryer 70 is fixed to the outlet condenser head 64, the refrigerant flowing into the outlet condenser head 64 is partitioned. Through the through hole 81 of the receiver and the dryer 70 is introduced, the moisture and dust is removed from the inside of the receiver and the dryer 70, and then discharged through the outlet pipe 71 to the expansion valve.

However, in the receiver and dryer integrated capacitor according to the prior art as described above, since the receiver and dryer 70 is integrally formed in the outlet condenser head 64, the flow path of the refrigerant is very short, and thus the refrigerant Is flowed into the receiver and dryer 70 along the short flow path, and the high heat of the refrigerant is transferred directly from the outlet condenser head 64 to the receiver and dryer 70, so that the liquid is in the supercooled state in the receiver and dryer 70. There is a problem that the refrigerant is not evaporated again, or the subcooling itself does not occur well, such that the flow of the refrigerant is not smooth, which acts as a factor to lower the heat exchange efficiency.

In addition, the outlet condenser head 64 and the receiver and dryer 70 must be separately formed, and a separate brazing operation and bolting are performed to fix the receiver and dryer 70 to the outlet condenser head 64. As the work is required, not only the work efficiency is lowered as a whole, but also the productivity is greatly reduced due to the increase in manufacturing cost.

Accordingly, a main object of the present invention is to provide a receiver and dryer integrated capacitor capable of realizing high heat exchange efficiency by transferring heat to the receiver and dryer with reduced heat of the condenser head.

It is still another object of the present invention to provide a receiver and dryer-integrated condenser that makes the manufacturing process simpler and easier to contribute greatly to productivity improvement.

1 is a schematic configuration diagram of a general refrigeration cycle.

2 is a block diagram illustrating a refrigerant flow path of a refrigeration cycle applied to a typical vehicle.

3 is a configuration diagram of a refrigeration cycle applied to a typical vehicle.

Figure 4 is a partial cross-sectional view showing the configuration of a receiver and dryer integrated capacitor according to the prior art.

5 and 6 show a receiver and dryer integrated capacitor according to the present invention,

5 is a partial cross-sectional view showing a main part configuration.

6 is a cross-sectional view showing the main part configuration.

7 and 8 show the configuration of the middle partition wall constituting the receiver and dryer integrated capacitor according to the present invention,

7 is a perspective view.

8 is a side cross-sectional view.

Explanation of symbols on the main parts of the drawing

100; Receiver and dryer integrated condenser

101; Refrigerant tube 102; Heat dissipation pin

103,104; Inlet and outlet side condenser head

105; Upper head cock 106; Lower head cock

107; Outlet pipes 110, 120; Inner and outer middle bulkhead

111; Lower pores 121; Upper pore

130; Refrigerant flow path 140; Condenser head

150; Receiver and dryer unit 160; Support bulkhead

161; Pore 170; Receiver and dryer case

171; Filter 172; drier

181; Upper head cock 182; Inlet pipe

183; Lower head cock 184; baffler

200; Receiver and dryer

In order to achieve the above object of the present invention, the refrigerant tubes arranged in parallel at a predetermined interval, the heat dissipation fins arranged between the refrigerant tubes, and the inlet and outlet are respectively provided at both ends of the refrigerant tube A receiver and dryer-integrated condenser composed of a side condenser head, comprising: an inner and an outer middle partition wall which is fixed and set at a predetermined interval in an inner middle of the outlet side condenser head, and a pore group is formed on the lower and upper portions, respectively, A refrigerant passage having a predetermined length formed between the outer intermediate partition walls, a condenser head unit and a receiver and dryer unit formed on both sides of the inner and outer intermediate partition walls, and a filter and a desiccant therein, the receiver being provided A receiver comprising a receiver and dryer case housed in an end dryer unit. A burr and dryer integrated condenser is provided.

Hereinafter, the receiver and dryer integrated capacitor according to the present invention will be described according to the embodiment shown in the accompanying drawings.

5 and 6 are a partial cross-sectional view and a cross-sectional view showing the configuration of the main part of the receiver and dryer integrated capacitor according to the present invention, Figures 7 and 8 show the configuration of the intermediate partition constituting the receiver and dryer integrated capacitor according to the present invention. Perspective and side cross-sectional view.

As shown in the drawing, the receiver and dryer integrated capacitor 100 according to the present invention includes a coolant tube 101 arranged in parallel at a predetermined interval and a heat dissipation fin arranged between the coolant tube 101. And the inlet and outlet side condenser heads 103 and 104 which are respectively provided at both ends of the refrigerant tube 101, and include a receiver and a dryer inside the outlet side condenser head 104. 200) is characterized in that the integral configuration.

That is, the receiver and dryer integrated capacitor 60 according to the related art has a structure in which the receiver and dryer 70 is attached and fixed to the side of the outlet condenser head 64, but the receiver and dryer integrated capacitor 100 according to the present invention is fixed. ) Configures the receiver and dryer 200 inside the outlet-side condenser head 104 having a hollow cylindrical shape, which greatly simplifies the external structure, and functions internally of the receiver and dryer 200. It is a technical feature to make full use of.

In more detail, two inner and outer intermediate partitions 110 and 120, which are formed in a rectangular plate shape, are respectively erected and fixed in the inner middle of the outlet-side condenser head 104, respectively.

The inner and outer intermediate partitions 110 and 120 are disposed at a predetermined interval d, and the refrigerant passage 130 between the inner and outer intermediate partitions 110 and 120 to induce the flow of the refrigerant. It is configured to serve as, the interior of the outlet condenser head 104 by the inner and outer intermediate partitions (110, 120) is divided into a condenser head portion 140 and the receiver and dryer unit (150) have.

A plurality of pores 111 and 121 are formed in the inner and outer intermediate partitions 110 and 120. That is, a plurality of pores 111 are formed in a group in a substantially rectangular shape at a lower portion of the inner middle partition wall 110, and a plurality of pores 121 are formed in a substantially rectangular shape at an upper portion of the outer middle partition wall 120. It is formed in a group, and each pore group of the inner and outer intermediate partitions 110 and 120 is formed at a predetermined distance to keep the refrigerant passage 130 long.

In addition, the support partition wall 160 is fixed at right angles to the lower side of the inner side of the inner middle partition wall 110, and the support partition wall 160 penetrates through the outer middle partition wall 120 to exit the condenser head 104. 6, the refrigerant passage 130 and the receiver and dryer unit 150 are bisected by the support partition wall 160 in plan view.

A plurality of pores 161 are formed in the support partition wall 160, and as shown in FIG. 8, the pores 161 of the support partition wall 160 are formed only in a portion of the receiver and dryer unit 150. And is not formed in the portion of the refrigerant passage 130.

The receiver and dryer unit 150 is mounted with a receiver and dryer case 170 in which a filter 171 and a desiccant 172 are stored, and a lower end thereof is supported by the support partition wall 160.

The head cock 105 is covered with an upper portion of the outlet condenser head 104, the head cock 106 is fixedly coupled to the lower portion, and an outlet pipe 107 connected to the expansion valve is connected to the lower end of the outer peripheral surface. It is.

On the other hand, the head cock 181 is covered in the upper part of the inlet condenser head 103, the inlet pipe 182 is connected and fixed to the middle part of the condenser head 181, and the head cock 183 in the lower part. This joint is fixed and the baffle 184 is provided horizontally in the middle inside.

Receiver and dryer integrated condenser 100 according to the present invention is configured as described above to form a refrigeration cycle with an expansion valve, an evaporator and a compressor to perform a normal cooling function of the receiver and dryer integrated condenser 100 The characteristic operation is described as follows.

First, the high temperature and high pressure refrigerant gas that has passed through the compressor is introduced into the inside through the inlet pipe 182 of the inlet condenser head 103. At this time, since the baffle 184 is provided in the horizontal direction in the inner middle of the inlet condenser head 103, the flow of the refrigerant gas is appropriately adjusted.

As such, after the high temperature and high pressure refrigerant gas introduced into the inlet condenser head 103 is forcedly cooled by the outside air and a radiator fan while moving to the outlet condenser head 104 along the coolant tube 101, Passed through the filter 171 and the precursor 172, and thus condensed inside the outlet condenser head 104 and stored in the liquid state, and then transferred to the expansion valve.

In more detail, the refrigerant passing through the inside of the refrigerant tube 101 is discharged by the heat dissipation fin 102 to the outside air and is cooled to the condenser head 140 of the outlet condenser head 104. The refrigerant in the liquid state rises along the refrigerant passage 130 through the lower pores 111 of the inner middle partition wall 110, and receives the receiver and dryer unit through the upper pores 121 of the inner middle partition wall 110. Flows into 150.

As such, the refrigerant gas introduced into the receiver and dryer unit 150 passes through the receiver and dryer case 170 supported on the upper portion of the support partition wall 160, thereby being absorbed by moisture and dust by the desiccant 172 and the filter 171. The back is removed, and the refrigerant is stored in the receiver and dryer 150 and then discharged to the expansion valve through the outlet pipe 107.

At this time, heat transmitted from the coolant tube 101 is blocked by the coolant flow path 130 formed between the inner and outer middle partition walls 110 and 120 so that the receiver and the dryer 70 are not affected by heat. .

As described above, the receiver and dryer integrated capacitor according to the present invention includes a refrigerant tube arranged in parallel at a predetermined interval, a heat dissipation fin arranged between the refrigerant tube, and both ends of the refrigerant tube. A receiver and dryer-integrated condenser composed of inlet and outlet side condenser heads, respectively, which is installed and fixed at predetermined intervals in an inner middle of the outlet side condenser head, and has an inner and outer middle having pore groups formed on the lower and upper portions, respectively. A partition wall, a condenser head portion formed by the inner and outer intermediate partition walls, a coolant flow path and a receiver and dryer unit, and a receiver and dryer case provided with a filter and a desiccant therein and stored in the receiver and dryer unit. The receiver can be configured to reduce heat at the outlet condenser head. High heat exchange efficiency is realized by being delivered to the drier, and the manufacturing process is more easily made by eliminating the separate brazing operation and bolting operation as in the conventional case, thereby greatly contributing to the productivity improvement. .

Claims (4)

A receiver and dryer integrated capacitor comprising a refrigerant tube arranged in parallel at a predetermined interval, heat dissipation fins arranged between the refrigerant tubes, and inlet and outlet side condenser heads respectively provided at both ends of the refrigerant tube. To A refrigerant having a predetermined length formed between the inner and outer middle partition walls, which are erected and fixed at predetermined intervals in the middle of the outlet side condenser head, and have pore groups formed on the lower and upper sides, respectively; And a flow path, a condenser head unit and a receiver and dryer unit formed on both sides of the inner and outer intermediate partition walls, and a receiver and dryer case provided with a filter and a desiccant therein and housed in the receiver and dryer unit. Receiver and dryer integrated condenser. According to claim 1, wherein the support partition wall passing through the outer intermediate partition wall is fixed to the lower side of the inner intermediate partition, the refrigerant flow path and the receiver and dry portion is divided into two, the receiver and dryer case is supported on the upper end of the support partition wall Receiver and dryer integrated condenser. The receiver and dryer integrated capacitor of claim 2, wherein several pores are formed in the support partition wall. The receiver and dryer integrated capacitor according to claim 1, wherein the outlet condenser head has a cylindrical shape.

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