JP7076562B2 - Heat exchanger - Google Patents

Description

The present invention relates to heat exchangers, and more particularly to heat exchangers capable of cooling air compressed to high temperature and high pressure by a supercharger in order to increase the output of an engine.

Of the heat exchangers, the intercooler is a device that cools the air compressed to high temperature and high pressure by a supercharger in order to increase the engine output.

The air rapidly compressed by the turbocharger becomes very hot, the volume expands, the oxygen density decreases, and as a result, the suction efficiency in the cylinder decreases. Therefore, the intercooler cools the high-temperature air compressed by the supercharger to increase the intake efficiency of the engine cylinder, improve the combustion efficiency, and improve the fuel efficiency.

The intercooler that plays such a role is divided into a water-cooled type and an air-cooled type according to the cooling method. Of these, the water-cooled intercooler has a similar principle to the air-cooled intercooler, but when cooling the intercooler through which high-temperature air passes, compressed air is used instead of external air, such as vehicle cooling water or water. There is a difference in cooling.

The water-cooled intercooler 10 illustrated in FIG. 1 is formed in a first header tank 20 and a second header tank 30 formed in parallel at a predetermined distance from each other, and in the first header tank 20 or the second header tank 30, respectively. A first inlet pipe 40 into which air flows in, a first outlet pipe 50 discharged from the pipe, and a plurality of tubes 60 fixed at both ends to the first header tank 20 and the second header tank 30 to form an air passage. , A fin 70 interposed between the tubes 60, a cover member 80 that accommodates the tube 60 and the assembly of the fins 70 and opens to one side surface and the other side surface where one side end of the tube 60 is located. It is formed on one side surface of the cover member 80, and includes a second inlet pipe 41 into which cooling water flows in and a second outlet pipe 51 in which cooling water is discharged.

On the contrary, the cooling water passes through the inside of the tube, and the heat exchanger core, which is an assembly in which the header tank, the tube and the fins are assembled, is placed inside, and a case is formed so as to surround the core. This can be configured to allow air to pass through the inside of the case and be cooled by the core.

The water-cooled intercooler can improve the heat exchange efficiency by preventing air from passing between the inside of the case and the outside of the core and allowing all the air to pass through the core. However, in order to insert and assemble the core inside the case, there should be play so that the inside of the case and the outside of the core are separated, so that air is bypassed through the separation between the case and the core. However, the heat exchange performance may deteriorate. Alternatively, the structure and assembly of the case is complicated because the case must be formed with several cuts and then assembled in order to join the inside of the case and the outside of the core so that they are in close contact with each other. Structural strength can be reduced.

Republic of Korea Patent Application No. 10-1116844 B1

The present invention has been made to solve the above-mentioned problems, and the present invention has been made so that air does not bypass through the space between the core portion of the heat exchanger and the housing. It is an object of the present invention to provide a heat exchanger capable of improving heat exchange efficiency by installing a sealing member.

The heat exchanger 1000 of the present invention for achieving the above object has an inlet tank portion 110 and an outlet tank portion 120 in which a space for storing and flowing cooling water is formed therein, and the tank portions 110 and 120. A core portion 100 in which both ends are connected to each other to form a cooling water flow path C, a plurality of tubes 130 arranged apart from each other, and a sealing member insertion groove 150 is formed concavely on the outer surface, and the above. A sealing member 200 including a main body 210 having one side inserted and coupled to the sealing member insertion groove 150 of the core portion 100 and a lip seal 220 extending from the main body 210 and protruding from the outer surface of the core portion 100. Can be.

Further, the core portion 100 may be formed by laminating a tube 130 in which a cooling water flow path C through which cooling water flows is formed by the coupling of the first plate 130a and the second plate 130b.

Further, in the core portion 100, the tubes 130 are laminated and arranged in the height direction, and the sealing member insertion groove 150 is formed on one or more side surfaces of both side surfaces in the length direction formed by laminating the tubes 130. obtain.

Further, the outer sides of the first plate 130a and the second plate 130b are joined to each other to form the first joint portion 201, and the first vertical portion 132 is extended from the first horizontal portion 131 forming the first joint portion 201. The second horizontal portion 133 is extended from the first vertical portion 132, and the second horizontal portion 133 of the first plate 130a and the second horizontal portion 133 of the second plate 130b facing each other of the adjacent tubes 130 are formed from each other. The second joint portion 202 is formed by being joined, and the first plate 130a and the second plate 130b are formed by extending the second vertical portion 134 from the second horizontal portion 133, and the first plate 130a and the second plate 130b are formed. The seal member insertion groove 150 may be formed in a concave shape in a form in which a part of the second horizontal portion 133 and the second vertical portion 134 is removed.

Further, in the seal member 200, the main body 210 inserted into the seal member insertion groove 150 of the core portion 100 is inserted by being locked to the second vertical portion 134 of the first plate 130a and the second plate 130b. It can be coupled to the seal member insertion groove 150 so as not to come off in the direction.

Further, in the seal member 200, the width WL of the lip seal 220 may be formed to be narrower than the width WB of the main body 210.

Further, the seal member 200 is formed from the side surface sealing portion 200-1 inserted and connected to the seal member insertion groove 150 formed on the side surface of the core portion 100 in the length direction and the lower end of the side surface sealing portion 200-1. It can be extended in the width direction and include a lower end sealing portion 200-2 arranged under the lower surface of the core portion 100.

Further, the heat exchanger 1000 of the present invention is formed in a concave shape, and the core portion 100 to which the seal member 200 is bonded is inserted and housed therein, and an air inlet 710 through which air flows is formed on one side. A housing 700 having an air discharge port 720 for discharging air to the other side is further included, and the seal member 200 includes a lip seal 220 in contact with the inner surface of the side wall of the housing 700, and the core portion 100. The space between the housing 700 and the housing 700 may be sealed.

Further, the length L2 of the seal member 200 may be formed longer in the length direction than the distance L1 between the bottom surface of the seal member insertion groove 150 of the core portion 100 and the inner side surface of the side wall of the housing 700.

Further, the lip seal 220 of the seal member 200 may be formed so as to be inclined at a specific angle with respect to a direction perpendicular to the inner surface of the side wall of the housing 700.

Further, the lip seal 220 warps toward the front side in the flow direction of air, and one surface of the free end portion on the width direction side may come into contact with the housing.

Further, in the heat exchanger 1000 of the present invention for achieving the above-mentioned object, the housing 700 provided with an inlet and an outlet so that the boosted air flows in the first direction as the first fluid, and the housing 700. A core portion 100 that is inserted and opens in the first direction so that the first fluid flows, and cooling water flows as a second fluid that exchanges heat with the first fluid, and the core portion 100 and a housing. It can include a sealing member 200 for preventing the first fluid from flowing between the 700 and the 700.

Further, the sealing member 200 can be extended in a second direction intersecting the first direction to seal between the core portion 100 and the housing 700.

Further, the seal member 200 may be fixed to any one of the core portion 100 and the housing 700.

The heat exchanger of the present invention has an advantage that the air does not bypass through the space between the core portion and the housing and the heat exchange efficiency is improved by the sealing member.

It also has the advantage of being easy to assemble, as the sealing member can be easily attached to the housing without the need for separate adhesives or ribs for reinforcement.

It is an exploded perspective view which shows the conventional water-cooled intercooler. It is an exploded perspective view which shows the heat exchanger by one Embodiment of this invention. It is an exploded perspective view which shows the heat exchanger by one Embodiment of this invention. It is an assembly perspective view which shows the heat exchanger by one Embodiment of this invention. It is a top view which shows the heat exchanger according to one Embodiment of this invention. It is an exploded perspective view which shows the core part of the form of the laminated heat exchanger by one Embodiment of this invention. It is a front sectional view which shows the core part of the form of the laminated heat exchanger by one Embodiment of this invention. It is a partial cross-sectional view which shows the closed structure in the state which the core part, the seal member and the housing are connected by one Embodiment of this invention. It is a perspective view which shows the seal member by one Embodiment of this invention.

Hereinafter, the heat exchanger of the present invention having the above configuration will be described in detail with reference to the accompanying drawings.

2 to 5 are an exploded perspective view, an assembled perspective view, and a plan sectional view showing a heat exchanger according to an embodiment of the present invention.

As shown in the figure, in the heat exchanger 1000 according to the embodiment of the present invention, the inlet tank portion 110 and the outlet tank portion 120 in which the space for storing and flowing the cooling water is formed, the inlet tank portion 110, and the above. A core portion in which both ends are connected to the outlet tank portion 120 to form a cooling water flow path C, the core portion includes a plurality of tubes 130 arranged apart from each other, and a sealing member insertion groove 150 is formed concavely on the outer surface. A sealing member 200 including a 100, a main body 210 having one side inserted and connected to the sealing member insertion groove 150 of the core portion 100, and a lip seal 220 extending from the main body 210 and protruding from the outer surface of the core portion 100. And can be included.

First, the heat exchanger 1000 of the present invention may be composed of a core portion 100 in which a seal member insertion groove 150 is formed and a seal member 200, and may further include a housing 700. Further, a part of the seal member 200 may be inserted into the seal member insertion groove 150 and the seal member 200 may be connected to the core portion 100, and the seal member 200 may be inserted into the housing 700 with the seal member 200 coupled to the core portion 100 to be inserted into the core. The space between the portion 100 and the housing 700 may be sealed by the sealing member 200.

The core portion 100 may be composed of an inlet tank portion 110, an outlet tank portion 120 and a tube 130, and may further include fins 140 interposed between adjacent tubes 130. The inlet tank portion 110 is a portion that forms a space in which the cooling water that has flowed in from the outside can be stored inside and the cooling water can flow along the inside, is formed in the height direction, and is connected to the inlet pipe 111. obtain. The outlet tank portion 120 is a portion where cooling water heat-exchanged with air passing through the core portion 100 is collected and stored, and the cooling water flows along the inside to form a space that can be discharged to the outside. It can be formed in the height direction so as to be connected to the pipe 121. One end of the tube 130 is connected to the inlet tank portion 110 and the other end is connected to the outlet tank portion 120 to form a cooling water flow path C in which heat can be exchanged with air while the cooling water flows. Can be arranged apart in the height direction and formed in parallel. At this time, the inlet tank portion 110, the outlet tank 120, and the tube 130 can be formed in various forms, and as an example, the inlet tank portion 110, the outlet tank 120, and the tube 130 are formed in the form of a laminated heat exchanger in which a plurality of plates are laminated and integrally formed. Obtained, a plurality of tubes 130 in the form of a tube may be connected to a tank in the form of a tube or a header tank to be formed in the form of a fixed extruded tube heat exchanger. Fins 140 for improving heat exchange efficiency may be interposed between the tubes 130, for example, the fins 140 may be formed in the form of wrinkled corrugated fins and bonded to the tubes 130. Further, the tank portion may be arranged on one side of both sides in the length direction or on both sides, but the drawings show that the tank portion is formed on one side in the length direction. , Such an embodiment will be described as a reference. Further, as shown in the figure, the tank portion and the tube 130 will be described with reference to the form of a laminated heat exchanger in which a plurality of plates are laminated and formed integrally. Here, the core portion 100 can be formed in such a form that the cooling water flowing into the inlet tank portion 110 flows in a form of making a U-turn along the tube 130 and can be discharged to the outside through the outlet tank portion 120. As a result, the cooling water flowing in from the outside flows in the height direction along the inlet tank portion 110 and is distributed to the tube 130, flows in the length direction along the tube 130 and makes a U-turn, and the outlet tank portion 120 It can gather in the water, flow in the height direction, and be discharged to the outside. At this time, the air may flow from the front side to the rear side in the width direction of the core portion 100, and heat is exchanged while the air passes between the tubes 130, and the air may be configured to cool.

Further, by connecting the lower reinforcing plate 400 to the lower surface of the core portion 100 and the upper reinforcing plate 500 to the upper surface of the core portion 100, the strength of the core portion 100 can be reinforced, and the core portion 100 can be formed. The constituent parts and reinforcing plates may be joined and joined by brazing or welding after being assembled. Further, the inlet pipe 111 and the outlet pipe 121 may be coupled so as to penetrate the joint hole formed through the upper reinforcing plate 500, and the inlet pipe 111 and the outlet pipe 121 may be vertically reinforced by brazing or welding. It can be bonded and fixed to the plate 500.

Further, as an example, the core portion 100 may have the sealing member insertion grooves 150 formed in a concave shape on both side surfaces in the length direction of the outer surface. At this time, the seal member insertion groove 150 may be formed on the side surface of the core portion 100 in the length direction, or may be formed in the central portion in the width direction, and at this time, the seal member insertion groove 150 may be continuously formed along the height direction. It may be formed from the upper end to the lower end including the tube 130 and the lower reinforcing plate 400 except for the upper reinforcing plate 500.

The seal member 200 may be made of an elastic and flexible material, the seal member 200 is composed of a main body 210 and a lip seal 220, and the main body 210 is inserted into and connected to the seal member insertion groove 150 of the core portion 100. obtain. The main body 210 can be formed in the form of a rod continuously formed in the height direction so that it can be inserted into the seal member insertion groove 150, and the corner portion toward the seal member insertion groove 150 is chamfered to form a seal member. The main body 210 of the seal member 200 may be easily inserted into the insertion groove 150. Further, in the main body 210, the lip seal 220 is formed so as to extend outward in the length direction from the central portion in the width direction of the opposite surface toward the core portion 100, and the lip seal 220 is formed in the height direction like the main body 210. It can be formed continuously and in the form of a thin plate whose width is relatively narrower than that of the main body. Here, the seal member 200 is formed in a state in which the lip seal 220 of the seal member 200 protrudes from the outer surface of the core portion 100 in a state where the main body 210 is inserted and coupled to the seal member insertion groove 150 of the core portion 100. obtain.

The housing 700 may be formed in a concave shape, the inside may be hollow, and the upper side may be open. Exit 720 can be formed. Further, the core portion 100 to which the seal member 200 is coupled can be inserted and accommodated inside the housing 700. At this time, the upper reinforcing plate 500 coupled to the upper side of the core portion 100 is formed to be wider than the upper surface of the core portion 100, and through holes penetrating the upper and lower portions are formed in the peripheral edge portion of the upper reinforcing plate 500, and the housing 700 is formed. After assembling so that the core portion 100 is inserted into the inside of the above, the upper reinforcing plate 500 can be connected to the housing 700 by using a fastening means or the like.

At this time, the sealing member insertion groove 150 of the core portion 100 and the main body 210 of the sealing member 200 are in close contact with each other in the length direction, and the lip seal 220 of the sealing member 200 is the side wall in the length direction of the housing 700. The inner side surface of the side wall of the housing 700 and the side surface in the length direction of the core portion 100 may be sealed by the sealing member 200. Thereby, the air flowing into the air inlet 710 of the housing 700 may be configured to pass between the tubes 130 of the core 100 and be discharged through the air outlet 720.

Thereby, in the heat exchanger of the present invention, the air does not bypass through the space between the core portion and the housing by the seal member, and the heat exchange efficiency can be improved.

6 and 7 are an exploded perspective view and a front sectional view showing a core portion of a laminated heat exchanger according to an embodiment of the present invention.

Referring to FIGS. 6 and 7, the core portion 100 may be formed by laminating a tube 130 in which a cooling water flow path C through which cooling water flows is formed by the coupling of the first plate 130a and the second plate 130b.

As shown in the figure, the core portion 100 can be formed in a form in which a plurality of tubes 130 are laminated and joined in the height direction, and the tube 130 can be formed by joining the first plate 130a and the second plate 130b. .. At this time, in the tube 130, the first horizontal portion 131 is formed on the outer side of the first plate 130a and the second plate 130b in the horizontal direction which is a plane in the length direction and the width direction, respectively, and the first plate 130a and the second plate 130a and the second plate 130a are formed. After the first horizontal portions 131 of 130b are laminated so as to be in contact with each other, they may be joined by brazing or the like to form the first joint portion 201. As a result, the outside can be sealed by joining the first plate 130a and the second plate 130b, and a cooling water flow path C through which the cooling water, which is a heat exchange medium, can flow is formed inside the joined joint portion 201. obtain. Further, the first plate 130a and the second plate 130b can be formed so that the flow adjusting bead 137 and the protruding bead 138 project on the surface of the plate 135 on the side where the cooling water flow path C is formed, respectively, and the flow adjusting bead 137 can be formed. Can be formed long so that the cooling water flow path C can be divided or the flow direction of the refrigerant can be adjusted so as to guide the flow of the refrigerant, and the protruding bead 138 can have a large heat exchange area with the cooling water. It can be formed in a cylindrical shape or the like. Further, in the first plate 130a and the second plate 130b, the cup portion 136 may be formed so as to project from the surface of the plate 135 toward the adjacent tubes 130 in the direction opposite to the beads 137 and 138, and the cup portion 136 may protrude. A communication hole that penetrates the upper and lower parts may be formed at the end portion, and a part of the protruding end portion of the cup portion 136 is formed horizontally inward, and the cup portions 136 of the tubes 130 adjacent to each other are formed. Can be easily joined and combined. As a result, the space formed by the cup portion 136 of the tube 130 is formed so as to be connected, and may be formed in the inlet tank portion 110 and the outlet tank portion 120, respectively. As a result, as shown in the figure as an example, when the inlet tank portion 110 and the outlet tank portion 120 are all formed on one side in the length direction, the refrigerant flowing into the inlet tank portion 110 via the inlet pipe 111 is discharged. After being distributed and flowed into each tube 130, it flows in the length direction along the cooling water flow path C on one side in the width direction formed in each tube 130 by the flow adjustment bead 137, and then makes a U-turn. It may be configured to flow in the length direction along the cooling water flow path C formed on the other side in the width direction, then collect in the outlet tank portion 120 and be discharged through the outlet pipe 121. Further, as shown in the figure, the first plate 130a and the second plate 130b are formed in the same form, and the one overlying the first plate 130a may be the second plate 130b, which is not shown, but is not shown. The 1st plate 130a and the 2nd plate 130b may be formed in different forms.

At this time, in the core portion 100, the tubes 130 are laminated and arranged in the height direction, and the seal member insertion groove 150 may be formed on the side surface in the length direction formed by the stacking of the tubes 130, and the seal member insertion groove 150 may be formed. It may be formed on only one of both sides of the core portion 100 in the length direction, or may be formed on both sides. As shown as an example, all the sealing member insertion grooves 150 are formed on both side surfaces of the core portion 100 in the length direction, and the sealing member 200 can be inserted and coupled to both of them.

Further, referring to FIG. 7, in the tube 130 of the core portion 100, the outer sides of the first plate 130a and the second plate 130b are joined to each other to form the first joining portion 201, and the first joining portion 201 is formed. The first horizontal portion 132 is extended from the first horizontal portion 131, the second horizontal portion 133 is extended from the first vertical portion 132, and the second horizontal portion of the first plates 130a facing each other of the adjacent tubes 130 is formed. The second horizontal portion 133 of the second plate 130b and 133 are joined to each other to form the second joint portion 202, and the first plate 130a and the second plate 130b have the second horizontal portion 133 to the second vertical portion 134. The sealing member insertion groove 150 may be formed in a concave shape by being extended and having a part of the second horizontal portion 133 and the second vertical portion 134 of the first plate 130a and the second plate 130b removed.

That is, the tubes 130 face each other at the outer end portions in the length direction of the first horizontal portion 131 of the first plate 130a on which the first joint portion 201 is formed and the first horizontal portion 131 of the second plate 130b. The first vertical portions 132 may be extended in the height direction toward the opposite sides. Further, the second horizontal portion 133 may be extended from the end portion in the height direction of the first vertical portion 132 toward the outer side in the length direction. That is, the first vertical portion 132 is extended upward from the end of the first horizontal portion 131 of the first plate 130a on which the first joint portion 201 is formed, and the second vertical portion 132 is formed outward from the end of the first vertical portion 132. The horizontal portion 133 is extended and the first vertical portion 132 is extended from the end of the first horizontal portion 131 of the second plate 130b on which the first joint portion 201 is formed, and the first vertical portion 132 is formed. A second horizontal portion 133 may be extended outward from the end. Further, the adjacent tubes 130 are joined to each other and bonded to each other, and at this time, the second horizontal portion 133 of one tube 130 and the second horizontal portion 133 of the other tube 130 are joined to each other to join the second horizontal portion 202. Can be formed.

As a result, the second joint portion 202 is further formed on the outside of the first joint portion 201, which is the portion where the tubes 130 are joined and joined, so that the end portion of the first vertical portion 132 of one tube 130 and the other The ends of the first vertical portion 132 of one tube 130 are all joined by the first joint portion 201 and the second joint portion 202, and as a whole, all the first vertical portions 132 of the tube 130 in the height direction are connected. It can be linked and formed into a combined form. Therefore, the rigidity of the side surface of the core portion 100 can be increased by the first vertical portion 132, the second horizontal portion 133, and the second joint portion 202 that act as reinforcing materials, and the first plate 130a and the second plate 130b can be combined with each other. Since the reinforcing material that can integrally reinforce the strength is formed, the formation of the tube, the formation of the heat exchanger core, and the reinforcement of the strength can be performed by laminating and joining the plates. Further, the seal member insertion groove 150 is formed in a concave shape in a form in which a part of the second horizontal portion 133 and the second joint portion 202 which serve as a reinforcing material is cut and removed, and the seal member 200 is inserted and joined. be able to.

Further, in the seal member 200, the main body 210 inserted into the seal member insertion groove 150 of the core portion 100 is locked and inserted in the second vertical portion 134 of the first plate 130a and the second plate 130b in the opposite direction. It may be coupled to the seal member insertion groove 150 so as not to come off.

Referring to FIG. 8, as an example, the seal member 200 is formed of an elastic material, and at this time, the width WB of the main body 210 is formed to be slightly larger than the width WG of the seal member insertion groove 150, and the seal member insertion groove 150 is formed. When the main body 210 of the seal member 200 was inserted and joined in the length direction, the main body 210 was pressed to reduce the width, was press-fitted into the seal member insertion groove 150, and the main body 210 was inserted into the seal member insertion groove 150. In the state, the main body 210 returns to the initial width by elasticity, and the main body 210 can be locked and fixed to the second vertical portion 134 of the core portion 100. Further, in a state where the main body 210 is inserted into the seal member insertion groove 150 in the length direction, it is possible to prevent the main body 210 from coming off in the opposite direction of the insertion, and the seal member can be inserted into the core portion without using another structure and member. Can be easily combined and fixed to.

Further, in the seal member 200, the width WL of the lip seal 220 is formed to be narrower than the width WB of the main body 210, and the main body 210 portion may be pressed with the lip seal 220 portion removed, and the seal member of the core portion 100 may be pressed. The seal member 200 can be easily coupled to the insertion groove 150.

Further, referring to FIG. 9, the seal member 200 has a side surface sealing portion 200-1 inserted and connected to the seal member insertion groove 150 formed on the side surface of the core portion 100 in the length direction, and a side surface sealing portion 200-1. It can include a lower end sealing portion 200-2 which is formed to extend in the width direction from the lower end of the core portion 100 and is arranged under the lower surface of the core portion 100.

That is, as shown in the figure, the seal member 200 may be formed in an "L" shape, and the seal member 200 may be formed in a form in which the seal member 200 is connected to the entire side surface side of the core portion 100 and a part of the lower surface side. As a result, as shown in FIG. 3, when the seal member 200 is coupled to the core portion 100 and inserted into the housing 700 for assembly, the lip seal 220 of the side sealing portion 200-1 of the seal member 200 is formed. Even if the sealing member 200 is inserted in contact with the housing 700, the side sealing portion 200-1 may not be pushed up because the lower end sealing portion 200-2 of the sealing member 200 is locked to the lower surface of the core portion 100. It is possible to prevent the side sealing portion 200-1 from being deformed or detached.

Further, the length of the seal member 200 is longer than the distance L1 between the bottom surface (the surface on the length direction side) of the seal member insertion groove 150 of the core portion 100 and the inner surface of the side wall in the length direction of the housing 700. L2 can be formed longer.

As a result, when the core portion 100 is inserted into the housing 700 and assembled while the seal member 200 is coupled to the core portion 100, the lip seal 220 of the seal member 200 can be inserted and inserted in a warped and deformed state. Even when this is completed, the lip seal 220 is warped and is in close contact with the side wall of the housing 700. Further, the lip seal 220 of the seal member 200 is in close contact with the housing 700, and airtightness can be reliably maintained.

At this time, the lip seal 220 of the seal member 200 may be formed so as to be inclined at an acute angle which is a specific angle with respect to the direction perpendicular to the inner surface of the side wall of the housing 700. Further, when the core portion 100 is inserted into the housing 700 and assembled while the seal member 200 is coupled to the core portion 100, the lip seal 220 may be warped in only one direction in the width direction depending on the angle of the lip seal 220. It can be done and airtightness can be maintained more reliably.

Further, the lip seal 220 warps toward the front side in the air flow direction, and one surface of the free end portion on the width direction side may come into contact with the housing 700. That is, as shown in the figure, the free end portion of the lip seal 220 is in contact with the housing 700 so as to warp toward the inflow of air, and the lip seal is also caused by the high pressure air flowing into the inside of the housing 700. The 220 may not be separated from the inner surface of the side wall of the housing 700.

Further, the inside of the housing 700 and the outside of the core portion 100 may be formed so as to be separated from each other. That is, the area of the core portion 100 is formed smaller than the area of the inner space of the housing 700 when viewed from above so that the core portion 100 can be easily inserted into the empty space inside the housing 700. The side surface and the outer surface of the core portion 100 may be arranged apart from each other. Further, the outer side surfaces of the core portion 100 and the inner side surfaces of the housing 700 are formed so as to be separated from each other in the length direction, and the core is formed from the upper side to the lower side through the open upper side of the housing 700. The portion 100 can be easily inserted and assembled inside the housing 700.

It goes without saying that the present invention is not limited to the above examples and has various scopes of application, and the present invention does not deviate from the gist of the present invention claimed within the scope of the claims, and is ordinary knowledge in the field to which the present invention belongs. It goes without saying that anyone who has the above can carry out various modifications.

For example, although it has been described in the above embodiment that the seal member 200 is fixed to the core portion 100, the seal member 200 may be fixed to any one of the core portion 100 and the housing 700. At this time, it is preferable that the seal member 200 is bonded to the housing 700 in a state of being fixed to the core portion 100. The reason is that it is easier to insert the seal member 200 into the housing 700 in a state of being coupled to the core portion 100.

Further, in the sealing member 200, a large number of lip seals 220 may be formed in order to improve the sealing ability.

1000 Heat exchanger 100 Core part 110 Inlet tank part 111 Inlet pipe 120 Outlet tank part 121 Outlet pipe 130 Tube 130a 1st plate 130b 2nd plate 131 1st horizontal part 132 1st vertical part 133 2nd horizontal part 134 2nd vertical Part 135 Plate 136 Cup part 137 Flow adjustment bead 138 Protruding bead 140 Fin 150 Sealing member Insertion groove 200 Sealing member 200-1 Side sealing part 200-2 Lower end sealing part 210 Main body 220 Lip seal 400 Lower reinforcing plate 500 Upper reinforcing plate 700 Housing 710 Air inlet 720 Air outlet

Claims (8)

Both ends are connected to the inlet tank portion (110) and the outlet tank portion (120) in which a space for storing and flowing cooling water is formed, and the inlet tank portion (110) and the outlet tank portion (120). With the core portion (100) forming the cooling water flow path (C), including a plurality of tubes (130) arranged apart from each other, and having a concave sealing member insertion groove (150) formed on the outer surface. ,
One side of the core portion (100) is inserted into the seal member insertion groove (150) and joined to the main body (210), which is extended from the main body (210) and protrudes from the outer surface of the core portion (100). A seal member (200) including a lip seal (220) and
The core portion (100) formed in a concave shape and to which the seal member (200) is bonded is inserted and housed inside, and an air inlet (710) through which air flows in is formed on one side and air is formed on the other side. Includes a housing (700) in which an air outlet (720) is formed.
In the sealing member (200), the lip seal (220) comes into contact with the inner side surface of the side wall of the housing (700), and the core portion (100) and the housing (700) are sealed.
The core portion (100) is
The tube (130) in which the cooling water flow path (C) through which the cooling water flows is formed by the coupling of the first plate (130a) and the second plate (130b) is laminated and formed.
The outer sides of the first plate (130a) and the second plate (130b) are joined to each other to form a first joint portion (201), and a first horizontal portion (131) forming the first joint portion (201). The first vertical portion (132) is extended from the first vertical portion (132), the second horizontal portion (133) is extended from the first vertical portion (132), and the first plate of the adjacent tubes (130) facing each other. The second horizontal portion (133) of (130a) and the second horizontal portion (133) of the second plate (130b) are joined to each other to form the second joint portion (202), and the first plate (130a) is formed. The second plate (130b) is formed by extending a second vertical portion (134) from the second horizontal portion (133).
The seal member insertion groove (the seal member insertion groove) in a form in which a part of the second horizontal portion (133) and the second vertical portion (134) of the first plate (130a) and the second plate (130b) is removed. A heat exchanger characterized in that 150) is formed. The core portion (100) is
The tubes (130) are laminated and arranged in the height direction, and the sealing member insertion groove (150) is formed on one or more side surfaces of both side surfaces in the length direction formed by laminating the tubes (130). The heat exchanger according to claim 1 . The seal member (200) has a main body (210) inserted into the seal member insertion groove (150) of the core portion (100) of the first plate (130a) and the second plate (130b). The heat exchanger according to claim 1 , wherein the heat exchanger is coupled to the seal member insertion groove (150) so as to be locked to the second vertical portion (134) and inserted so as not to come off in the opposite direction. The heat exchanger according to claim 1, wherein the seal member (200) is formed so that the width (WL) of the lip seal (220) is narrower than the width (WB) of the main body (210). .. The seal member (200) is
A side sealing portion (200-1) inserted and connected to the sealing member insertion groove (150) formed on the side surface of the core portion (100) in the length direction, and a lower end of the side sealing portion (200-1). The heat exchanger according to claim 1, further comprising a lower end sealing portion (200-2) formed extending in the width direction from the core portion (100) and arranged below the lower surface of the core portion (100). The length of the seal member (200) in the length direction from the distance (L1) between the bottom surface of the seal member insertion groove (150) of the core portion (100) and the inner surface of the side wall of the housing (700). The heat exchanger according to claim 1, wherein the (L2) is formed for a long time. The lip seal (220) of the seal member (200) is formed so as to be inclined at a specific angle with respect to a direction perpendicular to the inner surface of the side wall of the housing (700). The heat exchanger according to 1. The sixth aspect of claim 6 , wherein the lip seal (220) warps toward the front side in the flow direction of air, and one surface of the free end portion on the width direction side comes into contact with the housing (700). Heat exchanger.

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