KR102653244B1 - Condenser - Google Patents

Abstract

The present invention relates to a condenser, and more specifically, to a condenser including a condensation area in which plates are stacked to condense the refrigerant and a supercooling area in which the refrigerant is supercooled, wherein the refrigerant flow path in the condensation area has multiple passages in the vertical direction. It relates to a condenser that, when equipped, can prevent the flowability of the refrigerant from being reduced by controlling the diameter of the passage through which the refrigerant flows in an upward direction.

Description

Condenser {Condenser}

The present invention relates to a condenser, and more specifically, to a condenser including a condensation area in which plates are stacked to condense the refrigerant and a supercooling area in which the refrigerant is supercooled, wherein the refrigerant flow path in the condensation area has multiple passages in the vertical direction. It relates to a condenser that, when equipped, can prevent the flowability of the refrigerant from being reduced by controlling the diameter of the passage through which the refrigerant flows in an upward direction.

In general, in the refrigeration cycle of a vehicle air conditioner, the actual cooling effect occurs through an evaporator in which a liquid heat exchange medium absorbs heat equivalent to the heat of vaporization from the surroundings and is vaporized.

The gaseous heat exchange medium that flows into the compressor from the evaporator is compressed to high temperature and pressure in the compressor, and in the process of liquefying the compressed gaseous heat exchange medium as it passes through the condenser, heat of liquefaction is released to the surroundings, and the liquefied heat exchange medium is reused again. By passing through the expansion valve, it becomes low-temperature, wet-saturated vapor, and then flows back into the evaporator to vaporize, forming a cycle.

In other words, a high-temperature, high-pressure gaseous refrigerant is introduced into the condenser, condensed into a liquid state while releasing liquefaction heat through heat exchange, and then discharged. It is formed of an air-cooled type that uses air as a heat exchange medium to cool the refrigerant, and a water-cooled type that uses liquid. It can be.

Figures 1 and 2 are diagrams conceptually showing the refrigerant flow and coolant flow in a conventional water-cooled condenser.

Referring to FIG. 1, the refrigerant in the conventional condenser 10 is preferentially introduced into the condensation area 11 and condensed, and after being separated from gas-liquid in the gas-liquid separator 13, it flows to the supercooling area 12 and is supercooled. , it is supercooled and then discharged to the outside.

Referring to FIG. 2, the cooling water in the conventional condenser 10 preferentially flows into the supercooling area 12, flows into the condensation area 11 through a connection means such as the connection plate 14, and then flows to the outside. is discharged.

At this time, the refrigerant in the condensation area 11 flows from the upper part of the condensation area 11 to ensure good flowability (flow speed) and flows in the lower direction (usually in the direction of gravity), but the condenser is miniaturized and has high performance. For this purpose, there may be multiple passes in the upper and lower directions.

While the condenser 10 having multiple passes in the upper and lower directions can improve heat exchange efficiency, in the case of a pass in which the refrigerant flows in the upper direction opposite to the direction of gravity, the speed of the fluid significantly decreases. do.

This has a problem in that the performance of the condenser deteriorates due to a decrease in the flowability of the refrigerant.

Republic of Korea Patent Publication No. 2012-0061534

The present invention was made to solve the problems described above. The object of the present invention is to provide a condenser including a condensation area where plates are stacked and the refrigerant condenses and a supercooling area where the refrigerant is supercooled. When the flow path has multiple flow paths in the vertical direction, a condenser is provided that can prevent the flowability of the refrigerant from being reduced by controlling the diameter of the flow path through which the refrigerant flows in the upper direction.

The condenser according to the present invention is formed by stacking a plurality of first plates 110 and second plates 120 in the longitudinal direction to alternately form coolant flow parts 130 and refrigerant flow parts 140 through which coolant and refrigerant flow. , a condensation area 200 where the refrigerant is condensed, and a coolant flow part 130 and a refrigerant flow part 140 in which a plurality of first plates 110 and second plates 120 are stacked in the longitudinal direction, and through which coolant and refrigerant flow. ) are formed alternately, a supercooling region 300 in which supercooling of the refrigerant occurs, a connection plate 400 formed so that the condensation region 200 and the supercooling region 300 communicate with each other, and the condensation region 200 and the It includes a gas-liquid separator 500 provided on the outer side in the width direction and in communication with the connection plate 400 so as not to overlap in the stacking direction of the supercooling area 300, wherein the condensation area 200 is such that the refrigerant flows from the top to the bottom. It includes a lower path (P1) through which the refrigerant flows from the lower part to the upper part, and an upper path (P2) through which the refrigerant flows, the diameter of the upper path (P2) being smaller than the diameter of the lower path (P1), and the connection plate (400) is a connection plate body 410 formed between the condensation area 200 and the supercooling area 300 to be capable of being coupled to the first plate 110 or the second plate 120, and the connection plate body A coolant connection passage 420 formed in a hollow space at 410 to communicate with the coolant flow hole 154 of the condensation area 200 and the supercooling area 300, and a condensation area (410) in the connection plate body 410. 200) and a refrigerant flow passage 430 formed to communicate with the refrigerant flow hole 152 of the supercooling area 300 and the gas-liquid separator 500, and the coolant connection passage 420 and the refrigerant flow passage ( 430) is inserted and disposed in the hollow interior of the connection plate body 410, and one side and the other side of the connection plate body 410 are one side of the first plate 110 or the second plate 120. It is in contact with the surface of the first plate 110 or all the edges of one side 120 of the second plate, and one side and the other side of the connection plate body 410 each have hollow parts spaced apart in the vertical direction. It is formed to have, and the connection plate 400 is formed adjacent to two or more hollow portions spaced apart from each other in the vertical direction and penetrating in the horizontal direction, between one side and the other side of the connection plate body 410. It includes two or more partition walls connected to the condensation area 200 and the supercooling area 300 in a stacking direction, and the partition wall is located between the coolant connection passage 420 and the refrigerant connection passage 430 and between the coolant connection passage 430. It is characterized in that it is provided between the connection passage 420 and the gas-liquid separator 500.

In addition, the condensation area 200 is characterized in that the refrigerant preferentially flows into the upper portion and flows through the first lower pass (P1).

In addition, the condensation region 200 is characterized in that at least one upper path (P2) is formed between the lower paths (P1) in the longitudinal direction.

In addition, the gas-liquid separator 500 has a gas-liquid separator inlet at the bottom through which the refrigerant passing through the condensation area 200 flows, and a gas-liquid separator outlet at the top through which the gas-liquid separated refrigerant flows to the supercooling area 300. It is characterized by being formed in .

In addition, the first plate 110 and the second plate 120 communicate with the refrigerant flow portions 140 formed alternately in the stacking direction and have refrigerant inflow and outflow holes 151 and refrigerant flow holes (151) that are hollow to allow the refrigerant to flow. 152); and a coolant inflow and outflow hole 153 and a coolant flow hole 154 that communicate between the coolant flow parts 130 formed alternately in the stacking direction and are hollow to allow the coolant to flow.

In addition, the refrigerant inflow and outflow hole 151 is formed on its circumference with a first protrusion 161 that protrudes toward the coolant flow part 130, and the refrigerant flow hole 152 is formed on its circumference towards the coolant flow part 130. A protruding second protrusion 162 is formed, and a third protrusion 163 protruding toward the refrigerant flow part 140 is formed around the coolant outflow hole 153, and the coolant flow hole 154 is It is characterized in that a fourth protrusion 164 protruding toward the refrigerant flow part 140 is formed around the circumference.

In addition, the connection plate 400 includes a connection plate body 410 formed between the condensation area 200 and the supercooling area 300 to be capable of being coupled to the first plate 110 or the second plate 120. , a coolant connection passage 420 formed in a hollow space in the connection plate body 410 to communicate with the coolant flow hole 154 of the condensation area 200 and the supercooling area 300, and the connection plate body 410. It is characterized in that it includes a refrigerant flow passage 430 formed to communicate with the refrigerant flow hole 152 of the condensation area 200 and the supercooling area 300 and the gas-liquid separator 500.

In addition, the connection plate 400 is formed in an open shape to surround a portion of the gas-liquid separator 500 on one side in the width direction, and further includes a gas-liquid separator coupling portion 440 to which the gas-liquid separator 500 is coupled. It is characterized by including.

In addition, the connection plate 400 protrudes to the other side in the width direction, but extends in the longitudinal direction, and is formed to be coupled to the side of the first plate 110 or the second plate 120. An auxiliary fixing part 450 It is characterized in that it further includes.

The condenser according to the present invention includes a condensation area in which the refrigerant is condensed by stacking plates and a supercooling area in which the refrigerant is supercooled. When the refrigerant passage in the condensation area has multiple passages in the vertical direction, the refrigerant flows upward. There is an advantage in that the diameter of the passage through which the refrigerant flows can be controlled to prevent the flowability of the refrigerant from deteriorating.

1 is a diagram conceptually showing the refrigerant flow in a conventional condenser.
Figure 2 is a diagram conceptually showing the cooling water flow in a conventional condenser.
Figure 3 is a perspective view showing a condenser according to an embodiment of the present invention.
Figure 4 is an exploded perspective view of a condenser according to an embodiment of the present invention.
Figure 5 is a diagram conceptually showing the refrigerant flow in a condenser according to an embodiment of the present invention.
Figure 6 is a diagram conceptually showing the condensation area of a condenser according to an embodiment of the invention.
Figure 7 is a view showing first plates stacked in a condenser according to an embodiment of the present invention.
Figure 8 is a view showing a second plate stacked in a condenser according to an embodiment of the invention.

Hereinafter, a condenser according to an embodiment of the present invention as described above will be described in detail with reference to the attached drawings.

Figure 3 is a perspective view showing a condenser according to an embodiment of the present invention, Figure 4 is an exploded perspective view showing a condenser according to an embodiment of the present invention, and Figure 5 is a diagram showing a condenser according to an embodiment of the present invention. This is a diagram conceptually showing the refrigerant flow in the condenser, and Figure 6 is a diagram conceptually showing the condensation area of the condenser according to an embodiment of the invention.

Referring to FIGS. 3 to 6, the condenser 1000 according to an embodiment of the present invention is largely divided into a condensation region 200 in which the refrigerant flows and condensation of the refrigerant, a subcooling region 300 in which the refrigerant is supercooled, and a length. A connection plate 400 located between the condensation area 200 and the supercooling area 300 in the direction, and connected to communicate the condensation area 200 and the supercooling area 300 with each other, and a gas liquid located on the connection plate 400 It includes a separator (500).

In the condensation area 200, a plurality of first plates 110 and second plates 120 are alternately stacked in the longitudinal direction, through which coolant flows in the space between the first plate 110 and the second plate 120. The coolant flow part 130 through which the coolant flows and the refrigerant flow part 140 through which the refrigerant flows can be formed to alternate.

At this time, the refrigerant is preferentially introduced into the condensation area 200 and condensation of the refrigerant occurs.

The supercooled area 300 is formed by stacking a plurality of first plates 110 and second plates 120 alternately in the longitudinal direction, through which coolant flows between the first plate 110 and the second plate 120. The coolant flow portion 130 and the refrigerant flow portion 140 through which the refrigerant flows may be formed to alternate.

At this time, coolant is preferentially supplied to the supercooling area 300 to supercool the refrigerant.

The connection plate 400 is disposed between the condensation area 200 and the supercooling area 300 in the longitudinal direction, and is formed so that the condensation area 200 and the supercooling area 300 communicate with each other, so that the condensation area 200 and the supercooling area 300 communicate with each other. The coolant and refrigerant in area 300 may be allowed to flow in communication with each other.

The connection plate 400 is disposed between the condensation area 200 and the supercooling area 300, which are formed by stacking the first plate 110 and the second plate 120, and is connected to the first plate 110 or the second plate ( By being combined with 120), there is no need to separately provide an end plate on which the first plate 110 and the second plate 120 are stacked, thereby reducing the overall weight of the condenser.

The gas-liquid separator 500 is in communication with the connection plate 400 and is provided on one side in the width direction, and has a gas-liquid separator inlet (not shown) where the condensed refrigerant flows through the condensation area 200 and flows into the gas-liquid separated refrigerant. It includes a gas-liquid separator discharge unit (not shown) that discharges to the supercooling area 300.

That is, in the condenser 1000 according to an embodiment of the present invention, the refrigerant is preferentially introduced into the condensation area 200 and exchanges heat with the cooling water, thereby condensing the refrigerant, and the condensed refrigerant is converted into gas-liquid in the gas-liquid separator 500. After separation, it flows into the supercooling area 300 and exchanges heat with the coolant preferentially flowing into the supercooling area 300, thereby achieving supercooling of the refrigerant.

In contrast to the refrigerant, the coolant preferentially flows into the supercooling area 300, exchanges heat with the refrigerant, passes through the connection plate 400, flows into the condensation area 200, and is then discharged to the outside.

By first supplying and flowing the coolant to the supercooling area 300, secondary cooling of the refrigerant is improved, which improves the efficiency of the vehicle's air conditioning system.

At this time, the condensation area 200 of the condenser 1000 according to an embodiment of the present invention has a lower path (P1) through which the refrigerant flows from the upper to the lower part, and an upper path (P2) through which the refrigerant flows from the lower to the upper. It is done including.

That is, the condensation area 200 of the condenser 1000 according to an embodiment of the present invention has a lower pass (P1) through which the refrigerant flows downward and a lower path P1 through which the refrigerant flows upward to improve heat exchange efficiency between the refrigerant and the coolant. It includes an upper pass (P2).

At this time, it is desirable to form the refrigerant flow portion 140 so that the diameter D2 of the upper path P2 is smaller than the diameter D1 of the lower path P1.

In other words, in the upper pass (P2), the refrigerant flows from the bottom to the top, so the refrigerant does not flow smoothly due to gravity, which may reduce the flowability of the refrigerant.

To this end, the condenser 1000 according to an embodiment of the present invention forms the refrigerant flow portion 140 so that the diameter D2 of the upper path P2 is smaller than the diameter D1 of the lower path P1. , it is possible to prevent the refrigerant flowability in the upper pass (P2) from being deteriorated due to the difference in diameter.

In addition, the condensation area 200 of the condenser 1000 according to an embodiment of the present invention is formed to have at least two lower passes (P1), and at least one upper pass (P2) between the lower passes (P1). It is desirable to form more than one.

It is desirable to preferentially form the lower pass (P1) through which the refrigerant flows in the direction of gravity to ensure smooth flow of the refrigerant. When the upper pass (P2) is formed in the space of the condensation area 200, the lower pass At least one is formed between (P1), but the diameter (D2) of the upper pass (P2) is formed smaller than the diameter (D1) of the lower pass (P1) to ensure smooth flow of the refrigerant flowing in the opposite direction of gravity. desirable.

Accordingly, the condenser 1000 according to an embodiment of the present invention is formed to have a lower path (P1) that flows in a downward direction so that the refrigerant from the supercooled area 300 flows into the upper part, so that the refrigerant flows smoothly. It is desirable to do so.

For this purpose, in the condensation area 200, the refrigerant flows downward through the lower pass (P1), or the refrigerant that flows upward through the upper pass (P2) and then flows downward again through the lower pass (P1) is transferred to the supercooling area. In order to flow to the upper part of the gas-liquid separator 500, a gas-liquid separator inlet through which the refrigerant passing through the condensation area 200 flows is formed at the lower part, and a gas-liquid separator outlet through which the gas-liquid separated refrigerant is discharged is formed at the upper part. By doing so, it is desirable for the supercooled region 300 to have a lower path (P1) through which the refrigerant flows from the top to the bottom.

That is, the gas-liquid separator 500 described above has a gas-liquid separator inlet portion formed at the bottom and a gas-liquid separator discharge portion formed at the top, so of course it must be formed so that the gas-liquid separated refrigerant flows upward and flows into the supercooled area 300. am.

The condenser according to an embodiment of the present invention described above will be described in more detail.

Referring to Figures 8 and 9, the first plate 110 and the second plate 120 communicate with the refrigerant flow portions 140 formed alternately in the stacking direction, and have refrigerant inflow and outflow holes 151 hollow to allow the refrigerant to flow. ) and a coolant flow hole 152 are formed, and a coolant flow hole 153 and a coolant flow hole 154 are connected to the coolant flow parts 130 formed alternately in the stacking direction and are hollow to allow the coolant to flow. It comes true.

At this time, the refrigerant outflow hole 151, the refrigerant flow hole 152, the coolant outflow hole 153, and the coolant flow hole 154 are adjacent to each corner within the first plate 110 and the second plate 120. It is desirable to form

The refrigerant inflow and outflow holes 151 are formed to be hollow to allow the refrigerant to flow by communicating between the refrigerant flow parts 140 formed alternately in the stacking direction, and a first protrusion 161 protruding toward the coolant flow part 130 is formed around the refrigerant inflow and outflow holes 151. is formed.

The refrigerant flow hole 152 is formed to be hollow to allow the refrigerant to flow by communicating between the refrigerant flow parts 140 formed alternately in the stacking direction, and a second protrusion 162 protruding toward the coolant flow part 130 around the refrigerant flow hole 152. is formed.

The coolant inflow and outflow holes 153 are formed to be hollow so that the coolant flows by protruding between the coolant flow parts 130 formed alternately in the stacking direction, and there is a third protrusion 163 around the coolant flow part 163 that protrudes toward the coolant flow part 140. is formed.

The coolant flow hole 154 is formed hollow to allow coolant to flow between the coolant flow parts 130 formed alternately in the stacking direction, and a fourth protrusion 164 protruding toward the coolant flow part 140 is formed around the coolant flow hole 154. do.

At this time, the condenser 1000 according to an embodiment of the present invention may be formed with a refrigerant inlet through which the refrigerant flows and a refrigerant outlet through which the refrigerant is discharged in the refrigerant inlet/outlet hole 151 located on the outermost surface in the longitudinal direction.

In addition, a coolant inlet through which coolant flows in and a coolant outlet through which coolant is discharged may be formed in the coolant outflow hole 153 located on the outermost surface in the longitudinal direction.

Of course, the condenser 1000 according to an embodiment of the present invention preferably has a refrigerant inlet and a refrigerant outlet formed so that the refrigerant preferentially flows into the condensation area 200 and is discharged through the supercooling area 300. , It is desirable to form a coolant inlet and a coolant outlet so that coolant flows preferentially into the supercooling area 300, passes through the condensation area 200, and then is discharged.

In particular, in addition to the above-described configuration, the condenser 1000 according to an embodiment of the present invention is formed so that the refrigerant preferentially flows into the upper part and has the lower path (P1) as much as possible, and the refrigerant also flows through the lower path in the supercooled region 300. Since it has (P1), it is preferable that the refrigerant outlet is formed at the bottom.

Referring to FIG. 4, the connection plate 400 may include a connection plate body 410, a coolant connection passage 420, and a refrigerant flow passage 430.

The connection plate body 410 is disposed between the condensation area 200 and the supercooling area 300, and the first plate 110 or the second plate 120 is stacked on the condensation area 200 and the supercooling area 300. It is formed to be capable of being combined with, and is combined with the first plate 110 and the second plate 120 to distinguish between the condensation area 200 and the supercooling area 300, and can be of various shapes as long as it is of a shape that is easy to combine. possible. In more detail, the connection plate body 410 may include a hollow portion and a partition wall. The hollow portion may be formed through one side and the other side of the connection plate body 410, and two or more hollow portions may be formed to be spaced apart from each other along the vertical direction of FIG. 4, and the above-mentioned vertical direction and condensation area 200 of FIG. And the supercooled region 300 may have a slit shape extending in a direction perpendicular to the direction in which the connection plate body 410 is stacked (hereinafter referred to as the horizontal direction). In addition, two or more partition walls may be formed, and may be formed adjacent to the above-described hollow portion, and may be formed between one side and the other side of the connection plate body 410 in the stacking direction of the condensation region 200 and the supercooling region 300. It can be formed to connect along. Accordingly, the coolant connection passage 420, the refrigerant connection passage 430, and the gas-liquid separator disposed between the condensation area 200 and the supercooling area 300 are prevented from supporting the condensation area 200 and the supercooling area 300. Structural stability can be maximized through protection, and the connection plate 400 is formed in a lattice shape (including hollow parts and partitions), thereby reducing material costs and increasing durability. Additionally, the partition wall may be provided between the coolant connection passage 420 and the refrigerant connection passage 430 and between the coolant connection passage 420 and the gas-liquid separator 500, respectively. That is, a partition is formed between the coolant connection passage 420 and the refrigerant connection passage 430, which are key points requiring support, so that the coolant connection passage 420, the refrigerant connection passage 430, and the gas-liquid separator 500 can be replaced and Repairs can become easier.

The coolant connection passage 420 is formed in the connection plate body 410 and is formed in a hollow shape so that the coolant flow holes 154 of the condensation area 200 and the supercooling area 300 communicate with each other.

Of course, the coolant connection passage 420 must be formed to be capable of being coupled to the coolant flow hole 154, and is formed hollow so that the coolant in the condensation area 200 and the supercooling area 300 can flow.

At this time, since the condenser 1000 according to an embodiment of the present invention preferentially supplies coolant to the supercooling area 300, the coolant flowing into the supercooling area 300 flows through the coolant flow hole 420 of the connection plate 400. After flowing into the condensation area, it can be formed to be dischargeable.

The refrigerant flow passage 430 is formed so that the refrigerant flow hole 152 of the condensation area 200, the gas-liquid separator 500, and the refrigerant flow hole 154 of the supercooling area 300 communicate with each other.

That is, the refrigerant flow passage 430 contains the refrigerant that has flowed through the lower pass (P1) in the condensation area 200, or the refrigerant that has flowed through the upper pass (P2) at least once and flowed through the lower pass (P1). It is in communication with the gas-liquid separator inlet and is formed to communicate with the gas-liquid separator outlet and the inner flow hole 154 of the supercooling area 300. Since the gas-liquid separator 500 is located on the side in the width direction of the connection plate 400, the refrigerant The flow passage 430 may be formed by bending.

As described above, the condenser 1000 according to an embodiment of the present invention includes a condensation region 200 into which the refrigerant preferentially flows and a supercooling region 300 into which the cooling water preferentially flows. It includes a connection plate 400 that separates the area 200 and the supercooling area 300 from each other, and the connection plate 400 is connected to the first plate 110 or the second of the condensation area 200 and the supercooling area 300. A connection plate body 410 coupled to the plate 120, a coolant connection passage 420 that is hollow inside the connection plate body 410 and allows coolant to flow between the supercooled area 400 and the condensation area 200, and A refrigerant flow passage ( 430).

Through this, there is no need to separately provide end plates to the first plate 110 and the second plate 120 laminated in the condensation area 200 and the supercooling area 300 by the connection plate body 410, thereby reducing the weight. There is an advantage in reducing this.

In addition, since the coolant and the refrigerant can be communicated with each other or supplied to the gas-liquid separator 500 through the simple connection plate 400, pipes through which the refrigerant flows to the gas-liquid separator 500 are omitted and connected. Since it can be replaced with the plate 400, there is an advantage that there is less risk of damage or water leakage due to external impact, and in particular, the overall configuration and shape of the condenser 1000 is simplified.

In addition, the connection plate 400 is formed in an open shape to surround a portion of the gas-liquid separator 500 on one side in the width direction and further includes a gas-liquid separator coupling portion 440 to which the gas-liquid separator 500 is coupled.

As shown in the drawing, the gas-liquid separator coupling portion 440 may be formed in an open shape by being curved corresponding to the outer peripheral surface of the gas-liquid separator 500, which is mostly formed in a cylindrical shape, through which the gas-liquid separator 500 The connection plate 400 can be easily fixed to one side in the width direction.

That is, the condenser 1000 according to an embodiment of the present invention can position and fix the gas-liquid separator 500 on one side in the width direction through the connection plate 400, making it easy to place and fix the gas-liquid separator 500. There is one advantage, which is the advantage of saving space in the longitudinal direction in a vehicle equipped with the condenser 1000.

In addition, since the gas-liquid separator coupling portion 440 of the connection plate 400 can be positioned at a position selected from both sides in the width direction to be coupled to the gas-liquid separator 500, it can be easily placed in various vehicles equipped with the condenser 1000. It has the advantage of being easy to apply to a variety of vehicles.

In addition, the connection plate 400 protrudes to the other side in the width direction, but extends in the longitudinal direction and is coupled to the side of the first plate 110 or the second plate 120 of the condensation region 200 and the supercooling region 300. It may further include a possible auxiliary fixing part 450.

The auxiliary fixing part 450 is formed to be capable of being coupled to the side of the first plate 110 or the second plate 120 stacked on the condensation area 200 and the supercooling area 300, thereby forming the condensation area 200 and the supercooling area. Since the connection plate 400 can be firmly coupled between the regions 300, leakage of refrigerant or coolant can be prevented.

Of course, the shape of the auxiliary fixing part 450 is not limited as long as it is easily combined with the first plate 110 or the second plate 120 of the condensation area 200 and the supercooling area 300, and can be of various shapes. Of course, examples are possible.

The present invention is not limited to the above-described embodiments, and the scope of application is diverse, and those skilled in the art will be able to understand various Of course, modifications are possible.

1000: Condenser
110: first plate 120: second plate
130: coolant flow part 140: refrigerant flow part
151: Refrigerant outflow hole 152: Refrigerant flow hole
153: Coolant outflow hole 154: Coolant flow hole
161: first protrusion 162: second protrusion
163: 3rd protrusion 164: 4th protrusion
200: Condensation area
300: Supercooled area
400: Connection plate
410: Connection plate body 420: Coolant connection passage
430: Refrigerant connection passage 440: Gas-liquid separator coupling part
450: Auxiliary fixing unit
500: Gas-liquid separator
P1: Lower pass
P2: Upper pass

Claims (9)

A coolant flow portion 130 in which a plurality of first plates 110 and second plates 120 are stacked in the longitudinal direction and through which coolant and refrigerant flow, and
A condensation area 200 in which refrigerant flow parts 140 are alternately formed and condensation of the refrigerant takes place;
A coolant flow portion 130 in which a plurality of first plates 110 and second plates 120 are stacked in the longitudinal direction and through which coolant and refrigerant flow, and
A supercooling region 300 formed by alternating refrigerant flow parts 140 and where supercooling of the refrigerant occurs;
A connection plate 400 formed to communicate with the condensation area 200 and the supercooling area 300; and
A gas-liquid separator 500 communicated with the connection plate 400 and provided on the outer side in the width direction so as not to overlap the condensation region 200 and the supercooling region 300 in the stacking direction,
The condensation area 200 includes a lower path (P1) through which the refrigerant flows from the top to the bottom, and an upper path (P2) through which the refrigerant flows from the bottom to the top,
The diameter of the upper path (P2) is smaller than the diameter of the lower path (P1),
The connection plate 400 is
A connection plate body 410 formed between the condensation area 200 and the supercooling area 300 to be capable of being coupled to the first plate 110 or the second plate 120,
A coolant connection passage 420 formed in a hollow space in the connection plate body 410 to communicate with the coolant flow hole 154 of the condensation area 200 and the supercooling area 300,
The connection plate body 410 includes a refrigerant connection passage 430 formed to communicate with the refrigerant flow hole 152 of the condensation area 200 and the supercooling area 300 and the gas-liquid separator 500,
The coolant connection passage 420 and the refrigerant connection passage 430 are inserted and arranged into the hollow interior of the connection plate body 410,
One side and the other side of the connection plate body 410 are in contact with one side of the first plate 110 or the second plate 120, and one side of the first plate 110 or the second plate ( 120) and is joined to all edges of
One side and the other side of the connection plate body 410 are each formed to have hollow portions spaced apart in the vertical direction,
In addition, the connection plate 400,
It is formed adjacent to two or more hollow parts spaced apart from each other in the vertical direction and penetrating in the horizontal direction, and the condensation area 200 and the supercooling area 300 are formed between one side and the other side of the connection plate body 410. It includes two or more partition walls connected in the stacking direction,
The condenser is characterized in that the partition wall is provided between the cooling water connection passage 420 and the refrigerant connection passage 430 and between the cooling water connection passage 420 and the gas-liquid separator 500.
According to clause 1,
The condensation area 200 is
A condenser formed so that the refrigerant preferentially flows into the upper portion and flows through the first lower pass (P1).
According to clause 2,
The condensation area 200 is
A condenser in which at least one upper pass (P2) is formed between the lower passes (P1) in the longitudinal direction.
According to clause 3,
The gas-liquid separator 500 is
A condenser, wherein a gas-liquid separator inlet portion through which the refrigerant passing through the condensation zone 200 flows is formed at the bottom, and a gas-liquid separator discharge portion through which the gas-liquid separated refrigerant flows to the supercooling zone 300 is formed at the upper portion.
According to clause 4,
The first plate 110 and the second plate 120 are
Refrigerant inflow and outflow holes 151 and refrigerant flow holes 152 communicate with the refrigerant flow parts 140 formed alternately in the stacking direction and are hollow to allow the refrigerant to flow; and
A condenser comprising: coolant outflow and inlet holes 153 and coolant flow holes 154 that communicate between coolant flow parts 130 formed alternately in the stacking direction and are hollow to allow coolant to flow.
According to clause 5,
The refrigerant inflow and outflow hole 151 has a first protrusion 161 formed around it that protrudes toward the coolant flow part 130,
The refrigerant flow hole 152 has a second protrusion 162 formed around it that protrudes toward the coolant flow part 130,
A third protrusion 163 protruding toward the refrigerant flow part 140 is formed around the coolant outflow hole 153,
A condenser in which a fourth protrusion 164 protruding toward the refrigerant flow part 140 is formed around the coolant flow hole 154.
delete According to clause 1,
The connection plate 400 is
The condenser is formed in an open shape to surround a portion of the gas-liquid separator 500 on one side in the width direction, and further includes a gas-liquid separator coupling portion 440 to which the gas-liquid separator 500 is coupled.
According to clause 8,
The connection plate 400 is
The condenser further includes an auxiliary fixing part 450 that protrudes to the other side in the width direction, extends in the longitudinal direction, and is formed to be coupled to a side of the first plate 110 or the second plate 120.

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