DE102004045021B4 - Heat exchanger for internal combustion engines - Google Patents

Abstract

A heat exchanger for internal combustion engines, comprising a first, elongated flow channel (1) for passing exhaust gases of the internal combustion engine, a second, adjacent to the first flow channel (1) arranged flow channel (2) for carrying out the exhaust gases, one of the second flow channel (2) A newspaper (4) for carrying a medium, which is a refrigerant, wherein heat energy between the exhaust gas of the first flow channel (1) and the medium of the conduit (4) is exchangeable, and wherein heat energy between the exhaust gas in the second flow channel (2) and the medium in the conduit is at least not substantially exchangeable, and a valve channel (6, 6 ', 6' ') with a stellar valve element (3, 9, 10), wherein by a position of the valve element (8, 9, 10 ) a distribution of the exhaust gases to the first flow channel (1) and the second flow channel (2) is adjustable, characterized in that the valve channel (6, 6 ', 6' ') is a vent ilkanalgehäuse (30), which is composed of a first housing part (31) and at least a second housing part (32).

Description

The invention relates to a heat exchanger for internal combustion engines according to the preamble of claims 1, 8, 22 and 26.

In the modern construction of motor vehicles with internal combustion engines heat exchangers are increasingly used, by means of which heat of the vehicle exhaust gases is released to a coolant. This may be desired for purposes of rapid heating of the coolant or for purposes of cooling the exhaust, for example, in conjunction with an exhaust gas recirculation system. In this case, in particular in connection with other components and units of modern motor vehicles problems with regard to the exhaust system as well as the installation space.

DE 102 03 003 A1 describes a heat exchanger for exhaust gases, in which a first and a second flow channel for exhaust gases are arranged in parallel in a common housing, wherein a flow channel upstream valve channel has the same flow direction as the flow channels, that is arranged linearly to the flow channels.

DE 100 25 877 A1 describes a heat exchanger for exhaust gases in several embodiments, in which each one of the flow channels upstream valve channel on the input side has a same flow direction as the flow channels, that is arranged linearly to the flow channels.

The publication FR 2 854 200 A1 discloses an exhaust system, wherein a bypass channel is arranged parallel to the heat exchanger. Through a three-way valve, the exhaust gas flow can be routed through the heat exchanger in one position and through the bypass channel in another position.

Furthermore, the document discloses DE 103 46 250 A1 an exhaust gas cooler with a bypass. Both the bypass and the exhaust gas cooler is assigned a common exhaust pipe. Via a first throttle body and a second throttle body, the exhaust gas flow rates for the bypass and the exhaust gas cooler are controllable and / or controllable. Both throttle bodies are arranged in the Abgaszuführleitung.

The publication DE 103 55 649 B4 discloses a longitudinally flowed exhaust gas cooler. The exhaust gas cooler has a heat transfer area, which can be acted upon via an exhaust gas supply pipe with an exhaust gas, which can be removed via an exhaust gas discharge pipe from the heat transfer area. In the heat transfer area while an isolated bypass channel is integrated. Furthermore, the heat transfer region has an actuating element which acts on the division of the exhaust gas flow into the bypass channel and the remaining heat transfer region. In particular, the inlet opening or the outlet opening can be closed or opened by the adjusting element.

The publication DE 699 12 335 T2 discloses an exhaust gas heat exchanger device having a main exhaust pipe and a branch pipe connected in parallel thereto. The branch line has a heat exchanger. The exhaust gas heat exchanger device further comprises movable means for closing the main pipe. In addition, the exhaust gas heat exchanger device has means for adjusting the flow cross section of the branch line.

It is the object of the invention to provide a heat exchanger mentioned above, which is particularly advantageous with regard to the exhaust system, in particular with regard to the arrangement of the exhaust-carrying channels and the exhaust gas flow to the channels.

This invention is achieved according to the invention for a heat exchanger mentioned above with the characterizing features of claim 1.

This advantageously ensures that the heat exchanger can be arranged flexibly even in a limited space, such as in the engine compartment of a motor vehicle. In addition, it is advantageous that the valve element is not in the same flow axis as the flow channels, as thus formed by the pulsating exhaust gas flow of internal combustion engines, speed-dependent standing waves affect less on the mechanics of the valve element. Similarly, longitudinal and transverse vibrations of the heat exchanger housing are reduced in the region of the valve channel, which is also favorable for the function and life of the valve mechanism.

In a preferred embodiment of a heat exchanger according to the invention in the flow direction of the exhaust gases, the valve channel is arranged in front of the flow channels and an inlet channel in front of the valve channel, wherein particularly preferably a flow axis of the inlet channel has a different direction than the flow axis of the valve channel and as the flow axis of the flow channels. As a result, a stepwise curvature of the exhaust system is made possible, so that an unhindered exhaust gas flow is ensured with a total of small construction. Particularly preferred is an angle between the flow axis of the Valve channel and the flow axis of the inlet channel greater than 30 degrees to achieve a sufficiently large deflection of the exhaust gas stream.

Also preferably, an angle between the flow axis of the valve channel and the flow axis of the flow channel is greater than 30 degrees, more preferably greater than 40 degrees. In this case, the angle between the flow channel and valve channel and valve channel and inlet channel can add in terms of the exhaust system to achieve a total of particularly a large deflection of the exhaust stream, without taking into account disadvantages associated with appreciable extent in purchasing. In particular, an unfavorable in terms of turbulence and flow resistance exhaust system, which forces a deflection of the exhaust gas flow of 90 degrees in the smallest space is effectively avoided.

In order to avoid the aforementioned disadvantages to a particular extent, an angle between the flow axis of the valve channel and the flow axis of the flow channel is particularly preferably less than 60 degrees. This does not preclude the aforementioned two-stage diversion of the exhaust flow to total angles of up to about 90 degrees.

In a preferred embodiment of the invention, an average flow length of one of the flow channels is at least a factor of two, more preferably a factor of 2.5, greater than an average flow length of the valve channel. In this case, flow length is understood to be the mean path length of the exhaust gases, that is to say the path along an axis of symmetry of an exhaust gas duct. On the basis of the predetermined by the predetermined heat exchanger capacity dimensioning of the flow channels thereby a particularly space-saving design of a heat exchanger according to the invention is achieved.

Further preferably, the valve element has exactly one adjustable flap element, so that only a small number of components is required. With regard to a correspondingly simple and effective mechanism of the valve element, the flap element is preferably accommodated on a rotatable shaft which can be driven.

Particularly preferably, the valve channel has a dividing wall adjoining the flap element, the valve channel being divided by the dividing wall at least in sections into two valve channel halves. This allows both a simple design and a low-swirl exhaust system.

In a preferred embodiment of the invention, the second flow channel is arranged substantially parallel to the first flow channel, and particularly preferably the first flow channel and the second flow channel are accommodated in a common housing. As a result, a compact construction of the heat exchanger is favored in each case.

The object of the invention we also solved with the characterizing features of claim 15. By the plant of the valve element on the molding, it is advantageously possible that one of the flow channels is particularly well sealed against the flow of exhaust gases. In addition, premature wear of material in the area of contact between valve element and valve channel can be avoided in a simple manner.

Advantageously, the valve channel in this case has a circular cross section, and the shaping can be formed by deformation of a wall of the valve channel, in particular by embossing. As a result, the molding is simple and inexpensive to produce.

The object of the invention is further achieved by the characterizing features of claim 26. Due to the double wall of the second flow channel, a particularly good insulation of the exhaust gas flowing through this channel is made possible against a heat exchange.

Advantageously, the second flow channel in this case comprises an inner tube, which is accommodated in a housing, wherein an outer surface of the inner tube is spaced from the housing. This makes it possible that the heat exchanger can be kept small overall construction, in particular, a further combination of the housing with the first flow channel to a unit is advantageous.

The spacing of the housing to the inner tube can be advantageously fixed by means of distance means. These may comprise a plurality of nubs arranged on the outer surface of the inner tube, whereby a double wall of the second flow channel with good thermal insulation can be realized by simple means.

Furthermore, it is advantageously provided that the inner tube is connected directly to a guide plate, wherein the guide plate is arranged in the valve channel. In this case, the valve element is particularly advantageously arranged movably on the guide plate, and the valve channel is connected directly to the housing. This results in a reliable and simple sequence in the manufacture of the heat exchanger according to the invention, by first guide plate, inner tube and housing aligned with each other and connected to each other. Then then the valve channel can be brought over the baffle, aligned with this and connected to the housing. The particular connection can be made by welding or brazing, with other types of fixing are not excluded.

Depending on requirements, the valve element of a device according to the invention can be rotatably mounted on the valve channel at a single bearing point. Alternatively, a bearing can be provided at two spaced bearings on the valve channel.

The object of the invention is also achieved with the characterizing features of claim 1. Due to the at least two-part design of the valve channel housing, it is advantageously possible to produce a complex shape of the valve channel in terms of an optimized exhaust system in a simple manner.

Preferably, it is provided that the valve element is received between the first and the second housing part, wherein it is particularly advantageous movably mounted on at least one of the housing halves. As a result, before easy installation of the heat exchanger even with complex shape of the parts allows and by appropriate control during assembly a functionally reliable storage of the valve element allows even with occurring dimensional tolerances of the components.

Advantageously, the housing parts are firmly connected to each other, in particular by means of welding. As a result, a high gas-tightness can be combined with a high temperature resistance. Alternatively, other temperature resistant connections such as brazing may be provided. Also, a connection of the housing parts by means of screwing or riveting or crimping is possible, with regard to the gas tightness depending on the requirement, if necessary, additional sealing means are provided.

In the interest of cost-effective production, at least one of the housing parts is preferably designed as a formed part, in particular a deep-drawn part. This also advantageously allows the use of materials whose manufacture is problematic via casting processes, such as stainless steel. It is understood that the two-part design of the valve channel does not contradict any of the aforementioned features of the invention, so that each of the features mentioned can be combined with the two-part design of the valve channel. In particular, the above-mentioned formations for surface contact of the valve element may be formed on the housing parts of the valve channel. In particular when the housing parts are designed as formed parts, these formations of the valve channel wall can advantageously already be formed by way of the forming process.

Further features and advantages of the invention will become apparent from the following embodiment and from the dependent claims.

Hereinafter, three preferred embodiments of a heat exchanger according to the invention will be described and explained in more detail with reference to the accompanying drawings.

1 shows a plan view of a first embodiment of a heat exchanger according to the invention from above.

2 shows the heat exchanger according to 1 turned by 90 degrees.

3 shows the heat exchanger according to 2 turned by 90 degrees.

4 shows a frontal plan view of the heat exchanger according to 1

5 shows a schematic sectional view through the valve channel of the heat exchanger in the orientation according to 2 ,

6 shows a cutaway spatial view of a section of the heat exchanger 1 ,

7 shows a spatial representation of a second embodiment of a heat exchanger according to the invention.

8th shows a detailed view of the heat exchanger 7 , wherein the interior of the valve channel is shown.

9 shows a spatial view of the valve element of the heat exchanger 7 and 8th ,

10 shows a three-dimensional view of a third embodiment of a heat exchanger according to the invention, wherein internal components of the heat exchanger are partially shown.

11 shows a schematic plan view from above of a detail of the heat exchanger 10 ,

12 shows a schematic plan view of the detail of 11 of the page.

13 shows a schematic plan view of the detail of 11 from the front.

14 shows a schematic plan view of an inner tube of the heat exchanger 10 to 8th ,

15 shows a spatial view of a detail of a heat exchanger according to the invention.

16 shows a spatial view of a modification of a valve channel of the second embodiment of a heat exchanger according to 7 to 9 ,

17 shows the valve channel 16 from another spatial perspective.

18 shows the valve channel 16 from another spatial perspective.

The heat exchanger according to the invention according to the first embodiment comprises a first flow channel 1 and a second flow channel 2 , In this case, the first flow channel 1 is formed as a majority of parallel individual channels (see 6 ). 6 shows that the two flow channels 1 . 2 arranged parallel to each other and in the same housing 3 are housed.

A line 4 for guiding a liquid coolant is also in the housing 3 guided and occurs at an inlet-side connection 4a and an outlet side port 4b each out of the case 3 out. The administration 4 is inside the case 3 only with the first flow channel 1 in substantial thermal contact, so that a relevant heat exchange between the exhaust gas and the coolant takes place only when the first flow channel 1 flows through the exhaust gas.

The heat exchanger has in the flow direction of the exhaust gases at the end an outlet channel 5 in the present case with regard to the exhaust gas flow parallel to the flow channels 1 . 2 is aligned. For special requirements, however, it may be preferred that the outlet channel 5 angular to the flow channels 1 . 2 runs.

In the flow direction in front of the flow channels 1 . 2 is a valve channel 6 arranged with the housing 3 is welded. The valve channel 6 is has a circular cross-section and is at an angle W1 of about 42 ° with respect to the flow channels 1 . 2 on the housing 3 appropriate. This angle W1 exists between an input-side flow axis SV and respective flow axes SK1, SK2 of the first flow channel 1 and second flow channel 2 (please refer 2 ).

In the flow direction S in front of the valve channel 6 is an inlet channel 7 welded, the input side via a flange 7a can be connected to the further exhaust pipe. An inlet-side flow axis SE of the inlet channel encloses an angle W2 of 35 ° with the input-side flow axis SV of the valve channel. The angles W1 and W2 lie in a plane such that the flow axes SE of the inlet channel and the flow axes SK1, SK2 of the flow channels 1 . 2 total angle 77 °. Alternatively, however, the angles can also lie in different planes and deviate from the present values, in order to make it possible to adapt to any given exhaust gas routing. In the valve channel 6 is designed as a drivable movable flap valve element 8th recorded (see 5 ). The flap 8th is fixed with a rotatable shaft 9 connected, which extends along an end edge of the flap 8th and vertically through the valve channel 6 extends. In addition, a fixed baffle 10 provided in the valve passage, which serves as a continuation of the valve flap. conditioned by the baffle 10 is an outlet-side end portion of the valve channel in a first valve channel half 6a and a second valve channel half 6b divided, each of the valve channel halves 6a . 6b each with one of the flow channels 1 . 2 are connected. Through the baffle 10 , the flap 8th and the wave 9 Therefore, a total of a valve element is formed, through which the exhaust gas flow can be selectively directed into at least two different channels.

The flap 8th is at her of the wave 9 bent or elliptically shaped to form a sealing fit to the wall of the circular cross-section valve channel 6 to reach. Preferably, the wall of the valve channel in the area of the system of the valve flap have a corresponding processing.

The flap 8th is about a drive 11 the wave 9 movable, the drive 11 in this case, a vacuum box 12 comprising, through which a push rod 13 is movable. The push rod 14 is end with one on the shaft 9 fixed pivot 13 connected via a ball joint. This results in a push or pull movement of the push rod 14 to a rotation of the shaft 9 and thus to an adjustment of the flap 8th , Depending on the position of the flap then exhaust gas can not, at any proportion or completely by the heat exchange serving first flow channel 1 be directed.

The dimensioning of the heat exchanger is advantageously designed so that it is a total of small construction, without hindering the exhaust gas flow. Mean flow lengths of the two flow channels 1 . 2 are equal and correspond to the geometric length of the two channels. An average flow length of the valve channel 6 is about the geometric length of a center line of the valve channel 6 , In the present case, the mean flow length of a flow channel 1 . 2 approximately 2.7 times larger than the mean flow length of the valve channel 6 , Thus, while retaining the advantages of the invention, the vast majority of the overall length of the heat exchanger for the actual heat exchange available.

The heat exchanger according to the second embodiment ( 7 to 9 ) has, as in the first embodiment, a valve channel 6 on, opposite the flow channels 1 . 2 is arranged angularly. The valve element 15 includes a baffle 10 , on which one on a wave 9 recorded valve flap 8th is arranged.

The valve channel 6 comprises a section of substantially circular cross-section. Formations are provided in the wall of this section, on which an edge area 8a the flap 8th flat against, when the flap is in an end position. The attachment to the first formation 16 is the passage of the exhaust gas flow through the second flow channel 2 and the attachment to the molding 17 the passage through the first flow channel 1 assigned. 8th shows the passage through the second flow channel 2 ,

The formations 16 . 17 are each by pressing a correspondingly shaped punch in the wall of the valve channel 6 made so that they are visible from the outside. Due to the flat contact of the flap 8th at the formations 16 . 17 the seal of the flap is improved and a vibrating striking of the flap against the wall of the valve channel 6 reduced.

The valve element 15 according to 9 a first depository 18 and a second, spaced storage location 19 on. The wave 9 is in each case with each of the bearing points on the valve channel 6 stored, wherein the first bearing is associated with a breakthrough of the valve channel and the second bearing point 19 a bag-like receptacle on the valve channel 6 on the opposite side of the breakthrough. But it can also be provided that on the second storage location 19 is omitted, so that the shaft only in the region of a passage through the valve channel 6 at a single depository 18 rotatable on the valve channel 6 is included.

The heat exchanger according to the third embodiment ( 10 to 14 ) has, in contrast to the previous embodiments, a valve channel 6 on, which is parallel to the flow channels 1 . 2 is aligned. The heat exchanger comprises a housing 3 in which a total of fifteen parallel tubes 1a are arranged, which together the first flow channel 1 form. The walls of the tubes 1a are directly flowed around by the coolant, which flows through the housing 3 flows, the second flow channel 2 is also in the housing 3 added. The flow channel 2 includes an inner wall 3a , what a 11 and 13 is shown as a dashed line and as a two-sided open, tube-like passage through the housing 3 is trained. Furthermore, the second flow channel comprises 2 an inner tube 20 which is inserted in the passage. An outer surface of the inner tube 20 comprises a number of spacing means 21 , which as protruding nubs on the outer surface of the inner tube 20 are formed. in the inserted state in the passage only touch the knobs 21 the inner wall 3a of the housing 3 (see in particular 13 ), so that the thermal contact between the coolant flow around the passage of the housing and the exhaust gas flowed through the inner tube 20 is very small. Overall, the arrangement described a double wall of the second flow channel 2 with a first wall (housing passage 3 ) and a second wall (inner tube 20 ) educated.

The inner tube 20 and the passage 3a of the housing have an elongated cross-section and close at their end faces in each case flush with each other.

The detailed representation according to 15 shows in contrast to 10 a valve channel with angled orientation, but corresponds with respect to the arrangement and fixing of housing 3 , Inner tube 20 and valve element 15 the third embodiment. The representation of 15 shows a preferred sequence of mounting and fixing the components: The baffle 10 includes an angled edge 10a with a cross section of the inner tube 20 adapted opening. First, the baffle 10 with a front side of the inner tube 20 welded around the edge of the opening. This unit will then enter the passageway 3a of the housing 3 pushed in, due to the pimples 21 regularly a good frictional retention of the inner tube is achieved. Subsequently, the inner tube and / or the guide plate 10 welded to the housing, where appropriate, a points is sufficient.

After that, the valve channel 6 over the baffle 10 pushed and possibly the valve flap 8th and the wave 9 assembled. After exact alignment of the valve channel 6 to the valve element 15 becomes the valve channel 6 welded to the housing with a circumferential around the front side of the housing weld.

A particularly advantageous in particular with respect to the modification of the inventive heat exchanger according to the second embodiment show 16 to 18 , Here, the reference to the second embodiment is merely exemplary and the modification may also be combined with each of the other embodiments.

The outer wall of the valve channel is not formed as a one-piece housing, but includes a valve channel housing 30 that consists of a first housing part 31 and a second housing part 32 is composable. The present two housing parts are formed substantially as mirror-symmetrical halves, wherein the Symmetriebene perpendicular through the shaft 9 of the valve element 9 . 10 . 11 runs. The mirror symmetry is not accurate because the wave 9 the first housing part 31 passes through and rotatable in the region of the passage on the first housing part 31 is stored. On the second housing part 32 is in the example shown no storage of the shaft 9 intended. Alternatively, the wave 9 but also in a corresponding recess of the second housing part 32 additionally stored. Each of the housing parts has a part of a respective shape already described in the second embodiment 16 . 17 for flat contact of the valve flap 8th on. In the drawings 16 to 18 is the sake of clarity, the valve flap 8th Not shown.

That in the 16 to 18 contrast illustrated baffle 10 is substantially perpendicular to said symmetry or sectional plane of the valve channel housing, in this case, the baffle 10 end tip formations 10a on, in the corresponding edge-side formations of the housing parts 31 . 32 engage and by means of which the baffle 10 between the assembled housing parts 31 . 32 is held. In addition to a merely clamping bracket can thereby an additional welding of baffle 10 and housing parts 31 . 32 be provided. It should be noted that the baffle 10 not with the wave 9 is firmly connected but extends only to their immediate vicinity or with a correspondingly accurate adjustment slidably rests against the shaft.

Each of the housing parts 31 . 32 has been made by forming by deep drawing from a corresponding blank. In the fully assembled state of the heat exchanger, the housing parts, which are particularly advantageously made of stainless steel, fixed together by welding, the installation of the heat exchanger is carried out in the region of the valve channel advantageously as follows:
First, the valve flap 8th with her wave 9 connected (usually by welding) and in the first housing part 31 rotatably inserted. The following are the housing parts 31 . 32 fixed to each other by means of welding. Depending on whether the baffle 10 clamped and / or secured by welding, its mounting and fixing can be done before or after welding of the housing parts or even before and in part afterwards.

After fixing the baffle 10 can when using the inner tube 20 of the third embodiment, first, the inner tube 20 with the baffle 10 be welded. A correspondingly advantageous shape of the baffle for this purpose 10 can be taken from the description of the third embodiment.

Finally, the so pre-assembled valve channel 6 '' with the housing 3 , possibly with insertion of the inner tube 20 , brought together and with the case 3 gas-tight welded.

In the case of the assembly process described above by way of example, the fact is taken into account that the exhaust gases initially enter in the region of the valve channel and therefore the valve channel in particular reaches particularly high temperatures. Therefore, the welding, optionally also Hartverlötung the items is the preferred means for connecting the Telle.

Depending on the requirements, the respective special features of the exemplary embodiments described are not limited to these, but can be combined freely with each other, wherein, if appropriate, by means of certain combinations, particularly advantageous heat exchangers can be formed. In particular, shaping, mounting and mounting of the inner tube 20 applicable to the first two embodiments, and the formations 16 . 17 of the valve channel for installation of the valve flap 8th are not limited to angular orientation valve channels.

LIST OF REFERENCE NUMBERS

1

first flow channel

1a

tube

2

second flow channel

3

casing

3a

4

management

4a

inlet side connection

4b

outlet side connection

5

outlet channel

6, 6 '

valve channel

6a

first valve channel half

6b

second valve channel half

7

Enlaßkanal

8th

flap

8a

Edge of the flap

9

wave

10

baffle

11

drive

12

Vacuum unit

13

pivot

14

pushrod

15

valve element

16

first formation

17

second formation

18

first depository

19

second depository

20

inner tube

21

Distance means, nubs

30

Valve channel housing

31

first housing part of the valve channel housing

32

second housing part of the valve channel housing

W1

Angle input valve channel to flow channel

W2

Angle Enlaßkanal to valve channel

S

flow direction

SK1

Flow axis first flow channel

SK2

Flow axis second flow channel

SV

inlet-side flow axis valve channel

S

inlet-side flow axis inlet channel

Claims (34)

Heat exchanger for internal combustion engines, comprising a first, elongated flow channel ( 1 ) for the passage of exhaust gases of the internal combustion engine, a second, to the first flow channel ( 1 ) adjacent flow channel ( 2 ) for carrying out the exhaust gases, one of the second flow channel ( 2 ) separate newspaper ( 4 ) for carrying out a medium, which is a coolant, wherein thermal energy between the exhaust gas of the first flow channel ( 1 ) and the medium of the line ( 4 ) is exchangeable, and wherein heat energy between the exhaust gas in the second flow channel ( 2 ) and the medium in the conduit at least not to a considerable extent interchangeable, and a valve channel ( 6 . 6 ' . 6 '' ) with a stellar valve element ( 3 . 9 . 10 ), wherein by a position of the valve element ( 8th . 9 . 10 ) a distribution of the exhaust gases on the first flow channel ( 1 ) and the second flow channel ( 2 ) is adjustable, characterized in that the valve channel ( 6 . 6 ' . 6 '' ) a valve channel housing ( 30 ) comprising a first housing part ( 31 ) and at least one second housing part ( 32 ) is composable. Heat exchanger according to claim 1, characterized in that the valve element ( 8th . 9 . 10 ) between the first housing part ( 31 ) and the second housing part ( 32 ) is recorded. Heat exchanger according to claim 1 or 2, characterized in that the valve element ( 8th . 9 . 10 ) is movably mounted on at least one of the two housing parts. Heat exchanger according to one of claims 1 to 3, characterized in that the housing parts ( 31 . 32 ) are firmly connected. Heat exchanger according to one of the preceding claims, characterized in that the housing parts ( 31 . 32 ) are connected to each other by welding. Heat exchanger according to one of claims 1 to 4, characterized in that at least one of the housing parts ( 31 . 32 ) is formed as a formed part. Heat exchanger according to one of the preceding claims, characterized in that at least one of the housing parts ( 31 . 32 ) is designed as a deep-drawn part. Heat exchanger according to one of the preceding claims, characterized in that an input-side flow axis (SV) of the valve channel ( 6 ) has a different direction than a flow axis (SK1) of the first flow channel ( 1 ). Heat exchanger according to claim 8, characterized in that in the flow direction of the exhaust gases of the valve channel ( 6 ) in front of the flow channels ( 1 . 2 ) and an inlet channel ( 7 ) in front of the valve channel ( 6 ) are arranged. Heat exchanger according to claim 9, characterized in that a flow axis (SE) of the inlet channel (SE) 7 ) has a different direction than the flow axis (SV) of the valve channel ( 6 ) and as the flow axes (SK1, SK2) of the flow channels ( 1 . 2 ). Heat exchanger according to claim 10, characterized in that an angle (W2) between the flow axis (SV) of the valve channel ( 6 ) and the flow axis (SE) of the inlet channel ( 7 ) is greater than 30 degrees. Heat exchanger according to one of the preceding claims, characterized in that an average flow length of one of the flow channels ( 1 . 2 ) is at least a factor of two greater than an average flow length of the valve channel ( 6 ). Heat exchanger according to one of the preceding claims, characterized in that an average flow length of one of the flow channels ( 1 . 2 ) is at least a factor of 2.5 greater than an average flow length of the valve channel ( 6 ). Heat exchanger according to one of the preceding claims, characterized in that an angle (W1) between the flow axis (SV) of the valve channel and the flow axis (SK1) of the first flow channel ( 1 ) is greater than 30 degrees. Heat exchanger according to one of the preceding claims, characterized in that an angle (W1) between the flow axis (SV) of the valve channel and the flow axis (SK1) of the first flow channel ( 1 ) is greater than 40 degrees. Heat exchanger according to one of the preceding claims, characterized in that an angle between the flow axis (SV) of the valve channel and the flow axis (SK1) of the first flow channel is less than 60 degrees. Heat exchanger according to one of the preceding claims, characterized in that the valve element ( 8th . 9 . 10 ) exactly one adjustable flap element ( 8th ) having. Heat exchanger according to claim 17, characterized in that the flap element ( 8th ) on a rotatable shaft ( 9 ) is recorded. Heat exchanger according to claim 17 or 18, characterized in that the valve channel ( 6 ) one to the flap element ( 8th ) subsequent partition wall ( 10 ), wherein the valve channel ( 6 ) through the partition wall ( 10 ) at least in sections in two valve channel halves ( 6a . 6b ) is shared. Heat exchanger according to one of the preceding claims, characterized in that the second flow channel ( 2 ) substantially parallel to the first flow channel ( 1 ) is arranged. Heat exchanger according to one of the preceding claims, characterized in that the first flow channel ( 1 ) and the second flow channel ( 2 ) in a common housing ( 3 ) are included. Heat exchanger according to one of the preceding claims, characterized in that the valve channel ( 6 ) a shaping ( 16 . 17 ), wherein the valve element ( 8th . 9 . 10 ) at least in an end position substantially flat at the formation ( 16 . 17 ) is present. Heat exchanger according to claim 22, characterized in that the valve channel ( 6 ) has a substantially circular cross-section. Heat exchanger according to one of the preceding claims, characterized in that the shaping ( 16 . 17 ) by deformation of a wall of the valve channel ( 6 ) can be formed. Heat exchanger according to one of the preceding claims, characterized in that the shaping ( 16 . 17 ) by pressing or embossing a wall of the valve channel ( 6 ) can be formed. Heat exchanger according to one of the preceding claims, characterized in that the second flow channel ( 2 ) a double wall ( 3a . 20 ) having. Heat exchanger according to claim 26, characterized in that the second flow channel ( 2 ) an inner tube ( 20 ), which in a housing ( 3 . 3a ), wherein an outer surface of the inner tube ( 20 ) to the housing ( 3 . 3a ) is spaced. Heat exchanger according to claim 27, characterized in that the inner tube ( 20 ) Spacing agent ( 21 ), by means of which the spacing of the inner tube ( 20 ) to the housing ( 3 ) is determinable. Heat exchanger according to claim 28, characterized in that the spacing means are a plurality of on the outer surface of the inner tube ( 20 ) arranged nubs ( 21 ). Heat exchanger according to one of the preceding claims, characterized in that the inner tube ( 20 ) with a baffle ( 10 ) is directly connected, wherein the baffle ( 10 ) in the valve channel ( 6 ) is arranged. Heat exchanger according to claim 30, characterized in that a valve flap ( 8th . 9 ) movable on the guide plate ( 10 ) is arranged. Heat exchanger according to one of the preceding claims, characterized in that the valve channel ( 6 ) with the housing ( 3 ) is directly connected. Heat exchanger according to one of the preceding claims, characterized in that the valve element ( 8th . 9 . 10 ) at only one depository ( 18 ) rotatable on the valve channel ( 6 ) is stored. Heat exchanger according to one of the preceding claims, characterized in that the valve element ( 8th . 9 . 10 ) at two spaced bearings ( 18 . 19 ) rotatable on the valve channel ( 6 ) is stored.

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