DE3826244A1 - Oil cooler - Google Patents

Abstract

An oil cooler has a housing through which water is conducted, and in the housing a cooling block made from disc-shaped flat tubes through the interior of which the oil to be cooled is conducted. Partitioning (screening, bulkheading) parts directed at right angles to the direction of flow of the cooling medium and the plane of the flat tubes are arranged in the respective lateral gap between the longitudinal side of the cooling block and the adjacent housing wall. The partitioning parts are formed from webs which are in one piece with the flat tubes and are extended from a shell of the respective flat tube as far as the flat tube next in the stack and, moreover, are bent off to the side and bear against the inside of the adjacent housing wall, preferably in an elastic fashion. The effect of the webs is to reduce a bypass on the water side in the gap, and to permit manufacturing tolerances to be compensated, and this without additional separate parts.

Description

The invention relates to an oil cooler in the upper Concept of claim 1 defined art.

In a known oil cooler of this type (OE-OS 29 03 543) are the bulkhead parts arranged in the bilateral gap as continuous separate profile elements formed that cross to the individual flat tubes and thus across the flow direction of the cooling medium and the gap in individual, Subdivide chamber-like sections. This can cause a Only form the bypass flow in these sections. The are separate profile elements provided for the partition complex and expensive. On the one hand, they provide separate components are additionally manufactured and kept ready for assembly and must be used. On the other hand, this profile is necessary elements a relatively high accuracy of the cooling block and Housing, so that when fitting into the housing on the one hand the Profile elements lie close to the inside of the housing wall and on the other hand, these are also on the cooling block, and this without possibly damaging the cooling block.

The invention has for its object an oil cooler to create the type mentioned in the preamble of claim 1, where the performance without additional costly components ability is improved.  

The task with an oil cooler is in the preamble of Claim 1 defined genus according to the invention by the Features solved in the characterizing part of claim 1.

The fact that the bulkhead parts from with the flat tubes lumpy ridges are formed is a cooling capacity increase without additional and costly parts achieved. The webs are in the shape of the shells, from which the individual flat tubes are formed, the same provided with. Therefore, they do not require any special additional material and manufacturing costs. Furthermore there is the possibility of the elasticity of the material of the shells from which the individual flat tubes are formed are to be exploited, so that thereby an off equal to manufacturing tolerances between cooling block and bilateral housing walls is achieved. Because of the There is a reduction in the water-side bypass is reached between the housing wall and the radiator block this significantly increases the cooling capacity.

Advantageous embodiments of the oil cooler according to claim 1 result from claims 2-17.

Further details and advantages of the invention emerge otherwise from the following description.

The full wording of the claims is above just to avoid unnecessary repetitions given, but instead only by mentioning the Claim numbers referenced it, however, all these claim characteristics as express at this point and disclosed to be essential to the invention. Here are all in the foregoing and following description Features mentioned as well as those from the drawing alone removable features further components of the invention, even if not particularly highlighted and in particular are not mentioned in the claims.

The invention is based on one in the Drawing illustrated embodiment explained in more detail. Show it:

Fig. 1 shows a schematic cross section through an oil cooler,

Fig. 2 is a schematic plan view of the oil cooler,

Fig. 3 shows a schematic section along the line III-III in Fig. 2.

The cooler 10 shown in FIGS. 1-3 is particularly suitable as a liquid cooler and here, for example, as an oil cooler. It has a molded from metal or plastic Ge housing 11 , which is approximately trough-shaped and open at the top and closed there with a lid, not shown. The housing 11 is provided with an inlet 13 and an outlet 14 for a cooling medium to be passed through this, for example water, which are each formed by a pipe socket 16 or 17 inserted into the housing wall 15 , for example.

In the housing 11 , a metallic cooling block 20 is contained, which is formed from individual disc-shaped flat tubes 21 , 22 and other, not shown. The flat tubes 21 , 22 lie between one another, leaving gaps 23 between them, as is known per se for such oil coolers. In the gaps 23 , the heat transfer area enlarging, in cross-section approximately zigzag-shaped elements 24 are included. Elements 25 of the same type are located in the intermediate space 26 between the housing base 27 and the lower flat tube 21 and above the flat tube 22 . The flat tubes 21 , 22 and others are connected to each other with their inner space and are traversed by the medium to be cooled, for example oil. This is fed to the cooling block 20 via an inlet 28 and discharged via an outlet 29 . The cooling block 20 is thus flowed around on the outside by the cooling medium, for example water, while it is flowed through on the inside by the medium to be cooled, for example oil.

The flat tubes 21 , 22 and others are in the form of approximately rectangular longitudinal parts 30 , 31 which are approximately parallel to one another and have longitudinal parts. Between the longitudinal sides 30 , 31 and the adjacent housing walls 32 , 33 there is a gap 34 or 35 , which is fundamentally undesirable since it enables a bypass flow of the cooling medium, which thereby does not participate in the heat exchange and thus the Performance of the cooler 10 is reduced. To counteract this, bulkhead parts 36 and 37 directed transversely to the flow direction of the cooling medium and to the plane of the flat tubes 21 , 22 are arranged in the respective lateral gap 34 and 35 between the edge of the cooling block 20 and the adjacent housing wall 32 , 33 . These bulkhead parts 36 , 37 are formed from webs 38-43 in one piece with the flat tubes 22 , 21 on the flat tube 22 or 44 , 45 on the underlying flat tube 21 , which consist, for example, of rags of the flat tubes 21 , 22 .

As shown in FIG. 2 in particular, each flat tube 21 , 22 has a plurality of such webs on the respective longitudinal side 30 , 31 , in the exemplary embodiment shown three webs 38-40 and 41-43 per longitudinal side 30 and 31 on the flat tube 22 and in in the same way on the underlying flat tube 21 .

In the flat tube 22 , the webs 38-40 of the long side 30 follow one another at equal intervals. Likewise, the ratios on the other long side 31 with respect to the webs 41-43 there . In the same way, the webs 44 , 45 and others are arranged in the flat tube 21 running underneath. The flat tubes 21 , 22 thus have such a piece-like webs on their two longitudinal sides 30 and 31 .

The integrally formed webs 38-45 are each arranged at the same place on the flat tubes 21 , 22 , the webs 38-45 , viewed transversely to the plane of the flat tubes 21 , 22 , connecting to one another, for example to form a continuous separating web. This connection is shown in particular in FIG. 1. There, the right webs 38 and 44 essentially adjoin one another in this direction, transversely to the plane of the flat tubes 21 , 22 , and likewise the webs 41 , 45 on the left, so that each of them on the long side approximately from above Form a continuous divider down to the bottom. The webs 38-45 each have an approximately V-shaped cross section. This is shown in FIG. 2. The tip of the V faces the inside of the housing wall 32 , 33 , the respective web 38-45 lying with this tip on the housing wall 32 , 33 and forming a seal in the gap 34 and 35 , respectively.

The entire cooling block 20 together with the webs 38-45 , which are in one piece with it, can be measured in the transverse direction from the long side to the long side in excess with respect to the transverse dimension of the housing, measured between the housing walls 32 , 33 . Then the cooling block 20 together with the webs 38 to 45 is received with clamping in the housing 11 . Because of the excess, the cooling block 20 is pressed into the housing 11 from above with little effort. The webs 38-45 can deform elastically, or possibly plastically, at least within limits.

The flat tubes 21 , 22 are each composed of an upper shell 46 and 47 and a lower shell 48 and 49 , which are firmly and tightly connected, for example, soldered ver. In the interior formed in this way, approximately zigzag-shaped elements 50 and 51 are contained, which enlarge the surface participating in the heat exchange.

The webs 38-43 visible in the flat tube 22 are all together with one-piece components of the lower shell 49 which overlaps the upper shell 47 all around. The same applies to the flat tube 21 , in which the webs 44 , 45 are also integral components of the lower shell 48 . As can be seen in particular in FIG. 1, the respective webs 38-43 and 44 , 45 are extended above the plane of the flat tube 22 and 21 , respectively. This extension of the webs takes place, as can be seen in particular for the lower webs 44 , 45 in FIG. 1, up to the next following flat tube 22 , so that the webs 44 , 45 this flat tube 22 in the region of the long sides 30 , 31 can spread. The upwardly elongated webs 44 , 45 extend into the gap 34 , 35 between the flat tube 22 and the adjacent housing wall 32 , 33 . To achieve this, the individual webs 38-45 are bent from the respective shell 48,49 in Fig. 1 to the right or left to the side, in such a way that the webs 38-45 on the adjacent inside of the housing wall 32 , 33 - preferably approximately linearly - abut.

In another embodiment, not shown, the flat tubes 21 , 22 are placed the other way round, in such a way that the individual webs 38-45 are not extended upwards but in opposite directions downwards. Furthermore, it is possible that in the case of the flat tubes 21 , 22 the respective upper shell 46 , 47 has webs in one piece in a corresponding manner. Furthermore, it is also possible that corresponding one-piece webs are formed on the upper shell 48 , 47 and the lower shell 48 , 49 of each flat tube 21 , 22 . Here, on each longitudinal side 30 , 31 of the flat tubes 21 , 22 upward webs and downward webs can alternate. In this way, a labyrinth and a bypass stop can also be achieved at such a height of each flat tube 21 , 22 , on which there is no web 38 - 45 in the exemplary embodiment shown in FIGS. 1 and 2. This would be the respective free area below the visible webs 38-45 .

By integrally formed on the flat tubes 21, 22 webs 38-45 which participating in the heat exchange surface of the flat tubes 21 is enlarged 22nd Since the webs 38-45 rest against the inside of the housing walls 32 , 33 - preferably approximately with line contact - and since the webs 38-45 have a substantial height h , as shown in particular in FIGS. 1 and 3, the webs 38-45 effect approximately at this height a partition of the gap 34 or 35 . As a result, a water-side bypass between the cooling block 20 and the housing 11 is reduced in these areas. The achievable cooling capacity is thus increased. At the same time to compensate for manufacturing tolerances between the cooling block 2 D on the one hand and the housing walls 32, 33 on the other hand allows. All advantages are achieved without the need for separate elements and additional parts; because the webs 38-45 are created with the flat tubes 21 , 22 as one-piece elements during their manufacture, which means practically no additional effort. In everything, the elasticity of the material from which the flat tubes 21 , 22 are formed can be used in a particularly advantageous manner.

In another exemplary embodiment, not shown, the webs 38-45 , viewed in cross section, are approximately arc-shaped and here are convexly curved outward in the direction of the housing wall 32 or 33 .

It goes without saying that, starting from the embodiment shown, the webs 38-45, for example, can also rest only in the region of their respective upper end on the inside of the housing wall 32 or 33 .

Claims (17)

1. Oil cooler, with a housing which is provided with an inlet and an outlet for a cooling medium to be passed through this, for example water, with a cooling block ( 20 ) contained in the housing ( 11 ), which consists of individual parts leaving gaps ( 23 ) is formed in between over approximately disc-shaped flat tubes ( 21 , 22 ), each of which is composed of shells and through the interior of which the oil to be cooled is passed, and with transverse to the flow direction of the cooling medium and to the level of the flat tubes ( 21 , 22 ) directed bulkhead parts ( 36 , 37 ) in the respective lateral gap ( 34 , 35 ) between the edge of the cooling block ( 20 ) and the adjacent housing wall ( 32 , 33 ), characterized in that the bulkhead parts ( 38 , 37 ) from the flat tubes ( 21 , 22 ) one-piece webs ( 38-45 ) are formed ge. 2. Oil cooler according to claim 1, characterized in that the flat tubes ( 21 , 22 ) on a longitudinal side ( 30 , 31 ) have a plurality of integral webs ( 38-45 ). 3. Oil cooler according to claim 2, characterized in that the webs ( 38-45 ) follow one another in the longitudinal direction at approximately equal intervals. 4. Oil cooler according to one of claims 1-3, characterized in that the flat tubes ( 21 , 22 ) on their two longitudinal sides ( 30 , 31 ) thus have integral webs ( 38-45 ). 5. Oil cooler according to one of claims 1-4, characterized in that the webs ( 38-45 ) are in one piece with a shell ( 48 , 49 ) of the respective flat tube ( 21 , 22 ). 6. Oil cooler according to one of claims 1-5, characterized in that the respective webs ( 38-45 ) on the plane of the flat tube ( 21 , 22 ) are extended upwards and / or downwards. 7. Oil cooler according to claim 8, characterized in that the respective webs ( 38-45 ) are extended up to the next flat tube ( 21 , 22 ) next to the top and bottom of the stack and into the gap ( 34 , 35 ) between them grip the latter flat tube ( 21 , 22 ) and the adjacent housing wall ( 32 , 33 ). 8. Oil cooler according to one of claims 5-7, characterized in that the webs ( 38-45 ) from the respective shell ( 48 , 49 ) are bent to the side and on the adjacent inside of the housing wall ( 32 , 33 ) , preferably about linear. 9. Oil cooler according to one of claims 5-8, characterized in that the lower shell ( 48 , 49 ) at least some flat tubes ( 21 , 22 ) thus has one-piece webs ( 38-45 ). 10. Oil cooler according to claim 9, characterized in that on the lower shell ( 48 , 49 ) of each flat tube ( 21 , 22 ) thus one-piece webs ( 41- 45 ) are arranged. 11. Oil cooler according to one of claims 5-10, characterized in that the upper shell ( 46 , 47 ) of at least some flat tubes ( 21 , 22 ) thus has one-piece webs. 12. Oil cooler according to claim 11, characterized in that one-piece webs are arranged on the upper shell ( 46 , 47 ) of each flat tube ( 21 , 22 ). 13. Oil cooler according to one of claims 5-12, characterized in that the integrally formed webs ( 38-45 ) are arranged at the same place in each case of the flat tubes ( 21 , 22 ) and themselves, transversely to the plane of the flat tubes ( 21 , 22nd ) seen, connect to each other to form a continuous divider. 14. Oil cooler according to one of claims 5-12, characterized characterized in that each longitudinal side of the flat tubes upward webs and Alternate downward webs. 15. Oil cooler according to one of claims 1-14, characterized in that the webs ( 38-45 ) each have an approximately V-shaped cross section, the tip of the V facing the inside of the housing wall ( 32 , 33 ) and on it is present. 16. Oil cooler according to one of claims 1-14, characterized in that the webs each have an arcuate and outwardly convexly curved cross section and are arched to the inside of the housing wall ( 32 , 33 ) and bear against it. 17. Oil cooler according to one of claims 1-16, characterized in that the cooling block ( 20 ) with the thus integral webs ( 38-45 ) in the transverse direction from long side to long side measured oversize with respect to the transverse dimension of the housing ( 11 ) and with clamping between the two-sided housing walls ( 32 , 33 ) is received.