EP2998686A2 - Heat exchanger - Google Patents

Abstract

The invention relates to a heat exchanger with a tube bundle with tubes as a heat transfer matrix, wherein the tubes are flowed through by a first fluid and define a first fluid channel and are flowed around by a second fluid and define such a second fluid channel, wherein the tube bundle is formed closed to the outside to terminate the second fluid channel or disposed in a housing to complete the second fluid channel, wherein the tubes are frontally open for inflow or outflow of the first fluid, wherein at least one end face of the tubes, a diffuser to the housing or with the Tube bundle is connected, wherein the diffuser has a collar as an overreach, which is pushed over the housing or over the tube bundle, wherein the diffuser has a wall thickness (d) and the length (L2) of the overmold area is greater than three or four times the material thickness ( d) of the D iffusors or the housing or the tube bundle.

Description

Technical area

The invention relates to a heat exchanger, in particular a charge air cooler or an exhaust gas cooler for a motor vehicle, in particular according to the preamble of claim 1.

State of the art

Exhaust coolers have the task of cooling hot exhaust gas from internal combustion engines, so that this cooled exhaust gas can be added to the intake air again. In this case, to increase the thermodynamic efficiency of an internal combustion engine, the cooling to a very low level. This principle is generally known as cooled exhaust gas recirculation and is used to achieve a reduction of pollutants, in particular nitrogen oxides, in the exhaust gas.

The temperature transition from the very hot, uncooled gas inlet region due to the hot gas at the gas inlet to the region of the cooler in communication with the coolant leads to high voltages because of the different thermal expansion due to the different temperatures occurring.

Furthermore, the gas flow in the inlet region usually takes place with relatively thick-walled diffusers in order to withstand the high pressures and temperatures, whereas the heat-transferring parts of the heat exchanger are designed as thin as possible for reasons of heat transfer and cost and weight reasons. Exactly in this area of the heat exchanger with the highest temperature gradients is the joint between the gas inlet diffuser and the heat exchanger matrix, where there is a thickness transition, which in addition leads to strong notch effects. This notch effect leads to critical thermal stresses at certain areas of the heat exchanger. In particular, the corners of the heat transfer matrix are often heavily loaded.

Usually, the heat transfer matrix is enclosed by a relatively thick-walled, coolant-carrying housing, with which the gas inlet diffuser is connected, usually by welding or soldering. This has the advantage that no such large thickness jump occurs and the notch effects are lower. However, if too high voltages occur, a thicker walled bottom or additional stiffening of the housing can be used through a sprue raceway.

The thermal deformations are prevented by relatively thick-walled, rigid components, such as through the coolant housing or the bottom of the susceptible, thin-walled heat exchanger tubes. This leads to a high component weight and high costs.

Presentation of the invention, object, solution, advantages

It is the object of the invention to provide a heat exchanger which is improved over the prior art and exhibits a longer service life due to reduced thermal stresses.

This is achieved with the features of claim 1.

An embodiment of the invention relates to a heat exchanger with a tube bundle, the tubes are either arranged in a housing and are flowed through by a first fluid and define a first fluid channel and are flowed around by a second fluid and thus define a second fluid channel, or its tubular elements alternately are stacked and thus form tubes having a first fluid channel and a second fluid channel, wherein the first fluid channel is frontally open for inflow or outflow of the first fluid, wherein at least one end face of the first fluid channel, a diffuser connected to the housing or with the tube bundle is, wherein the diffuser has a collar as an overreach, which is pushed over the housing or over the tube bundle, wherein the diffuser has a wall thickness as a material thickness and the length of the overmold area is greater than three or four times the material thickness d it diffuser or housing or tube bundle.

It is advantageous if the diffuser has a wall thickness as a material thickness and the length of the overmold area is greater than 5 to 20 times the material thickness (d) of the diffuser or the housing or the tube bundle.

This is also achieved with the features of claim 3.

An embodiment of the invention relates to a heat exchanger with a tube bundle, the tubes arranged either in a housing and are flowed through by a first fluid and define such a first fluid channel and are flowed around by a second fluid and thus define a second fluid channel, or its tubular elements are stacked alternately, forming tubes with a first fluid channel and a second fluid channel, wherein the first Fluid channel is formed open at the end face for inflow or outflow of the first fluid, wherein at least one end face of the first fluid channel, a diffuser is connected to the housing or with the tube bundle, wherein the diffuser has a collar as an overreach, which via the housing or via the Tube bundle is pushed, wherein the collar of the over-insertion in the region of at least one corner has a recess, in particular a slot.

This is also achieved with the features of claim 4.

An embodiment of the invention relates to a heat exchanger with a tube bundle, the tubes are either arranged in a housing and are flowed through by a first fluid and define a first fluid channel and are flowed around by a second fluid and thus define a second fluid channel, or its tubular elements alternately are stacked and thus form tubes having a first fluid channel and a second fluid channel, wherein the first fluid channel is frontally open for inflow or outflow of the first fluid, wherein at least one end face of the first fluid channel, a diffuser connected to the housing or with the tube bundle is, wherein the diffuser has a collar as an over-insertion area, which is pushed over the housing or over the tube bundle, wherein the collar of the over-insertion region in the region of at least one corner has a bulge.

It is advantageous if the Überstecklänge in the region of a corner is greater than between two corners.

This is also achieved with the features of claim 6.

An embodiment of the invention relates to a heat exchanger with a tube bundle, the tubes are either arranged in a housing and are flowed through by a first fluid and define a first fluid channel and are flowed around by a second fluid and thus define a second fluid channel, or its tubular elements alternately are stacked and thus form tubes having a first fluid channel and a second fluid channel, wherein the first fluid channel is frontally open for inflow or outflow of the first fluid, wherein at least one end face of the first fluid channel, a diffuser connected to the housing or with the tube bundle is, wherein the diffuser has a collar as an overreach, which is slid over the housing or over the tube bundle, further wherein a connection piece is provided with a flange, wherein the flange is connected to the housing or with the tube bundle, the Flansc h of the connecting piece is connected to the overreach area of the diffuser in shock.

It is advantageous if a collar is pushed onto the shock, which is also connected to the over-insertion area and the collar.

This is also achieved with the features of claim 8.

An embodiment of the invention relates to a heat exchanger with a tube bundle, the tubes are either arranged in a housing and are flowed through by a first fluid and define a first fluid channel and are flowed around by a second fluid and thus define a second fluid channel, or its tubular elements alternately Are stacked and thus form tubes having a first fluid channel and a second fluid channel, wherein the first fluid channel is formed open at the end for inflow or outflow of the first fluid, wherein at least one Front end of the first fluid channel, a diffuser is connected to the housing or with the tube bundle, wherein the diffuser has a collar as an overreach, which is pushed over the housing or over the tube bundle, wherein further a connection piece is provided with a collar, wherein the collar of Connecting piece is connected to the housing or with the tube bundle, wherein the collar of the connecting piece is connected to the Übersteckbereich of the diffuser overlapping.

It is expedient if the collar engages over the Übersteckbereich or the Übersteckbereich engages over the collar.

This is also achieved with the features of claim 10.

An embodiment of the invention relates to a heat exchanger with a tube bundle, the tubes are either arranged in a housing and are flowed through by a first fluid and define a first fluid channel and are flowed around by a second fluid and thus define a second fluid channel, or its tubular elements alternately are stacked and thus form tubes with a first fluid channel and a second fluid channel, wherein the first fluid channel is frontally open for inflow or outflow of the first fluid, wherein at least one end face of the first fluid channel, a diffuser connected to the housing or with the tube bundle is, wherein the diffuser has a collar as an overreach, which is pushed over the housing or over the tube bundle, wherein further a connection piece is provided with a collar, wherein the collar of the connection piece is connected to the housing or with the tube bundle t, wherein the collar with the connecting piece and the over-insertion region each having a projecting, flared flange, which are interconnected.

Further advantageous embodiments are described by the following description of the figures and by the subclaims.

Brief description of the drawings

Fig. 1

eine schematische Ansicht eines Diffusors nach dem Stand der Technik, wie er auf einen Endbereich eines Gehäuses eines Wärmetauschers aufgesetzt ist,

Fig. 2

eine schematische Ansicht eines Diffusors, wie er auf einen Endbereich eines Gehäuses eines Wärmetauschers gemäß eines Erfindungsgedankens aufgesetzt ist,

Fig. 3

eine dreidimensionale Ansicht eines Diffusors,

Fig. 4

eine Ansicht eines Diffusors und eines Anschlussstutzens, die an einem Gehäuse angeordnet sind,

Fig. 5

eine dreidimensionale Ansicht eines Diffusors,

Fig. 6

eine dreidimensionale Ansicht eines Diffusors,

Fig. 7

eine schematische Schnittansicht des Gehäuses mit Diffusor und Anschlussstutzen,

Fig. 8

eine schematische Schnittansicht des Gehäuses mit Diffusor und Anschlussstutzen,

Fig. 9

eine dreidimensionale Ansicht des Gehäuses mit Diffusor und Anschlussstutzen,

Fig. 10

eine schematische Schnittansicht des Gehäuses mit Diffusor und Anschlussstutzen,

Fig. 11

eine schematische Schnittansicht des Gehäuses mit Diffusor und Anschlussstutzen, und

Fig. 12

eine schematische Schnittansicht des Gehäuses mit Diffusor und Anschlussstutzen.

The invention will be explained in more detail on the basis of at least one embodiment with reference to the drawings. Show it:

Fig. 1

a schematic view of a diffuser according to the prior art, as it is placed on an end portion of a housing of a heat exchanger,

Fig. 2

a schematic view of a diffuser, as it is placed on an end portion of a housing of a heat exchanger according to an inventive idea,

Fig. 3

a three-dimensional view of a diffuser,

Fig. 4

a view of a diffuser and a connecting piece, which are arranged on a housing,

Fig. 5

a three-dimensional view of a diffuser,

Fig. 6

a three-dimensional view of a diffuser,

Fig. 7

a schematic sectional view of the housing with diffuser and connecting piece,

Fig. 8

a schematic sectional view of the housing with diffuser and connecting piece,

Fig. 9

a three-dimensional view of the housing with diffuser and connecting piece,

Fig. 10

a schematic sectional view of the housing with diffuser and connecting piece,

Fig. 11

a schematic sectional view of the housing with diffuser and connecting pieces, and

Fig. 12

a schematic sectional view of the housing with diffuser and connecting pieces.

Preferred embodiment of the invention

The FIG. 1 shows a view of a housing 2 of a heat exchanger 1 according to the prior art, which has a tube bundle 3 with tubes 4, wherein the tubes 4 of the tube bundle 3 are traversed by a first fluid and the tubes 4 are flowed around by a second fluid, so that a heat transfer from the first fluid to the second fluid can take place.

The tubes 4 of the tube bundle 3 are open at their end faces 5, so that the first fluid according to arrow 6 can flow into the open tube ends 7. For distributing the first fluid to the pipe ends 7, a diffuser 8 is provided, which is connected to the housing 2. In this case, the diffuser 8 engages over the housing 2 over the length L1. It has been found that due to the material thickness d of the diffuser and the rather low material thickness of the housing 2 or of the tubes 4, thermally induced stresses can arise due to the thermal expansion of the diffuser. This is indicated by the fact that the diffuser 8 is shown with a solid line in the hot state and with broken Line in cold condition. The diffuser 8 widens with an increase in temperature and leads to stresses in the end region of the housing 2 and in particular where the diffuser 8 ends on the housing 2.

The FIG. 2 shows a view of a housing 12 of a heat exchanger 11 according to the invention, which has a tube bundle 13, also called heat transfer matrix, with tubes 14, wherein the tubes 14 of the tube bundle 13 are flowed through by a first fluid and the tubes 14 are flowed around by a second fluid , so that a heat transfer from the first fluid to the second fluid can take place. The tubes 14 of the tube bundle 13 are open at their end faces 15, so that the first fluid according to arrow 16 can flow into the open tube ends 17. For distributing the first fluid to the pipe ends 17, a diffuser 18 is provided, which is connected to the housing 12. In this case, the diffuser 18 engages over the housing 12 over the length L2. It has been found that due to the material thickness d of the diffuser or of the housing 2 or of the tubes 14 and the invention according to greater length L2 thermal expansion of the diffuser 18 no unacceptably high thermally induced voltages.

Due to the shape of the diffuser can thus be achieved, that in particular in the connection region to the heat transfer matrix no critical thermally induced stresses arise.

For joining the diffuser 18 and the housing 12, a certain insertion or insertion depth L2 is required in order to ensure a workable weld or soldered seam. This soldering depth L2 is greater for solder joints than for welded joints and is preferably 3 to 4 times the material thickness of the thinner joining partner, ie the housing 12 or the tubes 14. This usually ensures that the soldered seam between the diffuser 18 and the housing 12 and the tubes 14 despite the lower strength of the solder achieves the same strength as the thinner joining partner.

According to the invention, the diffuser 18 is overlapped with the length L2 via the tube bundle 13 or via the heat transfer matrix, so that a secure connection is produced and the thermally induced voltages are reduced. The length L2 is considerably larger than it would have to be for the load capacity of the solder joint.

In the overlapped region of length L2, the diffuser 18 connects to the housing 12 or to the tube bundle 13 in a non-positive manner, for example by soldering. For this purpose, the diffuser 18 has an approximately cylindrical or approximately rectangular region 19, which is aligned in the longitudinal direction of the housing 2 or the tube bundle 13 and the housing 12 or the tube bundle 13 engages around the outside. The diffuser 18 is preferably plugged so far that in the overlapped region 19, the temperature almost reaches the temperature of the second fluid, ie the coolant temperature.

The FIG. 3 shows such a diffuser 18 in a three-dimensional representation. The contour of the diffuser 18 widens in a flowing course from the inlet 20 in the hot region to the region 19, wherein the region 19 is cylindrical or rectangular or cuboid, around the housing 12 or the tube bundle 13 or the heat transfer matrix according to their design to include. The stiffness of the rather thick-walled diffuser 18 prevents a strong constriction and associated strong notch effects. The Überstecklänge L2 of the diffuser 18 is advantageously greater than 4 times the material thickness d of the diffuser 18 in order to achieve sufficient cooling of the diffuser 18 in the overmold 19. For the heat conduction properties of stainless steel components in particular, an insertion length L2 of more than 5 times the Diffuser wall thickness d advantageous, in particular, the Überstecklänge L2 between 7 to 20 times the diffuser wall thickness d.

The production of long cylindrical areas 19 is not unlimited. Accordingly, simulations have shown that a large proportion of the effect is achieved by a diffuser with a long plug-in area, even if the corners 21 of the plug-in area 19 are slotted or wedge-shaped. Accordingly, the shows FIG. 3 slotted or wedge-shaped cuts 22 in the corner regions of the over-insertion region 19.

Alternatively, or in addition, it may be provided that the corners 21 of the over-insertion area 19 are widened outwards, as is the case FIG. 3 shows. The corner region 23 is widened radially outwards. Also, the stub length in the widened corner portion 23 is reduced from the middle portion of FIG.

By this widening in the corner region 23, a larger radius and thus better formability of the corner region 23 is achieved. In the corner region 23, this results in a pocket 24 at the end of the plug-over region 19 which is not soldered to the housing 12 or the tube bundle 13 or the heat exchanger matrix, but which leads to a circumferential support of the plug-in region 19 of the diffuser 18, which causes the constriction of the Diffuser end 25 counteracts. When using castings as a diffuser 18, these flared areas 24 of larger radius may also remain unworked to reduce manufacturing costs.

The over-insertion region 19 of the diffuser 18 can also be designed slotted in a sawtooth pattern or with recesses for other components.

Also, the over-insertion region 18 need not be formed circumferentially around the housing 12 or the tube bundle 13 or the heat transfer matrix completely encompassing it may be sufficient if only the most critical failure areas are encompassed, such as the corners of the heat transfer matrix or areas with special shaping, for example for coolant guidance such as wells or domes in panes or pipes or coolant inlets or outlets etc.

The FIG. 4 shows a diffuser 18 according to FIG. 3 , which engages over the housing 12 and the tube bundle 13 with its over-insertion region 19. In this case, a connecting piece 30 is further provided with a circumferential collar 31, wherein the circumferential collar 31 rests against the housing 12 and to the tube bundle 13. The collar 31 is partially pushed on one side 32 under the widened region 24 in order to be able to rest in a sealing manner on the housing 12 or on the tube bundle 13. The connecting piece 30 serves to supply or discharge of the second fluid according to arrow 33, wherein the diffuser 18 of the supply or discharge of the first fluid according to arrow 16 is used.

The FIGS. 5 and 6 show diffusers 40 and 50, which according to the diffuser 18 of FIG. 3 are formed, wherein instead of the slot 22 at the corner portions 41, 51 widenings 42, 52 are provided. In this case, the Überstecklänge L2 in the embodiment of FIG. 5 over the circumference of the overmold portion 43 is substantially constant. In the embodiment of FIG. 6 is the Überstecklänge L2 over the circumference of the overreach 53 is not constant. Rather, the Überstecklänge L2 between the corner regions 51 is less than at the corner regions 51 itself.

Alternatively, instead of the extended over-insertion region 19 of the diffuser 18, a two-part embodiment may be provided, in which a sleeve can be pushed over the housing or the heat transfer matrix, the wall thickness of the sleeve being at least 30%, advantageously more than 50%, of the diffuser wall thickness d should and for the Überstecklänge the same lengths should be provided, as for the one-piece diffuser 18th

As a result, in the case of heat exchangers with a housing or even without a housing, a diffuser is connected either to the housing or directly to the heat exchanger matrix, whereby the thermally induced voltages can be kept low. As a result, the thermal resistance can be significantly increased. In designs without a housing, the diffuser wall thickness is usually a multiple of the disk or tube wall thickness of the heat exchanger matrix. An inventively large Übersteckbereich the diffuser 18 has resulted in a multiplication of the life of the heat exchanger.

The FIGS. 7 to 12 show different variants, such as a heat exchanger can be formed with a housing or without housing but with a tube bundle with a diffuser and a connecting piece with circumferential collar, so that the collar can be sealingly attached to the housing or on the tube bundle. In this case, the diffuser is preferably soldered to each other with a connecting piece forming a fluid box. This results in a rigid composite with high wall thickness and thus good heat conduction, whereby the temperature jumps are greatly mitigated. It adjusts accordingly a flowing geometry and the stresses on the components can be reduced so that the thermal strength can be increased several times.

According to the invention, the diffuser with the connecting piece forming a fluid box has a joining surface in the region of the collar which is non-positively connected by soldering or welding.

In the simplest case, the two components diffuser and collar of the connection piece can be butted together, so that a joining surface the width of the material thickness of the thinner component, such as the diffuser or the connecting piece is formed. This is done by the FIG. 7 shown. The diffuser 70 engages with its over-insertion region 71 the housing 72 or the tube bundle or the heat transfer matrix 73, depending on whether a housing 72 is provided. In this case, the connecting piece 74 is arranged and fastened with its collar 75 on the housing 72 or on the tube bundle 73. The collar 75 abuts butt against the over-insertion region 71 of the diffuser 70. The connection takes place via the solder seam 76. In this way, a considerable improvement in the thermal resistance can already be achieved.

However, since jointed seams, in particular, solder seams with nickel-based solders in stainless steel coolers often have a considerably lower strength than the base materials, in the case of blunt joining the solder seam 76 as a joining seam 76 still represents an improvement worthy of improvement. In addition, blunt soldering does not allow for tolerance compensation for dimensional variations of the individual parts or Position deviations in the construction of the cooler.

An enlarged joint seam can be achieved, for example, in that one of the joining partners is overlapped with the other, preferably the joint seam is almost parallel to the pressing-on direction of the diffuser. Thus, the width of the joint gap can be increased, in particular to a width of more than one material thickness of the thinner joining partner. In addition, a tolerance compensation is also made possible.

The FIGS. 8 and 9 show an embodiment in which the collar of the connection piece is pushed under the diffuser. The diffuser 80 engages with its over-insertion region 81 the housing 82 or the tube bundle or the heat transfer matrix 83, depending on whether a housing 82 is provided. In this case, the connecting piece 84 is arranged and fastened with its collar 85 on the housing 82 or on the tube bundle 83.

The collar 85 is pushed under a bulge 86 of the over-insertion region 81 of the diffuser 80. The connection takes place via the soldering seam 87, which is arranged and enlarged substantially parallel to the mounting direction of the diffuser 80. In this way, even a considerable improvement in the thermal resistance can be achieved.

The FIG. 10 shows an embodiment in which the collar of the connecting piece is pushed over the diffuser. The diffuser 90 engages with its plug-in region 91 the housing 92 or the tube bundle or the heat transfer matrix 93, depending on whether a housing 92 is provided. In this case, the connecting piece 94 is arranged and fastened with its collar 95 on the housing 92 or on the tube bundle 93.

The collar 95 engages over the Übersteckbereich 91 of the diffuser 90. The connection is made via the solder seam 96, which is arranged and enlarged substantially parallel to the mounting direction of the diffuser 90. In this way, as well as a significant improvement in the thermal resistance can be achieved.

The FIG. 11 shows a further embodiment in which the collar of the connecting piece is arranged in abutment with the Übersteckbereich of the diffuser, wherein over the shock a collar is pushed. The diffuser 100 engages with its over-insertion region 101 the housing 102 or the tube bundle or the heat transfer matrix 103, depending on whether a housing 102 is provided. In this case, the connecting piece 104 is arranged and fastened with its collar 105 on the housing 102 or on the tube bundle 103. The collar 105 is arranged next to the over-insertion region 101 of the diffuser 100 in abutment. Furthermore is pushed over the shock 106, a collar 107 which improves the connection, because the soldering seam is increased. The connection takes place via the soldering seam 108 which, in addition to the soldering seam in the joint 106, is arranged substantially parallel to the attachment direction of the diffuser 100. In this way, as well as a significant improvement in the thermal resistance can be achieved.

The FIG. 12 shows a further embodiment in which the collar of the connecting piece and the overmold portion 111 of the diffuser 110 are aufgetulptpf and each forming a radially oriented flange, which abut against each other. The diffuser 110 engages with its over-insertion region 111 the housing 112 or the tube bundle or the heat transfer matrix 113, depending on whether a housing 112 is provided. In this case, the connecting piece 114 is arranged and fastened with its collar 115 on the housing 112 or on the tube bundle 113.

The collar 115 and the plug-in region form flared flanges 116, 117, which protrude in the radial direction or perpendicular to the longitudinal direction of the housing 112 or the heat transfer matrix 113. The two flanges 116, 117 are soldered together, which increases the solder seam 118. In this way, as well as a significant improvement in the thermal resistance can be achieved.

Claims (16)

Heat exchanger with a tube bundle, the tubes are either arranged in a housing and are flowed through by a first fluid and define a first fluid channel and are flowed around by a second fluid and thus define a second fluid channel, or its tubular elements are alternately stacked and thus pipes with form a first fluid channel and a second fluid channel, wherein the first fluid channel is frontally open for inflow or outflow of the first fluid, wherein at least one end face of the first fluid channel, a diffuser is connected to the housing or with the tube bundle, wherein the diffuser a Having collar as an overreach, which is pushed over the housing or over the tube bundle, characterized in that the diffuser has a wall thickness (d) as the material thickness and the length (L2) of the overmold area is greater than three or four times the material thickness (d) of the Diffusers or of the housing or the tube bundle. Heat exchanger according to claim 1, characterized in that the diffuser has a wall thickness (d) as the material thickness and the length (L2) of the overmold area is greater than the 5 to 20 times the material thickness (d) of the diffuser or the housing or the tube bundle. Heat exchanger with a tube bundle, the tubes are either arranged in a housing and are flowed through by a first fluid and define a first fluid channel and are flowed around by a second fluid and thus define a second fluid channel, or its tubular elements are alternately stacked and thus pipes with a first fluid channel and a Forming the second fluid channel, wherein the first fluid channel is open at the front end for inflow or outflow of the first fluid, wherein at least one end face of the first fluid channel, a diffuser is connected to the housing or with the tube bundle, wherein the diffuser has a collar as an overreach area, which is pushed over the housing or over the tube bundle, characterized in that the collar of the overreach area in the region of at least one corner has a recess, in particular a slot. Heat exchanger with a tube bundle, the tubes are either arranged in a housing and are flowed through by a first fluid and define a first fluid channel and are flowed around by a second fluid and thus define a second fluid channel, or its tubular elements are alternately stacked and thus pipes with form a first fluid channel and a second fluid channel, wherein the first fluid channel is frontally open for inflow or outflow of the first fluid, wherein at least one end face of the first fluid channel, a diffuser is connected to the housing or with the tube bundle, wherein the diffuser a Collar has as an overreach, which is pushed over the housing or over the tube bundle, characterized in that the collar of the overreach in the region of at least one corner has a bulge. Heat exchanger according to one of the preceding claims, characterized in that the Überstecklänge (L2) is greater in the region of a corner than between two corners. Heat exchanger with a tube bundle, the tubes are either arranged in a housing and can be flowed through by a first fluid and thus define a first fluid channel and can be flowed around by a second fluid and define such a second fluid channel, or its tubular elements are alternately stacked and thus form tubes having a first fluid channel and a second fluid channel, wherein the first fluid channel is frontally open for inflow or outflow of the first fluid, wherein at least one end face of the first fluid channel, a diffuser is connected to the housing or with the tube bundle, wherein the diffuser has a collar as an overreach, which is pushed over the housing or over the tube bundle, wherein further a connection piece is provided with a flange, wherein the flange is connected to the housing or to the tube bundle, characterized in that the flange of the connecting piece is connected to the over-insertion region of the diffuser in abutment. Heat exchanger according to claim 6, characterized in that on the push a collar is pushed, which is also connected to the Übersteckbereich and the collar. Heat exchanger with a tube bundle, the tubes are either arranged in a housing and are flowed through by a first fluid and define a first fluid channel and are flowed around by a second fluid and thus define a second fluid channel, or its tubular elements are alternately stacked and thus pipes with form a first fluid channel and a second fluid channel, wherein the first fluid channel is frontally open for inflow or outflow of the first fluid, wherein at least one end face of the first fluid channel, a diffuser is connected to the housing or with the tube bundle, wherein the diffuser a Collar has as an overreach, which is pushed over the housing or over the tube bundle, wherein further a connection piece is provided with a collar, wherein the collar is connected to the housing or with the tube bundle, characterized characterized in that the collar of the connecting piece is connected in an overlapping manner with the region of the overflow of the diffuser. Heat exchanger according to claim 8, characterized in that the collar engages over the Übersteckbereich or the Übersteckbereich engages over the collar. Heat exchanger with a tube bundle, the tubes are either arranged in a housing and are flowed through by a first fluid and define a first fluid channel and are flowed around by a second fluid and thus define a second fluid channel, or its tubular elements are alternately stacked and thus pipes with form a first fluid channel and a second fluid channel, wherein the first fluid channel is frontally open for inflow or outflow of the first fluid, wherein at least one end face of the first fluid channel, a diffuser is connected to the housing or with the tube bundle, wherein the diffuser a Collar has as an overreach, which is pushed over the housing or over the tube bundle, further comprising a connecting piece is provided with a collar, wherein the collar is connected to the housing or with the tube bundle, characterized in that the collar of the connecting piece and Ü Bersteckbereich of the diffuser each have a protruding, bulged flange, which are interconnected. Heat exchanger according to one of the preceding claims, characterized in that a tube bundle of a plurality of stacked discs or disc pairs is formed, which alternately form between them first and second fluid channels. Heat exchanger according to claim 11, characterized in that the first or the second fluid channels formed open frontally are and the second or the first fluid channels are closed at the front. Heat exchanger according to one of the preceding claims 1 to 10, characterized in that a tube bundle of a plurality of tubes is formed, which are flowed through and form a first fluid channel and which are flowed around and form a second fluid channel. Heat exchanger according to one of the preceding claims, characterized in that the second fluid channel are closed to the outside by the shape of the tubes, in particular by longitudinal corrugations at the edges of the tubes or by a housing, and wherein the tubes end face by a step-like widening or constriction so are formed, that the first or second fluid channels are closed and takes place through the non-closed channels, the inflow or outflow of a fluid through the diffuser. Heat exchanger according to claim 14, characterized in that the fluid channels for the second fluid are closed by protuberances or longitudinal corrugations on the tube sides to the outside. Heat exchanger according to claim 15, characterized in that no housing comprising the fluid channels is provided to the end of the second fluid channel to the outside.

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