KR101248786B1 - Condenser - Google Patents

Abstract

The present invention relates to a condenser, and more particularly, the present invention is that the gas-liquid separator can reduce the width of the condenser by using a rectangular cross-sectional body, thereby ensuring a sufficient distance between the condenser and the bumper beam can be damaged The present invention relates to a condenser that can be further reduced.

Description

Condenser {CONDENSER}

The present invention relates to a condenser, and more particularly, the present invention is that the gas-liquid separator can reduce the width of the condenser by using a rectangular cross-sectional body, thereby ensuring a sufficient distance between the condenser and the bumper beam can be damaged The present invention relates to a condenser that can be further reduced.

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 80 shown in FIG. 1 includes a pair of header tanks 10 formed side by side at a predetermined distance from each other; An inlet pipe 20 and an outlet pipe 30 formed in the header tank 10 to allow the heat exchange medium to flow in or out; A plurality of tubes (40) provided between the header tanks (10); A plurality of fins 50 stacked between the tubes 40; And a gas-liquid separator 60 provided at one side of the header tank 10 to separate the gas-phase heat exchange medium from the liquid-phase heat exchange medium. It is designed to induce subcooling by collecting only the liquid refrigerant in the gas-liquid separator.

The condenser as shown in FIG. 1 has the advantage of being able to further lower the enthalpy of the heat exchange medium by the supercooling to increase the cooling efficiency.

However, in the condenser as shown in FIG. 1, the gas-liquid separator is formed in a cylindrical shape because the desiccant provided therein is formed in a circular shape, and the lower filter integrated cap is formed in a circular shape so as to be mounted and replaced in a circular shape.

Accordingly, the cylindrical gas-liquid separator has a problem of widening the maximum forming width of the condenser.

2 is a top plan view of the condenser 80 shown in FIG. 1, and more specifically, in the conventional condenser 70, the width W60 of the gas-liquid separator 60 is the width of the header tank 10. As it is formed larger than the (W10), the width of the entire condenser 70 can not only be increased, thereby acting as an element preventing the miniaturization of the condenser 70.

In addition, there is a problem that it is difficult to reduce the distance (d1) between the gas-liquid separator 60 and the header tank (10).

Furthermore, in order to satisfy various preferences of users around the world, according to the current technical trend that light weight, compactness, and high performance of components in vehicles are progressed, research for miniaturization of the condenser is required.

In addition, when the width of the gas-liquid separator is large, it is difficult to form a sufficient distance from the bumper beam, and there is a high possibility that the gas-liquid separator of the condenser collides easily due to a small force during low-speed collision.

In particular, the RCAR (Research Council for Automobile Repairs) is an organization that calculates and studies the standards of durability and stability of each element of the vehicle. The assessment results will be assessed, and the results of the assessment will be used as the basis for calculating insurance premiums.

In other words, the lack of sufficient distance between the condenser and the bumper beam may increase the repair cost of the vehicle, which may be a major cause of the increase in the premium.

The present invention has been made to solve the above problems, the object of the present invention is that the gas-liquid separator is formed to include a body having a rectangular cross-sectional shape to reduce the width of the condenser to ensure a sufficient gas-liquid separation space while miniaturizing Is to provide a possible condenser.

An object of the present invention is to provide a condenser that can reduce the condenser width to sufficiently secure the distance between the condenser and the bumper beam by using the body to further reduce the possibility of breakage, thereby lowering the premium.

In addition, it is an object of the present invention by using a connecting means that can easily use the existing lower cap while using a body of a rectangular cross-section does not need to change the shape of the desiccant, filter and lower cap provided in the gas-liquid separator, the application It is to provide a condenser to improve the castle.

In addition, an object of the present invention is to improve the durability by forming the first hollow portion and the second hollow portion of the connecting means in close contact with the header tank, condenser that can narrow the distance between the gas-liquid separator and the header tank To provide.

Condenser 1000 of the present invention is a pair of header tank 100 formed side by side spaced apart a certain distance; An inlet pipe (110) formed in the header tank (100) to allow a heat exchange medium to be introduced therein and an outlet pipe (120) to be discharged; At least one baffle 130 provided inside the header tank 100 to control a heat exchange medium flow; A plurality of tubes 200 having both ends fixed to the pair of header tanks 100 to form a heat exchange medium flow path; 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. In the condenser 1000 comprising a, the gas-liquid separator 400 of the condenser 1000 is formed in the height direction to have a rectangular cross-sectional shape body 410; The second connecting portion is formed in a circular cross-sectional shape on the lower side of the first connecting portion 421 and the first connecting portion 421 of the rectangular cross-sectional shape so as to be connected to the lower portion of the body 410, the second fixing portion 423 is formed on the lower inner peripheral surface A connecting means 420 including a connecting portion 422 and having a first hollow portion 424 and a second hollow portion 425 formed in the height direction in the first connecting portion 421 or the second connecting portion 422, respectively. ;

First communicating means 431 and second communicating means 432 connecting the first hollow part 424 and the second hollow part 425 and the header tank 100 to communicate with the heat exchange medium; A drying material 440 provided in a portion of the body 410 and the connection means 420; A filter 450 supporting the drying material 440 and provided inside the second connecting portion 422 of the connecting means 420; And a lower cap 460 positioned below the filter 450 and fastened to the fixing part 423 of the second connecting part 422 to close the lower side of the connecting means 420. And the second electrode is formed.

At this time, the condenser 1000 includes a condensation region A1 through which the heat exchange medium introduced through the inlet pipe 110 condenses while flowing through some tubes 200; After passing through the condensation area A1, the gas-liquid separation area A2 through which the heat exchange medium introduced into the gas-liquid separator 400 through the first communication means 431 passes through the gas-liquid separator 400 to separate the gas-liquid. ; And a subcooled region A3 in which a liquid heat exchange medium having passed through the gas-liquid separation region A2 flows through the second tube 432 through the remaining tubes 200 to be supercooled. 120 is characterized in that the discharge through.

In addition, the body 410 is characterized in that the upper side is opened but the upper cap 411 is provided on the open upper side is formed integrally by brazing.

In addition, the gas-liquid separator 400 is characterized in that the lower cap 460 and the filter 450 is integrally formed.

In addition, the gas-liquid separator 400 is formed so that the lower side of the body 410 is stepped, the upper side of the connecting means 420 is formed to correspond to the lower side of the body 410 is integrally formed by brazing It is characterized by.

In addition, the connecting means 420 is formed to correspond to the outer peripheral surface of the header tank 100 so that the side where the first hollow portion 424 and the second hollow portion 425 are formed to be in close contact with the header tank 100. It is characterized by.

In addition, the condenser 1000 is characterized in that the third communication means 433 is further formed to connect the body 410 and the header tank 100 to communicate the heat exchange medium.

In this case, the condenser 1000 is condensed while the heat exchange medium flowing through the inlet pipe 110 flows through some of the tubes 200, and is branched upward and downward in the height direction to move, respectively. ; After passing through the condensation region (A1) branched to the upper side, after entering the gas-liquid separator (400) through the third communication means 433, or after passing through the condensation region (A1) branched to the lower side, A gas-liquid separation area A2 through which the heat exchange medium introduced into the gas-liquid separator 400 through the communication means 431 passes through the gas-liquid separator 400 to separate the gas-liquid; And a subcooled region A3 in which a liquid heat exchange medium having passed through the gas-liquid separation region A2 flows through the second tube 432 through the remaining tubes 200 to be supercooled. 120 is characterized in that the discharge through.

In addition, the condenser 1000 is characterized in that the width of the gas-liquid separator 400 is formed the same or smaller than the width of the header tank (100).

Accordingly, the condenser of the present invention has a merit that the gas-liquid separator is formed to include a body having a rectangular cross-sectional shape, thereby reducing the width of the condenser, thereby miniaturizing the gas-liquid separating space.

The condenser of the present invention can reduce the width of the condenser by using the body to sufficiently secure the distance between the condenser and the bumper beam to further reduce the possibility of breakage, thereby reducing the premium.

In addition, the condenser of the present invention does not need to change the shape of the desiccant, the filter and the lower cap provided in the gas-liquid separator by using a connecting means for easily using the existing lower cap while using a body having a rectangular cross section. There is an advantage to increase the sex.

In addition, the condenser of the present invention can improve durability by forming the first hollow portion and the second hollow portion of the connecting means in close contact with the header tank, the advantage of narrowing the distance between the gas-liquid separator and the header tank There is this.

In addition, the condenser of the present invention has the advantage that the heat exchange medium passing through the gas-liquid separator is introduced into the tube again and supercooled and then discharged, thereby lowering the enthalpy of the heat exchange medium, thereby increasing the cooling efficiency.

1 and 2 are a perspective view and a top plan view of a conventional condenser.
3 to 6 are a perspective view, a cross-sectional view, a top plan view, and an exploded perspective view of a condenser according to the present invention.
Figure 7 is a cross-sectional view of the body and the connecting means of the condenser according to the present invention.
8 is a perspective view showing a connecting means of the condenser according to the present invention.
9 is a schematic flow diagram of a condenser in accordance with the present invention.
10 and 11 are a perspective view and a flow diagram of a condenser according to the invention.

Hereinafter, the condenser 1000 of the present invention having the features as described above will be described in detail with reference to the accompanying drawings.

Condenser 1000 of the present invention is a pair of header tank 100 formed side by side spaced apart a certain distance; An inlet pipe (110) formed in the header tank (100) to allow a heat exchange medium to be introduced therein and an outlet pipe (120) to be discharged; At least one baffle 130 provided inside the header tank 100 to control a heat exchange medium flow; A plurality of tubes 200 having both ends fixed to the pair of header tanks 100 to form a heat exchange medium flow path; 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 comprises, but the gas-liquid separator 400 is the body 410, the connecting means 420, the first communication means 431, the second communication means 432, the drying material 440, filter 450 And a lower cap 460.

First, the header tank 100 is a space in which the heat exchange medium is introduced and discharged, and is a part for guiding the heat exchange medium to the tube 200, and is formed side by side at a predetermined distance.

At this time, the header tank 100 may be formed with a baffle 130 to block the flow of the heat exchange medium in the height direction to control the flow of the heat exchange medium.

4 illustrates an example in which two baffles 130 are formed in the left header tank 100 and two baffles 130 are formed in the right header tank 100, but the baffle 130 is a flow of a heat exchange medium. It can be formed in more various positions to adjust the number, the number can also vary.

The tube 200 is a portion in which both ends are fixed to the pair of header tanks 100 to form a heat exchange medium flow path, and some tubes 200 form a condensation region A1, and the remaining tubes 200. Forms the subcooling region A3.

The gas-liquid separator 400 is formed in one header tank 100 to serve to separate the gas-phase heat exchange medium and the liquid heat exchange medium. The liquid heat exchange medium passes through the gas-liquid separator 400 and then the remaining tubes ( 200) is supercooled by flowing.

Condenser 1000 of the present invention is formed long in the height direction so that the body 410 of the gas-liquid separator 400 has a rectangular cross-sectional shape.

In the present invention, the rectangular cross-sectional shape is formed to have four sides to increase space utilization, and is included in the scope of the present invention even when the corners are formed in a round shape as well as an angled shape.

The body 410 has an upper side and a lower side in an open shape, the open upper side can be closed by the upper cap 411, the body 410 and the upper cap 411 is the header tank 100 The header, the tube 200 and the pin 300 is formed of a material that can be integrally formed with the connecting means 420 by brazing.

That is, the open upper side of the body 410 is sealed by the upper cap 411 integrally formed by brazing.

The connecting means 420 is connected to the lower portion of the body 410, the lower cap 460 is a portion is fixed.

At this time, the upper predetermined region of the connecting means 420 is formed to have the same shape as the body 410, the first connecting portion 421 is formed in a cross-sectional shape and the lower remaining region is formed in a circular cross-sectional shape The two connecting portion 422 is formed.

That is, the connecting means 420 is formed so that the first connecting portion 421 is formed on the upper side to be connected to the body 410, the second connecting portion 422 is formed on the lower side to facilitate the lower cap 460 To be removed.

The second connection portion 422 has a fixing portion 423 for fixing the lower cap 460 is formed on the lower inner peripheral surface.

Through this, the condenser 1000 of the present invention can easily open and close the lower cap 460, there is an advantage that can be used as it is without changing the shape of the existing lower cap 460 to further increase the applicability. .

The body 410 and the connecting means 420 is preferably formed integrally by brazing coupling, is pre-assembled before brazing, the condenser 1000 of the present invention to increase the durability by increasing the bonding area is the body ( The lower side of the 410 is formed stepped, the upper side of the connecting means 420 is formed so as to correspond to the lower side of the body (410) to be formed integrally by brazing.

In FIG. 7, as an example, an inner circumference of the lower surface of the body 410 is formed to protrude downward, and an upper surface on which the first connecting portion 421 of the connecting means 420 is formed is the body ( The outer periphery of the upper surface is formed to be stepped so as to protrude upward in order to correspond to the lower surface of the 410.

Of course, the condenser 1000 of the present invention may protrude in the opposite direction, and the lower surface of the body 410 and the upper surface of the connecting means 420 have a stepped shape in addition to the body 410 and the connecting means 420. After pre-assembly it may be formed in various forms that can be integrally formed in the brazing.

At this time, the width of the body 410 and the connecting means 420 is a factor that determines the width of the gas-liquid separator 400, the width of the gas-liquid separator 400 is equal to or greater than the width of the header tank (100) It is preferable to form small.

That is, the condenser 1000 of the present invention can be miniaturized by reducing the width by using the body 410 of the rectangular cross-sectional shape while ensuring a sufficient space for separating the gas phase heat exchange medium and the liquid heat exchange medium. By reducing the width of the condenser 1000, the distance from the bumper beam can be increased compared to the conventional.

Accordingly, the condenser 1000 of the present invention can increase the evaluation result of the World Automobile Repair Technology Research Council, and can reduce the calculated premium.

In addition, the connecting means 420 is formed in the first connecting portion 421 or the second connecting portion 422, the first hollow portion 424 and the second hollow portion 425, respectively, in the height direction.

The first hollow part 424 and the second hollow part 425 respectively allow a heat exchange medium to flow into the gas-liquid separator 400 from the header tank 100, and the header tank 100 from the gas-liquid separator 400. This is an area for discharging the liquid heat exchange medium separated to the side, it is formed in the height direction.

In the figure, the hollow part located on the upper side is shown as the first hollow part 424, and the hollow part located on the lower side is shown as the second hollow part 425.

The first communication means 431 is formed in a pipe shape, one side of which is connected to the header tank 100 and the other to the first hollow portion 424 of the gas-liquid separator 400, and the second communication means 432. ) Is also formed in a pipe shape, one side of which is connected to the first hollow portion 424 of the gas-liquid separator 400 and the other side of the header tank 100.

In this case, the first hollow portion 424 and the second hollow portion 425 are formed and formed in the header tank 100 on the side where the first communication means 431 and the second communication means 432 are connected. Hollow areas corresponding to the height should be formed.

In the condenser 1000 of the present invention, the first heat exchanger 424 and the second hollow 425 are formed in the connecting means 420, and the liquid heat exchange medium passing through the gas-liquid separator 400 is a tube ( Subcooled over 200, and thus, the enthalpy of the heat exchange medium can be further lowered to increase the cooling efficiency.

In addition, the connection means 420 is formed to be in close contact with the side in which the first hollow portion 424 and the second hollow portion 425 is formed to correspond to the outer shape of the header tank 100.

That is, the connecting means 420 is an area for supporting the first communication means 431 and the second communication means 432, and the first communication means 431 and the second communication means 432 before brazing. It can be stably supported, can increase the coupling force to increase the coupling portion, there is an advantage that can narrow the distance between the gas-liquid separator 400 and the header tank (100).

When the header tank 100 and the gas-liquid separator 400 (the body 410 forming part) are provided with a configuration such as a bracket for fixing the condenser 1000, the connecting means 420 is formed of the thickness of the bracket The side in which the first hollow portion 424 and the second hollow portion 425 are formed may be extended so as to be spaced apart from each other.

In addition, there is an advantage that can increase the coupling force of the header tank 100 and the gas-liquid separator 400 more.

At this time, the interior of the space formed by the body 410 and the connecting means 420 is provided with a drying material 440 and the filter 450 from the upper side to the lower direction, the lower cap 460 below the filter 450 ) Is provided.

That is, the drying material 440, the filter 450 is supported by the lower cap 460, the filter 450 and the lower cap 460 is provided in the second connecting portion 422 forming part of the connecting member. do.

The lower cap 460 is formed in a form corresponding to the fixing portion 423 of the second connecting portion 422, in the figure is an example in which the screw thread corresponding to each other is formed in the fixing portion 423 and the lower cap 460 Indicated.

The filter 450 is provided to be in close contact with the entire space by being located in the second connection portion 422 forming part having a circular cross-sectional shape has an advantage of increasing the filter 450 ring effect.

At this time, the filter 450 is a member to be replaced, formed integrally with the lower cap 460, the filter 450 is external to the lower cap 460 by the opening of the lower cap 460 Can be withdrawn and replaced.

9 is a schematic flow diagram of the condenser 1000 according to the present invention. The condenser 1000 of the present invention includes a condensation region in which a heat exchange medium introduced through the inlet pipe 110 is condensed while flowing through some tubes 200. A1); After passing through the condensation area A1, the gas-liquid separation area A2 through which the heat exchange medium introduced into the gas-liquid separator 400 through the first communication means 431 passes through the gas-liquid separator 400 to separate the gas-liquid. ; And a subcooled region A3 through which the heat exchange medium in the liquid state passing through the gas-liquid separation region A2 flows through the remaining tubes 200 through the second communication means 432. After passing through the outlet pipe 120 is discharged.

At this time, the condensation region A1 may be formed in various ways by adjusting the formation position of the inlet pipe 110 and the discharge position of the header tank 100.

Referring to the flow of FIG. 9 in more detail, the condensation region A1 has a heat exchange medium flowing through the inlet pipe 110 formed in the left header tank 100 and the right header through some tubes 200 located above. A first condensation region A1-1 that is moved to the tank 100, a second condensation region A1-2 that is moved from the right header tank 100 to the left header tank 100 through some tubes 200, A third condensation region A1-3 is moved from the left header tank 100 to the right header tank 100 through some tubes 200.

The first condensation area A1-1, the second condensation area A1-2, and the third condensation area A1-3 may be controlled by the baffle 130 inside the header tank 100. Can be.

The flow of the condenser 1000 of the present invention shown in FIG. 9 may have a more various form as long as it includes the condensation region A1, the gas-liquid separation region A2, and the subcooling region A3.

The condenser 1000 of the present invention shown in FIGS. 10 and 11 has the configuration as described above, the third communication means 433 for connecting the body 410 and the header tank 100 is further An example is shown.

The third communication means 433 is configured to move the heat exchange medium to the gas-liquid separator 400 similarly to the first communication means 431, and the body 410 portion of the gas-liquid separator 400 Communicating.

To this end, the areas of the body 410 and the header tank 100 to which the third communication means 433 is connected are hollow.

FIG. 11 illustrates an example of a flow of the condenser 1000 to which the third communication means 433 is added. In the condenser 1000, a heat exchange medium introduced through the inlet pipe 110 may be partially connected to the tube 200. Condensation area (A1) which is condensed while flowing, but branched to the upper and lower sides in the height direction, respectively; After passing through the condensation region (A1) branched to the upper side, after entering the gas-liquid separator (400) through the third communication means 433, or after passing through the condensation region (A1) branched to the lower side, A gas-liquid separation area A2 through which the heat exchange medium introduced into the gas-liquid separator 400 through the communication means 431 passes through the gas-liquid separator 400 to separate the gas-liquid; And a subcooled region A3 in which a liquid heat exchange medium having passed through the gas-liquid separation region A2 flows through the second tube 432 through the remaining tubes 200 to be supercooled. Through 120).

More specifically, the condensation area A1 is a first condensation in which the heat exchange medium introduced through the inlet pipe 110 formed in the left header tank 100 is moved to the right header tank 100 through some tubes 200. A second condensation region A12 and a third condensation region A13 and a fourth condensation region A14 and a fifth condensation region A15, which are moved and branched downward, including the region A11, ).

The second heat exchange medium passing through the first condensation region A11 is moved from the right header tank 100 to the left header tank 100 through the tube 200 located above the first condensation region A11. The heat exchange medium passing through the condensation zone A12 and the second condensation zone A12 is connected to the right header tank from the left header tank 100 through the tube 200 located above the second condensation zone A12. After passing through the third condensation region A13, which is moved to 100, it is introduced into the gas-liquid separator 400 through the third communication means 433.

In addition, the heat exchange medium passing through the first condensation region A11 is moved from the rear header tank 100 to the left header tank 100 through the tube 200 positioned below the first condensation region A11. The heat exchange medium passing through the fourth condensation region A14 and the fourth condensation region A14 is connected to the right header from the left header tank 100 through the tube 200 located below the fourth condensation region A14. After passing through the fifth condensation region A15 that is moved to the tank 100, it is introduced into the gas-liquid separator 400 through the first communication means 431.

At this time, the heat exchange medium (the heat exchange medium passing through the second condensation area A12 and the third condensation area A13) passing through the condensation area A1 branched upward is condensed area A1 branched downward. ) As a gaseous state compared to the heat exchange medium passing through the heat exchange medium (the heat exchange medium passing through the fourth condensation region A14 and the fifth condensation region A15), so that the condensation effect can be enhanced. It is preferable that the area of the tri-condensation area A13 is larger than the areas of the fourth and fifth condensation areas A14 and A15.

That is, in the condenser 1000 of the present invention shown in FIGS. 10 and 11, the inlet pipe 110 is formed in the central region of the one side header tank 100, and when the condensation, the heat exchange medium of the gas phase and the liquid phase is upper and As an example to be branched to the lower region to be condensed, and moved to the gas-liquid separator, there is an advantage that the condensation performance can be more secured by adjusting the branched and moved region.

On the other hand, the condenser 1000 of the present invention can be manufactured by the following manufacturing process.

First, the tube 200, the fin 300, and the header tank 100 assembly, the body 410, the connecting means 420, the first communication means 431 for forming the gas-liquid separator 400, The second communication means 432 is assembled temporarily.

The prefabricated components are manufactured integrally through the brazing process.

Thereafter, after inserting the drying material 440 into the space formed by the body 410 and the connecting means 420, the filter 450 integral lower cap 460 of the second communication means 432 Manufacturing of the condenser 1000 is completed by coupling to the fixing part 423.

That is, since the drying material 440 is a material that can be oxidized when brazing, the drying material 400 is inserted into the gas-liquid separator 400 that is integrally manufactured through the brazing process, and the lower cap 460 is mounted. .

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.

1000 condenser according to the invention
100: header tank
110: inlet pipe 120: outlet pipe
130: baffle
200: tube
300: pin
400: gas-liquid separator
410: body 411: upper cap
420: connecting means 421: first connecting portion
422: second connection portion 423: fixed portion
424: First Hollow 425: Second Hollow
431: First communication means
432: second communication means
433: third communication means
440: drying material
450: filter
460: lower cap
A1: condensation zone (A1-1, A1-2, A1-3, A11 to A15)
A2: gas-liquid separation zone
A3: subcooling zone

Claims (9)

A pair of header tanks 100 formed side by side at a predetermined distance; An inlet pipe (110) formed in the header tank (100) to allow a heat exchange medium to be introduced therein and an outlet pipe (120) to be discharged; At least one baffle 130 provided inside the header tank 100 to control a heat exchange medium flow; A plurality of tubes 200 having both ends fixed to the pair of header tanks 100 to form a heat exchange medium flow path; 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. In the condenser 1000 comprising a,
The gas-liquid separator 400 of the condenser 1000
Body 410 is formed long in the height direction to have a rectangular cross-sectional shape;
The second connecting portion is formed in a circular cross-sectional shape on the lower side of the first connecting portion 421 and the first connecting portion 421 of the rectangular cross-sectional shape so as to be connected to the lower portion of the body 410, the second fixing portion 423 is formed on the lower inner peripheral surface A connecting means 420 including a connecting portion 422 and having a first hollow portion 424 and a second hollow portion 425 formed in the height direction in the first connecting portion 421 or the second connecting portion 422, respectively. ;
First communicating means 431 and second communicating means 432 connecting the first hollow part 424 and the second hollow part 425 and the header tank 100 to communicate with the heat exchange medium;
A drying material 440 provided in a portion of the body 410 and the connection means 420;
A filter 450 supporting the drying material 440 and provided inside the second connecting portion 422 of the connecting means 420;
A lower cap 460 positioned below the filter 450 and fastened to the fixing part 423 of the second connecting part 422 to close the lower part of the connecting means 420; Including,
The gas-liquid separator 400 is formed so that the lower side of the body 410 is stepped, the upper side of the connecting means 420 is formed to correspond to the lower side of the body 410 is integrally formed by brazing Condenser made.
The method of claim 1,
The condenser 1000 is a heat exchange medium introduced through the inlet pipe 110
A condensation region A1 that condenses while flowing through some tubes 200;
After passing through the condensation area A1, the gas-liquid separation area A2 through which the heat exchange medium introduced into the gas-liquid separator 400 through the first communication means 431 passes through the gas-liquid separator 400 to separate the gas-liquid. ; And
After passing through the gas-liquid separation area (A2), the liquid heat exchange medium flows through the second communication means 432 through the remaining tube 200, the supercooling area (A3); and after passing through the outlet pipe 120 A condenser, characterized in that discharged through).
The method of claim 2,
The body 410 is a condenser, characterized in that the upper side is opened but the upper cap 411 is provided on the open upper side is formed integrally by brazing.
The method of claim 2,
The gas-liquid separator 400 is characterized in that the lower cap 460 and the filter 450 is formed integrally.
delete The method of claim 2,
The connecting means 420 is formed to correspond to the outer peripheral surface of the header tank 100 such that the side where the first hollow portion 424 and the second hollow portion 425 are formed is in close contact with the header tank 100. Condenser made.
The method of claim 1,
The condenser (1000) is a condenser, characterized in that the third communication means (433) is further formed to connect the body (410) and the header tank (100) so that the heat exchange medium is in communication.
The method of claim 7, wherein
The condenser 1000 is a heat exchange medium introduced through the inlet pipe 110
Condensation area (A1) is condensed while flowing in some tubes 200, branched to the upper and lower in the height direction, respectively;
After passing through the condensation region (A1) branched to the upper side, after entering the gas-liquid separator (400) through the third communication means 433, or after passing through the condensation region (A1) branched to the lower side, A gas-liquid separation area A2 through which the heat exchange medium introduced into the gas-liquid separator 400 through the communication means 431 passes through the gas-liquid separator 400 to separate the gas-liquid; And
After passing through the gas-liquid separation area (A2), the liquid heat exchange medium flows through the second communication means 432 through the remaining tube 200, the supercooling area (A3); and after passing through the outlet pipe 120 A condenser, characterized in that discharged through).
The method according to any one of claims 1 to 4 and 6 to 8,
The condenser 1000 is
Condenser characterized in that the width of the gas-liquid separator 400 is formed equal to or smaller than the width of the header tank (100).

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