KR20190049472A - Heat exchanger for an internal combustion engine - Google Patents

Abstract

The present invention relates to a heat exchanger for an internal combustion engine, which is formed to cool air using a cooling fluid. The heat exchanger includes a housing, an inlet for a cooling fluid, and an outlet for a cooling fluid. The housing has lines for enabling air to pass through the inside of the housing, and the lines are extended by the housing. The inlet and the outlet for a cooling fluid are formed in the housing. The housing has multiple plate elements forming the housing, and the inlet and the outlet are formed in different plate elements. The inlet and/or the outlet are installed in a bulging unit of the plate elements. The bulging units have an extension unit having a component vertical to a straight line connecting the inlet and the outlet along the housing.

Description

HEAT EXCHANGER FOR AN INTERNAL COMBUSTION ENGINE

The present invention relates to a heat exchanger for an internal combustion engine.

In the field of automotive technology, a method of using an intercooler for gas cooling supplied to the internal combustion engine to cool the air supplied to the internal combustion engine is known. For this cooling, a heat exchanger is used, in which the air can be cooled by the cooling fluid. Corresponding heat exchangers are described, for example, in DE 10 2009 053884 A1, US 2012/0292002 A1, US 2008/0289833 A1, US 2009/0056922 Al, US 2010/0089548 A1, US 2006/0048759 A1, WO 2016 / 008854 A1, FR 2 968 753 B1, US 2013/0192803 A1, US 2013/0146267 A1, JP 5856068 B2 and JP 5856067 B2.

In the above-mentioned DE 10 2009 053884 Al, the heat exchanger as described above has connections for supplying the cooling fluid. These connecting portions are connected to the housing, and bulging portions are provided outside the housing. The housing is actually composed of two metal sheet forming parts, the bulging parts associated with the two connecting parts being formed of the same metal sheet forming part.

The inventors of the present application have noted that it is difficult to match the heat exchanger to different conditions in the design of such a heat exchanger. At the same time, as in the prior art, for example as described in US 2009/0056922 Al, the performance and durability of the heat exchanger is reduced, since a separate part must be provided for the diffusion of the cooling fluid, It has been found that reducing consumption may be required.

The present invention aims at at least partially alleviating the above-mentioned disadvantages.

The invention is defined by a heat exchanger according to claim 1. Preferred embodiments are defined in the dependent claims.

According to the present invention, a heat exchanger for an internal combustion engine formed to cool air using a cooling fluid has a housing. The housing has lines for passing air to be cooled therein, and these lines extend through the housing. The cooling fluid referred to may generally be a cooling liquid, such as, for example, water. However, other fluids may be used. The lines used to pass the air to be cooled are physically separated from the area through which the cooling fluid can pass, so that the cooling fluid and the air to be cooled are not mixed. According to the present invention, the housing has an inlet and an outlet for the cooling fluid, through which the cooling fluid can enter into and out of the housing.

The housing has a plurality of plate elements forming such a housing, wherein the inlet and outlet for the cooling fluid are formed in different plate elements. These plate elements are part of the heat exchanger forming the housing. Generally, these plate elements are made of metal plates that can be hard or soft soldered to each other.

According to the invention, the inlet and / or outlet are provided in the bulging portion of the plate elements. This bulging section is directed outward. The bulging portion has, along the housing, an extension having a component perpendicular to the straight line connecting the inlet and the outlet. The extension of the bulge is a straight line extending along the bulge and following the longest dimension of the bulge. In other words, in other words, the extension of the bulge follows the longest direction of this bulge. If the bulging portion consists of a plurality of elements which are actually linear rather than single linear elements, they may have different extending directions in each of the individual elements. In such a case, it suffices that one of the elements extends along the direction mentioned.

The bulging portion provided with the inlet and / or outlet is used to allow the cooling fluid to be distributed. In this way, there is no need to provide a separate apparatus for distributing the cooling fluid. As already mentioned above, this makes the structure of the heat exchanger less complex, and this avoids the mentioned disadvantages. Particularly, since the number of parts to be installed is small, the material consumption can be reduced, thereby reducing the material cost. It has also been proven that the corresponding heat exchanger is advantageous in a long and narrow installation space and relatively easy in heat exchange performance. Cooling power is increased by a good and uniform distribution of the cooling fluid due to this arrangement of the bulge. In addition, a uniform distribution of the cooling fluid prevents the cooling fluid from staying at a particular point or moving very slowly. This stagnation can pose a risk that the cooling fluid (in the case of liquid) may start to boil at this position, which can lead again to damage and degradation.

In contrast to the present invention, in the prior art, the cooling fluid is distributed through a separate cooling fluid distributor, but in the present invention such a distributor can be omitted.

In this regard, it is preferable that the extending direction is completely perpendicular to the direction in which the lines for cooling the air to be cooled extend. This allows an efficient distribution of the cooling fluid associated with the lines to cool the cooling fluid better.

Due to the fact that the inlet and outlet are formed in different plate elements, for example by replacing only one of the plate elements, the heat exchanger can easily be matched to various requirements.

It is preferred that the lines are connected to the base plates of the heat exchanger and the inlet and / or outlet for the cooling fluid are formed in a plate element integral with the associated base plate. In this case, the base plate means a plate in which air can be introduced into the line for passing the air to be cooled, i.e. having openings, wherein the openings are coplanar with the corresponding openings in the base plates And is connected to these openings. By forming the inlet and / or outlet in the plate element with the associated base plate, the corresponding heat exchanger can be easily manufactured and is less complex. This reduces manufacturing costs.

It is preferred that the components of the plate element followed by the inlet and / or outlet and the bottom plate are actually perpendicular to each other. A corresponding heat exchanger can be manufactured at low cost in terms of cost.

In addition, the plate element of the base plate also has peripheral components adjacent to the base plate, in which case the peripheral components preferably surround the base plate with the components to which the outlet or inlet is connected. With these additional peripheral components, the plate elements of the base plate as a whole have an apron shape. Thus, the construction of the heat exchanger can be facilitated, which again leads to cost reduction.

It is also preferred that the plate element provided with the inlet and / or outlet is overlapped with the other plate element of the housing such that the other plate element partially limits the boundary of the cavity formed by the bulging portion. The flow of cooling fluid flowing out of the cavity through such overlap can be controlled because the size of the overlap can be selected as desired during the manufacture of the heat exchanger. This leads to improved applicability of the heat exchanger to changing conditions.

It is preferred that the housing actually has the form of a parallelepiped, and the inlet and outlet are formed on the same side of the parallelepiped. This heat exchanger saves space and is easy to mount because the inlet and outlet are formed on the same side.

It is also preferable that one or more, preferably two, bulging portions are formed in an L-shape. By properly forming the bulges, the cooling fluid can be well distributed. However, other forms may also provide corresponding advantages.

Fig. 1 shows a perspective view of a heat exchanger according to the first embodiment.
Figure 2 shows an exploded view of the heat exchanger of Figure 1;
Figure 3 shows an inlet of the prior art for comparison.
Fig. 4 shows the functional principle of the inflow section according to the first embodiment.
Fig. 5 shows a second embodiment of the present invention.
Fig. 6 shows a third embodiment of the present invention.
Fig. 7 shows a fourth embodiment of the present invention.
Fig. 8 shows a fifth embodiment of the present invention.

1 shows a perspective view of a heat exchanger 10 according to a first embodiment. Fig. 2 (a) shows an exploded view of the heat exchanger of Fig. 1, and Fig. 2 (b) shows a heat exchanger observed in various directions.

The heat exchanger 10 has a housing 11 through which the lines 25 for passing air to be cooled are extended. These lines terminate in base plates 24 that form an interface with the periphery of the heat exchanger.

The base plates 24 provided on the inlet side and the outlet side of the lines together with the side plates 16, the lower plate 30 and the upper plate 18 form a housing 11 having the shape of a parallelepiped . In connection with the present invention, the side plates 16, the bottom plate 30, the top plate 18 and the base plate 24 are referred to as " plate elements ". Within the lines 25 are lamellae 25 'made of a metallic material and arranged to increase thermal conductivity. These thin films extend between the walls of the lines 25.

The side plates 16 are of a simple rectangular shape while the bottom plate 30 is of a rectangular shape with protruding side edges overlapping the side plates 16.

In such overlaps, the lower plate 30 and the side plates 16 are connected. The top plate 18 has actually an H shape, with the longitudinal sides of the top plate connected to the side plates 16. At the opening of the H, the elements 20 of the base plate 24 are arranged, and these elements 20 are connected to the upper plate 18. The elements (20) each have a bulging portion (21) extending perpendicularly to the extending direction of the lines (25) for passing air to be cooled.

Each of these bulging portions 21 is provided with an inlet 12 and an outlet 14 for cooling fluid (e.g., water), respectively. The cooling fluid flowing through the inlet 12 spreads in the bulging portion 21 which is perpendicular to the flow direction of the air to be cooled after being passed through the inlet opening 12 while the cooling fluid is simultaneously passed through the pipelines in the direction of the lower plate 30 Flows. In this case, the cooling fluid flows out from the heat exchanger 10 again through the outlet 14 provided in the bulging portion 21. For connection with the cooling air supply, the inlet or outlet of the air to be cooled is also provided with an adapter 26 or 28.

As can be seen from Fig. 4, there is an overlapping portion a between the top plate 18 and the cavity portion 20, which is bounded by the bulging portion 21. With this overlapping portion, the surface area at which the cooling fluid can flow out can be controlled. In this case, the cooling fluid flows as shown by the broken line in Fig. Since the superposition portion (a) can be easily changed, a corresponding heat exchanger can be easily applied to various applications. This is distinguished from the prior art example shown in FIG. 3 where such variable matching is not possible. In this case, the cooling fluid flows into the cavity 21 'through the inlet 12' without intentionally controlling the outflow of such cooling fluid.

On the other hand, a second embodiment of the present invention will be described with reference to Figs. 5A to 5C. An essential difference with the first embodiment in this case is that the base plate 124 has additional components 120 'which together with the component 120 are mounted on the base plate 124 in apron shape, . In these aprons, the remaining parts of the housing 110 may be inserted, in which case the apron stabilizes the parts. In this regard, the parallelepiped-shaped housing 110 as described above can be manufactured more easily. At the sides adjacent to the bulging portion 121 and surrounding the base plate 124, the part 120 'is formed to be less elevated than the other sides. According to the present invention, the material can be saved without adversely affecting the stability of the heat exchanger 110, since the forces acting at these locations are relatively small. Except for the noted differences, the other design of the housing is the same. 5A and 5B, reference numerals 126 and 128 denote corresponding adapters.

A third embodiment of the present invention will be described with reference to Figs. 6A to 6C. This is a modification of the second embodiment shown in Figs. 5A and 5B. In the second embodiment, the additional components 120 'extend at a variable height with respect to the base plate 124, and in the third embodiment, the corresponding components 220' . This design of the plate element 220 increases the stability of the heat exchanger 210 because no height variation occurs. In this embodiment, the inlet and outlet are also provided on the opposing surfaces of the parallelepiped, which may reduce flow resistance and lead to increased flow rates. In this respect, the cooling efficiency can be improved.

A fourth embodiment of the present invention will be described with reference to Fig. In this case, one of the expanding portions 321 'is designed to be L-shaped. This design of the inflation section further improves the distribution of the cooling fluid, resulting in less flow resistance. This is particularly advantageous when the bulging portion is provided at the inlet of the cooling fluid.

A fifth embodiment of the present invention is shown in Fig. In this case, the bulging portions of the inlet and the outlet are respectively L-shaped. This design further reduces flow resistance.

Claims (7)

A heat exchanger for an internal combustion engine formed to cool air using a cooling fluid, the heat exchanger having a housing, an inlet for cooling fluid and an outlet,
The housing having lines for passing air therethrough, the lines extending through the housing,
An inlet and an outlet for said cooling fluid are formed in said housing,
The housing has a plurality of plate elements forming such a housing, the inlet and outlet being formed in different plate elements,
Said inlet and / or outlet being provided in a bulging of said plate elements, said bulging portion (s) having, along said housing, an extension having a component perpendicular to a straight line connecting said inlet and said outlet , heat transmitter. The method according to claim 1,
Wherein the lines are connected to base plates of the heat exchanger and the inlet and / or outlet for the cooling fluid are formed in a plate element integral with the associated base plate. 3. The method of claim 2,
Wherein said base plate and said part of said plate element following said inlet and / or outlet are perpendicular to each other. The method of claim 3,
Wherein the plate element of the base plate further comprises peripheral components adjacent to the base plate and the peripheral components surround the base plate with the component to which the inlet or outlet is connected. The method according to claim 1,
Wherein the plate element provided with the inlet and / or outlet is overlapped with another plate element of the housing such that the other plate element partially restricts the boundary of the cavity formed by the bulging portion. The method according to claim 1,
Wherein the housing has a parallelepiped shape and the inlet and outlet are formed on the same side of the parallelepiped. The method according to claim 1,
Wherein at least one bulging portion is formed in an L-shape.

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