KR20200027773A - Plate type heat exchanger - Google Patents

Abstract

The present invention relates to a plate type heat exchanger. According to an embodiment of the present invention, the plate type heat exchanger includes a plate package in which a plurality of heat exchange plates are stacked. In addition, the heat exchange plate comprises: an inlet port; and a header provided on one side of the inlet port and having a connection port for distributing refrigerants to the adjacent heat exchange plates.

Description

Plate type heat exchanger

The present invention relates to a plate heat exchanger.

The heat exchanger is a device for guiding heat exchange between at least two fluids and may include, for example, a plate heat exchanger. The plate heat exchanger is composed of a plurality of heat exchange plates stacked, and between the plurality of stacked heat exchange plates, two or more flow paths through which fluids forming different temperatures flow, i.e., a first flow path through which the first fluid flows And a second flow path through which the second fluid flows.

The first and second flow paths may be alternately arranged to exchange heat. In one example, the first fluid may be composed of a refrigerant, the second fluid may be composed of water. The plate-type heat exchanger has an advantage of high heat exchange efficiency compared to other heat exchangers, and its structure can be reduced in size and weight.

The plate heat exchanger includes a refrigerant inlet through which the refrigerant flows, and the refrigerant introduced through the refrigerant inlet may be distributed to the first flow path and flow into a space between each plate.

On the other hand, when the plate heat exchanger is used as an evaporator, a refrigerant having a low dryness, that is, a liquid phase refrigerant and a gas phase refrigerant are mixed into the plate type heat exchanger. Liquid refrigerant and gaseous refrigerant have different specific gravity (density), and in the case of liquid refrigerant, the inertia force is relatively large in the process of flow, so that when the two-phase refrigerant flows into the plate heat exchanger, it is not evenly distributed to each plate. May appear.

Therefore, since the amount of refrigerant flowing into each plate is not evenly distributed, a problem that the heat transfer area of the heat exchange plate is not sufficiently utilized may occur.

In addition, a phenomenon in which a large amount of liquid refrigerant is distributed in one plate space and a large amount of gas phase refrigerant is distributed in a space between other plates may appear. In the evaporator, since the gaseous refrigerant is a refrigerant that does not require heat exchange, there is a problem in that the heat exchange performance decreases in the plate space where the gaseous refrigerant flows.

In connection with such a plate heat exchanger, the following prior art is introduced.

1. Japanese registered patent number (date of registration): Japanese patent 4856170 (November 4, 2011)

2. Name of invention: Plate heat exchanger

The present invention has been proposed to solve this problem, and an object of the present invention is to provide a plate heat exchanger capable of improving heat exchange performance by evenly distributing refrigerant through a plurality of heat exchange plates.

In addition, an object of the present invention is to provide a plate heat exchanger capable of uniformly distributing the amount of refrigerant flowing into each plate by applying a double pipe structure to the refrigerant inlet port side of each plate.

In particular, a header having a header inlet is provided around the inlet port of the refrigerant, and the refrigerant flowing into the header through the header inlet can flow to the header of an adjacent plate through the connection port, thereby improving the distribution performance of the refrigerant. An object of the present invention is to provide a plate heat exchanger that can be improved.

In addition, an object of the present invention is to provide a plate heat exchanger through which the refrigerant in the header is discharged to the refrigerant passage through the header outlet and flows to the outlet port of the refrigerant. In addition, a plurality of header outlets are provided, so that refrigerant discharge from the header can be easily performed.

In addition, it is an object to provide a plate heat exchanger through which the refrigerant flowing in the stacking direction through the connection port can be easily discharged from the header through an adjacent header outlet by allowing the connection port to be discharged between the plurality of header outlets. Is done.

In addition, by allowing the end of the header body to extend further in the circumferential direction than the header inlet, the liquid refrigerant flowing into the header through the header inlet flows downward by gravity and then flows upward toward the connection port, thereby causing two phases. It is an object of the present invention to provide a plate heat exchanger in which mixing of refrigerants can be easily performed.

In addition, an object of the present invention is to provide a plate heat exchanger that can easily distribute refrigerant between adjacent plates by cutting a top surface of the header body to form a flow path of the refrigerant without penetrating a separate connection port to the header body.

A plate heat exchanger according to an embodiment of the present invention includes a plate package formed by stacking a plurality of heat exchange plates.

The heat exchange plate includes an inlet port and a header provided on one side of the inlet port and having a connection port for distributing refrigerant to an adjacent heat exchange plate.

The heat exchange plate further includes a header inlet portion extending from the inlet port to the header and guiding the refrigerant passing through the inlet port to the header.

The heat exchange plate further includes a header outlet that extends from the header and discharges the refrigerant in the header to the refrigerant passage.

The header includes a plate body protruding from the plate body and forming a refrigerant flow space.

The connection port is formed through at least a portion of the plate body.

The connection port includes a plurality of connection ports arranged in a circumferential direction.

The header outlet portion extends radially from the outer surface of the header.

With respect to the two extension lines (ℓ3, ℓ4) respectively connecting the first and second header outlets from the center (C1) of the inlet port, the connection port can be located between the two extension lines (ℓ3, ℓ4). have.

The header extends in the circumferential direction from the outside of the inlet port, and may have first and second ends.

The first extension line L1 extending from the center C1 of the inlet port 130 to the first end and the second extension line L2 extending from the center C1 to the second end are set angles ( θ1) can be formed.

The set angle θ1 has a value of 90 degrees or more and 180 degrees or less.

The header inlet portion extends radially from the inlet port toward the arc surface of the header, and the arc surface is disposed to surround at least a portion of the circumference of the inlet port.

The first end may be disposed at a position extending further in a circumferential direction from a point of the arc surface to which the header inlet is connected.

The sum of the total cross-sectional area of the header inlet may be 20% or more and 100% or less of the cross-sectional area of the inlet port 130.

The cross-sectional area of the connection port may be formed at least three times the cross-sectional area of the header inlet.

The header body extends in the circumferential direction from the outside of the inlet port.

The connection port is formed in a circumferential direction on one surface of the header body.

According to the present invention according to the above-described solution, by installing a header around the refrigerant inlet port and guiding the flow of refrigerant to adjacent plates, the effect of improving the distribution performance of refrigerants to a plurality of heat exchange plates appears. Therefore, there is an advantage that the heat transfer area of a plurality of heat exchange plates can be evenly utilized.

In detail, by applying the double pipe structure of the refrigerant inlet port and the header, refrigerant flowing in the stacking direction through the refrigerant inlet port flows into the header of each plate, and the refrigerant in the header is laminated toward the header of the adjacent plate through the connection port. Direction, the refrigerant can be uniformly distributed to each plate.

In addition, the refrigerant flowing in the header may be discharged through the header outlet and flow to the outlet port of the refrigerant. In addition, a plurality of header outlets are provided, and since the plurality of header outlets extend in a direction from the header toward the outlet port of the refrigerant, the flow of refrigerant toward the outlet port of the refrigerant can be easily achieved.

In addition, since the connection port is discharged between the plurality of header outlets, refrigerant flowing in the stacking direction through the connection port can be easily discharged from the header through an adjacent header outlet.

In addition, since the lower end of the header body is located at a lower side than the header inlet, the liquid refrigerant flowing into the header through the header inlet may flow downward by gravity and then flow upward toward the connection port. Therefore, mixing of the two-phase refrigerant can be easily achieved.

Also, as a second embodiment, since a separate connection port is not formed through the header body, a flow path of the refrigerant can be formed by cutting an upper surface of the header body, so that refrigerant distribution between adjacent plates can be easily performed.

1 is a perspective view showing a configuration of a plate heat exchanger according to a first embodiment of the present invention.
2 is a view showing the configuration of a heat exchange plate constituting a plate-type heat exchanger according to the first embodiment of the present invention.
FIG. 3 is an enlarged front view of a portion “A” of FIG. 2.
4 is a view showing a state in which the first and second plates according to the first embodiment of the present invention are arranged in a stacking direction.
5 is a view showing a partial configuration of the plate package (P) according to the first embodiment of the present invention.
6 is a cross-sectional view taken along line VI-VI 'of FIG. 5.
7 is a schematic diagram showing the flow of refrigerant in the plate package P according to the first embodiment of the present invention.
8 is a view showing the flow of refrigerant from the refrigerant inlet port to the refrigerant outlet port in the plate according to the first embodiment of the present invention.
9 is a view showing the peripheral configuration of the refrigerant inlet port of the plate according to the second embodiment of the present invention.
10 is a view showing a state in which the first and second plates according to the second embodiment of the present invention are arranged in a stacking direction.
11 is a view showing a partial configuration of a plate package (P) according to a second embodiment of the present invention.
12 is a cross-sectional view taken along line XII-XII 'of FIG. 11.

Hereinafter, specific embodiments of the present invention will be described with reference to the drawings. However, the spirit of the present invention is not limited to the presented embodiments, and those skilled in the art to understand the spirit of the present invention may easily propose other embodiments within the scope of the same spirit.

1 is a perspective view showing a configuration of a plate heat exchanger according to a first embodiment of the present invention, and FIG. 2 is a diagram showing a configuration of a heat exchange plate constituting a plate heat exchanger according to a first embodiment of the present invention.

First, referring to FIG. 1, the plate heat exchanger 10 according to an embodiment of the present invention includes plate packages P including a plurality of heat exchange plates 100 and both sides of the plate packages P Two end plates 20 and 30 are included. For example, the heat exchange plate 100 and the two end plates 20 and 30 may have a quadrangular panel shape.

The heat exchange plate 100 may be made of a metal material having excellent thermal conductivity and excellent pressure resistance to pressure. For example, the heat exchange plate 100 may be made of stainless steel.

The plurality of heat exchange plates 100 may be arranged to be stacked in the front-rear direction (based on FIG. 1, vertical direction). The front-rear direction may be referred to as a "stacking direction".

Between the plurality of heat exchange plates 100, a flow path through which a fluid flows is formed. The flow path includes a first flow path through which the first fluid flows and a second flow path through which the second fluid flows. The first and second flow paths may be alternately arranged in sequence.

The two end plates 20 and 30 include a first end plate 20 provided in front of the plate package P and a second end plate 30 provided in the rear of the plate package P. Is included. That is, between the two end plates 20 and 30, the plate package P may be installed.

In the plate heat exchanger (10), a first inlet (61) to allow a first fluid to flow into the interior of the plate package (P) and a second fluid to flow into the interior of the plate package (P) 2 the inlet 71 is further included. The first inlet 61 and the second inlet 71 may be coupled to the first end plate 20. The first and second fluids have temperature differences, and may be heat exchanged with each other. In one example, the first fluid may be a refrigerant, and the second fluid may be water. Accordingly, the first inlet 61 may be referred to as a refrigerant inlet, and the second inlet 71 may be referred to as a water inlet.

In the plate heat exchanger 10, a first outlet portion 65 for allowing a first fluid to be discharged from the plate package P and a second outlet portion for allowing a second fluid to be discharged from the plate package P ( 75) is further included. The first outlet portion 65 and the second outlet portion 75 may be coupled to the first end plate 20.

For example, in the installation state of the plate heat exchanger 10, the first inlet 61 and the second outlet 75 are located below the plate heat exchanger 10, the first outlet ( 65) and the second inlet 71 may be located above the plate heat exchanger (10).

In detail, the first inlet portion 61 and the first outlet portion 65 may be disposed on the first and fourth corner sides arranged diagonally among the four corners of the end plate 20. In addition, the first inlet 61 may be located at the bottom of the first end plate 20, and the first outlet 65 may be located at the top of the first end plate 20.

The second inlet portion 71 and the second outlet portion 75 may be disposed at second and third edge sides arranged in different diagonal directions among the four corners of the end plate 20. In addition, the second inlet portion 71 may be positioned above the first end plate 20, and the second outlet portion 75 may be positioned below the first end plate 20.

In other words, the first inlet portion 61 and the second outlet portion 75 are disposed on both lower sides of the first end plate 20, and the first outlet portion 65 and the second inlet portion 71 ) May be disposed on both lower sides of the first end plate 20.

Next, referring to FIG. 2, in the heat exchange plate 100 according to the first embodiment of the present invention, a plate body 110 having a shape of a substantially quadrangular panel and a border surrounding the outside of the plate body 110 Part 120 is included.

The heat exchange plate 110 is arranged on the four corners of the plate body 110 and communicates with the first and second inlets 61 and 71 and the first and second outlets 65 and 75 to transfer fluid. A number of inlet and outlet ports 130, 135, 140 and 145 to guide the flow are included. The plurality of entry / exit ports 130, 135, 140, and 145 may be formed through at least a portion of the plate body 110.

The plurality of inlet and outlet ports (130,135,140,145) is formed at a position corresponding to the first inlet 61 and a first inlet port 130 and a first outlet 65 through which a first fluid (refrigerant) is introduced. It is formed in a corresponding position and includes a first outlet port 135 through which the first fluid is discharged. The first inlet port 130 may be referred to as a "refrigerant inlet port" and the first outlet port 135 may be referred to as a "refrigerant outlet port".

The refrigerant flows into the first flow path (R1, refrigerant flow path) of the plate package P in the process of flowing to the rear of the heat exchange plate 100 through the first inlet port 130, and heat exchanged in the refrigerant flow path The refrigerant is discharged from the plate package P through the first outlet port 135 and may flow forward toward the first outlet portion 65.

The plurality of inlet and outlet ports (130,135,140,145) is formed at a position corresponding to the second inlet portion (71) and a second inlet port (140) and a second outlet portion (75) through which a second fluid (water) flows. It is formed in a corresponding position and includes a second outlet port 145 through which the second fluid is discharged. The second inlet port 140 may be referred to as a “water inlet port” and the second outlet port 145 may be referred to as a “water outlet port”.

Water flows into the second flow path (W1, water flow path) of the plate package P in the process of flowing to the rear of the heat exchange plate 100 through the second inlet port 140, and heat exchanged in the water flow path Water is discharged from the plate package (P) through the second outlet port 145 and may flow forward toward the second outlet (75).

The front surface of the plate body 110 includes irregularities. In detail, the unevenness includes a protrusion 112 protruding forward from the front surface of the plate body 110 and a depression 114 recessed rearward from the front surface of the plate body 110. A plurality of protrusions 112 and depressions 114 may be provided, and may be alternately arranged. In addition, the unevenness may be included in the rear surface of the plate body 110.

For example, herringbone patterns may be formed on the front and rear surfaces of the plate body 110 by the plurality of protrusions 112 and the plurality of recesses 114.

The unevenness of the plate body 110 may be provided to contact the unevenness provided in another adjacent heat exchange plate 100. Then, the contact irregularities can be joined by a predetermined method. For example, the predetermined method may include an adhesive method by welding or adhesive. For example, a protrusion 112 of the second plate 102 may be attached to the depression 114 of the first plate 101.

3 is an enlarged front view of a portion “A” of FIG. 2, and FIG. 4 is a view showing a state in which the first and second plates according to the first embodiment of the present invention are arranged in a stacking direction, and FIG. 5 is the present invention FIG. 6 is a view showing a part of the plate package P according to the first embodiment of the present invention, and FIG. 6 is a cross-sectional view taken along line VI-VI 'of FIG. 5.

3 to 6, a first inlet port 130 formed through one edge of the plate body 110 is formed in the heat exchange plate 100 according to the first embodiment of the present invention. The first inlet port 130 may have, for example, a circular shape.

The plate body 110 includes a flat portion 115 disposed around the first inlet port 130 and having a flat surface. In other words, it may be understood that the first inlet port 130 is formed in the flat plate 115. The flat plate portion 115 may form a junction portion adjacent to the heat exchange plate.

The plate portion 115 may be provided with a header 200 through which at least a portion of the first fluid flowing through the first inlet port 130 flows. The header 200 may be configured to form an arc shape having a width w set in a radial direction. Here, the "radial direction" may be a direction defined based on the center of the first inlet port 130.

Therefore, the header 200 may be arranged to surround the outer circumferential surface of at least a portion of the outer circumferential surface of the first inlet port 130. In addition, a coolant flow space through which the coolant flows may be formed inside the header 200.

The header 200 may be located on the flat plate portion 115 in an area between the first inlet port 130 disposed at one corner side of the heat exchange plate 100 and the central portion of the heat exchange plate 100. have.

The header 200 extends from the header body 210 protruding from the flat plate portion 115 and the first inlet port 130 to the header body 210 so that refrigerant flows into the header 200. The header inlet portion 220 is included. The header inlet portion 220 protrudes from the flat plate portion 115 and may be connected to an outer surface of the header body 210.

In detail, the header inlet 220 is connected to the first arc surface 211 of the header body 210. The first arc surface 211 may surround at least a portion of the circumference of the first inlet port 130 and extend roundly in a circumferential direction at a set curvature. For example, the header inlet 220 may have a shape of a semi-circular or polygonal shape, the diameter or the internal length of the header inlet 220 may be formed in the range of up to 0.5 ~ 2.0mm.

Referring to FIG. 4, the heat exchange plate 100 includes first and second plates 101a and 101b disposed adjacent to each other. The first and second plates 101a and 101b are joined to each other, and a refrigerant flows in a space between the protrusion 112 and the depression 114 provided in the first and second plates 101a and 101b, respectively. A first flow path (R1, refrigerant flow path) may be formed.

The first and second plates 101a and 101b may be joined at a plurality of joints. In detail, the plurality of joining portions include a first joining portion 118a provided at the edge end of the first and second plates 101a and 101b, a second joining portion 118b provided on the flat portion 115, and A third joining portion 118c disposed between the first inlet port 130 and the second outlet port 145 is included.

By the plurality of joining portions, two adjacent heat exchange plates 100 are sealed to the outside to form the first flow path R1 or the second flow path W1 (water flow path), and the first flow path R1 The second flow paths W1 may be separated from each other. Therefore, mixing of the first fluid (refrigerant) and the second fluid (water) can be prevented.

The first plate 101a includes a first header inlet portion 220a communicating with the first inlet port 130. The first header inlet portion 220a is configured to protrude forward from the first plate 101a.

The second plate 101b includes a second header inlet portion 220b communicating with the inlet port 130. The second header inlet portion 220b is configured to protrude rearward from the second plate 101b.

The refrigerant introduced through the first and second header inlets 220a and 200b flows into each header 200 of the first and second plates 101a and 101b, and the first through the header outlet 230. It can flow to the first flow path (R1) formed by the two plates (101a, 101b). In addition, since the internal space in each header 200 can be communicated through the connection port 240, the refrigerant in one header 200 can be distributed to the other header 200.

The first header inflow portion 220a and the second header inflow portion 220b are alternately arranged with respect to the front-rear direction (lamination direction) and are not positioned on the same line. That is, with respect to the front-rear direction (stacking direction), the first header inlet 220a and the second header inlet 220b may not overlap each other. According to such a configuration, since the inflow passages flowing into the first and second plates 101 and 101b may result in distribution into two flow passages, there is no interference between the incoming refrigerant flows and a wide plate-shaped heat exchange plate The distribution of the refrigerant to 100 can be made easily.

The header 200 further includes a header outlet 230 extending radially from the header body 210 and discharging the refrigerant in the header body 210 to the first flow path R1. The first flow path R1 may be formed in a space between two adjacent heat exchange plates 100. In addition, the header outlet portion 230 may protrude from the flat plate portion 115.

In detail, the header outlet portion 230 is connected to the second arc surface 212 of the header body 210. The second arc surface 212 may have a greater radius of curvature than the first arc surface 211 and may be roundly extended to a curvature set to surround the first arc surface 211.

A plurality of header outlets 230 may be provided. The plurality of header outlets 230 are spaced apart from each other in the circumferential direction, and each header outlet 230 may extend radially from the second arc surface 212. In detail, the plurality of header outlets 230 may include a first outlet portion 231, a second outlet portion 232, and a third outlet portion 233. By providing a plurality of the header outlets 230, the refrigerant in the header 200 can be easily flowed to the first flow path (R1).

The header 200 further includes a connection port 240 through which at least a portion of the header body 210 is formed. The connection port 240 may be formed on the front surface of the header body 210. The refrigerant in the header body 210 may be discharged through the connection port 240 and may be introduced into the header 240 through the connection port 240 of the adjacent heat exchange plate 100.

For example, the connection port 240 may have a circular shape. However, the shape of the connection port 240 is not limited to this, and may have a polygonal shape.

A plurality of connection ports 240 may be provided. The plurality of connection ports 240 are spaced apart from each other in the circumferential direction, and may include at least four connection ports 240. In detail, the plurality of connection ports 240 include a first port 241, a second port 242, a third port 243, and a fourth port 244. However, the number of the connection ports 240 is not limited.

The header body 210 includes a first end 215 and a second end 216 forming both ends of the header body 210. The first end 215 forms a lower portion of the header body 210, and the second end 216 forms an upper portion of the header body 210. In addition, it can be understood that the header body 210 extends in a circumferential direction from the first end 215 toward the second end 216.

The first end 215 may be located below the header inlet 220. In detail, the first end 215 may be formed at a position extending further in the circumferential direction from a point of the first arc surface 211 to which the header inlet 220 is connected. As described above, the header body 210 is further configured to extend downward from the header inlet 220, so that when the liquid refrigerant flows through the header inlet 220, the liquid refrigerant is applied to the agent by gravity. It becomes possible to flow toward one end 215 side. As a result, a storage space for the liquid refrigerant may be formed in the header body 210.

A first extension line L1 extending from the center C1 of the first inlet port 130 to the first end 215 and a second extension line extending from the center C1 to the second end 216 (ℓ2) forms a set angle (θ1). The set angle θ1 may form a value of 90 degrees or more and 180 degrees or less. According to this configuration, since the header 200 has a sufficient size, the refrigerant is easily distributed to the adjacent header 200, and the refrigerant flowing into the header 200 is easily directed toward the central portion of the heat exchange plate 100 Can be discharged.

When defining the third and fourth extension lines (ℓ3, ℓ4) connecting the plurality of header outlets 230 from the center (C1) of the first inlet port 130, the plurality of connection ports 240 One of the connection ports may be located between the third and fourth extension lines (ℓ3, ℓ4). That is, the third and fourth extension lines L3 and L4 may be configured not to meet the one connection port.

As an example, FIG. 3 shows that the fourth port 244 is positioned between the third and fourth extension lines ℓ3 and ℓ4. And, it shows that the third port 243 is located between the extension lines connecting the first and second outlets 231 and 232 from the center C1 of the first inlet port 130, respectively.

In this way, the connection port 240 for sending refrigerant to the header 200 of the adjacent heat exchange plate 100 and the outlet 230 are formed to be staggered with respect to each other in the circumferential direction, so that among the refrigerants in the header 200 The amount of refrigerant discharged through the outlet 230 may be prevented from being reduced. That is, it is possible to prevent the amount of refrigerant in the header 200 from being discharged through the connection port 240.

Referring to FIG. 5, the plate package P according to the first embodiment of the present invention includes a plurality of heat exchange plates 101a to 101n. For example, the plate package P may include 76 heat exchange plates. Of these, 1/2, that is, 38 heat exchange plates may be plates contributing to forming the first flow path R1, and the remaining 38 heat exchange plates may be plates contributing to forming the second flow path W1. .

In addition, adjacent plates forming the first and second flow paths R1 and W1 may be alternately disposed. In one example, the first and second plates 101a and 101b are joined to form the first flow path R1, and the second and third plates 101b and 101c are joined to form the second flow path W1. . Then, the third and fourth plates 101c and 101d may be joined to form the first flow path R1. This arrangement may be repeated to construct the plate package P.

In order to secure refrigerant heat exchange performance in the plurality of heat exchange plates 101a to 101n, an appropriate amount of refrigerant needs to be introduced into the header 200, and the size of the header inlet 220 is determined in consideration of this. There is a need. In detail, the sum of the cross-sectional areas of the header inlets 220 for introducing the refrigerant into the header 200, that is, the cross-sectional areas of the header inlets 220 of the 38 heat exchange plates forming the first flow path R1, is determined by the first cross section. One needs to be 20% or more of the cross-sectional area of the inlet port 130.

If, if the sum of the cross-sectional area of the header inlet 220 is not more than 20% of the cross-sectional area of the first inlet port 130, the inlet pressure of the plate heat exchanger 10, that is, the first inlet 61 A problem in which the pressure loss at is greatly increased may appear.

On the other hand, the sum of the cross-sectional areas of the header inlets 220 of the 38 heat exchange plates needs to be 100% or less of the cross-sectional area of the first inlet port 130. If, when the sum of the cross-sectional area of the header inlet 220 is 100% or more of the cross-sectional area of the first inlet port 130, the header 200 of each plate 100 from the first inlet port 130 There may be a problem in that the refrigerant distribution deviation introduced into the furnace is greatly increased.

The diameter of the connection port 240 may be formed in a range of approximately 1.2 ~ 1.8mm. In addition, the cross-sectional area of the connection port 240 may be formed in a size larger than or equal to a predetermined size in order to distribute the refrigerant evenly to the plurality of heat exchange plates 100. For example, the cross-sectional area of the connection port 240 provided in each plate 100 may be formed to be three times or more the cross-sectional area of the header inlet 220. The cross-sectional area of the connection port 240 may be understood as the total cross-sectional area of the plurality of connection ports 240.

If, when the sum of the cross-sectional areas of the plurality of connection ports 240 is not formed to be more than three times the cross-sectional area of the header inlet portion 220, an even distribution of refrigerant through play through the connection port 240 is achieved. It may not be.

Referring to FIG. 6, the first inlet ports 130 provided in each heat exchange plate 100 are arranged in the front-rear direction. In addition, the header 200 provided in each heat exchange plate 100 is arranged in the front-rear direction, and the connection port 240 formed in the header 200 may also be arranged in the front-rear direction. A collection of a plurality of headers 200 arranged in the front-rear direction may be referred to as a "header assembly".

In detail, the plurality of heat exchange plates 100 include a first plate 101a, a second plate 101b, a third plate 101c, and a fourth plate 101d stacked from front to rear.

Each of the first to fourth plates 101a, 101b, 101c, and 101d has first inlet ports 130 through which the first fluid flowing through the first inlet 61 flows, and a plurality of first inlets. Port 130 may be aligned in the front-rear direction.

The first to fourth plates 101a, 101b, 101c, and 101d are each formed with a second outlet port 145 through which the second fluid heat-exchanged with the first fluid flows toward the second outlet 75, respectively. The second outlet port 145 may be aligned in the front-rear direction.

The first fluid flowing from the first inlet port 130 toward the first flow path R1 and the second fluid flowing from the second flow path W1 toward the second outlet port 145 are: 3 can be separated from each other by the joining portion of the protrusion 112 and the depression 114 formed on the joint 118c and the plate 100.

The first to fourth plates 101a, 101b, 101c, and 101d include first plate ports 240a, second plate ports 240b, third plate ports 240c, and second headers provided in each header 220. 4 plate port 240d may be configured to be aligned in the front-rear direction. The first to fourth plate ports 240a, 240b, 240c, and 240d may be understood as "connection ports" provided in each plate.

Refrigerant distribution between plates may be achieved through the aligned first to fourth plate ports 240a to 240d. That is, the refrigerant flowing into each header 200 of the plate through the first inlet port 130 flows in the front-rear direction through the first to fourth plate ports 240a to 240d, thereby allowing a plurality of heat exchange plates 100 ) Side.

As a result, the refrigerant present in the header 200 of any one heat exchange plate 100 may flow into the header 200 of another adjacent heat exchange plate 100 through the connection port 240. That is, since the refrigerant can flow to the adjacent heat exchange plate 100 through the header 200 arranged in the front-rear direction, the refrigerant distribution performance to each plate 100 can be improved.

7 is a schematic diagram showing a flow of refrigerant in the plate package P according to the first embodiment of the present invention, and FIG. 8 is a plate according to the first embodiment of the present invention, from the refrigerant inlet port to the refrigerant outlet port It is a view showing the flow of the refrigerant.

Referring first to FIG. 7, the refrigerant f1 introduced through the first inlet 61 flows backward, passing through the first inlet ports 130 aligned up and down of the plate package P, and each heat exchange plate. Each header body 210 may be introduced through the header inlet 220 of the (100) (f2).

The refrigerant introduced into the header body 210 may flow in a circumferential direction along the header body 210 extending round in an arc shape (f3), and the first flow path R1 through the header outlet 230 It can be introduced into (f4). The first flow path R1 may be defined as a space between two stacked heat exchange plates 100 as an inner space of the protrusion 112 and the depression 114 joined together.

The refrigerant in the first flow path R1 may be heat-exchanged with water in the adjacent second flow path W1. The second flow path W1 may be defined as a space between two heat exchange plates 100 of another combination, and may be defined as an inner space of the protrusion 112 and the depression 114 joined together.

On the other hand, the inner space of the header body 210, that is, the flow space of the refrigerant is communicated with the header body 210 of the adjacent plate by the connecting port 240 arranged in the vertical direction, so that the flow to the adjacent plate without loss of refrigerant Refrigerant distribution may be achieved. That is, as the pressure of the refrigerant flowing through the first inlet ports 130 aligned in the front-rear direction is equalized, the refrigerant is equalized to the header 200 of each heat exchange plate 100 through the header inlet 220. Can be dispensed.

Next, referring to FIG. 8, the refrigerant flowing into the first flow path R1 through the header outlet portion 230 flows in a diagonal direction of the heat exchange plate 100 and faces the first outlet port 135.

The first outlet port 135 is formed through at least a portion of the heat exchange plate 100. In addition, a port connection portion 136 for guiding the refrigerant from the first flow path R1 to the first outlet port 135 may be provided on the circumferential side of the first outlet port 135. A plurality of the port connection parts 136 are provided, and may be radially extended from the outer circumference of the first outlet port 135. Therefore, the refrigerant in the first flow path R1 may be discharged to the first outlet port 135 through the plurality of port connections 136.

In a state in which a plurality of heat exchange plates 100 are stacked in the front-rear direction, the first outlet ports 135 of each heat exchange plate 100 may be aligned in the front-rear direction. Refrigerants discharged to the first outlet port 135 of each heat exchange plate 100 are laminated with each other, and the laminated refrigerant may be discharged from the plate heat exchanger 10 through the first outlet 65.

Hereinafter, a second embodiment of the present invention will be described. Since this embodiment has only some differences in the structure of the header compared to the first embodiment, the differences are mainly described, and the same parts as the first embodiment are described with reference to the first embodiment and reference numerals.

9 is a view showing the peripheral configuration of the refrigerant inlet port of the plate according to the second embodiment of the present invention, and FIG. 10 shows a state in which the first and second plates according to the second embodiment of the present invention are arranged in a stacking direction. 11 is a view showing a partial configuration of a plate package P according to a second embodiment of the present invention, and FIG. 12 is a cross-sectional view taken along line XII-XII 'of FIG. 11.

9 to 12, the heat exchange plate 100 ′ according to the second embodiment of the present invention includes a header 200 ′ disposed on the circumferential side of the first inlet port 130. The heat exchange plate 100 ′ further includes a header inlet 220 extending radially from the first inlet port 130 and connected to the header 200 ′.

As described in the first embodiment, at least some of the refrigerant passing through the first inlet port 130 may be introduced into the header 200 ′ through the header inlet 220.

The header 200 ′ includes a header body 210 ′ forming the through portion 215. The through portion 215 may be understood as being formed through the front portion of the header body 210 ′. The through portion 215 may be formed in a circumferential direction at the front portion of the header body 210 '.

The through part 215 may function as a plurality of connection ports 240 described in the first embodiment. In other words, in the case of the first embodiment, a plurality of connection ports 240 are formed in the header body 210 to guide the refrigerant in the header 200 toward the adjacent heat exchange plate, whereas in this embodiment, one through portion ( 215) is largely formed to perform a function of guiding the refrigerant of the header 200 'toward the adjacent heat exchange plate. Therefore, the through part 215 may be referred to as a “connection port”.

The through portion 215 is formed, so that distribution of refrigerant to the plurality of heat exchange plates 100 may be facilitated. And, the process of forming the through portion 215 in the heat exchange plate 100 can be made simply.

With respect to the header inlet 220, it will be described in more detail.

The first header inlet 220a provided in the first plate 101a and the second header inlet 220b provided in the second plate 101b are staggered (not overlapped) with respect to the front-rear direction, that is, the stacking direction. Not).

In detail, referring to FIG. 12, when considering four plates 101a, 101b, 101c, and 101d sequentially stacked in the front-rear direction among the plate packages P, the second plate 101b is the first plate 101a. It is arranged at the rear, and the third plate 101c is disposed at the rear of the second plate 101b. Further, the fourth plate 101d is disposed behind the third plate 101c.

The first flow path R1 may be defined in a space between the first and second plates 101a and 101b and a space between the third and fourth plates 101c and 101d.

The first header inlet portion 220a provided in the first plate 101a and the second header inlet portion 230a provided in the second plate 101b may not overlap with each other in the front-rear direction. In addition, the third header inlet portion 220c provided in the third plate 101c and the fourth header inlet portion 220d provided in the fourth plate 101d may not overlap with each other in the front-rear direction. .

The first header inlet 220a and the third header inlet 220c may overlap each other with respect to the front-rear direction. In addition, the second header inlet 220b and the fourth header inlet 220d may overlap each other.

Some of the refrigerants passing through the first inlet ports 130 of the plurality of heat exchange plates 100 flow into the first and second header inlets 220a and 220b, respectively, and each of the first and second plates 101a and 101b. It flows inside the header 200 'and is discharged through the header outlet 230. Then, the discharged refrigerant may flow into the first flow path R1a formed by the first and second plates 101a and 101b.

On the other hand, some of the refrigerant passing through the first inlet port 130 of the plurality of heat exchange plates 100 is introduced into the third and fourth header inlets 220c and 220d, and the third and fourth plates 101c, It flows into the interior of each header 200 'of 101d). In addition, some of the refrigerants present in each header 200 ′ of the first and second plates 101a and 101b are respectively disposed in the third and fourth plates 101c and 101d through the through portion 215. It can flow into the interior of the header 200 '.

And, the refrigerant inside each header 200 'of the third and fourth plates 101c and 101d is discharged through the header outlet 230, and the discharged refrigerant is the third and fourth plates 101c and 101d. Yiru can flow into the first flow path (R1b). The first flow path R1b may be disposed behind the first flow path R1a.

On the outer periphery of the header body 210 ', a plurality of header outlets 230 for discharging at least a portion of the refrigerant present in the header body 210' into the first flow paths R1a and R1b. It is provided. The description of the configuration of the header outlet 230 is based on the description of the first embodiment.

The refrigerant discharged through the plurality of header outlets 230 may flow toward the first outlet port 135 via the first flow path R1. The refrigerant may flow to the first outlet port 135 through the port connection part 136. In addition, the refrigerant in the first outlet port 135 may be discharged from the plate heat exchanger 10 through the first outlet portion 65.

10: plate heat exchanger 20,30: end plate
61: first inlet 65: first outlet
71: second inlet 75: second outlet
100: heat exchange plate 110: plate body
112: protrusion 114: depression
130: first inlet port 135: first outlet port
140: second inlet port 145: second outlet port
200: header 210: header body
220: header inlet 230: header outlet
240: connection port

Claims (16)

A first inlet through which the refrigerant flows;
A plate package which is connected to the first inlet and is formed by stacking a plurality of heat exchange plates to form a refrigerant passage; And
It is connected to the plate package, and includes a first outlet through which refrigerant is discharged,
In the heat exchange plate,
A plate body having an inlet port through which the refrigerant introduced from the inlet passes;
A header provided on one side of the inlet port and having a connection port for distributing refrigerant to an adjacent heat exchange plate;
A header inlet extending from the inlet port to the header and guiding the refrigerant passing through the inlet port to the header; And
A plate heat exchanger extending from the header and including a header outlet for discharging the refrigerant in the header to the refrigerant flow path. The method of claim 1,
In the header,
A plate heat exchanger protruding from the plate body and including a header body forming a refrigerant flow space. According to claim 2,
The connection port is a plate heat exchanger formed by passing at least a portion of the header body. The method of claim 1,
The connection port, plate-shaped heat exchanger including a plurality of connection ports. The method of claim 4, wherein
The header is disposed on the circumferential side of the inlet port,
The plurality of connection ports are plate heat exchangers arranged in a circumferential direction. The method of claim 1,
The header outlet,
A plate heat exchanger extending radially from the outer surface of the header. The method of claim 6,
The header outlet, the plate-type heat exchanger including the first and second header outlets. The method of claim 7,
With respect to the two extension lines (ℓ3, ℓ4) respectively connecting the first and second header outlets from the center (C1) of the inlet port,
The connection port is a plate heat exchanger located between the two extension lines (ℓ3, ℓ4). The method of claim 1,
The header extends in the circumferential direction from the outside of the inlet port, and has a plate type heat exchanger having first and second ends. The method of claim 9,
The first extension line L1 extending from the center C1 of the inlet port 130 to the first end and the second extension line L2 extending from the center C1 to the second end are set angles ( θ1),
The set angle (θ1) is a plate heat exchanger having a value of 90 degrees or more and 180 degrees or less. The method of claim 9,
The header inlet portion extends radially from the inlet port toward the arc surface of the header,
The arc-shaped surface heat exchanger surrounding at least a portion of the circumference of the inlet port. The method of claim 11,
The first end is a plate heat exchanger disposed at a position extending further in a circumferential direction from a point of the arc surface to which the header inlet is connected. The method of claim 1,
The plate-type heat exchanger provided in each of the plurality of heat exchange plates, the sum of the total cross-sectional area of the header inlet is 20% or more and 100% or less of the cross-sectional area of the inlet port. The method of claim 1,
The cross-sectional area of the connection port, the plate-shaped heat exchanger is formed at least three times the cross-sectional area of the header inlet. The method of claim 3,
The header body extends in the circumferential direction from the outside of the inlet port,
The connection port is a plate heat exchanger formed in a circumferential direction on one surface of the header body. The method of claim 1,
A second inflow part through which water exchanged with the refrigerant flows;
A water flow path formed in the plate package and heat-exchanging the refrigerant flow path; And
A plate heat exchanger connected to the plate package and further including a second outlet portion through which the water is discharged.

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