KR20230071339A - Heat exchanger - Google Patents

Abstract

The present invention, the upper plate provided with the inlet and outlet ports of the refrigerant; a lower plate spaced apart from the upper plate and provided with first and second cooling water inlet and outlet ports, respectively; and a heat exchange unit interposed between the upper plate and the lower plate and exchanging heat with each other while the refrigerant and the first and second coolants flow, wherein the heat exchange unit includes a plurality of first refrigerants flowing under the upper plate. A first heat exchange part in which a refrigerant plate and a plurality of first coolant plates through which the first coolant flows are alternately stacked, and between the first heat exchange part and the lower plate, the refrigerant passing through the first refrigerant plate flows It provides a heat exchanger including a second heat exchange unit in which a plurality of second refrigerant plates for cooling and a plurality of second cooling water plates through which the second cooling water flows are alternately stacked.
According to the heat exchanger according to the present invention, the first heat exchange unit and the second heat exchange unit are integrated into an integral heat exchange unit, the inlet and outlet of the refrigerant are unified, and the first coolant inlet and outlet and the second coolant inlet and outlet are respectively one side and the other side. Arranged on the other side to simplify the arrangement, which is advantageous for simplifying the line and securing space inside the vehicle.
In addition, if the present invention is used, it is possible to integrate two heat exchangers into one and apply it advantageously to secure the interior space of the vehicle. For example, cooling water of a battery and electrical components may flow through a single integrated heat exchanger as in the present invention so that the refrigerant can efficiently absorb heat when recovering waste heat.

Description

Heat exchanger {Heat exchanger}

The present invention relates to a heat exchanger, and more particularly, to a heat exchanger in which cooling water and a refrigerant, which are different working fluids, flow into the inside to exchange heat with each other.

In general, in an electric vehicle, a drive motor for driving a vehicle, a high voltage junction box (HV J/BOX), a motor controller including an inverter (MCU: Motor Control Unit), a power converter (LDC: Low Voltage DC/DC Converter), and others Electric components, such as various controllers and high-voltage components, are cooled to prevent thermal damage and maintain durability, but a water cooling method using cooling water is generally applied.

In addition, in an electric vehicle, when the battery is used for a long time, heat is generated from the battery, and especially during charging, the temperature inside the battery rises rapidly. status becomes unusable. Therefore, a water cooling method using cooling water is applied to the battery in order to prevent thermal damage and maintain durability.

Conventional air-conditioning and heating systems for electric vehicles use waste heat from electric component cooling water that flows through various electrical components and battery cooling water that flows through a separate water-cooled heat exchanger, and uses heat energy absorbed from high-temperature cooling water through heat exchange with a refrigerant for indoor heating. did

The conventional water-cooled heat exchanger uses a separate water-cooled heat exchanger, and the cooling water line becomes complicated, resulting in heat loss and unreasonable use of space.

Republic of Korea Patent Publication No. 10-2016-0053806 (title of invention: heat exchanger)

The present invention has been created to solve the above problems, by integrating separate water-cooled heat exchangers into one heat exchanger to increase the heat exchange efficiency of the integrated heat exchanger and to be advantageous in modularization compared to configuring separate heat exchangers. do.

The present invention, the upper plate provided with the inlet and outlet ports of the refrigerant; a lower plate spaced apart from the upper plate and provided with first and second cooling water inlet and outlet ports, respectively; and a heat exchange unit interposed between the upper plate and the lower plate and exchanging heat with each other while the refrigerant and the first and second coolants flow, wherein the heat exchange unit includes a plurality of first refrigerants flowing under the upper plate. A first heat exchange part in which a refrigerant plate and a plurality of first coolant plates through which the first coolant flows are alternately stacked, and between the first heat exchange part and the lower plate, the refrigerant passing through the first refrigerant plate flows It provides a heat exchanger including a second heat exchange unit in which a plurality of second refrigerant plates for cooling and a plurality of second cooling water plates through which the second cooling water flows are alternately stacked.

A first refrigerant inlet hole through which the refrigerant supplied from the refrigerant inlet port can flow is formed in each of the first refrigerant plates, except for the first refrigerant plate disposed at the lowermost end of the first heat exchange unit, and the first heat exchange unit is formed. Each first refrigerant plate of the part has a first refrigerant outlet hole through which the refrigerant flowing into the first refrigerant inlet hole flows downward, and the refrigerant flowing through each of the second refrigerant plates flows to the refrigerant discharge port. A first refrigerant discharge hole may be formed through which the refrigerant can be discharged.

The first refrigerant discharge hole may be disposed between the first refrigerant inlet hole and the first refrigerant outlet hole.

Each of the first refrigerant plates includes first refrigerant partition walls protruding respectively to block both sides and the top of the first refrigerant discharge hole, and the upper part of the first refrigerant partition wall extending to both sides to expand the flow path of the refrigerant. It may include a first refrigerant extension partition wall.

Each of the first refrigerant plates has a first coolant inlet through hole through which the first coolant introduced from the first coolant inlet port passes, and a first coolant discharged through the first coolant discharge port through which the first coolant passes. A first coolant discharge through hole may be formed.

Each of the first refrigerant plates may include a first coolant mixing prevention part protruding to surround the circumferences of the first coolant inlet through-hole and the first coolant discharge through-hole to prevent mixing of the first coolant with the refrigerant.

Each of the first coolant plates includes a first coolant inlet hole communicating with the first coolant inlet through hole so that the first coolant flows in from the first coolant inlet port, and the first coolant introduced from the first coolant inlet hole. A first coolant discharge hole communicating with the first coolant discharge through hole may be formed so that is discharged to the first coolant discharge port.

Each of the first coolant plates may include a first coolant partition that protrudes to partially block a space between the first coolant inlet hole and the first coolant discharge hole and expands a flow path of the first coolant.

Each of the first coolant plates has a first refrigerant inlet communication hole communicating with the first refrigerant inlet hole so that the refrigerant supplied from the refrigerant inlet port can pass therethrough, and the refrigerant discharged from the first refrigerant outlet hole flows downward. A first refrigerant discharge communication hole communicating with the first refrigerant discharge hole and a first refrigerant discharge communication hole communicating with the first refrigerant discharge hole to be discharged to the refrigerant discharge port may be formed. there is.

Each of the first coolant plates protrudes to surround the circumferences of the first refrigerant inlet communication hole, the first refrigerant outlet communication hole, and the first refrigerant discharge communication hole, respectively, to prevent mixing of the refrigerant and the first coolant. A refrigerant mixing prevention unit may be provided.

Each of the second refrigerant plates has a second refrigerant inlet hole communicating with the first refrigerant outlet hole so that the refrigerant can be introduced from the first refrigerant outlet hole, and after the refrigerant introduced from the second refrigerant inlet hole flows. , A second refrigerant discharge hole communicating with the first refrigerant discharge hole may be formed so that the refrigerant can be discharged to the discharge port.

Each of the second refrigerant plates may include a second refrigerant barrier protruding to block a gap between the second refrigerant inlet hole and the second refrigerant discharge hole.

Each of the second refrigerant plates may further include second refrigerant extension partition walls extending from ends of the second refrigerant partition wall to both sides and extending a flow path of the refrigerant.

Each of the second refrigerant plates includes a first coolant inlet communication hole communicating with the first coolant inlet hole for supplying the first coolant from the first coolant inlet port to the first coolant plate, and the first coolant outlet. In order to discharge the first coolant discharged from the hole to the first coolant discharge port, the first coolant discharge communication hole communicated with the first coolant discharge hole passes through, and the second coolant introduced from the second coolant inlet port passes therethrough. A penetrating second coolant inlet through hole and a penetrating second coolant discharge through hole through which the second coolant discharged to the second coolant discharge port passes may be formed.

In each of the second refrigerant plates, edges of the first coolant inlet communication hole, the first coolant discharge communication hole, the second coolant inlet through hole, and the second coolant discharge through hole protrude, so that the refrigerant flows through the first and second coolant plates. A second cooling water mixing preventing unit may be provided to prevent mixing with the cooling water.

According to the heat exchanger according to the present invention, the second coolant mixing prevention part protruding from the edge of each of the first coolant inlet through hole and the first coolant discharge hole is “A” shape, and the second coolant inlet through hole and the second coolant inlet through hole The second coolant mixing prevention part protruding from an edge of each of the two coolant discharge through-holes may have an annular shape.

Each of the second coolant plates includes a second coolant inlet hole through which the second coolant flows from the second coolant inlet port, and a second coolant introduced through the second coolant inlet hole so that the second coolant is discharged. A second coolant discharge hole communicating with the discharge port may be formed.

Each of the second coolant plates may include a second coolant partition that protrudes to partially block a space between the second coolant inlet hole and the second coolant discharge hole and expands a flow path of the second coolant.

Each of the second coolant plates includes a first coolant inlet hole communicating with the first coolant inlet hole so that the first coolant passes from the first coolant inlet port, and the first coolant is discharged to the first coolant discharge port. A first coolant discharge passage hole communicating with the first coolant discharge hole may be formed as much as possible.

Each of the second coolant plates may include a coolant mixing prevention part that protrudes to surround the first coolant inlet hole and the first coolant discharge hole and prevents the first coolant from mixing with the second coolant.

Each of the second coolant plates includes a second refrigerant inlet hole through which the refrigerant flowing out of the first refrigerant outlet hole passes, and a second refrigerant discharge hole through which the refrigerant can be discharged to the refrigerant discharge port. can be formed.

Each of the second coolant plates may include a second refrigerant mixing preventing part protruding to surround the circumferences of the second refrigerant inlet hole and the second refrigerant discharge hole to prevent the second coolant from being mixed with the refrigerant. .

The heat exchange unit may include a refrigerant flow line through which refrigerant flows, a first coolant flow line through which first cooling water flows, and a second coolant flow line through which second coolant flows.

The refrigerant flow line includes a first refrigerant flow line through which the refrigerant introduced through the first refrigerant inlet hole flows through each of the first refrigerant plates and then flows out through the first refrigerant outlet hole, and the first refrigerant outlet hole The refrigerant passing through is introduced through the second refrigerant inlet hole, flows through each of the second refrigerant plates in the opposite direction to the flow in the first refrigerant plate, and then is discharged through the second refrigerant discharge hole. It may include 2 refrigerant flow lines.

In the first coolant flow line, after the first coolant is introduced through the first coolant inlet port through the first coolant inlet hole to flow through each of the first coolant plates, the first coolant flows through the first coolant discharge hole. It may be characterized in that it is discharged through the first cooling water discharge port.

In the second coolant flow line, after the second coolant is introduced through the second coolant inlet hole through the second coolant inlet port and flows through each of the second coolant plates, the second coolant flows through the second coolant discharge hole. It may be characterized in that it is discharged through the second cooling water discharge port.

According to the heat exchanger according to the present invention, the inlet and outlet ports of the first cooling water and the inlet and outlet ports of the second cooling water may be disposed to face each other on both sides of the lower plate.

The refrigerant inlet and outlet ports may be disposed between the inlet and outlet ports of the first and second cooling water.

According to the heat exchanger according to the present invention, the inside of the first and second refrigerant plates and the first and second coolant plates includes a plurality of projections (embossed) or inner fins to increase the heat exchange area and induce turbulent flow. Additions can be combined.

The plurality of protrusions (embossed) or inner fins may be arranged parallel to the flow direction of the refrigerant or the first and second cooling water.

According to the heat exchanger according to the present invention, the first heat exchange unit and the second heat exchange unit are integrated into an integral heat exchange unit, the inlet and outlet of the refrigerant are unified, and the first coolant inlet and outlet and the second coolant inlet and outlet are respectively one side and the other side. Arranged on the other side to simplify the arrangement, which is advantageous for simplifying the line and securing space inside the vehicle.

In addition, if the present invention is used, it is possible to integrate two heat exchangers into one and apply it advantageously to secure the interior space of the vehicle. For example, cooling water of a battery and electrical components may flow through a single integrated heat exchanger as in the present invention so that the refrigerant can efficiently absorb heat when recovering waste heat.

1 is an exploded perspective view of a heat exchanger according to an embodiment of the present invention;
Figure 2 is a bottom perspective view of the heat exchanger shown in Figure 1;
3 is a plan view showing a first refrigerant plate of a first heat exchange unit shown in FIG. 1;
4 is a plan view showing a first refrigerant plate at the bottom of the first heat exchange unit shown in FIG. 1;
5 is a plan view showing a first cooling water plate of a first heat exchanger shown in FIG. 1;
6 is a plan view showing a second refrigerant plate of a second heat exchange unit shown in FIG. 1;
7 is a plan view showing a second coolant plate of the second heat exchanger shown in FIG. 1;
FIG. 8 is a partially enlarged view of A in FIG. 3 by enlarging it.

Although the present invention has been described with reference to the embodiments shown in the drawings, this is only exemplary, and those skilled in the art will understand that various modifications and equivalent other embodiments are possible therefrom. Therefore, the true technical scope of protection of the present invention should be determined by the technical spirit of the appended claims.

Hereinafter, the configuration of the heat exchanger 1000 according to an embodiment of the present invention will be described with reference to FIGS. 1 to 8 .

Referring to FIGS. 1 and 2 , the heat exchanger 1000 includes an upper plate 1100 , a lower plate 1200 and a heat exchanger 1300 .

The upper plate 1100 is provided with refrigerant inlet and outlet ports 1110 and 1120 . Here, the refrigerant inlet and outlet ports 1110 and 1120 are disposed between the first and second cooling water inlet and outlet ports 1210, 1220, 1230 and 1240 provided in the lower plate 1200.

The lower plate 1200 is spaced apart from the upper plate 1100 . In addition, first and second cooling water inlet and outlet ports 1210, 1220, 1230, and 1240 are respectively provided. Here, the first cooling water inlet and outlet ports 1210 and 1220 and the second cooling water inlet and outlet ports 1230 and 1240 are disposed to face each other on both sides of the lower plate 1200 .

The heat exchange part 1300 is interposed between the upper plate 1100 and the lower plate 1200 . Here, the refrigerant and the first and second cooling water exchange heat with each other while flowing, and include a first heat exchange unit 1310 and a second heat exchange unit 1320.

The first heat exchange part 1310 includes a plurality of first refrigerant plates 1311 and 1312 through which the refrigerant flows under the upper plate 1100, and a plurality of first coolant plates 1313 through which the first cooling water flows. ) are alternately stacked. And the second heat exchange part 1320 is between the first heat exchange part 1310 and the lower plate 1200, a plurality of second refrigerant plates through which the refrigerant passing through the first refrigerant plates 1311 and 1312 flows. 1321 and a plurality of second cooling water plates 1322 through which the second cooling water flows are alternately stacked.

Referring to FIGS. 3 and 7 , each plate of the first heat exchanger 1310 and the second heat exchanger 1320 alternately stacked on the heat exchanger 1300 will be described.

Referring to FIGS. 3 and 4 , it is a plan view of the first refrigerant plate 1311 of the first heat exchange unit 1310 and the first refrigerant plate 1312 disposed at the bottom.

Each first refrigerant plate 1311, except for the first refrigerant plate 1312 disposed at the bottom of the first heat exchange part 1310, is penetrated so that the refrigerant supplied from the refrigerant inlet port 1110 can flow in. A first refrigerant inlet hole 1-H1 is formed. A first refrigerant outlet hole 1-H2 is formed through which the refrigerant flowing into the first refrigerant inlet hole 1-H1 flows downward. A first refrigerant discharge hole 1-H3 is formed through which the refrigerant flowing through each second refrigerant plate 1321 of the second heat exchange unit is discharged to the refrigerant discharge port 1120, and the first refrigerant discharge hole 1-H3 is formed. The refrigerant discharge hole 1-H3 is disposed between the first refrigerant inlet hole 1-H1 and the first refrigerant outlet hole 1-H2.

In addition, each of the first refrigerant plates 1311 and 1312 is formed with a protruding first refrigerant partition wall 1-P1 to block both sides and an upper portion of the first refrigerant discharge hole 1-H3. In addition, a first refrigerant extension partition 1-P2 protrudes from the upper portion of the first refrigerant partition 1-P1 to extend a flow path of the refrigerant by extending the upper part of the first refrigerant partition 1-P1 to both sides.

Also, each of the first refrigerant plates 1311 and 1312 has a first coolant inlet through hole 1-H4 through which the first coolant introduced from the first coolant inlet port 1210 passes. A first coolant discharge through hole 1-H5 is formed through which the first coolant discharged to the first coolant discharge port 1220 passes.

The first coolant mixing prevention part 1 protrudes to surround the circumferences of the first coolant inlet through-hole 1-H4 and the first coolant discharge through-hole 1-H5 to prevent mixing of the first coolant and the refrigerant. -P3) is formed.

Referring to FIG. 5 , it is a plan view of the first coolant plate 1313 of the first heat exchange unit 1310 .

Each of the first coolant plates 1313 has a first coolant inlet hole 2-H4 communicating with the first coolant inlet through hole 1-H4 so that the first coolant flows in from the first coolant inlet port 1210. ) is formed. Also, the first coolant discharged through the first coolant discharge through hole 1-H5 so that the first coolant introduced from the first coolant inlet hole 2-H4 is discharged to the first coolant discharge port 1220. A hole 2-H5 is formed. The first coolant partition wall 2-P1 protrudes to partially block the space between the first coolant inlet hole 2-H4 and the first coolant discharge hole 2-H5 and expands the flow path of the first coolant. is formed

In addition, each of the first coolant plates 1313 has a first refrigerant inlet communication hole 2 communicating with the first refrigerant inlet hole 1-H1 so that the refrigerant supplied from the refrigerant inlet port 1110 can pass therethrough. -H1) is formed. And a first refrigerant outlet communication hole 2-H2 communicating with the first refrigerant outlet hole 1-H2 is formed so that the refrigerant flowing out from the first refrigerant outlet hole 1-H2 can flow downward. do. Also, a first refrigerant discharge communication hole 2-H3 communicating with the first refrigerant discharge hole 1-H3 is formed so that the refrigerant can be discharged to the discharge port 1120. And the first refrigerant inlet communication hole (2-H1), the first refrigerant outflow communication hole (2-H2), and the first refrigerant discharge communication hole (2-H3) are protruded to surround each of the circumferences, and the refrigerant and the first A first refrigerant mixing prevention unit 2-P2 preventing mixing with the cooling water is formed.

Referring to FIG. 6 , it is a plan view of the second refrigerant plate 1321 of the second heat exchange unit 1320 .

Each second refrigerant plate 1321 has a second refrigerant inlet hole (3-H2) communicating with the first refrigerant outlet hole (1-H2) so that the refrigerant can be introduced from the first refrigerant outlet hole (1-H2). H2) is formed. And the second refrigerant discharge communicated with the first refrigerant discharge hole (1-H3) so that the refrigerant introduced from the second refrigerant inlet hole (3-H2) flows and then is discharged to the refrigerant discharge port (1120). A hole 3-H3 is formed. And the second refrigerant partition wall 3-P1 and the second refrigerant partition wall 3-P1 protruding to block the gap between the second refrigerant inlet hole 3-H2 and the second refrigerant discharge hole 3-H3. Second refrigerant extension partition walls 3-P2 protruding from the ends to both sides to expand the flow path of the refrigerant are formed.

In addition, each second refrigerant plate 1321 is connected to the first coolant inlet hole 2-H4 to supply the first coolant from the first coolant inlet port 1210 to the first coolant plate 1313. A first coolant inlet communication hole 3-H4 is formed. And, in order to discharge the first coolant discharged from the first coolant discharge hole 2-H5 to the first coolant discharge port 1220, the first coolant discharge communicated with the first coolant discharge hole 2-H5. A communication hole 3-H5 is formed. A second coolant inlet through hole 3-H6 is formed through which the second coolant introduced from the second coolant inlet port 1230 passes. A second coolant discharge through-hole 3-H7 is formed through which the second coolant discharged to the second coolant discharge port 1240 passes.

In addition, edges of the first coolant inlet communication hole 3-H4 and the first coolant discharge communication hole 3-H5 protrude to prevent the refrigerant from mixing with the first and second coolant. The prevention part 3-P3 is provided and is formed as an “a” shaped barrier rib. In addition, the edges of the second coolant inlet through-hole 3-H6 and the second coolant discharge through-hole 3-H7 protrude to prevent the refrigerant from mixing with the first and second coolant. The prevention part 3-P4 is provided and formed in an annular shape.

Referring to FIG. 7 , it is a plan view of the second coolant plate 1322 of the second heat exchange unit 1320 .

Each second coolant plate 1322 has a second coolant inlet hole 4 - H6 through which the second coolant flows from the second coolant inlet port 1230 . A second coolant discharge hole 4-H7 communicating with the second coolant discharge port 1240 is formed so that the second coolant introduced through the second coolant inlet hole 4-H6 is discharged. Here, a second coolant bulkhead 4-P1 protrudes to partially block the space between the second coolant inlet hole 4-H6 and the second coolant discharge hole 4-H7 and expands the flow path of the second coolant. do.

In addition, each second coolant plate 1322 has a first coolant inlet passage hole 4 communicating with the first coolant inlet hole 2-H4 so that the first coolant passes from the first coolant inlet port 1210. -H4) is formed. A first coolant discharge passage hole 4-H5 communicating with the first coolant discharge hole 2-H5 is formed so that the first coolant is discharged to the first coolant discharge port 1220. Here, the coolant mixing prevention unit protrudes to surround the circumferences of the first coolant inlet hole 4-H4 and the first coolant discharge hole 4-H5 to prevent the first coolant from mixing with the second coolant ( 4-P3).

Further, each second coolant plate 1322 is formed with a second refrigerant inlet hole 4-H2 through which the refrigerant flowing out from the first refrigerant outlet hole 1-H2 can pass. A second refrigerant discharge passage hole 4-H3 is formed so that the refrigerant can be discharged to the discharge port 1120. Here, the second refrigerant mixing prevention unit protrudes to surround the circumferences of the second refrigerant inlet hole 4-H2 and the second refrigerant discharge hole 4-H3 to prevent the second coolant from being mixed with the refrigerant. (4-P2) is provided.

Hereinafter, with reference to FIG. 1, the refrigerant flowing through the heat exchanger 1300 of the heat exchanger 1000 of the present invention, each refrigerant flow line R of the first and second coolants, and the first coolant flow line CW1 And the second coolant flow line (CW2) will be described.

The heat exchange unit 1300 has a refrigerant flow line R through which refrigerant flows, a first coolant flow line CW1 through which first cooling water flows, and a second coolant flow line CW2 through which the second coolant flows, respectively. Fluid.

The refrigerant flow line (R) is connected to the first refrigerant outlet hole (1-H2) after the refrigerant introduced through the first refrigerant inlet hole (1-H1) flows through the first refrigerant plate (1311, 1312). A first refrigerant flow line (R1) flowing out through is formed. And the refrigerant passing through the first refrigerant outlet hole (1-H2) is introduced through the second refrigerant inlet hole (3-H2), in the opposite direction to the flow in the first refrigerant plate (1311, 1312) After flowing through each of the second refrigerant plates 1321, a second refrigerant flow line R2 discharged through the second refrigerant discharge hole 3-H3 is formed.

In the first coolant flow line CW1, first coolant is introduced through the first coolant inlet port 1210 through the first coolant inlet hole 2-H4, and the first coolant plate 1313 is After flowing, it is discharged to the first coolant discharge port 1220 through the first coolant discharge hole 2-H5.

In the second coolant flow line CW2, the second coolant is introduced through the second coolant inlet port 1230 through the second coolant inlet hole 4-H6, and the second coolant plate 1322 is formed. After flowing, it is discharged to the second coolant discharge port 1240 through the second coolant discharge hole 4-H7.

Hereinafter, a plurality of projections (embossed) or inner pins formed inside the first and second refrigerant plates 1311, 1312, and 1321 and the first and second coolant plates 1313 and 1322 will be described.

8 is an enlarged view of A of the first refrigerant plate 1311 of FIG. 3 according to an embodiment of the present invention, and the first and second refrigerant plates 1311, 1312, and 1321 and the first and second coolants Inside the plates 1313 and 1322, a heat exchange extension 1400 including a plurality of protrusions (embossed) or inner fins is coupled to increase the heat exchange area and induce turbulence. Here, the plurality of protrusions (embossed) or inner fins are disposed parallel to the flow direction of the refrigerant or the first and second cooling water.

1000: heat exchanger
1100: upper plate 1110: refrigerant inlet port
1120: refrigerant discharge port 1200: lower plate
1210: first coolant inlet port 1220: first coolant outlet port
1230: second cooling water inlet port 1240: second cooling water outlet port
1300: heat exchange unit 1310: first heat exchange unit
1311, 1312: first refrigerant plate 1-H1: first refrigerant inlet hole
1-H2: first refrigerant outlet hole 1-H3: first refrigerant outlet hole
1-H4: first coolant inlet through hole 1-H5: first coolant discharge through hole
1-P1: first refrigerant bulkhead 1-P2: first refrigerant extension bulkhead
1-P3: first coolant mixing prevention unit 1313: first coolant plate
2-H1: first refrigerant inlet communication hole 2-H2: first refrigerant outlet communication hole
2-H3: 1st refrigerant discharge pipe hole 2-H4: 1st coolant inlet hole
2-H5: first coolant discharge hole 2-P1: first coolant bulkhead
2-P2: first refrigerant mixing prevention unit 1320: second heat exchange unit
1321: second refrigerant plate 3-H2: second refrigerant inlet hole
3-H3: 2nd refrigerant discharge hole 3-H4: 1st coolant inlet communication hole
3-H5: 1st coolant discharge hole 3-H6: 2nd coolant inlet through hole
3-H7: 2nd coolant discharge through-hole 3-P1: 2nd refrigerant bulkhead
3-P2: 2nd refrigerant extension bulkhead 3-P3, 3-P4: 2nd coolant mixing prevention unit
1322: second coolant plate 4-H2: second refrigerant inlet hole
4-H3: 2nd refrigerant discharge passage hole 4-H4: 1st coolant inflow passage hole
4-H5: 1st coolant discharge passage hole 4-H6: 2nd coolant inlet hole
4-H7: 2nd coolant discharge hole 4-P1: 2nd coolant bulkhead
4-P2: 2nd Refrigerant Mixing Prevention Unit 4-P3: Cooling Water Mixing Prevention Unit
1400: heat exchange expansion part R: refrigerant flow line
R1: first refrigerant flow line R2: second refrigerant flow line
CW1: 1st coolant flow line CW2: 2nd coolant flow line

Claims (30)

An upper plate equipped with refrigerant inlet and outlet ports;
a lower plate spaced apart from the upper plate and provided with first and second cooling water inlet and outlet ports, respectively; and
A heat exchange unit interposed between the upper plate and the lower plate and exchanging heat with each other while the refrigerant and the first and second cooling water flows,
The heat exchange part,
A first heat exchange unit in which a plurality of first refrigerant plates through which the refrigerant flows and a plurality of first cooling water plates through which the first cooling water flows are alternately stacked under the upper plate;
Between the first heat exchange part and the lower plate, a plurality of second refrigerant plates through which the refrigerant passing through the first refrigerant plate flows and a plurality of second cooling water plates through which the second cooling water flows are alternately stacked. A heat exchanger including two heat exchange units. The method of claim 1,
A first refrigerant inlet hole through which the refrigerant supplied from the refrigerant inlet port can flow is formed in each first refrigerant plate except for the first refrigerant plate disposed at the lowermost end of the first heat exchange unit,
Each first refrigerant plate of the first heat exchange unit has a first refrigerant outlet hole through which the refrigerant flowing into the first refrigerant inlet hole flows downward, and the refrigerant flowing through each of the second refrigerant plates A heat exchanger having a first refrigerant discharge hole through which the refrigerant can be discharged through the discharge port. The method of claim 2,
The first refrigerant discharge hole is disposed between the first refrigerant inlet hole and the first refrigerant outlet hole. The method of claim 3,
Each of the first refrigerant plates,
first refrigerant partition walls protruding to block both sides and upper portions of the first refrigerant discharge hole;
A heat exchanger comprising a first refrigerant extension partition wall extending a flow path of the refrigerant by extending an upper portion of the first refrigerant partition wall to both sides. The method of claim 2,
Each of the first refrigerant plates,
a first coolant inlet through hole through which the first coolant introduced from the first coolant inlet port passes;
A heat exchanger having a first coolant discharge through-hole through which the first coolant discharged through the first coolant discharge port passes. The method of claim 5,
Each of the first refrigerant plates,
A heat exchanger having a first coolant mixing prevention part protruding to surround the circumferences of the first coolant inlet through-hole and the first coolant discharge through-hole to prevent mixing of the first coolant with the refrigerant. The method of claim 5,
Each of the first cooling water plates,
a first coolant inlet hole communicating with the first coolant inlet through-hole so that the first coolant flows in from the first coolant inlet port;
A heat exchanger having a first coolant discharge hole communicating with the first coolant discharge through-hole so that the first coolant introduced from the first coolant inlet hole is discharged to the first coolant discharge port. The method of claim 7,
Each of the first cooling water plates,
and a first coolant partition wall protruding to partially block a space between the first coolant inlet hole and the first coolant discharge hole to expand a flow path of the first coolant. The method of claim 7,
Each of the first cooling water plates,
A first refrigerant inlet communication hole communicating with the first refrigerant inlet hole so that the refrigerant supplied from the refrigerant inlet port can pass therethrough;
A first refrigerant outlet communication hole communicating with the first refrigerant outlet hole so that the refrigerant flowing out from the first refrigerant outlet hole can flow downward;
A heat exchanger having a first refrigerant discharge communication hole communicating with the first refrigerant discharge hole so that the refrigerant can be discharged to the discharge port. The method of claim 9,
Each of the first cooling water plates,
A heat exchanger having a first refrigerant mixing prevention unit protruding to surround each of the first refrigerant inlet communication hole, the first refrigerant outlet communication hole, and the first refrigerant discharge communication hole to prevent mixing of the refrigerant and the first coolant. . The method of claim 9,
Each of the second refrigerant plates,
A second refrigerant inlet hole communicating with the first refrigerant outlet hole so that the refrigerant can flow from the first refrigerant outlet hole;
A heat exchanger having a second refrigerant discharge hole communicating with the first refrigerant discharge hole so that the refrigerant introduced from the second refrigerant inlet hole flows and then is discharged to the refrigerant discharge port. The method of claim 11,
Each of the second refrigerant plates,
A heat exchanger comprising a second refrigerant barrier protruding to block between the second refrigerant inlet hole and the second refrigerant discharge hole. The method of claim 12,
Each of the second refrigerant plates,
The heat exchanger further comprises second refrigerant extension partition walls protruding to extend from ends of the second refrigerant partition wall to both sides to expand a flow path of the refrigerant. The method of claim 11,
Each of the second refrigerant plates,
a first coolant inlet communication hole communicating with the first coolant inlet hole to supply first coolant from the first coolant inlet port to the first coolant plate;
a first coolant discharge communication hole communicating with the first coolant discharge hole to discharge the first coolant discharged from the first coolant discharge hole to the first coolant discharge port;
a second coolant inlet through-hole through which the second coolant introduced from the second coolant inlet port passes;
A heat exchanger having a second coolant discharge through-hole through which the second coolant discharged through the second coolant discharge port passes. The method of claim 14,
Each of the second refrigerant plates,
An edge of each of the first coolant inlet communication hole, the first coolant discharge communication hole, the second coolant inlet through hole, and the second coolant discharge through hole protrudes to prevent the refrigerant from being mixed with the first and second coolant. 2A heat exchanger having a cooling water mixing prevention unit. The method of claim 15
The second coolant mixing prevention part protruding from the edge of each of the first coolant inlet communication hole and the first coolant discharge communication hole has an “A” shape,
The second coolant mixing prevention part protruding from the edge of each of the second coolant inlet through-hole and the second coolant discharge through-hole is an annular heat exchanger. The method of claim 14,
Each of the second coolant plates,
a second coolant inlet hole through which the second coolant flows from the second coolant inlet port;
A heat exchanger having a second coolant discharge hole communicating with the second coolant discharge port so that the second coolant introduced through the second coolant inlet hole is discharged. The method of claim 17
Each of the second coolant plates,
and a second coolant partition wall protruding to partially block a space between the second coolant inlet hole and the second coolant discharge hole to expand a flow path of the second coolant. The method of claim 17
Each of the second coolant plates,
a first coolant inlet passage hole communicating with the first coolant inlet hole so that the first coolant passes from the first coolant inlet port;
A heat exchanger having a first coolant discharge passage hole communicating with the first coolant discharge hole so that the first coolant is discharged to the first coolant discharge port. The method of claim 19
Each of the second coolant plates,
and a coolant mixing prevention unit protruding to surround the circumferences of the first coolant inlet hole and the first coolant discharge hole to prevent the first coolant from mixing with the second coolant. The method of claim 19
Each of the second coolant plates,
A second refrigerant inlet through hole through which the refrigerant flowing out from the first refrigerant outlet hole passes;
A heat exchanger having a second refrigerant discharge hole through which the refrigerant can be discharged to the discharge port. The method of claim 21,
Each of the second coolant plates,
A heat exchanger having a second refrigerant mixing prevention part protruding to surround the circumferences of the second refrigerant inlet hole and the second refrigerant discharge hole to prevent the second coolant from being mixed with the refrigerant. The method of claim 21,
The heat exchange part,
A refrigerant flow line through which a refrigerant flows;
A first coolant flow line through which the first coolant flows;
A heat exchanger comprising a second coolant flow line through which the second coolant flows. The method of claim 23
The refrigerant flow line,
A first refrigerant flow line through which the refrigerant introduced through the first refrigerant inlet hole flows through each of the first refrigerant plates and then flows out through the first refrigerant outlet hole;
The refrigerant that has passed through the first refrigerant outlet hole is introduced through the second refrigerant inlet hole, flows through each of the second refrigerant plates in the opposite direction to the flow in the first refrigerant plate, and then discharges the second refrigerant. A heat exchanger including a second refrigerant flow line discharged through a hole. The method of claim 24
The first coolant flow line,
The first coolant is introduced through the first coolant inlet port through the first coolant inlet hole, flows through each of the first coolant plates, and then is discharged through the first coolant discharge hole to the first coolant discharge port. A heat exchanger, characterized in that. The method of claim 24
The second coolant flow line,
The second coolant is introduced through the second coolant inlet port through the second coolant inlet hole, flows through each of the second coolant plates, and then is discharged to the second coolant discharge port through the second coolant discharge hole. A heat exchanger, characterized in that. 27. The method according to any one of claims 1 to 26,
The inlet and outlet ports of the first cooling water and the inlet and outlet ports of the second cooling water are arranged to face each other on both sides of the lower plate. The method of claim 27
The inlet and outlet ports of the refrigerant are disposed between the inlet and outlet ports of the first and second cooling water. 27. The method according to any one of claims 1 to 26,
A heat exchanger in which a heat exchange extension part including a plurality of projections (embossed) or inner fins is coupled to the inside of the first and second refrigerant plates and the first and second coolant plates to increase the heat exchange area and induce turbulence. The method of claim 21,
The plurality of protrusions (embossed) or inner fins are disposed parallel to the flow direction of the refrigerant or the first and second cooling water.

Images