DE102014208259A1 - Cooling device for cooling a fluid medium, exhaust gas recirculation system for an internal combustion engine and internal combustion engine - Google Patents

Abstract

It is a cooling device (1) for cooling a fluid medium, with
- A conduit means (3) for the fluid medium having a in a first direction (x) extending hot region (5) and a substantially parallel to the hot region (5) extending cold region (7), wherein
- The hot region (5) with the cold region (7) via a deflection region (9) is connected, and wherein
- An inlet (11) for a cooling medium along a second direction (y) on a hot region (5) facing side opens into the cooling device (1), wherein the second direction (y) is oriented transversely to the first direction (x) , proposed.
The cooling device is characterized in that
- Between the hot region (5) and the cold region (7) a flow guide (21) is arranged and designed such that by the inlet (11) inflowing cooling medium from the flow guide (21) at least partially in the first direction (x) is deflected ,

Description

The invention relates to a cooling device for cooling a fluid medium according to claim 1, an exhaust gas recirculation system for an internal combustion engine according to claim 13 and an internal combustion engine according to claim 14.

A cooling device of the type mentioned here has a conduit means for a fluid medium, the conduit means having a hot region extending in a first direction and a cold region extending substantially parallel, typically parallel to the hot region. The hot area is connected to the cold area via a deflection area. Therefore, the fluid medium enters the hot region of the conduit means on a first side as seen along the first direction, flows through the hot region along the first direction, and becomes on a second side opposite to the first side along the first direction deflected, after which it again along the first direction - but now with opposite orientation - flows through the cold area back to the first side, where it exits the conduit means and thus typically at the same time from the cooling device. An inlet for a cooling medium is provided, which opens into the cooling device along a second direction, which is oriented transversely, typically perpendicular to the first direction, on a side facing the hot region. The cooling medium is therefore introduced transversely, preferably perpendicular to the first direction in the cooling device, wherein it flows around the conduit means and thereby cools the fluid flowing in this medium.

Such a cooling device is used, for example, as an exhaust gas recirculation cooler for cooling recirculated exhaust gas of an internal combustion engine.

A disadvantage of the cooling device is that inflowing through the inlet cooling medium along the second direction can flow unhindered over the hot area out into the cold area, wherein a flow distribution is formed, in which the cooling medium substantially - after a relatively short distance through the hot area therethrough - flows along the cold area, before it finds back from there into the hot area.

This results in a flow distribution with which certain zones - so-called dead zones - of the hot area are not detected. It may therefore come to an early damage to the conduit means in the hot area due to the non-ideal coolant flow around. In particular, in the above-mentioned dead zones, which are insufficiently flowed around by the cooling medium, there may be damage to the conduit means, since this is not sufficiently washed in its course by the cooling medium. Thus, it is at the same time only imperfectly possible to meet essential requirements for the cooling device, namely a uniform heat transfer, prevention of nucleate boiling, especially in the hot area, a required life, and avoiding the formation of dead zones.

The invention has for its object to provide a cooling device which does not have the disadvantages mentioned. In addition, the invention has for its object to provide an exhaust gas recirculation system for an internal combustion engine and an internal combustion engine, which do not have the disadvantages mentioned.

The object is achieved by providing a cooling device with the features of claim 1. Characterized in that between the hot region and the cold region a flow guide is arranged and designed so that at least partially deflected by the inlet inflowing cooling medium from the flow guide in the first direction, a shooting through a main amount of cooling medium from the hot area directly into the cold area prevented. Rather, the cooling medium is deflected by the flow guide in the direction of the first direction, and thus in the direction of the longitudinal course of the hot region, so that dead zones are effectively avoided in this. Thus, it is possible, in particular to supply critical areas in the hot area sufficiently with cooling medium or to flow around, at the same time negative effects on the cooling medium flow in the region of the inlet are avoided. The improved cooling of the conduit means in the hot zone reduces stresses in the components and avoids premature damage to the conduit means. At the same time a uniform heat transfer is realized, with a cooling capacity, an outlet temperature of the fluid to be cooled, fluid and other parameters can be fulfilled by default. Bubble boiling in the hot zone is prevented by the improved cooling media flow.

In a preferred embodiment of the cooling device, the cold region extends parallel to the hot region along the first direction. Alternatively or additionally, it is provided that the second direction is oriented perpendicular to the first direction. In this case, the cooling medium is introduced perpendicular to the first direction, and thus perpendicular to a longitudinal extent of the conduit means in the cooling device. there realize in a special way, the advantages of the cooling device proposed here, as by means of the flow guide a shooting through a large amount of the cooling medium is effectively prevented directly into the cold area. Rather, the cooling medium is effectively distributed in the hot area or deflected in this, so that here no or at most greatly reduced dead zones arise.

An embodiment of the cooling device is preferred, which is characterized in that the conduit device has an end element which is arranged transversely to the first direction. The end element has an inlet for the fluid medium in the hot area and an outlet for the fluid medium from the cold area. The fluid medium to be cooled thus enters the hot region through the end element, flows through it, is deflected in the deflection region, flows back into the cold region, and finally exits the cooling device again through the end element. It is preferably provided that the inlet - seen along the first direction - opens in the region or on the side of the Stirnelements in the cooling device. This has the advantage that the cooling medium flowing into the cooling device comes into direct contact with the hottest point of the hot region, namely an environment of the inlet, and thus can cool the fluid medium very quickly and efficiently.

A drain for the cooling medium is preferably provided - as seen along the first direction - in the region or on the side of the deflection region, ie at an opposite end of the conduit device or the cooling device. The cooling medium thus has the same flow direction in the cooling device as the fluid medium to be cooled in the hot region. In contrast, in the cold area, a countercurrent cooling, because here the fluid medium flows in the opposite direction as the flowing from the inlet to the drain cooling medium. This combination of a co-current flow of cooling medium and fluid medium in the hot region and a counterflow in the cold region is particularly advantageous for a fast and efficient cooling of the fluid medium.

An embodiment is preferred in which the end element is arranged perpendicular to the first direction, or in which the first direction is perpendicular to the end element. This is geometrically and also particularly favorable production technology. This also makes it possible to realize a particularly compact and space-saving cooling device.

The front element is preferably - viewed along the first direction - the deflection arranged opposite. Accordingly, the fluid medium flows from the end member along the hot region to the baffle, where it is deflected, and flows along the cold region from the baffle back to the brow member.

It is also preferred an embodiment of the cooling device, which is characterized in that the flow guide is at least partially spaced from the end element - seen in the first direction - spaced. This means that the flow guide at least does not bear along its entire height on the end element, but rather - at least partially - results in a gap between the end member and the flow guide. It is also possible for the flow-guiding element to be arranged at a distance from the end element as a whole, with a gap occurring between the latter and the end element along the entire height of the flow-guiding element. Through the gap, cooling medium flowing in via the inlet into the cooling device can flow over from the hot region into the cold region. Thus, it is not completely prevented a flow of cooling media from the hot area in the cold area, but it is only a major amount of the incoming cooling medium is deflected by the flow guide in the first direction and thus in the hot area. By the size of the gap, thus the distance between the end element and the flow guide, the amount of cooling medium can be adjusted, which flows directly over the hot area in the cold area. In particular, a mass flow of cooling medium into the cold region can be adjusted by varying the gap width in this way. That cooling medium introduced into the cold region in this way then preferably flows in the cold region parallel to the cooling medium flow in the hot region, as viewed along the first direction, whereby it is also conducted through the flow guidance element.

It is preferably provided that the flow-guiding element does not extend over the entire length-seen along the first direction-of the conduit device. Rather, its length is tuned so that otherwise forming dead zones are effectively avoided in the hot region, wherein the flow guide is no longer formed, as it is required for this purpose. At the point at which the flow guide - as seen along the first direction - ends, unite the cooling media streams from the cold area and the hot area, where they flow around the remaining length of the conduit means together. Finally, the combined cooling media streams through the process from the Cooling device dissipated. This results in a particularly efficient cooling with high cooling capacity and extended service life of the conduit device.

It is also preferred an embodiment of the cooling device, which is characterized in that the flow guide is designed as a baffle. This is an easy to manufacture and inexpensive form of a flow guide. This is also very easy to install. It is possible that the baffle is designed differently depending on the requirement. For example, its contour, its position within the cooling device and in particular relative to the conduit device, its length, its width and its height according to requirements, in particular depending on a to be achieved flow distribution of the cooling medium in the cooling device, can be varied.

In a preferred embodiment, it is possible that the flow guide formed as a guide plate has at least one recess. Through the recess, in particular in addition to the gap between the end element and the flow guide, cooling medium can flow over from the hot region directly into the cold region. Thus, by means of the at least one recess, in particular by a suitable choice of its size and position, it is possible to define the flow distribution in the cooling device. Particularly preferably, it is possible that the flow guide is designed as a perforated plate, wherein it has a plurality of recesses. These can in turn be adapted in terms of their size, distribution and position to a desired flow distribution.

An embodiment of the cooling device is also preferred, which is characterized in that the flow-guiding element is at least partially spaced from at least one outer wall of the cooling device in a third direction, which is oriented transversely to the first direction and transverse to the second direction. In this way, in addition to the gap between the end element in the flow guide element, further gaps are created in edge regions of the flow guide element, via which cooling medium can flow directly into the cold region from the hot region. The flow distribution in the cooling device can be additionally influenced in this way. Preferably, the third direction is perpendicular to both the first direction and the second direction.

Particularly preferably, the first direction is a length of the cooling device, but in particular a length of the conduit means. The second direction is preferably a width of the cooling device, wherein the third direction preferably represents a height of the cooling device. The flow guide, which is preferably designed as a guide plate, is preferably oriented so that the width of the cooling device is perpendicular to it. It is thus a longitudinal baffle. It preferably does not extend over the entire length of the cooling device and also not over the entire length of the conduit means. Rather, it ends up in an area, by ensuring that no more relevant dead zones form in the hot area. The baffle preferably does not extend over the entire height of the cooling device. Rather, here at least one side preferably remains a gap between an outer wall of the cooling device and the flow guide, so that in the region of an upper side and / or in the region of an underside of the flow guide cooling medium can pass directly from the hot area in the cold area. The gaps provided in this respect are preferably provided in addition to the gap between the end element and the flow guide.

It is also preferred an embodiment of the cooling device, which is characterized in that the conduit means comprises at least one tube in the hot region and in the cooling region. The fluid medium is thus guided within the conduit means by at least one tube which is flowed around by the cooling medium. Preferably, a plurality of tubes is provided, which are particularly preferably oriented parallel to each other. It is possible that at least one U-shaped tube is used which has the deflection region in the connection region between the two legs of the U. Alternatively, the deflection region is preferably provided as a separate element, in particular as a deflection bell, into which at least one pipe associated with the hot region and a pipe associated with the cold region open. The fluid medium occurs within the Umlenkglocke initially from the tube, which is assigned to the hot zone, is deflected in the Umlenkglocke, and then enters the tube, which is associated with the cold area. Preferably, a plurality of tubes for the hot zone and a further plurality of tubes for the cold zone are provided.

Particularly preferably, the conduit device has tube packages, in particular at least one tube bundle associated with the hot zone, and at least one tube bundle associated with the cold zone, preferably three tube bundles oriented parallel to each other, each tube bundle having a plurality of tubes oriented parallel to each other. In this case, the tubes of a tube bundle are preferably arranged one above the other along the third direction, the tube bundles being arranged alongside one another along the second direction.

In a preferred embodiment, two pipe packages are provided for the hot area, wherein a pipe package is provided for the cold area. The hot region thus comprises approximately twice the volume of the cold region, which accommodates the lower density at the higher temperature of the fluid medium in the hot region. In this way, it is preferably possible to keep the flow velocity of the fluid medium constant in the hot region on the one hand and in the cold region on the other hand.

An embodiment of the cooling device is also preferred, which is characterized in that the end element is designed as a front plate. In the face plate, the at least one tube is held and / or guided. In this way, the line device can be very simple and inexpensive to build. Preferably, the end element has a plurality of recesses, wherein in each recess preferably a tube is held and / or guided. The tubes are preferably inserted into the recesses of the Stirnlements or the face plate. A positive, non-positive or cohesive connection of the tubes with the end element, for example by welding, soldering, gluing or plugging / pressing, is possible.

The conduit device preferably has the end element, the at least one tube, in particular the at least one tube packet, and particularly preferably the multiplicity of tube pucks, and the deflection region. In particular, the conduit device preferably has the end plate, the at least one tube package, particularly preferably the plurality of tube packages, and the deflection bell. The deflecting bell preferably has - analogous to the end plate - a plurality of recesses, in each of which a tube is inserted.

Again, a positive, positive and / or cohesive connection of the tubes with the Umlenkglocke is possible. In particular, a fluid-tight connection to the tubes is preferably produced both in the region of the front element and in the area of the deflection bell, in order to prevent leakage of the fluid medium from the tubes and the penetration of cooling medium into the tubes.

It is also preferred an embodiment of the cooling device, which is characterized in that the conduit means is arranged in a housing of the cooling device, wherein the end element at least one cooling chamber of the housing closes the end face. It is possible that the housing has a plurality of cooling chambers, wherein in each cooling chamber, a cooling device is arranged. However, an embodiment of the cooling device is also preferred in which the housing has only one cooling chamber, which preferably comprises the entire housing. Accordingly, the housing is preferably closed by the end element on the entire front side. The conduit means is preferably constructed on the front element and held by this, where it can be mounted as a package together with the end element to the housing. In this case, the line device is preferably inserted into the housing, and the end element is attached to the front side of the housing. It is preferred that a fluid-tight connection between the end element and the housing is realized, so that no cooling medium can escape from the housing - apart from the sequence where the cooling medium emerges from the housing as intended.

It is also preferred an embodiment of the cooling device, which is characterized in that the housing has a side wall which extends substantially parallel to the first direction. The inlet is arranged in the side wall. The side wall preferably extends exactly parallel to the first direction, ie in the longitudinal direction or in the longitudinal direction of the cooling device and the conduit device. The inlet preferably passes through the side wall. Preferably, it is at least slightly spaced from the end element, resulting in a better flow behavior of the cooling medium into the housing.

In particular, the housing has a first side wall facing the hot region and a second side wall facing the cold region. The inlet is preferably arranged in the first side wall, which faces the hot region.

Also, the drain is preferably arranged in a side wall of the housing, which extends substantially parallel, preferably parallel to the first direction. Furthermore, the drain, which preferably passes through the side wall, is also arranged in the first side wall, which faces the hot region. Thus, preferably, the inlet and the outlet are arranged on the same side of the housing, in particular in the same side wall. This results in a particularly favorable and efficient cooling medium flow in the housing.

An embodiment of the cooling device is also preferred, which is characterized in that it has at least one baffle element which is set up and arranged for influencing the flow of the cooling medium in the cooling device. The baffle element is preferably designed as a baffle plate. Preferably, it also serves to hold the at least a pipe, so that this - seen along its longitudinal extent - in particular between the front plate and the deflection still supported and held by the at least one harassment element. In particular, if a plurality of pipes or tube packages is provided, the individual tubes can be protected against vibrations and consequent damage. The at least one baffle element preferably also serves as a spacer element between the individual tubes and / or tube pacts.

The cooling device preferably has a plurality of chicane elements. The arrangement of the at least one baffle element, preferably the plurality of baffle elements, is preferably optimized with regard to an optimal flow distribution of the cooling medium in the cooling device.

It turns out that the baffle elements can fulfill two functions at the same time, namely on the one hand support and support of at least one tube, in particular the plurality of tubes and / or tube packages, and on the other an influence on the flow distribution in the housing. This is advantageous both in terms of costs associated with the cooling device and in terms of space requirements.

An embodiment of the cooling device is also preferred, which is characterized in that the cooling device has a second flow-guiding element which is arranged in the hot region and designed so that the cooling medium flowing in through the inlet is partially deflected by the second flow-guiding element in the first direction becomes. Seen along the path of the inflowing cooling medium, the second flow guide is thus arranged in front of the first flow guide, wherein it diverts a portion of the flow of cooling media even before the deflection by the first flow in the hot region in the first direction. The second flow guide can help to minimize dead zones particularly efficient, preferably to eliminate.

Preferably, the second flow guide is designed as a baffle. It is particularly preferably arranged parallel to the first flow-guiding element. It is possible that the second flow guide is formed as a perforated plate. Alternatively or additionally, at least on one side, as in the case of the first flow-guiding element, at least one gap is provided in order to pass a portion of the cooling-medium flow past the second flow-guiding element. Particularly preferably, a smaller part of the cooling medium is deflected by the second flow guide, wherein a larger part is deflected by the first flow guide. The flow guide elements are preferably matched according to their dimensions and their column and / or recesses or holes corresponding to each other. Alternatively, however, it is also possible that identical flow guide elements, in particular identical guide plates, are used for the first and the second flow guide elements, wherein these are preferably arranged parallel to one another.

In a preferred embodiment, the second flow guide is disposed between the two tube packages of the hot region.

The second flow-guiding element is preferably characterized by at least one feature explained in connection with the first flow-guiding element.

An embodiment of the cooling device is preferred, which is characterized in that it is designed as an exhaust gas recirculation cooler. The cooling device is used for cooling recirculated exhaust gas of an internal combustion engine. In this case, the above-described advantages of the cooling device are realized in a particular manner, in particular because the exhaust gases, which are very hot under full load of the internal combustion engine and enter the hot region as a fluid medium, are cooled very efficiently by the cooling medium, dead zones and a premature resulting therefrom Damage to the conduit device can be avoided.

The object is also achieved by providing an exhaust gas recirculation system for an internal combustion engine having the features of claim 13. This is characterized by a cooling device according to one of the embodiments described above. This realizes for the exhaust gas recirculation system, the advantages that have already been explained in connection with the cooling device. It is possible that the exhaust gas recirculation system has a plurality of cooling devices, in particular a plurality of cooling devices of the type proposed here.

Finally, the object is also achieved by providing an internal combustion engine having the features of claim 14. This is characterized by an exhaust gas recirculation system according to one of the embodiments described above. Thus realized in connection with the internal combustion engine, the advantages that have already been explained in connection with the exhaust gas recirculation system and the cooling device.

The internal combustion engine is preferably designed as a reciprocating engine. In a preferred embodiment, the internal combustion engine is used the drive in particular heavy land or water vehicles, such as mine vehicles, trains, the internal combustion engine is used in a locomotive or a railcar, or ships. It is also possible to use the internal combustion engine to drive a defense vehicle, for example a tank. An exemplary embodiment of the internal combustion engine is preferably also stationary, for example, used for stationary power supply in emergency operation, continuous load operation or peak load operation, the internal combustion engine in this case preferably drives a generator. A stationary application of the internal combustion engine for driving auxiliary equipment, such as fire pumps on oil rigs, is possible. Furthermore, an application of the internal combustion engine in the field of promoting fossil raw materials and in particular fuels, for example oil and / or gas, possible. It is also possible to use the internal combustion engine in the industrial sector or in the field of construction, for example in a construction or construction machine, for example in a crane or an excavator. The internal combustion engine is preferably designed as a diesel engine, as a gasoline engine, as a gas engine for operation with natural gas, biogas, special gas or another suitable gas. In particular, when the internal combustion engine is designed as a gas engine, it is suitable for use in a cogeneration plant for stationary power generation.

The invention will be explained in more detail below with reference to the drawing. Showing:

1 a schematic representation of a cooling device and a flow distribution of a cooling medium in this;

2 a schematic detail of an embodiment of a cooling device;

3 a further schematic detail of the embodiment according to 2 , and

4 a schematic representation of the embodiment according to the 2 and 3 with a flow distribution of the cooling medium.

1 shows a schematic representation of a cooling device 1 according to the prior art, as well as a prevailing flow distribution. The cooling device 1 has a here only schematically indicated conduit device 3 for a fluid medium, in particular for recirculated exhaust gas of an internal combustion engine, wherein the conduit means 3 a hot area 5 and a parallel thereto oriented cold area 7 having. Both the hot area 5 as well as the cold area 7 extend along a first direction, which is designated here by x. At the same time, the x-direction corresponds to the longitudinal direction of the conduit device 3 and the cooling device 1 , The hot area 5 is with the cold area 7 over a deflection area 9 connected. It is an inflow 11 for a cooling medium, in particular for cooling water, provided along a second direction, which is referred to here as the y-direction, in the cooling device 1 empties. The second direction here is perpendicular to the first direction. The y-direction represents a width of the conduit means 3 and the cooling device 1 is perpendicular to the x-direction and to the y-direction extends a third direction, which is referred to here as the z-direction. This represents a height of the conduit device 3 and the cooling device 1 dar. The cooling medium passes through the inlet 11 in the cooling device 1 a, flows through this, where it is the conduit device 3 flows around, and exits the cooling device 1 through a process 13 out again. The flow direction of the cooling medium is indicated here by arrows P.

It turns out that by the inflow 11 entering cooling medium due to its perpendicular velocity component in the y-direction, which is perpendicular to the longitudinal x-direction, directly from the hot region 5 in the cold area 7 shoots. Only there is it through a wall of the cooling device 1 deflected in the x direction.

As a result, in the hot area 5 a comparatively large dead zone 15 arises, in which the conduit device 3 is hardly or not at all flowed around by cooling medium. In this area, therefore, only very insufficient - if any - heat can be removed from the fluid medium. Therefore, it can lead to premature damage to the conduit device 3 and / or come to a nucleate boiling of the cooling medium.

2 shows a three-dimensional detail of an embodiment of a cooling device according to the invention 1 , Identical and functionally identical elements are provided with the same reference numerals, so that reference is made to the preceding description. The cooling device 1 is preferably part of an exhaust gas recirculation system 17 an internal combustion engine 19 , In this respect, the cooling device 1 preferably designed as an exhaust gas recirculation cooler.

Shown here is in detail the conduit device 3 , It turns out that between the hot area 5 and the cold area 7 a flow guide 21 is arranged and designed so that by the inlet, not shown here 11 inflowing cooling medium from the flow guide 21 at least partially in the first direction, hence the x-direction, is deflected. The coolant flowing in along the y-direction hits it on the flow guide 21 and is characterized by this at least in its main amount of the flow into the cold area 7 prevented. Rather, it is redirected here in the x-direction, so that in any case no dead zone 15 which is as big as the one in 1 illustrated dead zone 15 , preferably no dead zone at all 15 , Thus, the conduit device becomes 3 in the hot area 5 and thus flows around in a critical range sufficiently from the cooling medium, wherein premature damage to the conduit means 3 and also nucleate boiling of the cooling medium can be avoided.

Based on 2 also shows that the conduit device 3 a front element 23 has, on which the x-direction is perpendicular here. The forehead element 23 extends here thus parallel to the yz plane. It has an inlet 25 for the fluid medium and an outlet 27 for this. The fluid medium, in particular the recirculated exhaust gas of the internal combustion engine 19 , enters through the inlet 25 in the hot area 5 a, flows through this, as shown here by arrows P ', up to the deflection 9 , is deflected there, and flows - as also shown by an arrow P '- along the cold area 7 back against the x-direction, passing through the outlet 27 exits again.

It also shows that the conduit device 3 here a plurality of pipes 29 , in particular three tube packages 31 . 31 ' . 31 '' , wherein the tubes 29 the individual tube packages 31 . 31 ' . 31 '' - Seen in the z-direction - are arranged one above the other, wherein the tube packages 31 . 31 ' . 31 '' - Seen in the y direction - are arranged side by side. Here are a first and a second tube package 31 . 31 ' the hot area 5 assigned, with a third tube package 31 '' the cold area 7 assigned. The single tubes 29 are in recesses 33 of the Stirnelements 23 plugged in. This is here as a face plate 35 formed in which the pipes 29 held and managed. It is possible that the pipes 29 with the face plate 35 force, shape and / or material fit, for example, by welding or soldering, are connected.

The deflection area 9 is here as Umlenkglocke 37 formed, with the tubes 29 preferably in recesses 39 the deflection bell 37 are plugged in. This embodiment is preferably analogous to the attachment of the tubes 29 in the face plate 35 educated. Preferably, the tubes 29 also with the deflection bell 37 non-positively, positively and / or materially bonded, in particular by soldering or welding.

The fluid to be cooled, in particular the recirculated exhaust gas of the internal combustion engine 19 So enter through the inlet 25 in the first tube package 31 and the second tube package 31 ' which is the hot area 5 are assigned, it being through these tube packages 31 . 31 ' to the deflection area 9 flows. In the deflection bell 37 unite the fluid media streams of the two tube packages 31 . 31 ' , are redirected together, and finally arrive in the third tube package 31 '' , which is the cold area 7 assigned. Through them they flow back to the outlet 27 where she is the conduit device 3 leave.

In 2 is also apparent that the cooling device 1 preferably at least one chicane element, here two chicane elements 41 having. These serve for a support of the tubes 29 , In particular, a support thereof against relative vibrations, and on the other hand, a suitable influence of the cooling medium flow in the cooling device 1 , Also the flow guide 21 is preferably of at least one chicane element 41 held.

The conduit device 3 is preferably in an in 2 Housing of the cooling device, not shown 1 arranged. Here are in the illustrated embodiment of the chicane elements 41 clip elements 43 arranged with which the conduit device 3 can be mounted in the housing, and / or with their help side walls of the housing to the conduit means 3 can be attached. The face plate 35 here also has mounting holes 45 for particular fluid-tight attachment to the housing. In this way it is possible that the front element 23 the housing frontally - in particular fluid-tight - closes.

3 shows a detailed representation of the embodiment of the cooling device 1 according to 2 , in which case in particular a detail of the conduit device 3 is shown. Identical and functionally identical elements are provided with the same reference numerals, so that reference is made to the preceding description. Here is the view of the observer here on the flow guide 21 directed, which is the cold area 7 assigned, third tube package 31 '' not shown. Rather, only the first tube package 31 and the second tube package 31 ' shown. The flow guide 21 is oriented parallel to the xz-plane, with the y-direction perpendicular to it.

It turns out that the flow guide preferably as a baffle 47 is trained. It is here at the edge, on one the front element 23 facing edge, cut so that it partially from the front element 23 - Seen in the x direction - is spaced. As a result, between the front element 23 and the flow guide 21 partially a gap 49 formed by which inflowing cooling medium from the hot region 5 directly into the cold area 7 can overflow. About the - measured in the x direction - width of the gap 49 can be the mass flow of the cooling medium in the cold area 7 be set.

It can also be clearly seen that the flow guide 21 not over the entire length of the conduit device 3 extends. A the front element 23 opposite end 51 the flow guide 21 is preferably positioned so that dead zones 15 in the hot area 7 be minimized or eliminated, at the same time an optimal flow of the cooling medium in the cooling device 1 taking into account efficient cooling also the cold area 7 established.

It also turns out that the flow guide 21 not over the entire - measured in the z direction - height of the second tube package 31 ' and thus the management device 3 extends. Therefore, it also has a distance from one in 4 schematically indicated outer wall 53 the cooling device 1 on, both to a ceiling area, as well as to a floor area of a likewise in 4 schematically indicated housing 55 the cooling device 1 , Also in the area of so to a ceiling or a bottom of the housing 55 resulting column may be a cooling medium flow from the hot area 5 in the cold area 7 To be defined.

4 shows a schematic representation of the embodiment of the cooling device 1 according to the 2 and 3 including a flow distribution. Identical and functionally identical elements are provided with the same reference numerals, so that reference is made to the preceding description. It turns out that by the inlet 11 inflowing cooling medium here - in contrast to the cooling device according to 1 - not with its bulk directly into the cold area 7 can einschießen, but rather by the flow guide 21 is deflected in the x direction. This completes the formation of the deadband 15 greatly reduced, preferably avoided, and the pipes 29 in the hot area 5 are sufficiently flowed around by cooling medium. About the gap 49 and preferably also over the gaps in the floor and ceiling area of the housing 55 However, a proportion of the cooling medium occurs from the hot area 5 in the cold area 7 over, so that here cooling medium flows to cool the fluid medium. Quasi downstream of the flow guide 21 the two cooling media streams unite from the hot area 5 and the cold area 7 again, enforce the case 55 continue, ultimately flow through the deflection area 9 , taking the bell 37 flow around, and finally step through the process 13 back out of the case 55 out.

It shows that the case 55 a the hot area 5 facing, first side wall 57 as well as the cold area 7 facing, second side wall 59 having. Here are both the inlet 11 as well as the process 13 in the first side wall 57 arranged, whereby they prevail preferentially. It shows further that the inflow 11 - in the x-direction - in the area of the Stirnelements 23 in the cooling device 1 opens, but it is arranged somewhat spaced from this. In this way results in a particularly favorable for the purpose of cooling the fluid medium flow of the cooling medium in the housing 55 , It also shows that the front element 23 a cooling chamber enclosed by the housing 61 closes the front side.

Furthermore, it turns out that the embodiment of the cooling device shown here 1 preferably three chicane elements 41 having. However, it is also a deviating number of chicane elements 41 possible.

In another embodiment of the cooling device 1 is it still possible that as a baffle 47 trained flow guide 21 is designed as a perforated plate. This allows the immediate of the hot area 5 in the cold area 7 overflowing proportion of cooling medium adjusted as needed and increased in particular in comparison to the embodiment shown in the figures.

In 4 dashed is still a second flow guide 63 which is optional in the hot area 5 especially between the tube packages 31 . 31 ' can be arranged. It is preferably parallel to the first flow guide 21 aligned. In the 4 However, flow distribution shown is based on a simulation of the cooling device 1 without the second flow guide 63 , Using the second flow guide 63 is it possible already in the hot area 5 To divert a portion of the cooling medium in the x direction and thus eliminate needful and efficient dead zones or at least minimize. In this case, the two flow guide elements 21 . 63 preferably coordinated so that a larger part of the cooling medium from the first flow guide 21 is deflected, with a smaller part in advance of the second flow guide 63 is diverted. Alternatively, it is also possible that identical flow guide elements, in particular identical guide plates, for the first and the second flow guide 21 . 63 be used, these are preferably arranged parallel to each other.

Overall, it turns out that the cooling device 1 enables a particularly efficient and at the same time material-saving cooling of a fluid medium. This is especially true for a fluid medium, which recirculated exhaust gas of an internal combustion engine 19 represents, so that the cooling device 1 is particularly preferably designed as exhaust gas recirculation cooler.

Claims (14)

Cooling device ( 1 ) for cooling a fluid medium, with - a conduit device ( 3 ) for the fluid medium having a hot region extending in a first direction (x) ( 5 ) and one substantially parallel to the hot region ( 5 ) extending cold area ( 7 ), wherein - the hot region ( 5 ) with the cold area ( 7 ) over a deflection area ( 9 ), and wherein - an inlet ( 11 ) for a cooling medium along a second direction (y) on a hot region ( 5 ) facing side in the cooling device ( 1 ), wherein the second direction (y) is oriented transversely to the first direction (x), characterized in that - between the hot region ( 5 ) and the cold area ( 7 ) a flow guide ( 21 ) is arranged and designed such that through the inlet ( 11 ) inflowing cooling medium from the flow guide ( 21 ) is deflected at least partially in the first direction (x). Cooling device ( 1 ) according to claim 1, characterized in that the conduit means ( 3 ) a front element ( 23 ), which is arranged transversely to the first direction (x) and an inlet ( 25 ) for the fluid medium in the hot area ( 5 ) and an outlet ( 27 ) for the fluid medium from the cold region ( 7 ), wherein the feed ( 11 ) - seen in the first direction - in the area of the Stirnelements ( 23 ) in the cooling device ( 1 ) opens. Cooling device ( 1 ) according to one of the preceding claims, characterized in that the flow guiding element ( 21 ) at least partially from the end element ( 23 ) - seen in the first direction (x) - is spaced. Cooling device ( 1 ) according to one of the preceding claims, characterized in that the flow guiding element ( 21 ) as baffle ( 47 ) is trained. Cooling device ( 1 ) according to one of the preceding claims, characterized in that the flow guiding element ( 21 ) in a third direction (z), which is oriented transversely to the first direction (x) and transversely to the second direction (y), at least in regions of at least one outer wall ( 53 ) of the cooling device ( 1 ) is spaced. Cooling device ( 1 ) according to one of the preceding claims, characterized in that the conduit device ( 3 ) at least one pipe ( 29 ) in the hot area ( 5 ) and in the cooling area ( 7 ) having. Cooling device ( 1 ) according to one of the preceding claims, characterized in that the front element ( 21 ) as a face plate ( 35 ) is formed, in which the at least one tube ( 29 ) is maintained and / or guided. Cooling device ( 1 ) according to one of the preceding claims, characterized in that the conduit device ( 3 ) in a housing ( 55 ) of the cooling device ( 1 ) is arranged, wherein the end element ( 23 ) at least one cooling chamber ( 61 ) of the housing ( 55 ) closes the front side. Cooling device ( 1 ) according to one of the preceding claims, characterized in that the housing ( 55 ) a side wall ( 57 ) which extends substantially parallel to the first direction (x), wherein the inlet ( 11 ) in the side wall ( 57 ) is arranged. Cooling device ( 1 ) according to one of the preceding claims, characterized in that the cooling device ( 1 ) at least one chicane element ( 41 ), which is arranged and arranged for influencing the flow of the cooling medium. Cooling device ( 1 ) according to one of the preceding claims, characterized in that the cooling device ( 1 ) a second flow guide ( 63 ) which in the hot region ( 5 ) is arranged and designed so that by the inlet ( 11 ) inflowing cooling medium from the second flow guide ( 63 ) is partially deflected in the first direction (x). Cooling device ( 1 ) according to one of the preceding claims, characterized in that the cooling device ( 1 ) is designed as exhaust gas recirculation cooler. Exhaust gas recirculation system ( 17 ) for an internal combustion engine ( 19 ), characterized by a cooling device ( 1 ) according to one of claims 1 to 12. Internal combustion engine ( 19 ), characterized by an exhaust gas recirculation system ( 17 ) according to claim 13.

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