KR20100130806A - Heat exchange core and intercooler using the heat exchanger core - Google Patents

Abstract

PURPOSE: A heat exchange device and a water-cooling intercooler for a vehicle using the same are provided to enhance productivity since the cooling water makes turbulent flow without a separate turbulator through the structure improvement of a heat exchange plate, which is heat-exchanged while the cooling water passes. CONSTITUTION: A water-cooling intercooler for a vehicle comprises a heat exchange device(100), a pair of air inlet/outlet covers(210,220), a pair of cooling water inlet/outlet covers(310,320) and a plurality of beads. A plurality of heat exchange plates are deposited on the heat exchange device at intervals. The cooling water or a plurality of main partition bars are installed between the heat exchange plates. The air inlet/outlet covers comprise an air inlet and an air outlet. The cooling water inlet/outlet covers comprise a cooling water inlet and a cooling water outlet. The beads are formed on the opposite side of a cooling-water flowing part of the facing sides of the heat-exchange plates. If two heat exchange plates are deposited, some of the beads make contact with each other and the other are separated and thus the cooling water makes turbulent flow.

Description

Heat exchanger and automotive water-cooled intercooler using the same {heat exchange core and intercooler using the heat exchanger core}

The present invention relates to a heat exchanger and an automotive water-cooled intercooler to which the same is applied, and more specifically, the flow of cooling water is turbulent without installing a separate turbulator by improving the structure of the heat exchanger plate at the portion where the cooling water passes through. In addition, the assembly work can be easily performed, thereby maximizing productivity.

In general, an automotive intercooler is a device that is installed between an impeller and an intake manifold to cool a supercharged air.

That is, by allowing the air charged by the impeller to be supplied to the engine after being cooled by the intercooler, it is possible to prevent the occurrence of knocking and a decrease in charging efficiency due to a decrease in the increase in air density due to the increase in the temperature of the charged air. will be.

The vehicle intercooler is classified into an air-cooled intercooler that cools the boost air by using air provided while driving and a water-cooled intercooler that cools the boost air by using coolant.

Here, the water-cooled intercooler is configured to cool the air while the coolant flows in a direction perpendicular to the direction in which air flows.

In particular, in the case of a conventional water-cooled intercooler, the air passing through each heat exchange plate or a coolant is provided between the heat exchange plates through which air and cooling water cross each other, and a turbulator manufactured separately from the heat exchange plate is installed. To generate turbulence, and thus, the heat exchange performance between the air and the cooling water is further improved.

However, the conventional water-cooled intercooler has a problem that the overall structure is complicated due to the turbulator installed between the heat exchange plates, the manufacturing cost is increased, and the overall assembly work can be relatively long.

The present invention has been made to solve the above-described problems according to the prior art, the object of the present invention is to improve the structure of the heat exchange plate of the heat exchanger while the cooling water passes through the structure of the cooling water without installing a separate turbulator The present invention provides a new type of heat exchanger and a water-cooled intercooler for automobiles using the same, which can maximize the productivity by allowing the flow to be turbulent and assembling easily.

According to the automotive water-cooled intercooler of the present invention for achieving the above object, a plurality of heat exchange plates are laminated while being spaced apart from each other, and each of the heat exchange plates is provided with a plurality of main partition bars for partitioning the flow space of cooling water or air. Consisting of a heat exchanger; A pair of air inlet / outlet covers each provided on one side wall surface of the heat exchanger and on a wall surface of the side opposite to the air exchanger and having an air inlet and an air outlet for inlet and outlet of air; A pair of cooling water inlet / outlet side covers provided on the other side wall surface of the heat exchanger and on a wall surface opposite to the heat exchanger and having a cooling water inlet and a cooling water outlet for inlet and outlet of the cooling water; In addition, the protrusions are formed on the opposite surfaces of the portions where the coolant flows among the opposing surfaces of the heat exchangers, and when the two heat exchange plates are stacked, some parts of each other are in contact with each other and are spaced apart from each other. And a plurality of beads: for turbulizing the flow of cooling water.

Here, any one of the coolant inlet and outlet of the pair of coolant inlet and outlet covers is formed with both the coolant inlet and the coolant outlet, and the other coolant inlet and outlet cover is formed to have a flow space in which the coolant flows. It features.

In addition, each of the cooling water inlet and the cooling water outlet are provided in plural, respectively, and are formed to be alternately disposed on the one cooling water inlet / side cover, and the compartment for guiding the flow direction of the cooling water in the flow space of the other cooling water inlet / side cover. A partition is formed.

In addition, the plurality of beads are formed to be inclined toward the outer side gradually toward both ends relative to the center portion in a plan view, or in a shape inclined toward a direction similar to the flow direction of the coolant in plan view. It features.

In addition, each bead is formed to form a plurality of rows based on the flow direction of the coolant, the beads formed in the same row is formed in the same shape with each other and in the shape opposite to the beads formed in other adjacent rows When formed and overlapping the two heat exchange plates to face each other, it is installed so that the direction toward each bead is opposite to each other, the auxiliary partition bar for partitioning the space between each other is characterized in that each provided.

In addition, a plurality of contact protrusions are formed on the cooling water inlet side and the cooling water outlet side toward the beads of each row among the surfaces on which the beads of each of the heat exchange plates protrude.

And, according to the heat exchanger of the present invention for achieving the above object a plurality of heat exchanger plates stacked while being spaced apart from each other; In addition, a plurality of beads protruded on opposite surfaces between the respective heat exchanger plates, and in the case of stacking two heat exchanger plates corresponding to each other, part of each other abutting and the other part spaced apart from each other to turbulent flow of the fluid: Characterized in that configured to include.

Here, the plurality of beads are formed to be inclined toward the outer side gradually toward both ends with respect to the center portion in a plan view, or in a shape inclined toward a direction similar to the flow direction of the fluid in plan view. It features.

In addition, each bead is formed to form a plurality of rows based on the flow direction of the fluid, the beads formed in the same row is formed in the same shape with each other and in the shape opposite to the beads formed in other adjacent rows When formed and overlapping the two heat exchange plates to face each other, it is installed so that the direction toward each bead is opposite to each other, the auxiliary partition bar for partitioning the space between each other is characterized in that each provided.

In addition, it is characterized in that a plurality of contact protrusions are formed on the fluid inlet side and the fluid outlet side toward the bead of each row of the bead of each heat exchange plate protruded.

As described above, the heat exchanger according to the present invention and the water-cooled intercooler for the vehicle to which the same is applied are configured for turbulence such as a separate turbulator because a plurality of beads are integrally formed on the heat exchanger plate for turbulence of the cooling water flow. It is possible to omit the work due to the installation of, thereby reducing the working time has the effect of achieving an improvement in productivity.

Particularly, each of the beads may be configured to be in contact with each other when the two heat exchange plates corresponding to each other are laminated to allow the coolant to flow in the horizontal direction, and also to flow in the vertical direction so that the coolant can be smoothly turbulent. It is possible to achieve an effect of improving the heat exchange performance.

Hereinafter, a preferred embodiment of the heat exchanger of the present invention and a water-cooled intercooler for a vehicle to which the present invention is applied will be described with reference to FIGS. 1 to 10.

First, the water-cooled intercooler for a vehicle according to a preferred embodiment of the present invention has a heat exchanger 100, a pair of air inlet / outlet covers 210 and 220, and a pair of coolant inlet / outlet covers 310 and 320 as shown in FIG. 1. ), And a plurality of beads (400).

The heat exchange apparatus 100 is a series of components configured to be discharged after being cooled by receiving charged air, and includes a plurality of heat exchange plates 110 and a plurality of main partition bars 120.

The plurality of heat exchange plates 110 are each formed as a rectangular thin plate and are installed to be stacked while being spaced apart from each other. Between each of the heat exchange plate 110 passes through while the coolant and air cross in a state partitioned with each other.

For example, the cooling water is configured to pass between one heat exchange plate 111 and another heat exchange plate 112 positioned directly below it, and the other heat exchange plate 112 and another heat exchanger positioned directly below it. Air is passed between the plates 113, the flow direction of the air and the cooling water is configured to be perpendicular to each other.

In addition, the plurality of main partition bars 120 are configured to partition the flow space of the coolant or air while being provided between the heat exchange plates 110.

At this time, each of the main partition bar 120 is provided so as to block both sides between the heat exchange plate 110 when viewed based on the flow direction of the cooling water or air. This is as shown in Figure 1 attached.

For example, between any one heat exchange plate 111 through which the coolant passes and the other heat exchange plate 112, the other heat exchanger is provided to block both portions on the side of the direction perpendicular to the passing direction of the coolant, and the other heat exchanger through which air passes. Between the plate 112 and the other heat exchange plate 113 is provided so as to block a portion on the side of the direction perpendicular to the passage direction of the air.

In addition, in the embodiment of the present invention, as shown in Figures 3 and 4 attached to the cooling water inlet side and the cooling water outlet side of each of the heat exchange plate 110 further presents that a plurality of contact protrusions 160 are formed protruding.

In this case, the adhesion protrusions 160 are provided to be pressed against each other when the two heat exchange plate 110 corresponding to each other to provide a pressing force to improve the adhesion between the main partition bar 120 and the two heat exchange plate 110. There is a series of configurations.

Next, the pair of air inlet / outlet covers 210 and 220 are configured for inflow of air into the heat exchanger 100 and outflow of air to the outside of the heat exchanger 100, and are provided with external air to receive a heat exchanger ( The air inlet side cover 210 provided in the inside and the air outlet side cover 220 for outflowing the air passing through the heat exchanger 100 to the outside.

Here, the air inlet side cover 210 is provided to surround the inlet side wall of the air when viewed in the direction of the air passing through the circumferential wall surface of the heat exchange device 100, the air outlet side cover 220 The outer wall of the circumferential wall of the heat exchange apparatus 100 is provided to surround the outlet side wall surface (wall surface opposite to the inlet side wall of the air) when viewed as a reference.

In this case, an air inlet 211 is formed in the air inlet cover 210 for the inflow of air, and an air outlet 221 is formed in the air outlet side cover 220 for the outflow of air.

Next, the pair of cooling water inflow and outflow side covers 310 and 320 are configured for inflow of cooling water into the heat exchanger 100 and outflow of cooling water to the outside of the heat exchanger 100.

The pair of cooling water inflow and outflow side covers 310 and 320 are wall surfaces in a direction perpendicular to a wall surface on which the air inflow side cover 210 and the air outlet side cover 220 are installed, among the peripheral wall surfaces of the heat exchanger 100. It is provided to surround each.

At this time, any one of the coolant inlet and outlet side cover (310,320) of the coolant outlet inlet cover (hereinafter referred to as "first coolant cover") 310 is formed with both the cooling water inlet (311,313) and the cooling water outlet (312,314) The other cooling water inflow and outflow side cover (hereinafter, referred to as “second cooling water cover”) 320 is formed to have a flow space in which the cooling water flows.

Particularly, in the embodiment of the present invention, a plurality of cooling water inlets 311 and 313 and cooling water outlets 312 and 314 formed in the first cooling water cover 310 are provided in plural, respectively, and are alternately arranged, and the second cooling water cover is provided. It is proposed that the partition partition 321 is formed inside the 320 to guide the flow direction of the coolant.

For example, as shown in FIG. 1 and FIG. 2, two cooling water inlets 311 and 313 and two cooling water outlets 312 and 314 are provided, respectively, so that the cooling water inlets 311 and 314 are alternately disposed with each other.

In this case, the coolant introduced into the heat exchanger 100 through the coolant inlet (hereinafter referred to as “first coolant inlet”) 311 provided at the bottom is heat-exchanged through the heat exchanger 100, and then the second The water is discharged toward the adjacent coolant outlet (hereinafter, referred to as “first coolant outlet”) 312 while being guided by the partition bulkhead 321 while passing through the coolant cover 320, and the first coolant outlet 312 is discharged. The coolant discharged through the heat exchanger 100 is re-introduced through another coolant inlet (hereinafter referred to as a “second coolant inlet”) 313, and then the second coolant cover is heat exchanged again. Discharged through the adjacent coolant outlet (hereinafter referred to as “second coolant outlet”) 314 via 320.

At this time, the pipe connecting the first coolant outlet 312 and the second coolant inlet 313 is connected to, for example, an oil cooler (not shown), so that the coolant that has undergone primary heat exchange is connected to the oil cooler. After being cooled again through the heat exchanger 100 is preferably configured to allow the heat exchange again. Detailed illustration thereof will be omitted.

Next, the plurality of beads 400 are provided on a path through which the coolant of the heat exchanger 100 flows, and as a series of configurations for turbulent flow of the flowing coolant to improve heat exchange performance, each heat exchange plate It is proposed that the projections are formed to correspond to the opposite surfaces of the portion where the coolant flows among the opposite surfaces between the 110.

That is, the structure for turbulent flow of the cooling water on the path through which the cooling water flows is provided in various forms, but in the embodiment of the present invention, the plurality of beads 400 are integrally formed on the heat exchange plate 110. By doing so, the provision of a separate component (eg, a conventional turbulator, etc.) for turbulence of the cooling water may be omitted, thereby reducing the manufacturing time and maximizing productivity. This is the same as in FIGS. 3 and 4.

In particular, in the exemplary embodiment of the present invention, when the two heat exchange plates 110 are stacked to face each other as shown in FIG. 6, each of the beads 400 formed on opposite surfaces between the heat exchange plates 110 contacts each other. In addition, the remaining parts are characterized by being configured in a form spaced apart from each other.

That is, as shown in FIGS. 7 to 9, the flow of the coolant is directed toward the horizontal direction (left or right direction based on the flow direction of the coolant) by the contact portions 401 between the beads 400. The non-contacting portions are such that the flow of the cooling water is directed toward the vertical direction (upper or lower when viewed based on the flow direction of the cooling water) so that the entire cooling water flow can be turbulent.

To this end, each of the beads 400 is formed in a shape that is gradually inclined toward the outside toward both ends with respect to the center portion in a plan view.

In addition, in the embodiment of the present invention, each of the beads 400 is formed to form a plurality of rows based on the flow direction of the cooling water, and the beads 400 formed in the same row are formed in the same shape with each other. In the case of overlapping the two heat exchange plate 100 manufactured in the same shape as opposed to the beads 400 formed in other adjacent columns facing each other, the directions facing the beads 400 are installed in opposite directions. To present. In addition, the auxiliary partition bar 130 for partitioning the space between each other and the row of the beads 400 are provided with each.

Of course, each of the bead 400 is formed to be inclined toward the direction (preferably diagonal direction) similar to the flow direction of the coolant when the heat exchange plate 100 in plan view as shown in FIGS. It may be.

Meanwhile, a turbulator (not shown) manufactured separately from the heat exchange plate 110 is installed in a space through which air passes among the spaces between the heat exchange plates 110 constituting the heat exchange device 100. . Of course, it can also be configured as a bead 400 formed to abut each other, as in the above-described embodiment of the air passage.

In the following, it will be described in more detail with respect to the assembly process of the water-cooled intercooler for automobiles according to the embodiment of the present invention described above.

First, a plurality of heat exchange plates 110 are prepared. At this time, the heat exchange plate 110 is manufactured such that the bead 400 forming a plurality of rows toward any one surface protrudes.

Subsequently, the surfaces of each of the heat exchanger plates 110 prepared as described above face each other with the surfaces of each of the beads 400 protruding from each other, and at the same time, the surfaces of each of the heat exchanger plates 110 protrude from each other. 400 are sequentially positioned so as to face each other that does not protrude.

In this case, a turbulator (not shown) manufactured separately from the heat exchange plate 110 is installed while forming a space in which air flows between the surfaces of the bead 400 of each heat exchange plate 110, from which protrusions are not formed. do.

Subsequently, by sequentially stacking each heat exchange plate 110 to face the same surface, the heat exchange plate 110 forms a space in which the coolant flows between the surfaces of the bead 400 protruding from each other. The bead 400 of each heat exchange plate 110 to form a space in which air flows between the surface is not protruding.

At this time, the beads 400 corresponding to each other on the opposing surfaces of the heat exchange plates 110 are arranged in a shape in which a part of the heat exchange plates 110 intersect with each other by the stacking between the heat exchange plates 110, and thus the coolant in the space. Turbulence of the coolant is possible even without installing a separate turbulator for turbulence.

In addition, the main partition bar 120 is provided on the circumferential side of each heat exchange plate 110 during the stacking of the heat exchange plates 110, and each bead 400 formed on each heat exchange plate 110 is formed. By installing the auxiliary partition bar 130 between the rows so that the flow direction of the coolant and air can be determined.

In addition, a pair of air inlet and outlet side covers 210 and 220 and a pair of cooling water inlet and outlet side covers 310 and 320 are respectively opposed to the circumferential wall surface of the heat exchanger 100 manufactured by the above-described process. By combining, the water-cooled intercooler for automobile according to the embodiment of the present invention is completed.

Next, the operation of the automotive water-cooled intercooler manufactured as described above will be described with reference to FIG. 10.

First, the hot air provided from the supercharger flows into the space of the portion between the heat exchange plate 110 where the beads do not protrude through the air inlet 211 of the air inlet cover 210 and passes through the space. While being heat-exchanged with the heat exchange plate 110, it is discharged through the air outlet 221 of the air outlet side cover 220.

In addition, during the above process, the coolant is introduced through the first coolant inlet 311 of the first coolant cover 310, and the coolant thus introduced is perpendicular to the flow direction of the air. Accordingly, the bead 400 of the space between the heat exchange plate 110 passes through the space of the protruding portion to exchange heat with the heat exchange plate 110 to cool the air flowing through the other space between the heat exchange plate (110).

Subsequently, the coolant is guided by the second coolant cover 320 and the partition partition 321 therein, and again flows in the reverse direction (the direction opposite to the flow direction according to the initial inflow), and then the first coolant outlet ( The coolant flowing out to the oil cooler (not shown) through 312 and subsequently cooled again while passing through the oil cooler passes through the heat exchanger 100 through the second coolant inlet 313 to exchange the heat exchanger. Heat exchanged with the plates 110 again to cool the air and is guided by the second coolant cover 320 to be discharged through the second coolant outlet 314.

In this case, as described above, the flow of the cooling water is caused by the plurality of beads 400 which are formed to face each other while the cooling water is formed on opposite surfaces between the heat exchange plates 110, and the portions are in contact with each other.

That is, the coolant is turbulent while horizontal flow is performed by the portions 401 which are in contact with each other between the opposed beads 400, while performing vertical flow by the portions which are not in contact with each other between the opposite beads 400. will be.

As such, since the horizontal flow and the vertical flow of the cooling water pass simultaneously, turbulence of the cooling water can be made more smoothly, and thus an excellent heat exchange effect between the cooling water and the heat exchange plate 110 can be obtained.

That is, as in the prior art, the coolant flows only in the horizontal direction to achieve turbulence, or flows only in the vertical direction, thereby achieving an excellent heat exchange effect.

On the other hand, the pair of cooling water inflow and outflow side cover 310, 320 of the configuration of the water-cooled intercooler for automobiles according to the embodiment of the present invention described above is not to be formed only with the configuration of the above-described embodiment.

For example, only the coolant inlet may be formed in the first coolant cover 310, and only the coolant outlet may be formed in the second coolant cover 320, and one coolant inlet 311 may be formed in the first coolant cover 310. In addition to forming one cooling water outlet 312, the second cooling water cover 320 may be formed in a variety of structures, such as simply configured to flow only the cooling water.

In addition, the structure of the heat exchanger 100 formed by forming a plurality of beads 400 having the same shape as the above-described embodiment on the heat exchange plate 110 may be applied only to a water-cooled intercooler for an automobile as in the embodiment of the present invention. no.

That is, it may be applied to various fields such as a heat exchanger or a radiator for a conventional air conditioner.

1 is an exploded perspective view illustrating the structure of an automotive water-cooled intercooler according to a preferred embodiment of the present invention.

Figure 2 is a perspective view showing a part of the coupling state of the water-cooled intercooler for automobiles according to a preferred embodiment of the present invention

3 is a perspective view illustrating the shape of a heat exchange plate of a water-cooled intercooler for a vehicle according to a preferred embodiment of the present invention.

Figure 4 is a plan view showing for explaining the shape of the heat exchange plate of the water-cooled intercooler for automobiles according to a preferred embodiment of the present invention

Figure 5 is a plan view showing for explaining the shape of another embodiment of the heat exchange plate of the water-cooled intercooler for automobiles according to a preferred embodiment of the present invention

FIG. 6 is a plan view illustrating a structure in which each bead is contacted by lamination between heat exchange plates in a water-cooled intercooler for automobiles according to a preferred embodiment of the present invention.

7 is a cross-sectional view taken along line II of FIG. 6.

8 is a cross-sectional view taken along the line II-II of FIG. 6.

9 is a cross-sectional view taken along the line III-III of FIG.

10 is a front view showing the flow of the coolant by the water-cooled intercooler for automobiles according to a preferred embodiment of the present invention

Explanation of symbols for main parts of the drawings

100. Heat exchanger 110,111,112,113. Heat exchanger plate

120. Main compartment bar 130. Second compartment bar

160. Contact Protrusion 210. Air Inlet Cover

211.Air inlet 220.Air outlet cover

221. Air outlet 310. First coolant cover

311. First Coolant Outlet 312. First Coolant Outlet

313. Second coolant inlet 314. Second coolant outlet

320. Second coolant cover 321. Partition bulkhead

400. Bead 401. Contact Area

Claims (10)

A plurality of heat exchangers formed by being stacked while being spaced apart from each other, and having a plurality of main partition bars configured to partition a flow space of cooling water or air between the heat exchange plates; A pair of air inlet / outlet covers each provided on one side wall surface of the heat exchanger and on a wall surface of the side opposite to the air exchanger and having an air inlet and an air outlet for inlet and outlet of air; A pair of cooling water inlet / outlet side covers provided on the other side wall surface of the heat exchanger and on a wall surface opposite to the heat exchanger and having a cooling water inlet and a cooling water outlet for inlet and outlet of the cooling water; And, It is formed to protrude on the opposing surface of the portion of the heat exchanger between the heat exchanger between the heat exchanger, the surface of the cooling water flows, when the two heat exchanger is laminated between the part of each other and the other part is spaced apart from each other A water-cooled intercooler for automobiles, comprising: a plurality of beads for turbulent flow. The method of claim 1, The cooling water inlet and the cooling water outlet are both formed at any one of the pair of cooling water inlet and outlet covers. Another coolant inlet / outlet cover is a water-cooled intercooler for automobiles, characterized in that it is formed to have a flow space in which the coolant flows. The method of claim 2, The cooling water inlet and the cooling water outlet are provided in plural, respectively, and are formed to be alternately disposed on the one cooling water inlet and side cover, The water-cooled intercooler for automobiles, characterized in that a partition partition for guiding the flow direction of the cooling water is formed in the flow space of the other cooling water inflow and outflow side cover. The method of claim 1, The plurality of beads Water-cooled intercooler for automobiles, characterized in that it is formed to be inclined toward the outer side gradually toward both ends with respect to the center portion in plan view, or to be inclined toward a direction similar to the flow direction of the coolant in plan view. . The method of claim 4, wherein Each bead is formed to form a plurality of rows based on the flow direction of the coolant, Beads formed in the same row are formed in the same shape as each other and in the opposite shape to beads formed in other adjacent columns. When the beads are overlapped to face each other between the two heat exchanger plates, the directions of the beads are opposite to each other. Installed, The water-cooled intercooler for automobile, characterized in that the auxiliary partition bar for partitioning the space between each other are provided between each row. The method of claim 5, The water-cooled intercooler for automobiles, characterized in that a plurality of contact protrusions are formed on the cooling water inflow side and the cooling water outlet side toward the beads of each row among the surfaces of each of the heat exchange plates protruding from the beads. A plurality of heat exchange plates stacked while being spaced apart from each other; And, A plurality of beads which protrude on opposite surfaces of each heat exchanger plate, and in which two heat exchanger plates corresponding to each other are stacked, part of each other abutting and spaced apart from each other while turbulent fluid flow. Heat exchanger, characterized in that configured. The method of claim 7, wherein The plurality of beads Heat exchanger characterized in that the inclined toward the outer side gradually toward the end toward both ends with respect to the center portion in the plane view, or in the shape inclined toward the direction similar to the flow direction of the fluid in plan view. The method of claim 8, Each bead is formed to form a plurality of rows based on the flow direction of the fluid, Beads formed in the same row are formed in the same shape as each other and in the opposite shape to beads formed in other adjacent columns. When the beads are overlapped to face each other between the two heat exchanger plates, the directions of the beads are opposite to each other. Installed, And an auxiliary partition bar for partitioning a space therebetween. The method of claim 9, Heat exchanger, characterized in that a plurality of contact protrusions are formed on the fluid inlet side and the fluid outlet side toward the bead of each row of the bead protruding surface of each heat exchange plate.

Images