KR100858514B1 - Receiver drier - integrated condenser - Google Patents

Abstract

The present invention relates to a receiver integrated condenser, the object of which relates to a receiver integrated condenser that can improve the mountability of the condenser to the vehicle. This includes a first header pipe and a second header pipe spaced apart in parallel with the first header pipe, a plurality of tubes installed side by side so that both ends communicate with the first header pipe and the second header pipe, and the tubes A corrugated pin interposed between the plurality of baffles, a plurality of baffles provided inside the first and second header pipes to form a refrigerant flow path, and a separator provided inside the condensation area of the second header pipe to form a separate compartment; And a receiver integrally formed to communicate with one side of the second header pipe, a connection pipe formed in a condensation region and an outlet pipe formed in a supercooling region to connect the second header pipe and a receiver, and the first and second headers. The refrigerant inlet formed in one side of the pipe, the refrigerant outlet formed in the subcooling region of the first header pipe, and the refrigerant introduced into the refrigerant inlet may include a plurality of tubes. A first refrigerant passage is formed while passing through the first refrigerant passage, and the refrigerant passing through the first refrigerant passage is a gaseous refrigerant separated from the separator compartment by passing through a second refrigerant passage formed above the first refrigerant passage. The liquid refrigerant flows into a third refrigerant flow path formed under the first refrigerant flow path and flows through the connecting pipe in the upper compartment of the second header pipe to the receiver, and the refrigerant flowing into the receiver flows through the outlet pipe. It passes through the fourth refrigerant passage in the subcooling region through the discharge to the refrigerant outlet.

Condenser, receiver, refrigerant flow path, separator

Description

Integral condenser with receiver {RECEIVER DRIER-INTEGRATED CONDENSER}

1 is a cross-sectional view of a receiver integrated condenser according to the prior art.

Figure 2 is a cross-sectional view showing one embodiment of a receiver integrated condenser according to the present invention.

3 is a refrigerant flow diagram of FIG.

4 is an exploded perspective view of the separator of the present invention installed.

Figure 5 is a cross-sectional view showing another embodiment of the receiver integrated condenser according to the present invention.

6 is a refrigerant flow diagram of FIG.

(Explanation of symbols for the main parts of the drawing)

10,20: 1st, 2nd header pipe 30: tube

40: corrugated pin 50: baffle

60: separator 70: receiver

80: connection pipe 81: outlet pipe

90: refrigerant inlet 91: refrigerant outlet

The present invention relates to a condenser integrated with a receiver, and more particularly, by installing a separator inside a header pipe, a plurality of pipes and receivers for connecting a header pipe and a receiver while maintaining a refrigerant flow of a conventional multi-stage liquid separation type condenser. The invention relates to a receiver integrated condenser that improves the mountability of a condenser that is not affected by size to a vehicle.

In general, the condenser liquefies by exchanging the high-temperature and high-pressure refrigerant delivered from the compressor to the outside air, and the receiver is installed between the condenser and the expansion valve on the cooling system to transfer the amount of refrigerant liquefied in the condenser to the evaporator according to the cooling load. It is a temporary storage for supply.

In addition, a desiccant and a filter are provided inside the receiver to filter out moisture and impurities contained in the refrigerant.

These condensers and receivers are generally combined in separate forms, but there is a problem in terms of space utilization of a limited engine room. Recently, a receiver integrated condenser in which the condenser and the receivers are integrally provided has been presented. Integral condenser of receiver is multi-stage liquid separation to maximize the condensation effect.

1 is a view showing an embodiment of a conventional receiver integrated condenser, it can be expressed as a multi-stage liquid separation type condenser.

As illustrated, the receiver integrated condenser has a first header pipe 1 and a second header pipe 2 spaced apart in parallel with the first header pipe 1, and both ends of the first and second header pipes ( 1) of the tube (3) installed side by side to communicate with (2), the corgate pin (4) interposed between the tube (3), and the first and second header pipe (1) (2) A plurality of baffles (5) installed inside the fluid passage (6) integrally communicating with the second header pipe (2), the second header pipe (2) and the receiver (6) ) Connecting pipe 7 formed in the condensation region and outlet pipe 7a formed in the subcooling region, refrigerant inlet 8 formed on one side of the first header pipe 1 and the first header pipe 1. And a coolant outlet 8a formed in the subcooling region.

The condenser integrated condenser configured as described above has a refrigerant flow path that flows through the refrigerant inflow passage 8 installed in the middle portion of the first header pipe 1 through the refrigerant inflow passage while the refrigerant in the gas phase rises upward. The condensate is condensed along the refrigerant flow path, while the relatively liquid refrigerant flows downward and condenses along the predetermined refrigerant flow path.

The refrigerant condensed while passing through the refrigerant passages is stored in the receiver 6, where moisture and impurities are removed by a drying material and a filter. The liquid refrigerant stored in the receiver 6 flows through the outlet pipe 7a to be recondensed to form an overcooling region and flows to the expansion valve (not shown) through the refrigerant outlet 8a.

However, the condenser integrated condenser as described above is composed of a plurality of pipes connecting the header pipe and the receiver, that is, two connecting pipes and one outlet pipe, which is a constraint for setting the position of the bracket for mounting on a vehicle.

That is, the vehicle mountability to the condenser was deteriorated by the installation position of the said pipe and the baffle which are provided in the inside of a header pipe and form a compartment.                         

In addition, the length of the receiver also required the same size as the length of the header pipe according to the flow of the coolant, the vehicle wearability is reduced.

The present invention has been made to solve such a conventional problem, and an object thereof is related to a receiver integrated condenser capable of improving the mountability of the condenser on a vehicle.

The present invention for solving the above object is provided in parallel with the first header pipe and the second header pipe spaced apart in parallel to the first header pipe, both ends are in communication with the first header pipe and the second header pipe. A plurality of tubes, corrugated pins interposed between the tubes, a plurality of baffles installed inside the first and second header pipes to form a refrigerant flow path, and installed inside the condensation region of the second header pipe. And a separator to form a separate compartment, a receiver integrally formed to communicate with one side of the second header pipe, a connection pipe formed in a condensation region to connect the second header pipe and a receiver, and an outlet pipe formed in a supercooling region. A coolant inlet formed in one side of the first and second header pipes, a coolant outlet formed in the subcooling region of the first header pipe, and the coolant The refrigerant flowing into the inlet forms a first refrigerant passage while passing through the plurality of tubes, and the refrigerant passing through the first refrigerant passage is a gaseous refrigerant in which gaseous liquid is separated from the separator compartment, and is formed above the first refrigerant passage. Recondensing while passing through the second refrigerant passage, the liquid refrigerant flows to the third refrigerant passage formed below the first refrigerant passage and flows to the receiver through the connection pipe in the upper compartment of the second header pipe, The refrigerant flowing into the receiver passes through the fourth refrigerant passage in the subcooling region through the outlet pipe and is discharged to the refrigerant outlet.

Further, a first header pipe and a second header pipe spaced apart in parallel with the first header pipe, a plurality of tubes installed side by side so that both ends communicate with the first header pipe and the second header pipe, and the tube Corrugated pins interposed between the first and second header pipes, a plurality of baffles are formed inside the first and second header pipes to form a refrigerant flow path, and are formed inside the condensation region of the first header pipe to form a separate compartment. A separator, a receiver integrally formed to communicate with one side of the second header pipe, a single connection pipe formed in a condensation region to connect the second header pipe and the receiver, and an outlet pipe formed in the supercooling region, and the first And a refrigerant inlet formed in one side of the second header pipe, a refrigerant outlet formed in the subcooling region of the first header pipe, and a refrigerant introduced into the refrigerant inlet. The refrigerant is separated up and down by a separator installed inside the pipe, and the first and second refrigerant passages are formed while passing through a plurality of tubes, and the refrigerant passing through the first and second refrigerant passages is the first and second refrigerant passages. After condensing and joining the third refrigerant flow path formed between the flow paths in a zigzag, the liquid flows into the receiver through a single connecting pipe, and the refrigerant in the receiver passes through the fourth refrigerant flow path in the subcooling region through the outlet pipe. To flow through the refrigerant outlet.

In addition, the receiver is size is determined by the installation position of the connecting pipe.                     

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

2 is a cross-sectional view showing an embodiment of a receiver integrated condenser of the present invention.

As shown in the receiver integrated condenser of the present invention, the first header pipe 10 and the second header pipe 20 are spaced apart at regular intervals, the first header pipe 10 and the second header pipe 20 A plurality of tubes (30) are installed side by side between the), and the corgate pin 40 is interposed between the adjacent tubes (30).

A plurality of baffles 50 are installed inside the first and second header pipes 10 and 20, and a separator 60 is installed inside the second header pipe 20 to form a refrigerant flow path.

That is, the first header pipe 10 is divided into four space portions of the upper compartment 11, the middle compartment 12, the lower compartment 13, and the auxiliary compartment 14 by three baffles 50, respectively. The second header pipe 20 is divided into three space portions of the upper compartment 21, the lower compartment 22, and the separator compartment 23 by one baffle 50 and one separator 60, respectively. It is done.

The separator compartment 23 vertically partitions the inside of the upper compartment 21, and a predetermined space is formed at the upper and lower sides of the separator compartment 23 to communicate with each other.

The receiver 70 is integrally communicated with the second header pipe 20. The connection pipe 80 is coupled to the condensation region, and the outlet pipe 81 is coupled to the subcooling region.                     

That is, the connecting pipe 80 communicates with the upper compartment 21, and the outlet pipe 81 communicates with the lower compartment 22.

In addition, the receiver 70 has a size determined by the installation position of the connection pipe 80 irrespective of the length of the second header pipe 20. In the present invention, the receiver 70 has a second length. It is preferable that it is two thirds of the length of the header pipe 20.

The central compartment 12 of the first header pipe 10 is provided with a refrigerant inlet 90 connected to a compressor (not shown), and an expansion valve (not shown) in the auxiliary compartment 14 of the first header pipe 10. Is connected to the refrigerant outlet (91).

Meanwhile, both ends of the first and second header pipes 10 and 20 are sealed by end caps, and a pair of end plates protect the corgate pins 40 disposed at the outermost sides, respectively.

3 is a flow chart of the refrigerant of FIG. 2. Referring to this, the refrigerant flow is described below. The solid arrows in the drawing indicate the flow direction of the gaseous phase refrigerant, and the arrows of the hidden lines indicate the flow direction of the liquid phase refrigerant.

For convenience of explanation, the refrigerant flow paths will be described with reference to the first to fourth refrigerant flow paths.

The refrigerant in the gas phase introduced into the refrigerant inlet 90 undergoes a heat exchange with the outside while flowing through the first refrigerant path P1 to undergo a condensation process. At this time, some of the refrigerant changes to a liquid phase and some remains in a gaseous state.

At this time, the relatively cool refrigerant is moved upward from the separator compartment 23 of the second header pipe 20 to pass through the second refrigerant passage P2 and is turned in the upper compartment 11 of the first header pipe 10. It flows to the upper compartment 21 of the second header pipe 20.

In addition, the heat exchanged while flowing through the first refrigerant flow path (P1), the relatively liquid refrigerant is moved downward by its own weight to pass through the third refrigerant flow path (P3), the lower compartment 13 of the first header pipe (10) U-turn to flow to the upper compartment 21 of the second header pipe (20).

The refrigerant passing through the second and third refrigerant passages P2 and P3 is introduced into the receiver 70 through a connecting pipe 80, and although not shown in the drawings, a filter installed inside the receiver 70 and The desiccant removes impurities and moisture.

The liquid refrigerant stored in the receiver 70 passes through the fourth refrigerant flow path P4 through the outlet pipe 81, and in the process, recondenses the liquid refrigerant to achieve a supercooled state. By lowering the discharge temperature of 91, the refrigerant efficiency is improved.

4 is an exploded perspective view of a state where the separator of the present invention is installed.

As shown in the drawing, the second header pipe 20 includes two components, a header 20a and a tank 20b, and the separator 60 includes a vertical plate 61 and a horizontal plate 62. The radius of curvature of the inner circumferential surface of the header 20a and the horizontal plate 62 of the separator 60 are made the same so that the gap is not generated during brazing bonding.

At least one of the header 20a or the separator 60 is coated with a cladding material, and the separator 60 is produced by an extrusion or press die.

5 is a cross-sectional view showing another embodiment of the receiver integrated condenser according to the present invention. The same reference numerals are used for the same components as those in the embodiment of FIG. 2, and overlapping contents are omitted to avoid complication of the description.

As shown, the first header pipe 10 includes three baffles 50 and one separator 60 each of the upper compartment 11, the lower compartment 13, and the separator compartment 15. It is divided into a space part, and four spaces of the upper compartment 21, the intermediate compartment 24, the lower compartment 22 and the auxiliary compartment 25 by three baffles 50 inside the second header pipe 20. It is divided into parts.

A coolant inlet 90 is connected to the upper compartment 11 of the first header pipe 10, a coolant outlet 91 is connected to the lower compartment 13, and a separator that vertically partitions the upper compartment 11. Although 60 is provided, space is secured and communicated with upper and lower portions of the upper compartment 11 in which the separator 60 is installed.

That is, the refrigerant introduced from the refrigerant inlet 90 is separated up and down by the separator 60 of the upper compartment 11 of the first header pipe 10, and the first and second refrigerant passages P1 (P1) ( To form P2).

A connection pipe 80 is installed in the intermediate compartment 24 of the second header pipe 20 to be connected to the receiver 70, and an outlet pipe 81 is connected to the auxiliary compartment 25.

6 is a flow chart of the refrigerant of FIG. 5. Referring to this, the refrigerant flow will be described below. For convenience of description, the refrigerant passage will be described with the first to fourth refrigerant passages.                     

The refrigerant in the gas phase introduced into the refrigerant inlet 90 is separated up and down by the separator 60 installed in the first header pipe 10, and passes through the plurality of tubes 30 to form the first and second refrigerant passages ( It will flow to P1) (P2).

The refrigerant passing through the first refrigerant passage P1 is u-turned in the upper compartment 21 of the second header pipe 20 and zigzag and flows into the third refrigerant passage P3. At this time, the refrigerant is turned in the separator compartment 15 of the first header pipe 10 and undergoes a condensation process.

The refrigerant passing through the second refrigerant passage P2 is U-turned in the lower compartment 22 of the second header pipe 20 and zigzag and flows into the third refrigerant passage P3. The refrigerant at this time is also the first header pipe ( The U-turn in the separator compartment 15 of 10) undergoes a condensation process, and the refrigerant passing through the first refrigerant passage P1 and the separator compartment 15 are joined to the intermediate compartment 24 of the second header pipe 20. In flows into the receiver 70 through a single connecting pipe (80).

The refrigerant introduced into the receiver 70 flows to the fourth refrigerant passage P4 through the outlet pipe 81 in the state in which impurities and moisture are removed by the filter and the drying material.

The fourth refrigerant passage P4 is a subcooling region for recooling the liquid refrigerant by condensation, thereby lowering the temperature of the refrigerant discharged to the expansion valve through the refrigerant outlet 91 to improve the freezing efficiency.

The receiver integrated condenser of the present invention as described in detail above is provided with a separator inside the header pipe to maintain the refrigerant flow of the conventional multi-stage liquid separation type condenser while being constrained to the installation position of the connection pipe and the outlet pipe according to the layout of the vehicle. Not only that, but also the variable size of the receiver can be applied to improve the mounting of the condenser to the vehicle.

Claims (3)

A second header pipe (20) spaced apart from and parallel to the first header pipe (10) and the first header pipe (10); A plurality of tubes (30) installed side by side so that both ends communicate with the first header pipe (10) and the second header pipe (20); Corrugated fins 40 interposed between the tubes 30; A plurality of baffles 50 installed in the first and second header pipes 10 and 20 to form a coolant flow path; A separator (60) installed inside the condensation area of the second header pipe (20) to form a separate compartment; A receiver 70 integrally formed to communicate with one side of the second header pipe 20; A connection pipe 80 formed in the condensation region and an outlet pipe 81 formed in the subcooling region so as to connect the second header pipe 20 and the receiver 70; A coolant inlet 90 formed at one side of the first and second header pipes 10 and 20 and a coolant outlet 91 formed in the subcooling region of the first header pipe 10; The refrigerant flowing into the refrigerant inlet 90 forms a first refrigerant passage P1 while passing through the plurality of tubes 30, and the refrigerant passing through the first refrigerant passage P1 is separated from the separator compartment 23. Gas-liquid is separated and the refrigerant in the gas phase is recondensed while passing through the second refrigerant passage P2 formed above the first refrigerant passage P1, and the liquid refrigerant is formed below the first refrigerant passage P1. Flowed into the third refrigerant flow path (P3) and flows to the receiver 70 through the connecting pipe 80 in the upper compartment 21 of the second header pipe 20, and flowed to the receiver 70 The refrigerant is discharged to the refrigerant outlet (91) through the fourth refrigerant passage (P4) of the subcooling region through the outlet pipe (81). A second header pipe (20) spaced apart from and parallel to the first header pipe (10) and the first header pipe (10); A plurality of tubes (30) installed side by side so that both ends communicate with the first header pipe (10) and the second header pipe (20); Corrugated fins 40 interposed between the tubes 30; A plurality of baffles 50 installed in the first and second header pipes 10 and 20 to form a coolant flow path; A separator 60 installed inside the condensation region of the first header pipe 10 to form a separate compartment; A receiver 70 integrally formed to communicate with one side of the second header pipe 20; A single connection pipe 80 formed in the condensation region and an outlet pipe 81 formed in the supercooling region to connect the second header pipe 20 and the receiver 70; A coolant inlet 90 formed at one side of the first and second header pipes 10 and 20 and a coolant outlet 91 formed in the subcooling region of the first header pipe 10; The refrigerant flowing into the refrigerant inlet 90 is separated from the refrigerant up and down by the separator 60 installed in the first header pipe 10, and passes through the plurality of tubes 30 to the first and second refrigerant passages. And a refrigerant passing through the first and second refrigerant passages P1 and P2 is formed between the first and second refrigerant passages P1 and P2. P3) is zigzag and recondensed and joined, and then flows into the receiver 70 through a single connecting pipe 80, and the refrigerant of the receiver 70 passes through the outlet pipe 81 in the subcooling region. A receiver integrated condenser, characterized in that the flow through the fourth refrigerant passage (P4) to the refrigerant outlet (91). The receiver integrated condenser according to claim 1 or 2, wherein the receiver is sized by the installation position of the connecting pipe (80).

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