KR20130057548A - Condenser - Google Patents

Abstract

PURPOSE: A condenser is provided to simplify structure of a vapor-liquid separator and to improve heat exchange efficiency. CONSTITUTION: A condenser includes a pair of header tanks, an inlet pipe, and outlet pipe, a plurality of baffles, a plurality of tubes, a plurality of fins, and gas-liquid separator. The header tanks and tubes are separated by the baffles, have a condensation region in the lower part, and have an overcooled region. The gas-liquid separator has a body, a partitioning plate(420) with a penetration hole(421); and a raising tube(430) which has a fixing part(431) fixing a drying material(440) and is formed of aluminum material. A heat exchange medium flows into the gas-liquid separator, flows to the upper side of the partitioning plate along the raising tube, and is discharged through the outlet pipe.

Description

Condenser

The present invention relates to a condenser, and more particularly, the present invention provides a condenser having a sub-cooling portion (sub cool) in the upper portion, by forming a refrigerant passage in the gas-liquid separator to separate the gas phase refrigerant and the liquid refrigerant to the liquid refrigerant only Cooling efficiency is improved by forming the rising tube which forms the refrigerant flow path for inflow to the supercooling part of the condenser upper part with excellent thermal conductivity, and the fixing part for fixing the drying material to the cooling tube is formed through extrusion as a unit. Relates to an easy condenser.

A heat exchanger is a device that absorbs heat from one side and dissipates heat to the other between two environments with a difference in temperature. In this case it will act as a heating system. Basically, the heat exchanger is composed of an evaporator that absorbs heat from the surroundings, a compressor for compressing the heat exchange medium, a condenser that releases heat to the surroundings, and an expansion valve for expanding the heat exchange medium.

In the cooling device, an actual cooling action is caused by an evaporator in which the heat exchange medium in the liquid state absorbs the amount of heat as vaporized heat from the surroundings and vaporizes. The heat exchange medium in the gas state flowing from the evaporator to the compressor is compressed at high temperature and high pressure in the compressor, and liquefied heat is released to the surroundings in the process of liquefying the compressed gas heat exchange medium through the condenser. As the medium passes through the expansion valve again, it becomes a low-temperature and low-pressure wetted vapor state, and then flows into the evaporator to evaporate to form a cycle.

As described above, in the condenser, a heat exchange medium in a gaseous state of high temperature and high pressure flows in, is discharged after being condensed in a liquid state while releasing liquefied heat by heat exchange, and a conventional condenser is shown in FIG. 1.

The condenser shown in FIG. 1 flows into the inlet 11 and passes through a lower condensation region 10 separated by a partition plate 12 to be converted into a liquid refrigerant. ) Flows into the gas-liquid separator 30, and only the liquid refrigerant flows through the filter 37 and the riser 34 to the upper side of the diaphragm 33, and passes through the second communication tube 32 to pass the subcooled region 20. Passing through, the liquid refrigerant is supercooled.

As a result, the enthalpy of the heat exchange medium can be further lowered by the supercooling to increase the cooling efficiency.

However, in the condenser as shown in FIG. 1, the gas-liquid separator 30 is provided with a drying material 35 to remove moisture of the refrigerant therein, and a gaseous refrigerant is collected above the drying material 35. And only the liquid refrigerant flows downward to the upper side of the diaphragm 33 along the riser tube 34 formed inside the gas-liquid separator 30, so that only the liquid refrigerant flows along the subcooling region 20 above the condenser. And supercooled.

However, as the riser 34 is formed inside the gas-liquid separator 30, the overall structure of the gas-liquid separator 30 is complicated, making it difficult to manufacture, and the shape of the fixing part 36 for fixing the drying material 35 is There is a problem that increases in size and complexity and difficult to assemble.

In addition, when the riser 34 is formed through plastic injection, it is difficult to form the fixing part 36 for fixing the drying material 35. The related art discloses a heat exchanger for a vehicle disclosed in Korean Laid-Open Patent Application (2008-0031662).

KR 10-2008-0031662 A (2008.04.10.)

The present invention has been made in order to solve the above problems, an object of the present invention is to form a refrigerant passage by forming a rising tube in the interior of the gas-liquid separator in the condenser having a subcooling region on the top, It is formed of aluminum material and can be manufactured integrally with the riser tube to fix the drying material through extrusion, so that the gaseous refrigerant and the liquid refrigerant can be separated so that only the liquid refrigerant can flow into the supercooling part of the upper part of the condenser along the riser tube. The structure of the gas-liquid separator can be simplified to provide a condenser that can be easily assembled and can reduce manufacturing costs.

In addition, it is to provide a condenser to form a fin on one side of the rise tube made of aluminum and to contact the fin and the gas-liquid separator body to improve the heat exchange efficiency.

Condenser of the present invention for achieving the object as described above, a pair of header tank 100 is formed side by side spaced apart a certain distance; An inlet pipe 110 and an outlet pipe 120 formed in the header tank 100 on one side to allow the heat exchange medium to flow in or out; A plurality of baffles 130 provided inside the header tank 100 to adjust a heat exchange medium flow; A plurality of tubes 200 having both ends fixed to the pair of header tanks 100 to form a flow path of the heat exchange medium; A plurality of pins (300) interposed between the tubes (200); And a gas-liquid separator 400 provided at one side of the header tank 100 to separate the gas phase heat exchange medium and the liquid phase heat exchange medium. The header tank 100 and the tube 200 are divided by the baffle 130 to form a condensation region A1 at a lower portion thereof and a subcooling region A2 at an upper portion thereof. The gas-liquid separator 400 has a body 410 formed long in the height direction; A partition plate 420 coupled to the inside of the body 410 and having a through hole 421 formed therein; And one end is connected to the through-hole 421 of the partition plate 420 is formed long to the lower side, the fixing part 431 is fixed to one side is fixed to the drying material 440 is formed integrally, is formed of an aluminum material Rising tube 430; It comprises a, the heat exchange medium introduced into the inlet pipe 110 is introduced into the gas-liquid separator 400 through the condensation zone (A1) to the upper side of the partition plate 420 along the rising tube (430) It flows and passes through the subcooling zone A2 and is discharged to the outlet pipe 120.

In addition, the rising tube 430 has a heat dissipation fin 433 is formed on one side, the heat dissipation fin 433 is characterized in that the contact with the inner peripheral surface of the gas-liquid separator body 410.

In addition, the gas-liquid separator 400 is formed with a cutout 412 on one side of the stopper 411 formed on the inner circumferential surface of the body 410, the heat tube 430 is a heat dissipation fin 433 is the cutout ( 412 is assembled to pass through.

In addition, the fixing part 431 is characterized in that the lower support portion 432 for supporting the lower portion of the drying material 440 is formed.

The present invention has been made in order to solve the problems described above, in the condenser having a subcooling region in the upper portion, by forming a riser tube to form a refrigerant passage inside the gas-liquid separator, by forming the riser tube made of aluminum The fixing part fixing the drying material through extrusion can be manufactured integrally with the rising tube, so that the liquid phase refrigerant and the liquid refrigerant can be separated so that only the liquid refrigerant can flow into the supercooling part of the upper part of the condenser along the rising tube. It is easy to assemble and has the advantage of reducing the manufacturing cost.

In addition, there is an advantage that can form a fin on one side of the aluminum rise tube and the fin and the gas-liquid separator body to improve the heat exchange efficiency.

1 is a schematic view showing a conventional condenser.
2 is a cross-sectional view showing a condenser of the present invention.
Figure 3 is a partial cross-sectional perspective view showing a gas-liquid separator according to the present invention.
Figure 4 is a perspective view of the riser tube and the drying material according to the present invention.
5 is a perspective view showing a rise tube according to the present invention.
FIG. 6 is a cross-sectional view taken along line AA ′ of FIG. 3.

With reference to the accompanying drawings, the condenser of the present invention for achieving the above object will be described in detail.

2 is a cross-sectional view showing a condenser of the present invention.

As shown, the condenser 1000 of the present invention includes a pair of header tanks 100 which are formed side by side at a predetermined distance from each other; An inlet pipe 110 and an outlet pipe 120 formed in the header tank 100 on one side to allow the heat exchange medium to flow in or out; A plurality of baffles 130 provided inside the header tank 100 to adjust a heat exchange medium flow; A plurality of tubes 200 having both ends fixed to the pair of header tanks 100 to form a flow path of the heat exchange medium; A plurality of pins (300) interposed between the tubes (200); And a gas-liquid separator 400 provided at one side of the header tank 100 to separate the gas phase heat exchange medium and the liquid phase heat exchange medium. It is made, including.

First, the header tank 100 is a space in which the heat exchange medium is introduced and discharged. The header tank 100 is a part for guiding the heat exchange medium to the tube 200. The header tank 100 is formed side by side at a predetermined distance, and the header tank 100 is located at one side of the header tank 100. The inlet pipe 110 and the outlet pipe 120 are formed.

In addition, both ends of the tubes 200 are fixed to the pair of header tanks 100 so that a flow path of a heat exchange medium is formed, and the fins 300 are interposed between the tubes 200.

In addition, a baffle 130 is formed inside the header tank 100 to block the flow of the heat exchange medium in the height direction so as to control the flow of the heat exchange medium, and the baffle 130 exits the left header tank 100. It is formed on the lower side of the pipe 120 and the lower inlet pipe 110, respectively, and formed on the lower side and the upper side of the lower communication tube 140 of the upper communication tube 150 of the right header tank 100, respectively.

At this time, the pair of baffles 130 formed on the lower side of the outlet pipe 120 of the left header tank 100 and the lower side of the upper communication tube 150 of the right header tank 100 is formed at the same height.

Thus, the tube 200 and the fin 300 formed under the pair of baffles 130 become the condensation area A1, and the tube 200 and the fin 300 formed in the upper direction are subcooled area A2. The heat exchange medium flowing into the inlet pipe 110 passes through the condensation area A1 and is cooled to convert the gaseous refrigerant into a liquid refrigerant and the gas-liquid separator 400 along the lower communication tube 140. The condenser of the upper sub cool type is introduced into the flow to the upper side flows along the upper communication pipe 150 and is subcooled in the subcooling area (A2) and discharged to the outlet pipe (120).

And the gas-liquid separator 400 connected to the lower communication tube 140 and the upper communication tube 150 is coupled to one side of the right header tank 100, the gas-liquid separator 400 is formed long in the height direction as shown in FIG. Body 410 is; A partition plate 420 coupled to the inside of the body 410 and having a through hole 421 formed therein; And one end is connected to the through-hole 421 of the partition plate 420 is formed long to the lower side, the fixing part 431 is fixed to one side is fixed to the drying material 440 is formed integrally, is formed of an aluminum material Rising tube 430; It is made, including.

This is the body 410 of the gas-liquid separator 400 is divided into an inner space by the partition plate 420, it is formed so that the heat exchange medium flows from the lower side to the upper side along the rising tube (430).

Thus, in the condenser 1000 of the present invention, the flow of the heat exchange medium is cooled while the heat exchange medium flowing into the inlet pipe 110 passes through the condensation area A1 to convert the gaseous refrigerant into a liquid refrigerant, and the lower communication tube ( Along the 140, the gas-liquid separator 400 is introduced to separate moisture from the drying material 440, and the gaseous refrigerant is separated upward. Only the liquid refrigerant flows into the lower end of the rising tube 430 and flows upward. Flows upward along the through-hole 421 of the partition plate 420 and passes from the inside of the filter 460 to the outside, and then flows along the upper communication tube 150 to be supercooled in the subcooling area A2. The outlet pipe 120 is discharged.

Hereinafter, the gas-liquid separator 400 will be described in detail.

First, the body 410 is formed long in the height direction, such as the header tank 100, the upper and lower ends are made of a pipe shape, the lower communication tube 140 and the upper communication tube 150 to the header tank It is connected to one side of the (100).

The lower end of the body 410 is sealed by a lower cap 470, and the partition plate 420, the rising tube 430, and the drying material 440 are provided in the body 410.

At this time, the rising tube 430 is inserted into the through-hole 421 of the partition plate 420, one end is coupled, the partition plate 420 is the gas-liquid separator 400 body 410 as shown in FIG. It is formed to be in close contact with the inner circumferential surface of the inner space of the body 410 is divided up and down by the partition plate 420 so that the heat exchange medium does not pass through, the through hole 421 formed in the partition plate 420 It should be configured to flow from the lower side to the upper side along the rising tube 430 connected to.

At this time, the body 410 of the gas-liquid separator 400 has a stopper 411 is formed on the inner peripheral surface, the partition plate 420 may be tightly coupled to the stopper 411.

That is, when assembling and inserting the partition plate 420, the rising tube 430, and the drying material 440 from the upper side of the body 410, the stopper 411 protruding from the inner circumferential surface of the body 410. The partition plate 420 is caught so that it can not be lowered anymore, and thus the lower end of the rising tube 430 is spaced apart from the lower cap 470 by a predetermined distance to allow the heat exchange medium to flow smoothly.

In addition, the stopper 411 and the partition plate 420 may be in close contact to prevent leakage of the heat exchange medium, and the heat exchange medium may be coated or interposed between the stopper 411 and the partition plate 420. Can be prevented from leaking. At this time, the filter 460 and the upper cap 450 is coupled to the upper side of the partition plate 420 to press the partition plate 420 to be surely in close contact with the stopper 411.

4 and 5, the rising tube 430 has a fixed portion 431 is fixed to the drying material 440 is formed on one side, formed of aluminum material and the rising tube 430 through extrusion, etc. The fixing part 431 can be manufactured integrally.

That is, the rising tube 430 is fixed to the one side is fixed to the drying material 440 fixed portion 431 is formed integrally, the fixing portion 431 is made of a pair, but at a predetermined interval It is formed in a state to insert the drying material 440 therein and then pinch the fixing portion 431 to fix the drying material 440.

Therefore, the structure can be simplified compared to the structure that combines a fixed hook or a fixed portion to the conventional riser, there is an advantage that it is easy to assemble and reduce the manufacturing cost.

Then, the partition plate 420 and the rising tube 430 are assembled by brazing, and the drying material 440 is assembled and fixed to the rising tube 430, and then inserted from the upper side of the body 410. Can be assembled.

In addition, as shown in FIGS. 5 and 6, the rising tube 430 has a heat dissipation fin 433 formed at one side thereof, and the heat dissipation fin 433 may be coupled to contact an inner circumferential surface of the gas-liquid separator body 410. The heat dissipation fin 433 is formed integrally with the rising tube 430 through extrusion of aluminum, and the heat dissipation fin (3) is formed on the inner circumferential surface of the body 410 when the heat dissipation fin 433 is integrally formed with the rising tube 430. 433) is assembled to be in close contact. At this time, the heat dissipation fin 433 is preferably formed to correspond to the shape of the inner circumferential surface to be in close contact with the inner circumferential surface of the body 410.

Thus, since the heat dissipation fin 433 and the body 410 of the gas-liquid separator 400 are in contact with each other, the heat dissipation fin 433 and the body 410 absorb heat from the heat exchange medium around the riser tube 430. The heat can be released to the outside along the () has the advantage of improving the heat exchange efficiency.

In addition, the gas-liquid separator 400 is formed with a cutout 412 on one side of the stopper 411 formed on the inner circumferential surface of the body 410, the heat tube 430 is a heat dissipation fin 433 is the cutout ( 412 may be assembled to pass through. This is a heat radiation fin 433 is formed on one side of the lifting tube 430 as shown in Figure 6 so that the close contact with the inner circumferential surface of the body 410, the stopper 411 formed on the inner circumferential surface of the body 410 The radiating fin 433 penetrates the cutout portion 412 when the rising tube 430 is inserted from the upper side of the body 410 so that the cutout portion 412 is formed at one side. This is to allow the 430 to be assembled inside the body 410.

In addition, the fixing part 431 may have a lower support part 432 supporting the lower part of the drying material 440. This is to prevent the drying material from being pushed downward due to vibration and shock when the condenser 1000 of the present invention is mounted and used in a vehicle so as not to block the lower end of the rising tube 430. The lower end of the drying material 440 is supported by the lower support part 432 in a state where the 440 is fixed to the fixing part 431 of the rising tube 430 so that the drying material 440 is securely fixed. The flow chart of the heat exchange medium can be made smoothly. At this time, the lower support portion 432 may be formed in a form surrounding the lower end of the drying material 440, as shown in Figures 4 and 5, inwardly in the state formed through extrusion integrally with the fixing portion 431. It may be formed in a shape to support the lower end of the drying material 440.

In addition, it is formed to cut open one side of the bottom of the riser tube 430, even if the bottom of the riser tube 430 is coupled to reach the lower cap 470, the flow path is not blocked, it is possible to smooth flow of the heat exchange medium. It can be made to.

And the rising tube 430 is formed in a long tubular shape as shown in Figure 5, it is formed so that the heat exchange medium flows inside. At this time, the rising tube 430 is flat, as shown is preferably formed to have an arc-shaped cross-section, ribs 434 are formed along the longitudinal direction therein to improve the rigidity of the rising tube 430 Deformation can prevent the passage from narrowing or clogging.

In addition, although the rising tube 430 may be formed of another metal material having excellent thermal conductivity in addition to the aluminum material, the rising tube 430 may be easily combined with the components constituting the gas-liquid separator 400 and the partition plate 420. Rising tube 430 is preferably formed of an aluminum material.

And the condenser of the present invention can be used as it is without changing the components, such as drying material, upper cap, filter and lower cap conventionally used even if the partition plate and the rising tube is configured inside the gas-liquid separator can reduce the manufacturing cost have.

In addition, since the configuration of the coolant flow path is not necessary to the outside by configuring the riser tube to allow the refrigerant to flow inside the gas-liquid separator, a compact configuration of the gas-liquid separator is possible, and the possibility of breakage in the manufacturing or conveying process can be reduced.

In addition, the header tank 100, the tube 200, the pin 300, the baffle 130, the lower communication tube 140 and the upper communication tube 150 is formed of a material that can be integrally formed by brazing. Preferably, the body 410, the partition plate 420, the riser tube 430 and the lower cap 470 of the gas-liquid separator 400 is also formed of the same material is preferably coupled by brazing.

It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims. It goes without saying that various modifications can be made.

1000: condenser (of the invention)
100: Header tank
110: inlet pipe 120: outlet pipe
130: baffle
140: lower communication tube 150: upper communication tube
200: tube
300: pin
400: gas-liquid separator
410: Body
411: stopper 412: incision
420: partition plate 421: through hole
430: rising tube
431 fixed part 432 lower support part
433: heat sink fin 434: rib
440: drying material 450: upper cap
460 filter 470 lower cap
A1: condensation region A2: supercooled region

Claims (4)

A pair of header tanks 100 formed side by side at a predetermined distance; An inlet pipe 110 and an outlet pipe 120 formed in the header tank 100 on one side to allow the heat exchange medium to flow in or out; A plurality of baffles 130 provided inside the header tank 100 to adjust a heat exchange medium flow; A plurality of tubes 200 having both ends fixed to the pair of header tanks 100 to form a flow path of the heat exchange medium; A plurality of pins (300) interposed between the tubes (200); And a gas-liquid separator 400 provided at one side of the header tank 100 to separate the gas phase heat exchange medium and the liquid phase heat exchange medium. The header tank 100 and the tube 200 are divided by the baffle 130 to form a condensation region A1 at a lower portion thereof and a subcooling region A2 at an upper portion thereof. ,
The gas-liquid separator 400 has a body 410 is formed long in the height direction; A partition plate 420 coupled to the inside of the body 410 and having a through hole 421 formed therein; And one end is connected to the through-hole 421 of the partition plate 420 is formed long to the lower side, the fixing part 431 is fixed to one side is fixed to the drying material 440 is formed integrally, is formed of an aluminum material Rising tube 430; , ≪ / RTI >
The heat exchange medium introduced into the inlet pipe 110 flows into the gas-liquid separator 400 through the condensation zone A1 and flows upwardly of the partition plate 420 along the rising tube 430 to the supercooling zone. Condenser characterized in that discharged to the outlet pipe 120 through (A2).
The method of claim 1,
The rising tube 430 is a heat dissipation fin 433 is formed on one side, the heat dissipation fin 433 is a condenser, characterized in that in contact with the inner peripheral surface of the gas-liquid separator body (410).
The method of claim 2,
The gas-liquid separator 400 has a cutout 412 formed at one side of the stopper 411 formed on the inner circumferential surface of the body 410, and the heat tube 430 has a heat dissipation fin 433 at the cutout 412. A condenser, characterized in that it is assembled to pass through.
The method of claim 1,
The fixing part (431) is a condenser, characterized in that the lower support portion 432 is formed to support the lower portion of the drying material (440).

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