WO2006122675A1 - Cooling device for recycled exhaust gases - Google Patents

Abstract

The invention relates to a cooling device (1) for recycled exhaust gases of an internal combustion engine, especially in a motor vehicle. Said cooling device (1) comprises a heat exchanger (2) encompassing an exhaust gas path (6) and a coolant path (7) that is coupled thereto in a heat-transferring manner. The cooling device (1) further comprises an inlet diffuser (3) that connects an exhaust gas inlet (8) of the cooling device (1) to an inlet (9) of the exhaust gas path (6) and/or an outlet diffuser (4) which connects an outlet (12) of the exhaust gas path (6) to an exhaust gas outlet (13) of the cooling device. At least one of the diffusers (3, 4) is provided with a double wall (15) which is located in a section (10, 14) conducting the exhaust gas and in which at least one coolant duct (16) is embodied.

Description

 Cooling device for recirculated exhaust gases

The present invention relates to a cooling device for recirculated exhaust gases of an internal combustion engine, in particular in a motor vehicle, having the features of the preamble of claim 1.

From DE 102 47 837 Al a cooling device is known, which preferably serves for the cooling of exhaust gases. The known cooling device has a heat exchanger which contains an exhaust gas path and a coolant path coupled therewith in a heat-transmitting manner. Furthermore, the known cooling device has an inlet diffuser which connects an exhaust gas inlet of the cooling device to an inlet of the exhaust gas path, and an outlet diffuser which connects an outlet of the exhaust gas path to an exhaust gas outlet of the cooling device. Moreover, it is provided in the known cooling device to equip the inlet diffuser in a section leading the exhaust gas with a double wall, in which a coolant channel is formed. In the known cooling device, the inlet diffuser is also provided with an inlet port and an outlet port, wherein the inlet port and the outlet port are connected to the coolant passage of the inlet diffuser. The coolant channel of the inlet diffuser is thus completely decoupled from the coolant path of the heat exchanger. Further cooling devices are known from DE 103 12 788 A1 and from DE-PS 1 551 553.

The present invention is concerned with the problem of providing for a cooling device of the type mentioned an improved embodiment, which is characterized in particular by a compact design.

This problem is solved according to the invention by the subject matter of the independent claim. Advantageous embodiments are the subject of the dependent claims.

The invention is based on the general idea of fluidly connecting the coolant channel arranged in the diffuser to the coolant path of the heat exchanger. This results in an integrated coolant guide within the cooling device, whereby additional connections can be omitted. The cooling device thereby builds compact and can be realized comparatively inexpensive.

According to a particularly advantageous embodiment, the diffuser can be connected via an axial plug connection to the heat exchanger, which connects the at least one coolant channel tightly to the coolant path and which connects the gas-conducting section of the diffuser tightly with the exhaust gas path. Such a connector simplifies the installation of the cooling device. Furthermore, it is particularly easy to achieve an axial connection between the coolant channel and the coolant path. As a result, for example, a 90 ° deflection, which occurs in a conventional radial connection piece omitted, whereby the flow resistance of the cooling device is reduced. At the same time, the axial connection between the coolant channel and Coolant path by eliminating the 90 ° deflection to an earlier calming of the coolant flow, which increases the effective radiator length, so the cooling capacity. At the same time, this embodiment allows for a given cooling performance, the realization of the cooling device with a reduced space.

Other important features and advantages of the invention will become apparent from the dependent claims, from the drawings and from the associated figure description with reference to the drawings.

It is understood that the features mentioned above and those yet to be explained below can be used not only in the particular combination given, but also in other combinations or in isolation, without departing from the scope of the present invention.

Preferred embodiments of the invention are illustrated in the drawings and will be described in more detail in the following description, wherein like reference numerals refer to the same or similar or functionally identical components.

Show, in each case schematically,

1 is a greatly simplified schematic longitudinal section through a cooling device according to the invention,

2 shows a view as in FIG. 1 in the region of a diffuser, but in another embodiment, FIG. 3 is a greatly simplified cross-section through a diffuser according to section lines III in Fig. 1 and Fig. 2,

Fig. 4 is an enlarged view of a detail IV in the

Figs. 1 and 2, but in another embodiment.

According to FIG. 1, a cooling device 1 according to the invention comprises a heat exchanger 2, an inlet diffuser 3 and an outlet diffuser 4. The cooling device 1 is used for cooling recirculated exhaust gases of an internal combustion engine, which is arranged in particular in a motor vehicle. In the mounted state, the cooling device 1 is therefore installed in an only indicated here return power 5, which recirculates exhaust gases from an exhaust gas side of the internal combustion engine to a fresh air side of the internal combustion engine with active exhaust gas recirculation. To increase the mass flow, the recirculated exhaust gases are cooled by means of the cooling device 1.

The heat exchanger 2 includes an exhaust path 6 through which the exhaust gas to be cooled flows, and a coolant path 7 through which a coolant used for cooling the exhaust gas flows. Coolant path 7 and exhaust path 6 are coupled to each other to transmit heat. For example, the heat exchanger 2 is a plate heat exchanger that operates with plates stacked on top of each other.

The inlet diffuser 3 connects an exhaust gas inlet 8 of the cooling device 1 to an inlet 9 of the exhaust gas path 6. In this case, the inlet diffuser 3 contains a section 10 leading the exhaust gas, which extends in the direction of flow of the exhaust gases having widening cross-section through. The exhaust gas flow is symbolized by arrows 11.

The outlet diffuser 4 connects an outlet 12 of the exhaust gas path 6 to an exhaust gas outlet 13 of the cooling device 1. In this case, the outlet diffuser 4 also has an exhaust gas-carrying section 14 which has a flow-through cross-section which is smaller in the flow direction of the exhaust gas flow 11.

At least one of the diffusers 3, 4 has a double wall 15 in the region of the exhaust-carrying section 10, 14. In the exemplary embodiment shown here, both the inlet diffuser 3 and the outlet diffuser 4 have such a double wall 15.

At least one of the diffusers 3, 4 has at least one coolant channel 16 formed in the double wall 15 or formed by the double wall 15 itself. According to the invention, the respective coolant channel 16 is now connected to the coolant path 7. In this way, the coolant path 7 of the heat exchanger 2 is connected via the at least one coolant channel 16 of the at least one diffuser 3, 4 to an unspecified coolant circuit, which may be formed for example by a branch of an engine cooling circuit of the internal combustion engine.

In the embodiment shown in FIG. 1, both the inlet diffuser 3 and the outlet diffuser 4 are each provided with the double wall 15 and are each provided with at least one coolant channel 16. In the embodiment shown here, the at least one coolant channel 16 of the outlet diffuser 4 connects at least one coolant inlet 17 of the cooling device 1 to at least one inlet 18 of the cooling device 1 Coolant paths 7. At the same time, the at least one coolant channel 16 of the inlet diffuser 3 connects at least one outlet 19 of the coolant path 7 with at least one coolant outlet 20 of the cooling device 1. In this way, cooling of the recirculated exhaust gas flow 11 results in the countercurrent principle.

Alternatively, it is in principle also possible in another embodiment to cool the exhaust gas flow 11 in the DC principle. In the DC principle, the coolant inlet 17 is formed on the inlet diffuser 3, while the coolant outlet 20 is arranged on the outlet diffuser 4.

According to FIG. 2, in another embodiment of the cooling device 1 it can be provided that only one of the diffusers 3, 4 contains the at least one coolant channel 16 connected to the coolant path 7. In FIG. 2, the outlet diffuser 4 is shown by way of example for this purpose. Likewise, it is basically possible to equip only the inlet diffuser 3 with the at least one coolant channel 16 connected to the coolant path 7. In such an embodiment, the respective diffuser, in this case the outlet diffuser 4, has at least one coolant channel 16, which is connected to the coolant path 7 in each case. In this case, at least one of these coolant channels 16 is connected to the at least one coolant inlet 17 of the cooling device 1 and to the at least one inlet 18 of the coolant path 7. At the same time, at least one other of these coolant channels 16 is connected to the at least one outlet 19 of the coolant path 7 and also to the at least one coolant outlet 20 of the cooling device 1. In this embodiment, therefore, the coolant on the same side of the cooling device 1, here on the exhaust gas outlet side and discharged. For certain applications, this may offer parts. To realize this, are in the double wall

15 of the respective diffuser 3, 4 accordingly arranged a plurality of coolant channels 16, which are arranged distributed circumferentially.

According to FIG. 3, the respective diffuser 3, 4 for forming the double wall 15 has an inner wall 21 and an outer wall 22, which are connected to one another via at least one longitudinal web 23. As soon as more than one coolant channel

16 is to extend in the double wall 15, at least two such longitudinal webs 23 are required to separate adjacent coolant channels 16 from each other. In the example shown in Fig. 3, four such longitudinal webs 23 are provided, which are arranged distributed symmetrically. Accordingly, four coolant channels 16 are formed in the double wall 15, which are flowed through in parallel in an embodiment of FIG. 1 and in an embodiment of FIG. 2 are flowed through in anti-parallel.

The diffusers 3, 4 may also contain only one coolant channel 16 in other embodiments. The longitudinal webs 23 are depending on the manufacturability / manufacturing process necessary to ensure the stability of the diffuser 3, 4. However, they are not mandatory for the function of the diffuser 3, 4.

In the embodiment shown in FIG. 2, the coolant inlet 17 is formed by a sealed plug connection 24 which is formed on the double wall 15 of the respective diffuser 3, 4. Additionally or alternatively, according to the embodiment shown here, the coolant outlet 20 may be formed by a sealed plug connection 25 which is formed on the double wall 15 of the respective diffuser 3, 4. Such a sealed plug connection 24, 25 operates on the principle "plug &seal", which means that a sufficiently tight connection can be made with the insertion of a plug complementary to the respective plug connection 24, 25. It is clear that in principle the one shown in FIG Embodiment with an inlet plug-in connection 24 and / or with an outlet plug-in connection 25 on the respective diffuser 3, 4 may be provided.

As can be seen in FIGS. 1 and 2, but preferably in FIG. 4, the respective diffuser 3, 4 and the heat exchanger 2 are matched to one another in such a way that the respective diffuser 3, 4 has an end region 26 facing the heat exchanger 2, which has the Heat exchanger 2 radially overlaps externally in the axial direction. It is crucial that the at least one coolant channel 16 extends into this end region 26. In particular, this makes it possible to connect the coolant channel 16 axially to the coolant path 7. This means that both an end section 27 of the respective coolant channel 16 facing the coolant path 7 and an end section 28 of the coolant path 7 facing the respective coolant channel 16 are aligned axially and are aligned with one another. Expediently coolant path 7 and coolant channel 16 in the end portions 27, 28 have the same cross-sections in order to avoid a jump in cross-section at the transition between the coolant channel 16 and the coolant path 7.

Due to the axial connection between the coolant channel 16 and the coolant path 7, the pressure drop for the coolant flowing through the cooling device 1 can be reduced. At the same time, even after a relatively short run length, a calmed coolant flow is formed which effectively cools can and thus increases the cooling capacity and the effective radiator length.

The coupling between the respective diffuser 3, 4 and the heat exchanger 2 is preferably realized by means of an axial connector 29. This connector 29 connects to a coolant path 7 tightly with the at least one coolant channel 16 and connects to the other the exhaust path 6 tightly with the respective gas-conducting portion 10 and 14 of the respective diffuser 3, 4th

According to Fig. 4, the connector 29 in a preferred embodiment, an outer collar 30 and an outer sealing zone 31 have. The outer collar 30 is formed on the respective diffuser 3, 4, protrudes axially, extends annularly closed, preferably on a radially outer edge. The outer sealing zone 31 is dimensioned to complement and is formed on the heat exchanger 2 and also extends annularly. In the assembled state, the outer collar 30 engages over the outer sealing zone 31 in the axial direction. In the outer sealing zone 31, here an annular groove 32 is formed, in which a sealing element 33 is located, which may be, for example, an O-ring. When plugged in, the sealing element 33 seals the outer sealing zone 31 with respect to the outer collar 30. It is clear that the annular groove 32 can in principle also be formed on the outer collar 30. Likewise, a plurality of annular grooves 32 may be formed on the outer sealing zone 31 and / or on the outer collar 30. By the outer collar 30, the outer sealing zone 31 and the at least one sealing element 23, the connection between the coolant path 7 and the at least one coolant channel 16 is sealed to the outside. In the embodiment shown here, the connector 29 also has an inner collar 34 and an inner sealing zone 35. The inner collar 34 is formed on the heat exchanger 2, protrudes axially from this and extends annularly closed. The inner sealing zone 35 is designed to be complementary to the inner collar 34, is formed on the respective diffuser 3, 4 and likewise extends annularly. When inserted, the inner collar 34 engages over the inner sealing zone 35 in the axial direction. In the variant shown here, the inner collar 34 is provided with an annular groove 36 into which a sealing element 37, preferably an O-ring, is inserted. It is clear that additionally or alternatively, the inner sealing zone 35 can be equipped with such an annular groove 36 with inserted sealing element 37. Furthermore, a plurality of annular grooves 36 with inserted sealing elements 37 may be formed on the inner collar 34 and / or on the inner sealing zone 35. In the plug-in state, the sealing element 37 seals the inner collar 34 with respect to the inner sealing zone 35. In this way, the connection between the at least one coolant channel 16 and the coolant path 7 is sealed inwardly by the inner collar 34, the inner sealing zone 35 and the sealing element 37. At the same time seals the sealing element 37 between inner collar 34 and inner sealing zone 35, the connection between the exhaust path 6 and the gas-conducting portion 10, 14th

The respective coolant channel 16 is thus connected in the preferred embodiment shown here between the outer sealing zone 31 and the inner sealing zone 35 to the coolant path 7, whereby this port is sealed both outwardly and inwardly.

Instead of the connector described here (as shown in Fig. 4), the diffusers 3, 4 in another Embodiment also be firmly connected to a non-descript housing of the heat exchanger 2, for example, welded.

Claims

DaimlerChrysler AGPatent claims

1. Cooling device for recirculated exhaust gases of an internal combustion engine, in particular in a motor vehicle,

with a heat exchanger (2) which contains an exhaust gas path (6) and a coolant path (7) coupled with heat transfer,

- With a an exhaust inlet (8) of the cooling device

(1) inlet diffuser (3) connecting to an inlet (9) of the exhaust gas path (6) and / or an outlet diffuser (4) connecting an outlet (12) of the exhaust gas path (6) to an exhaust gas outlet (13) of the cooling device (1),

- Wherein at least one of the diffusers (3, 4) in a portion carrying the exhaust gas (10, 14) has a double wall

(15), in which at least one coolant channel

(16) is formed, characterized in that the at least one coolant channel (16) is connected to the coolant path (7).

2. Cooling device according to claim 1, characterized in that

- The diffuser (3, 4) in a heat exchanger (2) facing the end region (26) the heat exchanger (2) axially overlaps radially outside, and / or - The at least one coolant channel (16) is connected axially to the coolant path (7).

3. Cooling device according to claim 1 or 2, characterized in that the diffuser (3, 4) via an axial plug connection (29) to the heat exchanger (2) is connected, the at least one coolant channel (16) sealed to the coolant path ( 7) connects and the gas-conducting portion (10, 14) of the diffuser (3, 4) connects tightly with the exhaust path (6).

4. Cooling device according to claim 3, characterized in that

- The connector (29) has an on the diffuser (3, 4) formed, axially projecting annular outer collar (30) which engages over an on the heat exchanger (2) formed annular outer sealing zone (31) axially, and / or

- The outer collar (30) and / or the outer sealing zone (31) has at least one annular groove (32) in which a sealing element (33) is arranged, and / or

- The connector (29) has a on the heat exchanger (2) formed, axially projecting annular inner collar (34), the one on the diffuser (3, 4) formed, annular inner sealing zone (35) axially Ü- berreifen, and / or

- The inner collar (34) and / or the inner sealing zone (35) has at least one annular groove (36), in which a sealing element (37) is arranged, and / or

- The at least one coolant channel (16) between the outer sealing zone (31) and the inner sealing zone (35) to the coolant path (7) is connected.

5. Cooling device according to one of claims 1 to 4, characterized in that both inlet diffuser (3) and outlet diffuser (4) are each formed as a double-walled with the coolant (15) equipped diffuser.

6. Cooling device according to claim 5, characterized in that

- The at least one cooling channel (16) of the inlet diffuser

(3) connects at least one coolant inlet (17) of the cooling device (1) to at least one inlet (18) of the coolant path (7), while the at least one coolant channel (16) of the outlet diffuser (4) at least one outlet (19) of the coolant path ( 7) connects with at least one coolant outlet (20) of the cooling device (1), or

- The at least one coolant channel (16) of the inlet diffuser (3) at least one outlet (19) of the coolant path (7) with at least one coolant outlet

(20) of the cooling device (1) connects, while the at least one coolant channel (16) of the outlet diffuser

(4) connects at least one coolant inlet (17) of the cooling device (1) with at least one inlet (18) of the coolant path (7).

7. Cooling device according to one of claims 1 to 4, characterized in that

either the inlet diffuser (3) or the outlet diffuser (4) as a double wall leading to the coolant

(15) equipped diffuser is configured,

- The diffuser (3, 4) at least two coolant channels

(16),

- That at least one of the coolant channels (16) at least one coolant inlet (17) of the cooling device (1) connects to at least one inlet (18) of the coolant path (7),

- At least one other of the coolant channels (16) at least one outlet (19) of the coolant path (7) with at least one coolant outlet (20) of the cooling device (1) connects.

8. Cooling device according to one of claims 1 to 7, characterized in that the diffuser (3, 4) in the double wall (15) includes a plurality of coolant channels (16) which are arranged distributed circumferentially and in particular by longitudinal webs (23) are separated from each other ,

9. Cooling device according to one of claims 1 to 8, characterized in that

- The double wall (15) has an inner wall (21) and an outer wall (22),

- Inner wall (21) and outer wall (22) via at least one longitudinal web (23) are interconnected.

10. Cooling device according to one of claims 1 to 9, characterized in that

- A coolant inlet (17) of the cooling device (1) by a on the double wall (15) of the diffuser (3, 4) formed, sealed plug connection (24) is formed, and / or

- A coolant outlet (20) of the cooling device (1) by a on the double wall (15) of the diffuser (3, 4) formed, sealed plug connection (25) is formed.