WO2008128762A1 - Exhaust gas heat exchanger, exhaust gas heat exchanger system, internal combustion engine and method for treating exhaust gases of an internal combustion engine - Google Patents

Abstract

The invention relates to an exhaust gas recirculation line system (4), comprising an exhaust gas heat exchanger (10) arranged in said exhaust gas recirculation line system (4), a high-temperature heat exchanger (3) and a low-temperature heat exchanger (7), the high-temperature heat exchanger being disposed in a primary cooling circuit (5) and the low-temperature heat exchanger in a secondary cooling circuit (9). The invention is characterized in that the exhaust gas recirculation line system (4) is configured to adjustably guide the exhaust gas stream (1, 11) from an upstream location (13) and deliver it to a downstream location (15), past the high-temperature heat exchanger (3). The downstream location (15) is disposed upstream of the low-temperature heat exchanger (7) and downstream of the high-temperature heat exchanger and the exhaust gas recirculation line system (4) comprises a bypass (17) only to the high-temperature heat exchanger (3) and a regulating means for adjusting the guide of the exhaust gas stream (1, 11) through the high-temperature heat exchanger (3), a ventilator (47) being associated to the primary and/or secondary cooling circuit (5, 9).

Description

 BEHR GmbH & Co. KG Mauserstrasse 3, 70469 Stuttgart

Exhaust gas heat exchanger, exhaust gas heat exchanger system, internal combustion engine and method for treating exhaust gases of an internal combustion engine

The invention relates to an exhaust gas heat exchanger system for cooling exhaust gas in a recirculated exhaust gas stream from an internal combustion engine, comprising: an exhaust gas recirculation line system for routing an exhaust stream from an engine exhaust to an engine inlet, an exhaust gas heat exchanger disposed in the exhaust gas recirculation line system having a high temperature heat exchanger and a low temperature Heat exchanger, wherein the low-temperature heat exchanger is arranged downstream of the high-temperature heat exchanger, wherein the high-temperature heat exchanger is arranged in a primary cooling circuit for recooling the high-temperature heat exchanger, and the low-temperature heat exchanger is arranged in a secondary cooling circuit for recooling the low-temperature heat exchanger, and the exhaust gas recirculation conduit system for adjustably guiding the exhaust gas flow from an upstream location to a downstream location at the high temperature heat exchange r (3) over, is designed.

Furthermore, the invention relates to an internal combustion engine and a method and a use for treating exhaust gases of an internal combustion engine.

The exhaust gas recirculation (abbreviation: EGR), in particular the cooled exhaust gas recirculation is used in today's vehicles due to legal regulations in order to reduce the particulate matter and pollutant, in particular nitrogen oxide reduce emissions. As the requirements for exhaust gas purification become stricter, larger exhaust gas mass flows are required, which can only be controlled to a limited extent with the known EGR systems.

Known EGR systems are arranged on the high pressure side of the internal combustion engine, as described in US 6,244,256 B1. The known EGR system has an exhaust gas turbocharger for a diesel engine and an EGR line with an EGR valve, which is arranged between the engine and the exhaust gas turbine. The recirculated exhaust gas is preferably fed in two stages, i. cooled in two exhaust gas heat exchangers, which are each cooled by a separate refrigerant circuit and are designed as high-temperature and low-temperature exhaust gas cooler. The cooled, recirculated exhaust gas is combined with compressed and cooled charge air and fed to the intake manifold of the engine.

Exhaust gas heat exchangers, in particular exhaust gas coolers are known in various embodiments: DE 199 07 163 A1 of the applicant, a welded construction for an exhaust gas heat exchanger was known, which consists of a bundle of exhaust pipes, which are surrounded on its outer side te of coolant, which the cooling circuit of Internal combustion engine is removed.

Exhaust heat exchangers are often also equipped with a bypass duct for the exhaust gas, i. for the case that a cooling of the exhaust gas or - for heating purposes - a heating of the coolant is not required or not advantageous. DE 199 62 863 A1 and DE 600 24 390 T2 of the applicant and DE 102 03 003 A1 disclose such exhaust gas heat exchangers with an integrated bypass, wherein a bypass valve, preferably in the form of a bypass flap, is arranged in an inlet diffuser or in the outlet region of the exhaust gas heat exchanger , which acts as a switch for the exhaust gas flow and this passes either through the bypassed by coolant tube bundle or through the bypass channel.

Applicant's DE 600 24 390 T2 discloses a two-stage recirculated exhaust gas cooling system for use with a vehicle diesel engine Turbocharger and an exhaust gas recirculation system. The exhaust gas recirculation system has an exhaust gas recirculation valve which controls the flow rate of the recirculated exhaust gas, as well as exhaust pipes, a secondary exhaust gas cooler and a primary exhaust gas cooler. The exhaust gas coolers are heat exchangers which transfer heat from the exhaust gas to liquid coolant. It is known to control the amount of exhaust gas via an exhaust gas recirculation valve, which is recirculated and mixed with the charge air of a turbocharger.

Such an exhaust gas recirculation system proves to be effective and efficient, since the recirculation of cooled exhaust gas reduces the emission of pollutants.

From DE 102 03 003 A1 a single-stage, equipped with a single heat exchanger exhaust gas recirculation system is known in which the heating of the coolant circuit can be prevented by the exhaust gas flow is passed through a bypass channel, which is thermally insulated from the exhaust pipes and the coolant. For this purpose, an exhaust valve is provided, which is arranged either in the exhaust gas inlet or outlet region and is actuated via an actuator. The exhaust valve is also described in more detail and allows a simple and reliable switching of the exhaust gas flow on the one hand through the heat exchanger part and on the other hand through the bypass channel.

As known from EP 1 030 050 A1, the bypass duct for the exhaust gas heat exchanger may also be separate, i. be arranged outside of the heat exchanger. Incidentally, in this known EGR system, the EGR valve is in the return of the EGR line, i. arranged in the exhaust gas flow direction behind the exhaust gas cooler.

DE 198 41 927 A1 has disclosed a device for exhaust gas recirculation with a valve device into which a bypass channel with a bypass flap is integrated. The exhaust gas heat exchanger has a bundle of U-shaped exhaust pipes, which are cooled by a liquid coolant. From DE 197 50 588 A1 a device for exhaust gas recirculation has been known, in which an exhaust gas heat exchanger with an exhaust gas recirculation valve (EGR valve) is integrated into a structural unit. This makes it possible to carry out a simplified and therefore cheaper production, since it is possible to dispense with individual parts.

A disadvantage of the known EGR systems that they consist of a variety of items that are manufactured separately and mounted individually, which increases the cost. Moreover, in the known EGR systems of disadvantage that larger exhaust gas mass flows can not be returned, since the pressure difference - due to the arrangement of the EGR system on the high pressure side of the engine - between the exhaust and suction of the engine is not sufficient to larger mass flows to promote.

From the applicant's 04-B-230 an initially mentioned exhaust gas heat exchanger system is known in which the integration of a first and a second exhaust gas heat exchanger is provided to form a structural unit or a module. This concept envisages a bypass channel that bridges both exhaust gas heat exchangers in common.

Exhaust gas recirculation systems of the type mentioned above are also in need of improvement. In addition to improvement aspects such as reduced particle content or NO _x emissions, lower component temperatures or an increase in performance, it has been shown above all that the operating costs of today's commercial vehicles are mainly caused by fuel costs. The goal should therefore be beyond that to achieve a fuel economy reduction.

According to the prior art, heat sources or heat inputs are fixedly assigned to a heat exchanger, that is to say they are integrated in either the high-temperature or the low-temperature cooling circuit, which can be disadvantageous for a division of the heat input into the heat exchangers.

At this point, the invention begins, the object of which is an exhaust gas heat exchanger system, an internal combustion engine and a method and a Use for treating exhaust gases of an internal combustion engine, which allows a further reduced fuel consumption.

With regard to the exhaust gas heat exchanger system, the object is achieved by an exhaust gas heat exchanger system of the type mentioned in the present invention, the downstream point upstream of the low-temperature heat exchanger and downstream of the high-temperature heat exchanger is arranged and the exhaust gas recirculation line system bypass only to the high-temperature heat exchanger and a control means for Setting the leadership of the exhaust stream through the high-temperature heat exchanger and the primary and / or secondary cooling circuit is associated with a fan.

According to the invention, the downstream location is located upstream of the low temperature heat exchanger and downstream of the high temperature heat exchanger. In other words, the exhaust gas conducted past the high-temperature heat exchanger is combined in an advantageous manner directly between the high-temperature heat exchanger and the low-temperature heat exchanger with an exhaust system passing through the high-temperature heat exchanger and together fed to the low-temperature heat exchanger.

According to the invention, the exhaust gas passage has a bypass to the high-temperature heat exchanger and a control means for adjusting the guidance of the exhaust gas flow through the high-temperature heat exchanger. This makes it possible to switch on the high-temperature stage of the exhaust gas heat exchanger regulated.

Suitably, the high-temperature heat exchanger is arranged in a primary cooling circuit for recooling the high-temperature heat exchanger. Suitably, the low-temperature heat exchanger is arranged in a secondary cooling circuit for recooling the low-temperature heat exchanger. The invention is based on the consideration that, in the context of over the prior art 04-B-230 - the disclosure of which is hereby incorporated into this application - further developed two-stage components, heat both in a cooling circuit of a high-temperature heat exchanger and in a cooling circuit of a low-temperature heat exchanger can be discharged and thus an improved distribution of heat to the heat exchanger is possible. The invention has recognized that a more efficient utilization of the heat exchanger can thus be achieved, and thus a reduction in the connection of the fan associated with a cooling circuit.

In particular heavy commercial vehicles are equipped with a high performance cooling system. High-performance cooling systems generally have high-performance fan systems which have a great potential for reducing drive power, which can be used to reduce fuel consumption. Generally, with this concept according to the invention, a significant reduction in fuel consumption becomes possible.

The invention has recognized that a fuel consumption reduction via a reduced fan connection in an exhaust gas heat exchanger system can be achieved by optimizing a distribution of the heat inputs into a high-temperature heat exchanger and a low-temperature heat exchanger. The invention has recognized that the need for cooling air and thus the need for fan switching for the heat exchanger with the concept of the invention is minimized. This can lead to considerable fuel savings and thus operating cost reduction. In other words, the invention provides an exhaust gas heat exchanger system, which is designed in two stages and in which the high-temperature stage can be switched on regulated, so that a fan connection is at least reduced.

Advantageously, this achieves a practically operating point-dependent distribution of heat quantities to a high-temperature heat exchanger and / or low-temperature heat exchanger with a correspondingly reduced fan connection and fuel consumption. Accordingly, the concept of the invention to an internal combustion engine, in particular a preferably heavy commercial vehicle, and a method and a use of the type mentioned, in which - according to claim 13 and 14 - according to the invention, the exhaust gas flow adjustable from an upstream point to a downstream point, on High-temperature heat exchanger is passed.

Advantageous developments of the invention can be found in the dependent claims and specify in detail advantageous ways to realize the above-described concept within the scope of the task, as well as with regard to further advantages.

With regard to the exhaust gas heat exchanger, the low-temperature heat exchanger is advantageously arranged downstream downstream of the high-temperature heat exchanger. In other words, the heat exchangers are arranged directly one behind the other in series, preferably arranged in a common line section. As a result, a particularly compact design can be achieved.

Preferably, a controlled connection of the high-temperature heat exchanger depending on the heat inputs in the high-temperature heat exchanger and / or low-temperature heat exchanger can be controlled. Preferably, by means of the control means, the exhaust gas can be fed to the high-temperature heat exchanger or completely fed to the low-temperature heat exchanger or between the high-temperature heat exchanger and the low-temperature heat exchanger - depending on the heat input in the heat exchangers, in particular depending on the ratio of heat inputs in the heat exchangers and depending on the capacity of the same - divisible. This makes it possible to achieve optimized utilization of the heat exchangers for virtually every operating state and operating point-dependent.

An advantageous constructive embodiment provides that the control means at least in the region of the upstream body and / or the stromabwärten is arranged. It has been found that the control means is particularly advantageously formed in the form of a controlled valve, in particular a controlled three-way valve. Advantageously, additionally or alternatively, a control means in the form of a bypass flap may be provided, as described in the Applicant's document 04- B-230. Other or modified or combinations of such control means are also possible.

Preferably, the control means may be integrated in unit with the high-temperature and / or low-temperature heat exchanger.

In a particularly preferred embodiment of the invention, the bypass to the high-temperature heat exchanger is the only bypass. In other words, no bypass is provided for the low-temperature heat exchanger. It has been shown that in the context of this development can be dispensed with a bypass for the low-temperature heat exchanger, since the temperature level of the high-temperature heat exchanger associated cooling circuit is usually too high to achieve the desired target temperatures after the AGK.

It has been shown that, in order to achieve a particularly compact and space-saving design, the exhaust system and the high-temperature heat exchanger are arranged in a common housing. It has also proved to be particularly advantageous that an exhaust system and the high-temperature heat exchanger and the low-temperature heat exchanger are arranged in an assembly.

Further advantageous developments of the invention with regard to the heat exchanger system can be found in the further subclaims and specify in detail advantageous possibilities for realizing the above-described concept within the scope of the problem as well as with regard to further advantages.

Advantageously, a cooling circuit in each case has a corresponding radiator, namely a high-temperature radiator and a low-temperature radiator. peraturradiator, and a corresponding pump, namely according to a primary pump and a secondary pump.

The aforementioned radiators are regularly cooled by preferably a single common fan or a plurality of fans whose connection is advantageously reduced according to the concept of the invention. In a particularly preferred development of the invention, the exhaust gas recirculation system has a motor outlet side and / or a motor inlet side exhaust gas recirculation valve, which is arranged upstream of the high temperature heat exchanger or downstream of the low temperature heat exchanger. By means of an exhaust gas recirculation valve, it is possible to determine the proportion of the exhaust gas which is to be recirculated to the engine or which proportion of the exhaust gas is to be emitted to the environment as emission gas.

In a particularly preferred embodiment of the invention, the engine cooling is connected to a primary cooling circuit. The re-cooling of the high-temperature heat exchanger can thus be carried out in an advantageous manner in the same circuit as the engine cooling. The engine cooling may be arranged with a regulated valve and a pump in a feedback loop of the primary circuit.

In a further particularly preferred development of the invention, a charge air system is connected upstream of the engine intake at the exhaust gas recirculation line system. This has an air intake, which feeds a compressor via an air filter charge air and these via a charge air cooler and a corresponding supply port to the exhaust gas recirculation line system supplies. Other advantageous embodiments of a charge air system can be seen from 04-B-230 and can be connected to the exhaust gas recirculation line system according to the present concept in the context of preferred refinements.

In a particularly preferred manner, the charge air cooler is in parallel with the low-temperature heat exchanger in the secondary integrated cooling circuit. Advantageously, it can also be cooled via the low-temperature radiator.

Embodiments of the invention will now be described below with reference to the drawing. This is not necessarily to scale the embodiments, but the drawing, where appropriate for explanation, executed in a schematized and / or slightly distorted form. With regard to additions to the teachings directly recognizable from the drawing reference is made to the relevant prior art. It should be noted that various modifications and changes may be made in the form and detail of an embodiment without departing from the general idea of the invention. The features of the invention disclosed in the description, in the drawing and in the claims may be essential both individually and in any combination for the development of the invention. In addition, all combinations of at least two of the features disclosed in the description, the drawings and / or the claims fall within the scope of the invention. The general idea of the invention is not limited to the exact form or detail of the preferred embodiment shown and described below or limited to an article which would be limited in comparison to the subject matter claimed in the claims. For the given design ranges, values within the stated limits should also be disclosed as limit values and be arbitrarily usable and claimable.

In detail, the drawing shows in:

1 is a schematic representation of a two-stage exhaust gas heat exchanger with a bypass line to the high-temperature heat exchanger exhaust system and a controlled valve upstream of the high-temperature heat exchanger, in a particularly preferred embodiment of an exhaust gas heat exchanger system according to the concept of the invention;

2 shows a particularly preferred embodiment of an exhaust gas heat exchanger system with an exhaust gas heat exchanger according to FIG. 1.

1 shows an exhaust gas heat exchanger 10 for cooling exhaust gas in an exhaust gas stream 1, 11 from an internal combustion engine 2 shown in more detail in FIG. 2. The exhaust gas heat exchanger 10 has a high-temperature heat exchanger 3, which is heated by a high-temperature cooling system shown in more detail in FIG. cycle, ie a primary cooling circuit 5, is recooled via connections 5A, 5B. The exhaust gas heat exchanger 10 further has a low-temperature heat exchanger 7, which downstream of the high-temperature heat exchanger 3, ie in a fixed by the reference numeral 1, 11 downstream direction of the exhaust stream 1, 11 is arranged downstream of the high-temperature heat exchanger in series. The low-temperature heat exchanger 7 is recooled to a low-temperature cooling circuit, namely a secondary cooling circuit 9 shown in greater detail in FIG. 2, via connections 9A, 9B. The exhaust gas routing from an upstream point 13 to a downstream point 15 can be carried out according to the concept of the invention past the high-temperature heat exchanger 3. For this purpose, the embodiment shown in FIG. 1 provides a bypass 17 to the high-temperature heat exchanger 3 and a control means in the form of a controlled valve 19 at the upstream point 13. By means of the controlled valve 19, the exhaust gas stream 1, 11 complete the high-temperature heat exchanger. 3 or be completely fed to the low-temperature heat exchanger 7 by the exhaust gas is completely passed to the high-temperature heat exchanger 3 through the bypass line 23. In the former case, the regulated closes Valve 19 completely the bypass line 23. In the latter case, the controlled valve 19 closes completely leading to the high-temperature heat exchanger 3 exhaust pipe 21. As a further alternative, the exhaust gas between the high-temperature heat exchanger 3 and the low-temperature heat exchanger 7 can be divided, in a part of the exhaust gas is fed directly to the high-temperature heat exchanger 3 and the remaining part of the exhaust gas via the bypass 17 is fed directly to the low-temperature heat exchanger. The ratio of the exhaust gas flows through the exhaust gas line 21, on the one hand, and the bypass line 23, on the other hand, can be effected by a control, which is not shown in more detail and regulates the regulated valve 19. This control can use the heat inputs in the high-temperature heat exchanger 3 and / or the low-temperature heat exchanger 7 in an advantageous manner to determine a utilization of the heat exchangers 3, 7 and accordingly set the exhaust gas flows through the lines 21, 23 so that a load of the Heat exchanger 3, 7 is optimized in terms of their capacity.

FIG. 2 shows a schematic representation of an exhaust gas heat exchanger system 20 with the exhaust gas heat exchanger 10 shown schematically in FIG. 1. Corresponding reference symbols have been used for the same parts.

As explained above, the control of the exhaust gas heat exchanger system 20 by means of the valve 19, which feeds the exhaust gas mass flow either via the bypass line 23 directly to the low-temperature cooler 7 or Ü over the exhaust pipe 21 feeds directly to the high-temperature heat exchanger. Thus, one can regulate the heat input in the high-temperature heat exchanger 3 associated cooling circuit 5 on the one hand and the low-temperature heat exchanger associated cooling circuit 9 on the other. In other words, the exhaust heat can be taken out of the high-temperature cooling circuit or primary circuit 5 and fed completely to the low-temperature circuit or the secondary circuit 9 or a heat input can be divided between the two cooling circuits 5, 9 in order to make optimal use of their capacity , In the present case, the exhaust gas heat exchanger 10 is connected to a manifold 29A, 29B of the engine 2, which is shown schematically here with its cylinders 31, via an exhaust gas recirculation valve 25 on the engine exhaust side and an engine exhaust side further exhaust gas recirculation valve 27.

In the embodiment shown in FIG. 2, in the exhaust gas recirculation valve 25 arranged upstream of the high-temperature heat exchanger 3, a complete or partial exhaust gas flow 1, 11 is exhausted from the engine exhaust side manifold 29A via a turbo exchanger 30 having a first turbine Compressor 33 and designed as a compressor second compressor 35 as E- missionsgas 37 possible and - as required - together with charge air 39 traceable. The turbine serves as a drive for the compressor. Accordingly, a charge air system 40 is connected via the engine inlet side to the low-temperature heat exchanger 7 downstream downstream exhaust gas recirculation valve 27, which also has a charge air cooler 41. Cooled charge air 43 can be supplied via the exhaust gas recirculation valve 27 together with the exhaust gas to the engine intake-side manifold 29B of the engine 2.

The intercooler (CAC) 41 is connected to the secondary circuit 9 and insofar arranged parallel to the low-temperature heat exchanger 7 in the secondary cooling circuit 9. The secondary circuit 9 carries a coolant, which in the present case differs from the coolant of the primary circuit 5, and which in turn is recooled via a low-temperature radiator 45 with cooling air 49 sucked by a fan 47. The coolant - present at about 40 ⁰ C - is circulated by means of a pump 51 in the secondary cooling circuit 9 and, as described above, the terminals 9 A, 9 B of the low-temperature heat exchanger 7 is supplied.

Furthermore, in the embodiment shown in FIG. 2, a cooling element 55 having a cooling element 55 for the engine 2, the pump 57 for circulating the coolant in the primary cooling circuit 5 is connected in the primary cooling circuit 5 via a further regulated valve 53. is used. The coolant - in the present case at about 90 ^° C. - of the primary cooling circuit 5 is in turn recooled via a high-temperature radiator 59 by means of the cooling air 49 drawn in by the fan 47.

The invention is based on an exhaust gas heat exchanger system for cooling exhaust gas in a recirculated exhaust gas stream 1, 11 of an internal combustion engine 2, comprising: an exhaust gas recirculation line system 4 for guiding an exhaust gas stream 1, 11 from an engine outlet 26 to an engine inlet 28, one in the exhaust gas recirculation -Leitungssystem 4 arranged exhaust gas heat exchanger 10 with a high-temperature heat exchanger 3 and a low-temperature heat exchanger 7, wherein the low-temperature heat exchanger 7 is arranged downstream of the high-temperature heat exchanger 3, wherein the high-temperature heat exchanger 3 in a primary cooling circuit 5 for recooling the high temperature Heat exchanger 3 is arranged, and the low-temperature heat exchanger 7 is arranged in a secondary cooling circuit 9 for recooling the low-temperature heat exchanger 7, and the exhaust gas recirculation line system 4 for adjustably guiding the exhaust stream 1, 11 from an upstream point 3 to a downstream point 15, the high-temperature heat exchanger 3 over, is designed. In order to achieve an improved distribution of the heat inputs to the heat exchangers 3, 7 and thereby a fuel consumption reduction, the concept of the invention provides that the downstream point 15 is arranged upstream of the low-temperature heat exchanger 7 and downstream of the high-temperature heat exchanger 3 and the exhaust gas recirculation Line system 4 has a bypass 17 only to the high-temperature heat exchanger 3 and a control means for adjusting the guidance of the exhaust stream 1, 11 through the high-temperature heat exchanger 3 and the primary and / or secondary cooling circuit 5, 9, a fan 47 is assigned. The invention leads to an internal combustion engine 2, a method for treating exhaust gases of an internal combustion engine 2 and a use of the exhaust gas heat exchanger system 20th In another embodiment, the exhaust gas heat exchanger system has a low-temperature bypass or a combination of a high-temperature bypass and a low-temperature bypass.

Claims

P a n t a n s p r e c h e

An exhaust gas heat exchanger system (20) for cooling exhaust gas in a recirculated exhaust gas stream (1, 11) from an internal combustion engine (2), comprising: an exhaust gas recirculation line system (4) for routing an exhaust gas stream (1, 11) from an engine exhaust (26) to a An engine inlet (28) having an exhaust gas heat exchanger (10) disposed in the exhaust gas recirculation line system (4) with a high temperature heat exchanger (3) and a low temperature heat exchanger (7), the low temperature heat exchanger (7) downstream of the high temperature heat exchanger (7). 3), wherein the high-temperature heat exchanger (3) is arranged in a primary cooling circuit (5) for recooling the high-temperature heat exchanger (3), and the low-temperature heat exchanger (7) in a secondary cooling circuit (9) for recooling the low-temperature Heat exchanger (7) is arranged, and the exhaust gas recirculation line system (4) for adjustably guiding the exhaust gas flow

(1, 11) from an upstream location (13) to a downstream location (15) past the high-temperature heat exchanger (3),

characterized in that

the downstream point (15) is arranged upstream of the low-temperature heat exchanger (7) and downstream of the high-temperature heat exchanger (3) and the exhaust gas recirculation line system (4) has a bypass (17) only for high-temperature

Heat exchanger (3) and a control means for adjusting the tion of the exhaust stream (1, 11) through the high-temperature heat exchanger (3) and the primary and / or secondary cooling circuit (5, 9) is associated with a fan (47).

2. Exhaust gas heat exchanger system (2) according to claim 1, characterized in that the bypass (17) to the high-temperature heat exchanger (3) is the only bypass (17).

3. Exhaust gas heat exchanger system (20) according to claim 1 or 2, characterized in that the control means is arranged at least in the region of the upstream point (13) and / or the downstream point (15).

4. exhaust gas heat exchanger system (10) according to one of claims 1 to 3, characterized in that the control means in the form of a controlled valve (19) is formed.

5. Exhaust gas heat exchanger system (20) according to any one of claims 1 to 4, characterized in that by means of the control means, the exhaust gas (1) completely to the high-temperature heat exchanger (3) can be supplied, or completely the low-temperature heat exchanger (7) supplied o- between the high-temperature heat exchanger (3) and the low-temperature heat exchanger (7) can be divided.

6. exhaust gas heat exchanger system (20) according to one of claims 1 to 5, characterized in that the control means in dependence of the heat inputs in the high-temperature heat exchanger (3) and / or the low-temperature heat exchanger (7) is controllable.

7. exhaust gas heat exchanger system (10) according to one of claims 1 to 6, characterized in that the high-temperature heat exchanger (3) and the low-temperature heat exchanger (7) are arranged in a single assembly.

8. Exhaust gas heat exchanger system (20) according to any one of claims 1 to 9, characterized by a motor outlet side exhaust gas recirculation valve (25), which is arranged upstream of the high-temperature heat exchanger (3).

9. exhaust gas heat exchanger system (20) according to any one of claims 1 to 8, characterized by a motor inlet side further exhaust gas recirculation valve (27) which is arranged downstream of the low-temperature heat exchanger (7).

10. exhaust gas heat exchanger system according to one of claims 1 to 9, characterized in that the exhaust gas heat exchanger (10) on a low pressure side of the internal combustion engine (2) is arranged.

11. Exhaust gas heat exchanger system (20) according to one of claims 1 to 10, characterized in that a charge air system (40) is connected to the exhaust gas recirculation line system (4) upstream of the engine inlet (28).

12. Internal combustion engine (2), in particular a diesel engine, in particular a commercial vehicle, with an exhaust gas heat exchanger system (20) according to one of claims 1 to 11.

13. A method for treating exhaust gases of an internal combustion engine (2), in which an exhaust gas flow (1, 11) in an exhaust gas recirculation line system (4) from an engine outlet (26) to an engine inlet (28) via an exhaust gas heat exchanger ( 10) with a in the exhaust gas recirculation line system (4) arranged upstream high-temperature heat exchanger (3) and downstream low-temperature heat exchanger (7) is guided, wherein the

High-temperature heat exchanger (3) in a primary cooling circuit (5) recooled and the low-temperature heat exchanger (7) is recooled in a secondary cooling circuit (9), and the exhaust gas stream (1, 11) adjustable from an upstream point (13) to a downstream point (15), at high temperature

Heat exchanger (3) is guided past, characterized in that the downstream point (15) upstream of the low-temperature heat exchanger (7) and downstream of the high-temperature heat exchanger (3) is arranged and the exhaust gas recirculation

Line system (4) has a bypass (17) only to the high-temperature heat exchanger (3) and with a control means, the leadership of the exhaust stream (1, 11) through the high-temperature heat exchanger (3) is set and the primary and / or Se secondary cooling circuit (5, 9) is associated with a fan (47).

14. The use of the exhaust gas heat exchanger system (20) according to any one of claims 1 to 11 or an internal combustion engine (2) according to claim 12, in a commercial vehicle.