DE102016219389A1 - Exhaust gas purification device, drive device and method for operating a drive device - Google Patents

Abstract

The invention relates to an exhaust gas purification device (1) having an exhaust gas filter (2) which has an exhaust gas filter body (3) arranged in an exhaust gas filter housing (4) and forming a plurality of flow channels, and an electric heating device for heating the exhaust gas filter body (3) Exhaust filter body (3) by a housing wall (5) of the exhaust filter housing (4) is enclosed, it is provided that on the exhaust filter body (3) facing away from the housing wall (5), a heat exchanger (10) is arranged, via the housing wall ( 5) is in heat transfer communication with the exhaust filter body (3). The invention further relates to a drive device with a waste-gas generating drive unit and an exhaust gas purification device (1) for cleaning the exhaust gas generated by the drive unit and a method for operating a drive device.

Description

The invention relates to an exhaust gas purification device with an exhaust gas filter, which has arranged in an exhaust filter housing, a plurality of flow channels forming exhaust filter body, and an electric heater for heating the exhaust filter body, wherein the exhaust filter body is enclosed by a housing wall of the exhaust filter housing. The invention further relates to a drive device with a waste-gas generating drive unit and an exhaust gas purification device for cleaning the exhaust gas generated by the drive unit and a method for operating a drive device.

The exhaust gas purification device is used to purify exhaust gas, which is generated by the exhaust gas generating drive unit, which is for example part of the drive device, during its operation. In particular, a conversion of pollutants contained in the exhaust gas into innocuous or at least less harmful substances is provided. The exhaust gas filter has the exhaust filter body, which exerts the actual filtering and / or catalytic effect on the exhaust gas or the pollutants contained therein. The exhaust filter body consists for example of a honeycomb body, in which the plurality of flow channels is present. The honeycomb body is preferably made of ceramic, for example cordierite. However, other materials may be used to make the honeycomb body.

The exhaust filter body may be provided with a catalytic coating in the case of an at least partial embodiment of the exhaust gas filter as exhaust gas catalytic converter. For example, this coating is in the form of a so-called washcoat, which has a high roughness, in particular a higher roughness than the exhaust filter body itself, to increase an effective surface. Preferably, at least one catalytically active element, for example a noble metal, is incorporated in the coating. For example, here one or more of the following precious metals are used: platinum, rhodium and palladium. The exhaust gas catalyst can be configured, for example, as a three-way catalyst or as a four-way catalyst. Alternatively or additionally, however, the exhaust gas filter may also be configured as a particle filter or at least have such a filter. The particulate filter is, for example, a gasoline particulate filter or a diesel particulate filter.

The exhaust filter body is disposed in the exhaust filter housing. The exhaust gas filter housing is used in particular for the flow guidance of the exhaust gas flow. In that regard, the exhaust filter housing has an exhaust gas inlet and an exhaust gas outlet. Exhaust gas can escape into the exhaust gas filter housing through the exhaust gas inlet. Subsequently, it flows through the exhaust filter housing and exits through the exhaust outlet from the exhaust filter housing. In the flow path between the exhaust gas inlet and the exhaust gas outlet of the exhaust filter body is arranged in the exhaust filter housing, this is provided such that the exhaust gas passes through the exhaust filter body or its flow channels in the flow through the exhaust filter housing, ie on the flow path between the exhaust inlet and the exhaust gas outlet , In this case, the exhaust filter body is preferably arranged in the exhaust filter housing such that the entire exhaust gas entering the exhaust gas filter housing through the exhaust gas inlet flows through the exhaust filter body or its flow channels.

The exhaust filter body is for this purpose preferably enclosed by the housing wall of the exhaust filter housing. For example, the housing wall surrounds the exhaust filter body in the circumferential direction with respect to a longitudinal center axis of the exhaust filter body or a flow direction of the exhaust filter housing completely. The housing wall preferably limits the exhaust gas inlet and / or via the exhaust gas outlet. Particularly preferably, the exhaust gas inlet and the exhaust gas outlet are each formed as an edge-closed opening in the housing wall. The housing wall thus ensures a flow guidance of the exhaust gas flowing through the exhaust filter housing from the exhaust gas inlet to the exhaust gas outlet.

The exhaust filter has its highest conversion rates for the pollutants at a certain operating temperature. In particular, at temperatures below this operating temperature, the conversion rates are extremely low, so that the exhaust gases can flow through without conversion the exhaust gas filter, thus emerge together with the exhaust gas from the exhaust gas outlet of the exhaust gas filter. To avoid this, the electric heater is provided. This serves to heat the exhaust filter body in order to bring it as quickly as possible to the operating temperature. This is preferably done before the start of operation of the exhaust-generating drive unit, ie before the exhaust gas filter is flowed through by exhaust gas. Particularly preferably, the exhaust filter body is already brought to its operating temperature by means of the heater before the exhaust-generating drive unit is put into operation, that is, exhaust gas is generated.

The heating of the exhaust filter body by means of the electric heater is extremely energy consuming. This is all the more true if the exhaust-generating drive unit is operated only temporarily, as for example in a Hybrid drive device of a motor vehicle may be the case. In this case, the exhaust filter body must be continuously heated during operation of the motor vehicle with switched off exhaust-generating drive unit, because the device can be started at any time.

It is an object of the invention to propose an exhaust gas purification device, which has advantages over known exhaust gas purification devices, in particular despite providing the electric heater for heating the exhaust filter body allows energy-efficient operation of the exhaust gas purification device.

This is achieved according to the invention with an exhaust gas purification device having the features of claim 1. It is provided that a heat exchanger is arranged on the side facing away from the exhaust filter body side of the housing wall, which is in heat transfer connection via the housing wall with the exhaust filter body.

The exhaust gas purification device therefore has the heat exchanger in addition to the exhaust gas filter. This is designed such that it serves to dissipate heat from the exhaust filter body. Accordingly, it is arranged such that it is in heat transfer communication with the exhaust filter body. The heat transfer connection is above the housing wall. For this purpose, the housing wall preferably consists of a thermally conductive material, in particular in a region of the housing wall, against which the exhaust filter body on the one hand and the heat exchanger on the other.

It can also be provided that the housing wall consists of several sections, which consist of different materials. For example, the housing wall in a partial region, against which both the heat exchanger and the exhaust filter body, is made of a material which has a higher thermal conductivity than a material, from which at least one further partial region consists of the housing wall, which is present away from the heat exchanger and the exhaust filter body , so is spaced from these.

Additionally or alternatively, it can be provided to arrange at least one heat-conducting element in the housing wall, via which the exhaust-gas filter body is in heat-transfer connection with the heat exchanger. Such a heat-conducting element can be, for example, a heat pipe, for example a heat pipe or a thermosyphon. If such a heat conduction device is provided, it goes without saying that the housing wall can be made of the same material throughout, that is, consist continuously of the same material.

The heat exchanger is arranged on the side facing away from the exhaust filter body side of the housing wall. In particular, the heat exchanger should not be directly flowed by exhaust gas and / or overflowed. Rather, the heat exchanger should be present outside exhaust-carrying areas of the exhaust filter housing. Accordingly, the heat exchanger ultimately serves the removal of heat from the exhaust filter body, but not the direct removal of heat from the exhaust gas. This is only provided indirectly via the exhaust filter body.

The heat removed by the heat exchanger the exhaust filter body heat can be supplied to any other device. For example, the heat exchanger is connected to a cooling circuit, which serves for the temperature control or cooling of a drive unit of the drive device. Additionally or alternatively, the heat can be used for tempering a passenger compartment of the motor vehicle. This means that, on the one hand, the exhaust filter body is heated by means of the electric heater, but the energy used for this purpose is also used for other purposes, especially when the exhaust filter body has already reached its operating temperature.

In addition, the thermal mass of the exhaust gas filter or the exhaust gas purification device is increased by the heat exchanger, so that a cooling of the exhaust gas filter, in particular starting from its operating temperature, is delayed in comparison with conventional exhaust gas purification devices. It is also possible to use the heat exchanger for cooling the exhaust gas. For example, the exhaust gas by means of the heat exchanger, a certain amount of heat withdrawn, which is chosen such that downstream of the heat exchanger, the exhaust gas has a certain exhaust gas temperature or at least does not exceed. This can be provided, for example, when the exhaust gas downstream of the exhaust gas cleaning device flows through an exhaust gas line which is present in the region of an energy store for electrical energy, in particular a battery, for example a high-voltage battery, or passes through it. Even if the exhaust pipe passes through a tunnel, the described procedure can be used.

As part of a further embodiment of the invention, it is provided that seen in the axial direction with respect to a longitudinal center axis of the exhaust filter body, the heat exchanger several more adjacent to the housing wall Heat exchanger regions having mutually different inner dimensions. For example, the exhaust filter housing or the housing wall is composed of several subregions. Preferably, these partial regions adjoin one another in the axial direction with respect to the longitudinal central axis of the exhaust filter body. Of course, some of the sections may also be spaced apart from each other. The portions of the exhaust filter housing may have different outer dimensions.

The heat exchanger is adapted to the exhaust gas filter housing or the subregions in shape and / or dimensions, in particular in such a way that it rests against it or against it from the outside. Accordingly, the heat exchanger on a plurality of different heat transfer areas, which have different inner dimensions. It may be provided that the heat exchanger has larger dimensions in the axial direction than the exhaust filter body. In particular, the heat exchanger extends in the downstream direction with respect to the direction of flow of the exhaust gas through the exhaust gas filter beyond the exhaust filter body. Alternatively, it may of course be provided that the heat exchanger is aligned on its downstream side with the exhaust filter body or ends upstream of this.

A further embodiment of the invention provides that at least one of the heat exchanger regions has a cylindrical, in particular circular-cylindrical, inner peripheral surface and / or at least one further of the heat-exchanger regions has a conical inner circumferential surface. In principle, the heat transfer areas can have any desired shape. However, one of the heat exchanger regions is preferably cylindrical and another of the heat exchanger regions is conical. This also applies correspondingly to the subsections of the housing wall or of the exhaust gas filter housing to which the respective heat exchanger area rests.

For example, it is provided that, viewed in the direction of flow of the exhaust gas, the exhaust gas filter housing initially has a cylindrical subarea, to which a conical subarea adjoins, so that the throughflow cross section in the flow direction increases. The conical portion is in turn followed by a cylindrical portion in which the exhaust filter body is present. Downstream of the exhaust filter body is again a conical portion, in which the flow cross-section decreases in the flow direction. In turn, a cylindrical section can follow this conical subregion. In the first-mentioned subarea, the exhaust gas inlet and in the last-mentioned subarea of the exhaust gas outlet may be present.

Finally, it can be provided within the scope of a further preferred embodiment that the exhaust gas filter housing and / or the heat exchanger is encompassed at least partially by one, in particular at least on the one hand of the heat exchanger or on both sides of the heat exchanger to the housing wall, heat insulation. The thermal insulation is used for thermal insulation of the exhaust gas purification device, so that as little heat of the exhaust filter body is lost, especially if it is not flowed through by exhaust gas. The heat insulation surrounds the exhaust filter housing and / or the heat exchanger at least in regions, in particular in the circumferential direction with respect to the longitudinal central axis of the exhaust filter body completely. The heat insulation is preferably applied to an outer peripheral surface of the exhaust filter housing and / or the heat exchanger.

More preferably, the heat insulation extends in the flow direction at least on one side, but preferably on both sides, beyond the heat exchanger addition. This means that the thermal insulation rests continuously in the flow direction on the heat exchanger and rests on both sides of the heat exchanger to the exhaust filter housing. It may be provided here that the heat insulation extends in the flow direction from the exhaust gas inlet to the exhaust gas outlet of the exhaust gas filter housing.

The invention further relates to a drive device with a waste gas generating drive unit and an exhaust gas purification device for cleaning the exhaust gas generated by the drive unit, in particular an exhaust gas purification device according to the above embodiments, wherein the exhaust gas purification device via an exhaust filter, which arranged in an exhaust filter housing, a plurality of flow channels forming exhaust filter body has, and has an electric heater for heating the exhaust filter body, wherein the exhaust filter body is enclosed by a housing wall of the exhaust filter housing. It is provided that a heat exchanger is arranged on the side facing away from the exhaust filter body side of the housing wall, which is in heat transfer connection via the housing wall with the exhaust filter body.

The advantages of such an embodiment of the exhaust gas purification device or the drive device has already been pointed out. Both the drive device and the exhaust gas purification device can according to the be further developed above, so that reference is made to this extent.

A further preferred embodiment of the invention provides a cooling circuit for controlling the temperature of the drive unit, which is fluidically connected to the heat exchanger. Generally speaking, the cooling circuit of the temperature control of the drive unit, so that it can also be referred to as tempering. The cooling circuit is fluidically connected to the heat exchanger, so that in the cooling circuit circulating coolant is at least partially guided by the heat exchanger. In this way, the heat taken from the exhaust filter body heat can serve the tempering of the drive unit, in particular if this is currently not operated.

A development of the invention provides that the cooling circuit is fluidically connected directly or via a further heat exchanger to a passenger compartment heating. The passenger compartment heating circuit serves to control the temperature of a passenger compartment of the motor vehicle. It can now be provided that the coolant used in the cooling circuit is supplied directly to the passenger compartment heating circuit. Alternatively, another heat exchanger can be present between the cooling circuit and the passenger compartment heating circuit, so that the cooling circuit and the passenger compartment heating circuit are fluidly decoupled from one another.

Finally, the invention relates to a method for operating a drive device, in particular a drive device according to the preceding embodiments, which has a waste gas generating drive unit and an exhaust gas purification device for cleaning the exhaust gas generated by the drive unit, the exhaust gas purification device via an exhaust filter, which arranged in a exhaust gas filter housing, has a plurality of flow channels forming exhaust filter body, and has an electric heater for heating the exhaust filter body, wherein the exhaust filter body is enclosed by a housing wall of the exhaust filter housing. It is provided that a heat exchanger is arranged on the side facing away from the exhaust filter body side of the housing wall, which is in heat transfer connection via the housing wall with the exhaust filter body.

With regard to the advantages of such an embodiment of the drive device and the corresponding procedure and with regard to possible developments of the drive device and the method, reference is again made to the above statements.

In a preferred embodiment of the invention can be provided that in a first mode of the exhaust filter body is heated by the heater, wherein a coolant flow is interrupted by the heat exchanger until the exhaust filter body has reached a target temperature and after reaching the sol temperature of the exhaust filter body by means of the heat exchanger Heat is taken, which is subsequently used for tempering at least one vehicle device, in particular the drive unit, a passenger compartment and / or an energy storage. In the context of the first operating mode, the exhaust filter body should first be brought to its operating temperature as quickly as possible. For this purpose, the exhaust filter body is preferably supplied with heat by means of the heating device. In addition, it can be supplied heat of the exhaust gas.

If the exhaust filter body has reached its setpoint temperature, that is, the temperature of the exhaust filter body is greater than or equal to the desired temperature, the coolant flow can be released by the heat exchanger, so that the coolant flows through the heat exchanger. Using the heat exchanger or the coolant heat is subsequently removed from the exhaust filter body and fed to at least one vehicle device.

Finally, a further embodiment of the invention can provide that in a second operating mode, the heating device is deactivated, wherein the exhaust filter body heat is removed by means of the heat exchanger for tempering the at least one vehicle device. In the second mode, the heater is disabled. The exhaust filter body is supplied so far no or only by means of the exhaust heat. In any case, however, the exhaust filter body can be removed by means of the heat exchanger heat, which is subsequently used for controlling the temperature of the at least one vehicle device.

For example, such a procedure is provided during the operation of the exhaust gas generating drive unit, so that the heat contained in the exhaust gas is used for controlling the temperature of the vehicle device. However, it can also be provided to remove the heat from the exhaust filter body, although heat is neither supplied to it by means of the heating device nor via the exhaust gas. In this case, for example, the exhaust filter body is used as a heat storage. This is preferably carried out when the temperature of the exhaust filter body is greater than the target temperature. The setpoint temperature may in this case correspond to the above-mentioned operating temperature.

It is preferably provided to carry out the first operating mode when it is detected that a driver approaches the vehicle. This is recognized in particular due to an approach of a vehicle key to the motor vehicle. Accordingly, the exhaust filter body is heated by means of the heater, so that its temperature increases in the direction of the setpoint temperature or operating temperature. If the exhaust filter body has reached its setpoint temperature, the heat supplied to the exhaust filter body by means of the heating device can be used in addition to controlling the temperature of the drive assembly, the passenger compartment or the like.

For example, a fluid can be present in the heat exchanger, which is circulated in the heat exchanger or within a closed coolant circuit associated with the heat exchanger. As a coolant, for example, thermal oil is used. This can be active in the heat exchanger or the coolant circuit either, ie by means of a conveyor, or passively circulated. For passive circulation, for example, the thermosiphon effect is used. In such an embodiment of the heat exchanger, the heat exchanger is fluidically connected via a further heat exchanger to the cooling circuit and / or the passenger compartment heating circuit.

The invention will be explained in more detail with reference to the embodiments illustrated in the drawings, without any limitation of the invention. The single FIGURE shows a schematic partial sectional view of an exhaust gas purification device having an exhaust filter, a heat exchanger and a heat insulation.

The figure shows a schematic partial sectional view of an exhaust gas purification device 1 , This has an exhaust filter 2 which in turn is an exhaust filter body 3 having. In the exhaust filter body 3 is formed a variety of not shown here in detail flow channels. The exhaust filter body is in an exhaust filter housing 4 arranged and is doing of a housing wall 5 the exhaust filter housing 4 edged. With respect to a flow direction of the exhaust gas purification device 1 flowing exhaust gas comprises the housing wall 5 the exhaust filter body 3 in the circumferential direction preferably completely. The flow direction of the exhaust gas is indicated by the arrows 6 indicated.

In the exhaust filter housing 4 are an exhaust inlet 7 and an exhaust outlet 8th educated. The exhaust gas flows through the exhaust gas inlet 7 into the exhaust filter housing 4 in and through the exhaust outlet 8th from the exhaust filter housing 4 out. In the flow direction of the exhaust gas between the exhaust gas inlet 7 and the exhaust outlet 8th is the exhaust filter body 3 arranged, namely such that the entire the exhaust filter 2 exhaust gas flowing through the exhaust filter body 3 or passes through the flow channels. To achieve this, the exhaust filter body 3 for example, via a fastener 9 on the housing wall 5 be tightly attached. The fastener 9 consists for example of an elastic material.

On the exhaust filter body 3 opposite side of the housing wall 5 is a heat exchanger 10 arranged. A fluid room 11 of the heat exchanger 10 , in which a coolant is present, for example, at least partially from the housing wall 5 with trained. The heat exchanger 10 is seen in the flow direction of the exhaust gas at least partially in overlap with the exhaust filter body 3 in front. In particular, the heat exchanger extends 10 both upstream and downstream via the exhaust filter body 3 out. Particularly preferred is the heat exchanger 10 while closer to the exhaust outlet 8th as at the exhaust inlet 7 , However, a reverse configuration may also be provided.

The heat exchanger 10 preferably has a plurality of fluid ports 12 and 13 on, wherein one of the fluid ports 12 and 13 as a fluid inlet and another of the fluid ports 12 and 13 serves as a fluid outlet. Through the fluid inlet, the heat exchanger 10 the coolant is supplied and removed through the fluid outlet. The heat exchanger is preferred 10 or his fluid space 11 a cooling circuit for cooling a drive unit associated with a drive device, wherein the exhaust gas purification device 1 Part of the drive device is.

In the fluid space 11 At least one flow-guiding element and / or at least one surface-enlarging element can be arranged. The at least one flow guide element is for example arranged and / or formed such that the fluid supplied through the fluid inlet is guided towards the fluid outlet. For example, the fluid inlet and the fluid outlet are spaced apart in the axial direction, in particular in the axial direction at opposite ends of the fluid space 11 arranged. For example, the flow guide element is now intended to guide the supplied fluid in a spiral shape in such a way that it is deflected by at least 180 ° in the circumferential direction on the way to the fluid outlet. Also, a deflection of at least 360 °, at least 720 °, at least 1080 °, at least 1440 ° or at least 1800 ° may be provided. For example, the flow guide element forms in the fluid space 11 a flow channel starting at the fluid inlet and terminating at the fluid outlet and having a plurality of turns in the circumferential direction, in particular at least 2, at least 3, at least 4 or at least 5.

Additionally or alternatively, the surface enlargement element is in the fluid space 11 intended. This is on the housing wall 5 attached and passes through the fluid space 11 in the radial direction preferably only partially. Alternatively, of course, a complete penetration can be provided. In this case, the surface enlarging element is additionally designed as a flow guide element.

Furthermore, it can be provided that downstream of the exhaust filter body 3 in the exhaust filter housing 4 at least one of the exhaust gas flows and / or overflowed Abgasleitelement is arranged. This is preferably designed such that it exhaust gas in the radial direction outward in the direction of the housing wall 5 directs. In this way, the exhaust gas, a comparatively large amount of heat can be withdrawn. Additionally or alternatively, this is the exhaust gas guide of the surface enlargement. In this case, the Abgasleitelement example, of a thermally conductive material and is thermally conductive with the housing wall 5 connected. The Abgasleitelement extends in each case, starting from the housing wall 5 starting in the radial direction inwards.

It can be seen that both the exhaust filter housing 4 as well as the heat exchanger 10 each at least partially of a thermal insulation 14 is encompassed. In particular, the thermal insulation extends 14 both upstream and downstream via the heat exchanger 10 out and thus lies on both sides of the heat exchanger 10 on the housing wall 5 at. For example, the thermal insulation extends 14 from the exhaust inlet 7 to the exhaust outlet 8th ,

It can also be seen that the heat exchanger 10 different heat exchanger areas 15 . 16 and 17 having. Each of these heat exchanger areas 15 . 16 and 17 is to the exhaust filter housing 4 adapted shape and dimensions. Here are the heat transfer areas 15 and 17 For example, cylindrical, in particular circular-cylindrical designed, while the heat exchanger area 16 is conical.

Using the emission control device described here 1 is an extremely efficient tempering of the exhaust gas filter 2 or the exhaust filter body 3 possible. In particular, it is using an electric heater, not shown here, the exhaust filter body 3 supplied heat after reaching an operating temperature through the exhaust filter body 3 supplied to at least one other device, in particular another vehicle device. In this case, the exhaust filter body 3 further heated by means of the heater. The other vehicle device may be, for example, the drive unit, a passenger compartment and / or an energy store or a heat store.

Claims (10)

Exhaust gas purification device ( 1 ) with an exhaust filter ( 2 ), one in an exhaust filter housing ( 4 ) arranged, a plurality of flow channels forming exhaust filter body ( 3 ), and an electrical heating device for heating the exhaust filter body ( 3 ), wherein the exhaust filter body ( 3 ) of a housing wall ( 5 ) of the exhaust filter housing ( 4 ) Is enclosed, characterized in that on (the exhaust gas filter body 3 ) facing away from the housing wall ( 5 ) a heat exchanger ( 10 ) is arranged, which over the housing wall ( 5 ) with the exhaust filter body ( 3 ) is in heat transfer connection. Exhaust gas purification device according to claim 1, characterized in that in the axial direction with respect to a longitudinal center axis of the exhaust filter body ( 3 ) seen the heat exchanger ( 10 ) several each on the housing wall ( 5 ) adjacent heat transfer areas ( 15 . 16 . 17 ), which have different inner dimensions from each other. Exhaust gas purification device according to one of the preceding claims, characterized in that at least one of the heat transfer areas ( 15 . 16 . 17 ) a cylindrical, in particular circular cylindrical, inner peripheral surface and / or at least one of the heat transfer regions ( 15 . 16 . 17 ) has a conical inner peripheral surface. Exhaust gas purification device according to one of the preceding claims, characterized in that the exhaust gas filter housing ( 4 ) and / or the heat exchanger ( 10 ) at least in regions of one, in particular at least on the one hand of the heat exchanger ( 10 ) or on both sides of the heat exchanger ( 10 ) on the housing wall ( 5 ) adjacent, thermal insulation ( 14 ) is encompassed. Drive device with a exhaust-generating drive unit and an exhaust gas purification device ( 1 ) for cleaning the exhaust gas generated by the drive unit, in particular an exhaust gas purification device ( 1 ) according to one or more of the preceding claims, wherein the exhaust gas purification device ( 1 ) via an exhaust filter ( 2 ), one in an exhaust filter housing ( 4 ) arranged, a plurality of flow channels forming exhaust filter body ( 3 ), and over an electrical heating device for heating the exhaust filter body ( 3 ), wherein the exhaust filter body ( 3 ) of a housing wall ( 5 ) of the exhaust filter housing ( 4 ), characterized in that on the exhaust filter body ( 3 ) facing away from the housing wall ( 5 ) a heat exchanger ( 10 ) is arranged, which over the housing wall ( 5 ) with the exhaust filter body ( 3 ) is in heat transfer connection. Drive device according to claim 5, characterized by a cooling circuit for temperature control of the drive unit, the fluidically to the heat exchanger ( 10 ) connected. Drive device according to one of the preceding claims, characterized in that the cooling circuit is fluidically connected directly or via a further heat exchanger to a passenger compartment heating. Method for operating a drive device, in particular a drive device according to one or more of the preceding claims, comprising a waste-gas generating drive unit and an exhaust gas purification device ( 1 ) for cleaning the exhaust gas generated by the drive unit, wherein the exhaust gas purification device ( 1 ) via an exhaust filter ( 2 ), one in an exhaust filter housing ( 4 ) arranged, a plurality of flow channels forming exhaust filter body ( 3 ), and via an electrical heating device for heating the exhaust filter body ( 3 ), wherein the exhaust filter body ( 3 ) of a housing wall ( 5 ) of the exhaust filter housing ( 4 ), characterized in that on the exhaust filter body ( 3 ) facing away from the housing wall ( 5 ) a heat exchanger ( 10 ) is arranged, which over the housing wall ( 5 ) with the exhaust filter body ( 3 ) is in heat transfer connection. A method according to claim 8, characterized in that in a first mode of the exhaust filter body ( 3 ) is heated by means of the heating device, wherein a coolant flow through the heat exchanger ( 10 ) is interrupted until the exhaust filter body ( 3 ) has reached a target temperature and after reaching the target temperature the exhaust filter body ( 3 ) by means of the heat exchanger ( 10 ) Heat is removed, which is subsequently used for tempering at least one vehicle device, in particular the drive unit, a passenger compartment and / or an energy storage. Method according to one of the preceding claims, characterized in that in a second operating mode, the heating device is deactivated, wherein the exhaust filter body ( 3 ) by means of the heat exchanger ( 10 ) Heat for tempering the at least one vehicle device is removed.

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