KR20220157081A - Water cooled condenser - Google Patents

Abstract

In accordance with a purpose of the present invention, provided is a water-cooled condenser capable of reducing the whole package and improving vibration durability by having a gas-liquid separator coupled between a condensing area and a supercooling area by a connection plate unit provided with an internal flow path. To achieve the purpose, in accordance with the present invention, the water-cooled condenser includes: a condensation area in which a refrigerant is condensed through a heat exchange between the refrigerant and cooling water; a gas-liquid separator separating gas and liquid from the refrigerant condensed in the condensation area, in an inner space; a supercooling area in which the refrigerant is supercooled through a heat exchange between the refrigerant having passed through the gas-liquid separator and the cooling water; and a connection plate unit having one side coupled between the condensation area and the supercooling area, and having the other side coupled to the gas-liquid separator, wherein the connection plate unit includes an internal flow path connected to the condensation area, the gas-liquid separator and the supercooling area.

Description

Water cooled condenser}

The present invention relates to a water-cooled condenser, and more particularly, to a water-cooled condenser in which an entire package is reduced by fixing a connection plate having an internal flow path and a gas-liquid separator coupled thereto between a condensation area and a supercooling area.

In general, a heat exchanger is a device designed to exchange heat between two or more fluids. Heat exchangers are used to exchange heat between different fluids for the purpose of cooling or heating fluids, and are typically applied to vehicle cooling and heating systems, refrigerators, and air conditioners.

In addition, the plate heat exchanger applied to the cooling and heating system for vehicles is characterized in that a passage is formed between plates having a certain thickness to allow fluid to flow, and a plurality of plates are arranged at regular intervals to allow different fluids to flow across the passage one by one. to be

Referring to Korean Patent Publication No. 10-2020-0000657, as shown in FIG. 1, the water-cooled condenser 1 is formed by alternately stacking a plurality of first plates and second plates, and the refrigerant flows in. A condensation area 20 in which the refrigerant is condensed, a supercooling area 30 in which a plurality of first plates and second plates are alternately stacked, and a supercooling area 30 in which the refrigerant is supercooled, the condensation area 20 and the supercooling area 30 It includes a connection plate 40 formed between and a receiver dryer 50 positioned on the connection plate 40.

Conventionally, the connection plate coupling the gas-liquid separator between the condensation area and the supercooling area forms a certain length in the stacking direction of the plates, so that when the water-cooled condenser is coupled to the vehicle package, it is subject to limitations in the mounting space, or the vehicle package There was a disadvantage of causing an increase, and as the length of the water-cooled condenser increased, a problem of deterioration in vibration durability occurred.

Republic of Korea Patent Publication No. 10-2020-0000657 (published on 2020.01.03.)

The present invention has been made to solve the above problems, and a gas-liquid separator is coupled between a condensation area and a supercooling area by a connecting plate having an internal flow path, reducing the overall package and improving vibration durability. Its purpose is to provide a condenser.

The water-cooled condenser according to the present invention includes a condensation area in which the refrigerant and cooling water are heat-exchanged to condense the refrigerant, a gas-liquid separator for separating gas-liquid from the refrigerant condensed in the condensation area in an internal space, and heat exchange between the refrigerant and the cooling water passing through the gas-liquid separator. and a supercooling region for supercooling the refrigerant and a connection plate portion having one side coupled between the condensation region and the supercooling region and the other side coupled to the gas-liquid separator, wherein the connection plate unit includes the condensation region, the gas-liquid separator, and the supercooling It may be characterized in that it comprises an internal flow path communicating with the region.

Furthermore, the connection plate part has a first connection plate whose outer side faces the outer surface of the condensation region and a second connection plate whose inner surface faces the inner surface of the first connection plate and whose outer side faces the outer surface of the supercooling region Plates may be included.

Furthermore, the internal passage may include a first line for transferring the refrigerant passing through the condensation area to the gas-liquid separator and a second line for transferring the refrigerant passing through the gas-liquid separator to the supercooling area.

At this time, the gas-liquid separator is formed on the lower side in the longitudinal direction, includes an inlet and an outlet connected to the inner space of the gas-liquid separator, and further includes a coupling plate interviewing the other outer surface of the second connection plate, wherein the inlet is the It is connected to the first line, and the outlet may be connected to the second line.

In addition, the first line includes a first inlet through which the refrigerant flows from the condensation region, a first passage through which the refrigerant introduced into the first inlet flows, and a passage through which the refrigerant passing through the first passage flows out to the gas-liquid separator. It includes a first outlet, and the second line includes a second inlet through which the refrigerant flows from the gas-liquid separator, a second passage through which the refrigerant flowing into the second inlet flows, and the refrigerant passing through the second passage passes through the supercooling region. It may include a second outlet that flows out to.

Furthermore, the first inlet is formed through the inner surface of the outer surface of the first connection plate, and the first outlet, the second inlet, and the second outlet penetrate through the inner surface of the outer surface of the second connection plate. can be formed

At this time, the first flow path is formed by engraving on at least one of the inner surface of the first connection plate and the inner surface of the second connection plate, and the second flow path is formed by intaglio on the inner surface of the first connection plate and the second connection plate. It may be formed by intaglio on one or more of the inner surfaces of.

In addition, when the first flow path or the second flow path is formed on the inner surface of the first connection plate and the inner surface of the second connection plate, the inner surface of the first connection plate and the inner surface of the second connection plate are symmetrical to each other shape can be made.

Furthermore, the condensation area and the supercooling area include a plurality of main plates stacked to form passages through which refrigerant and cooling water flow, and end plates that face outermost surfaces of the plurality of stacked main plates, and the connection plate The portion may be formed on a lower side of the end plate in a longitudinal direction.

In this case, the end plate and the connection plate may be formed of the same metal material, and may be melt-bonded to each other in a brazing process of the condensation area and the supercooling area.

The device may further include a connection pipe formed between the condensation area and the supercooling area on an upper side of the main plate in the longitudinal direction of the main plate to transfer cooling water from the supercooling area to the condensation area.

Furthermore, a fixed connector formed between at least two of the condensation area, the supercooling area, and the gas-liquid separator may be further included.

Through the above configuration, in the water-cooled condenser according to the present invention, the gas-liquid separator is located on the side of the coupling surface of the condensation region and the supercooling region, and the coupling of the gas-liquid separator, the condensation region, and the supercooling region is made by the connection plate portion, and the connector configuration The entire package can be reduced by removing, and the gas-liquid separator can be easily separated or assembled without disconnecting other components, so that maintenance or replacement is convenient.

1 is a perspective view of a conventional water-cooled condenser
Figure 2 is a simplified perspective view according to the first embodiment of the water-cooled condenser according to the present invention
Figure 3a is a plan view of the fluid flow connection plate unit according to the present invention
Figure 3b is a perspective view of the gas-liquid separator according to the present invention
Figure 4 is a plan view of the connection plate unit and the coupling plate combination according to the present invention
5 is a perspective view of a coupling plate according to a first embodiment of the present invention;
6 is a plan view according to a second embodiment of the connection plate unit according to the present invention
7 is a plan view according to a third embodiment of a connection plate unit according to the present invention;
8 is a detailed perspective view of a condensation zone and a supercooling zone according to the present invention;
9 is a simplified perspective view according to a second embodiment of a water-cooled condenser according to the present invention

Hereinafter, the technical idea of the present invention will be described in more detail using the accompanying drawings. Prior to this, the terms or words used in this specification and claims should not be construed as being limited to the usual or dictionary meaning, and the inventor appropriately uses the concept of the term in order to explain his/her invention in the best way. It should be interpreted as a meaning and concept consistent with the technical idea of the present invention based on the principle that it can be defined.

Therefore, since the embodiments described in this specification and the configurations shown in the drawings are only one of the most preferred embodiments of the present invention and do not represent all of the technical ideas of the present invention, various alternatives may be used at the time of this application. It should be understood that variations may exist.

Hereinafter, the technical idea of the present invention will be described in more detail using the accompanying drawings. Since the accompanying drawings are only examples shown to explain the technical idea of the present invention in more detail, the technical idea of the present invention is not limited to the form of the accompanying drawings.

2 and 3, the water-cooled condenser 1000 according to the present invention has a condensation area (A) in which the refrigerant (R) and the cooling water (C) are heat exchanged to condense the refrigerant (R), the condensation area in the inner space A gas-liquid separator (200) for separating gas-liquid from the refrigerant (R) condensed in (A), the refrigerant (R) passing through the gas-liquid separator (200) and the cooling water (C) exchange heat to supercool the refrigerant (R) A region (B) and one side are coupled between the condensation region (A) and the supercooling region (B), and a connection plate unit 100 to which the gas-liquid separator 200 is coupled to the other side, wherein the connection plate unit (100) may be characterized by comprising an internal flow path 110 communicating with the condensation region (A), the gas-liquid separator 200 and the supercooling region (B).

As shown in FIG. 8 , the condensation area A and the supercooling area B are formed by stacking a plurality of main plates 1100 , and a detailed description will be given in FIG. 8 .

In the gas-liquid separator 200, the refrigerant (R) passing through the condensation region (A) moves inside and is gas-liquid separated, and then moves to the supercooling region (B). The gas-liquid separator 200 has a tubular shape, and a drying material or filter is embedded therein. The gas-liquid separator 200 is disposed on the side of the condensation area (A) and the supercooling area (B).

The connection plate part 100 has one side coupled between the condensation region A and the supercooling region B, and the other side coupled with the gas-liquid separator 200 to form the gas-liquid separator 200 into the condensation region ( A) and coupled to the supercooling region (B).

The connection plate part 100 includes the internal passage 110, and the internal passage communicates with the condensation region A, the gas-liquid separator 200, and the supercooling region B, so that the condensation The refrigerant R may be transferred from the region A to the gas-liquid separator 200 and from the gas-liquid separator 200 to the supercooling region B.

Conventionally, a connector configuration for coupling the gas-liquid separator 200 between the condensation area (A) and the supercooling area (B) was required, and the gas-liquid separator 200 is connected to the condensation area (A) and the supercooling area. Positioned between regions B, the entire water-cooled condenser 1000 package extends along the stacking direction of the main plate 1100.

In the water-cooled condenser 1000 according to the present invention, the gas-liquid separator 200 is located on the side of the coupling surface between the condensation region A and the supercooling region B, but the gas-liquid separator 200 and the condensation region A and the supercooling region The combination of (B) is made by the connection plate part 100, the connector structure is removed and the entire package is reduced, and the gas-liquid separator 200 is easy to separate or assemble without disconnecting other components, so that maintenance or repair It has a convenient replacement effect.

Furthermore, the connection plate part 100 has an outer surface of the first connection plate 100a that faces the outer surface of the condensation region A and an inner surface of the first connection plate 100a that faces the inner surface of the first connection plate 100a. One side may include a second connection plate 100b that faces the outer surface of the supercooling region B.

The connection plate part 100 includes the first connection plate 100a that faces the outer surface of the condensation region A and the second connection plate 100b that faces the outer surface of the supercooling region B, The inner surface of the first connection plate 100a and the inner surface of the second connection plate 100b may be formed by interviewing each other. At this time, it is preferable that the internal passage 110 is formed over the first connection plate 100a and the second connection plate 100b.

If the connection plate part 100 is made of a single plate, it is difficult to check the processing state of the inner flow path 110 before processing for generating the inner flow path 110 and assembling the entire water-cooled condenser 1000, but the connection When the plate part 100 is composed of the first connection plate 100a and the second connection plate 100b, the process for generating the inner flow path 110 is easy and separation is possible, so that the inner flow path 110 Status check is easy.

In this case, the inner surface of the first connection plate 100a and the inner surface of the second connection plate 100b may be made of a clad material and bonded to each other through a brazing process.

3 and 4, the internal flow path 110 includes a first line L1 for transferring the refrigerant R passing through the condensation region A to the gas-liquid separator 200 and the gas-liquid separator ( 200) may include a second line (L2) for transferring the refrigerant (R) to the supercooling region (B). The first line L1 and the second line L2 have passages separated from each other. The first line L1 and the second line L2 are formed over inner surfaces of the first connection plate 100a and the second connection plate 100b.

At this time, the gas-liquid separator 200 is formed on the lower side in the longitudinal direction, includes an inlet 210 and an outlet 220 connected to the inner space of the gas-liquid separator 200, and the outer surface of the second connection plate 100b. It may further include a coupling plate 201 that faces the other side, the inlet 210 may be connected to the first line L1, and the outlet 220 may be connected to the second line L2. That is, the first connection plate 100a, the second connection plate 100b, and the coupling plate 201 are stacked on each other, and the first line L1 and the second line L2 are connected to the inlet ( 210) and the outlet 220 are connected to the inner space of the gas-liquid separator 200, and the refrigerant R flows through the first line L1, the inner space of the gas-liquid separator 200, and the second line It can flow along (L2).

4 and 5, the first line (L1) is a first inlet 111 into which the refrigerant (R) flows from the condensation area (A), the refrigerant (R) introduced into the first inlet 111 ) includes a first flow path 112 flowing and a first outlet 113 through which the refrigerant R passing through the first flow path 112 flows out to the gas-liquid separator 200, and the second line ( L2) includes a second inlet 114 through which the refrigerant R flows from the gas-liquid separator, a second flow path 115 through which the refrigerant R introduced into the second inlet 114 flows, and the second flow path ( 115) may include a second outlet 116 through which the refrigerant (R) flows out to the supercooling region (B).

At this time, the first line (L1) and the second line (L2) are formed separately without communicating with each other, and the first line (L1) and the second line (L2) of the condensation area (A) The arrangement of the refrigerant outlet hole, the refrigerant inlet hole 1201 of the supercooling region (B), and the inlet 210 and outlet 220 of the gas-liquid separator 200 may vary depending on the formation positions.

The first flow path 112 communicates with the first inlet 111 and the first outlet 113 so as to start at the first inlet 111 and end at the first outlet 113, and the second The flow path 115 communicates with the second inlet 114 and the second outlet 116 so as to start at the second inlet 114 and end at the second outlet 116 .

At this time, the first inlet 111 is formed from the outer surface to the inner surface of the first connection plate 100a, and includes the first outlet 113, the second inlet 114, and the second outlet 116. ) may be formed from the outer surface to the inner surface of the second connection plate 100b.

In the first inlet 111, the refrigerant R passing through the condensation area A passes through the first passage 112 inside the first connection plate 100a and the second connection plate 100b. is formed through the first connection plate 100a so as to be introduced into the first connection plate 100a, and the first outlet 113 is formed on the inside of the first connection plate 100a and the second connection plate 100b. It is formed to pass through the second connection plate 100b so that the refrigerant R passing through the first flow path 112 can be delivered to the gas-liquid separator 200, and the second inlet 114 is the gas-liquid separator 200. The second connection allows the refrigerant (R) passing through the inner space of the 200 to flow into the second flow path 115 inside the first connection plate 100a and the second connection plate 100b. It is formed through the plate 100b, and the second outlet 116 is the refrigerant passing through the second flow path 115 inside the first connection plate 100a and the second connection plate 100b. (R) is formed through the second connection plate 100b so that it can be transferred to the supercooling region (B).

The refrigerant R passing through the first line L1 is introduced into the inlet 210 formed in the gas-liquid separator 200, formed in the coupling plate 201 and communicated with the inlet 210. The refrigerant (R) passed through the passage 230 and transferred to the inner space of the gas-liquid separator 200 and passed through the inner space of the gas-liquid separator 200 is formed on the coupling plate 201, and the gas-liquid separator 200 ) Passes through the outflow passage 240 communicating with the internal space and flows out to the outlet 220 and passes through the second line L2.

5 to 7, the first flow passage 112 is formed by intaglio on at least one of the inner surface of the first connection plate 100a and the inner surface of the second connection plate 100b, and The second flow path 115 may be formed by engraving on at least one of an inner surface of the first connection plate 100a and an inner surface of the second connection plate 100b.

At this time, when the first flow path 112 or the second flow path 115 is formed on the inner surface of the first connection plate 100a and the inner surface of the second connection plate 100b, the first connection plate 100a ) and the inner surface of the second connection plate 100b may be formed in a shape symmetrical to each other.

Referring to FIG. 5 , the first flow path 112 may be formed by being engraved in a symmetrical shape on the inner surfaces of the first connection plate 100a and the second connection plate 100b at the same time, and the second flow path 112 may be engraved. 115 may be formed by intaglio only on the inner surface of the first connection plate 100a.

Referring to FIG. 6 , the first flow path 112 and the second flow path 115 are simultaneously formed by intaglios in symmetrical shapes on the inner surfaces of the first connection plate 100a and the second connection plate 100b. It can be.

Referring to FIG. 7 , the first flow path 112 and the second flow path 115 may be engraved and formed only on the inner surface of the second connection plate 100b.

That is, the formation of the first flow path 112 and the second flow path 115 depends on the flow rate of the refrigerant R and the thickness of the first connection plate 100a and the second connection plate 100b. and shape can be changed.

Referring to FIG. 8, the condensation area (A) and the supercooling area (B) are stacked in plurality to form a flow path through which the refrigerant (R) and the cooling water (C) flow. An end plate 1200 facing an outermost surface of the main plate 1100 may be included, and the connection plate part 100 may be formed below the end plate 1200 in the longitudinal direction.

The main plate 1100 is a first communication part 1101, a second communication part 1102, and a third communication part 1103 forming a passage through which the refrigerant R or cooling water C flows by being stacked in plurality. ) and a fourth communication unit 1104.

An end plate 1200 is formed on the outermost surfaces of the condensation area (A) and the supercooling area (B), the refrigerant outlet hole is formed on the end plate 1200 of the condensation area (A), and the supercooling The refrigerant inlet hole 1201 is formed in the end plate 1200 of the region B, so that the condensation region A and the supercooling region B are connected to the internal passage 110 .

The connection plate part 100 has a length smaller than that of the main plate 1100 or the end plate 1200 and is formed below the main plate 1100 in the longitudinal direction.

In this case, the main plate 1100 and the end plate 1200 are formed of the same metal material, and can be melt-bonded to each other in the brazing process of the condensation area (A) and the supercooling area (B). That is, in the brazing process for bonding the condensation area (A) and the supercooling area (B), the end plate 1200 and the connection plate are melt-bonded to form the gas-liquid separator 200 in the condensation area (A). ) and the process for bonding to the supercooling region (B) can be reduced.

Referring to FIG. 9, the water-cooled condenser 1000 according to the present invention is formed on the upper side of the main plate 1100 in the longitudinal direction between the condensation area A and the supercooling area B, and the supercooling area ( It may further include a connection pipe 300 that transfers the cooling water (C) of B) to the condensation area (A). Through the connection pipe 300 , the cooling water C of the supercooling area B may be directly delivered to the condensation area A without passing through the connecting plate part 100 .

Furthermore, the water-cooled condenser 1000 according to the present invention further includes a fixed connector 400 formed between any two or more of the condensation area (A), the supercooling area (B), and the gas-liquid separator 200 can be made including

The fixed connector 400 is a blind connector in which fluid does not flow, and is between the condensation area (A) and the supercooling area (B), between the condensation area (A) and the gas-liquid separator 200, the supercooling area and It is installed at any one point between the gas-liquid separator 200 and between the condensation area (A), the supercooling area (B) and the gas-liquid separator 200, and the condensation area (A) and the supercooling area (B ) and the bonding force between the components of the gas-liquid separator 200 can be increased.

The present invention is not limited to the above embodiments, and the scope of application is diverse, and various modifications and implementations are possible without departing from the gist of the present invention claimed in the claims.

1000: water-cooled condenser
1100: main plate 1101: first communication part
1102: second communication unit 1103: third communication unit
1104: 4th communication unit
1200: end plate 1201: refrigerant inlet hole
100: connection plate portion 100a: first connection plate
100b: second connection plate 110: inner passage
111: first inlet 112: first flow path
113: first outlet 114: second inlet
115: second flow path 116: second outlet
A: condensation zone B: supercooling zone
R: Refrigerant C: Coolant
L1: 1st line L2: 2nd line
200: gas-liquid separator 201: coupling plate
210: entrance 220: exit
230: inflow passage 240: outflow passage
300: connector 400: fixed connector

Claims (12)

a condensation area in which the refrigerant and the cooling water are heat-exchanged to condense the refrigerant;
a gas-liquid separator separating gas-liquid from the refrigerant condensed in the condensation zone in the inner space;
a supercooling zone in which the refrigerant and cooling water that have passed through the gas-liquid separator perform heat exchange to supercool the refrigerant; and
A connection plate unit having one side coupled between the condensation region and the supercooling region and the other side coupled to the gas-liquid separator;
The connecting plate part,
an internal passage communicating with the condensation region, the gas-liquid separator, and the supercooling region;
A water-cooled condenser comprising a.
According to claim 1,
The connecting plate part,
a first connection plate having one side of its outer surface interviewed with the outer surface of the condensation area; and
a second connection plate having an inner surface interviewed with an inner surface of the first connection plate and an outer surface interviewed with an outer surface of the supercooling region;
A water-cooled condenser comprising a.
According to claim 2,
The inner flow path,
a first line for transferring the refrigerant passing through the condensation zone to the gas-liquid separator; and
a second line for transferring the refrigerant passing through the gas-liquid separator to the supercooling region;
A water-cooled condenser comprising a.
According to claim 3,
The gas-liquid separator,
A coupling plate formed on the lower side in the longitudinal direction, including an inlet and an outlet connected to the inner space of the gas-liquid separator, and interviewing the other outer surface of the second connection plate; further comprising,
The inlet is connected to the first line, and the outlet is connected to the second line.
According to claim 3,
The first line is
a first inlet through which refrigerant flows from the condensation area;
a first passage through which the refrigerant introduced into the first inlet flows; and
A first outlet through which the refrigerant passing through the first flow path flows out to the gas-liquid separator;
The second line is
a second inlet through which refrigerant flows from the gas-liquid separator;
a second passage through which the refrigerant introduced into the second inlet flows; and
a second outlet through which the refrigerant passing through the second passage is discharged to the supercooling region;
A water-cooled condenser comprising a.
According to claim 5,
The first inlet,
It is formed from the outer surface of the first connection plate through the inner surface,
The first outlet, the second inlet and the second outlet,
A water-cooled condenser formed by penetrating the inner surface from the outer surface of the second connection plate.
According to claim 6,
The first flow path,
It is formed by intaglio on at least one of the inner surface of the first connection plate and the inner surface of the second connection plate,
The second flow path,
A water-cooled condenser formed by engraving on at least one of an inner surface of the first connection plate and an inner surface of the second connection plate.
According to claim 7,
When the first flow path or the second flow path is formed on the inner surface of the first connection plate and the inner surface of the second connection plate, the inner surface of the first connection plate and the inner surface of the second connection plate are symmetrical to each other. water-cooled condenser.
According to claim 1,
The condensation region and the supercooling region,
a plurality of main plates stacked to form passages through which refrigerant and cooling water flow; and
Including; end plate interviewing the outermost surface of the plurality of stacked main plates,
The connecting plate part,
A water-cooled condenser formed below the end plate in the longitudinal direction.
According to claim 9,
The end plate and the connection plate are formed of the same metal material and are melt-bonded to each other in a brazing process of the condensation area and the supercooling area.
According to claim 9,
a connection pipe formed between the condensation area and the supercooling area on an upper side of the main plate in the lengthwise direction of the main plate to transfer cooling water from the supercooling area to the condensation area;
A water-cooled condenser further comprising a.
According to claim 1,
a fixed connector formed between at least two of the condensation area, the supercooling area, and the gas-liquid separator;
A water-cooled condenser further comprising a.

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