DE102015217926A1 - Apparatus and method for heating the contents of a reducing agent tank - Google Patents

Abstract

The invention relates to a device for heating the contents (30) of a reducing agent tank (20) of an SCR catalytic converter (12). This has a tank heater (26) and an additional heater (27). The tank heater (26) is arranged in the reducing agent tank (20). The additional heater (27) is arranged at an outlet (25) of a reducing agent return line (152) leading into the reducing agent tank (20). The additional heater (27) is connected to the tank heater (26) so that it can be supplied by the tank heater (26) with heat energy. In a method for thawing the contents (30) of the reducing agent tank (20), a reducing agent solution fed back into the reducing agent tank (20) through the reducing agent return line (152) is heated by the auxiliary heater (27) when the contents (30) of the reducing agent tank (30) at least partially frozen.

Description

The present invention relates to an apparatus and a method for heating the contents of a reducing agent tank of an SCR catalyst. Furthermore, the present invention relates to a computer program that performs each step of the method according to the invention, as well as a machine-readable storage medium, which stores the computer program. Finally, the invention relates to an electronic control device which is set up to carry out the method according to the invention.

State of the art

The SCR process (Selective Catalytic Reduction) for the reduction of nitrogen oxides (NOx) in oxygen-rich exhaust gases of a motor vehicle is based on a selective catalytic reduction by means of a commercially available under the name AdBlue ^® urea water solution (HWL). This consists of a third of urea as ammonia-releasing reagent and two-thirds of water. A nozzle sprays the liquid into the exhaust stream immediately before an SCR catalyst. There arises from the urea necessary for the further reaction ammonia. In the SCR catalytic converter, nitrogen oxides from the exhaust gas and the ammonia combine to form non-toxic nitrogen. Since AdBlue freezes at -11 ° C, a tank heater must be provided in the reducing agent tank, which thaws enough HWL to ensure effective exhaust aftertreatment. The period within which the SCR catalyst system must be ready for use after an engine start is regulated by law. This operational readiness must also be ensured if a motor vehicle is used only briefly over a relatively long period of time, for example when commuting to work every day. In such cases, the amount of HWL that can be thawed with conventional tank heaters is limited because they only work locally within the tank. In particular, in such cases, depending on the tank geometry, a formation of cavities in the ice may occur around a tank removal unit, so that the tank heater disposed on the tank removal unit can no longer thaw up any TC during subsequent runs.

To address this problem, electrically operated booster heaters are used which aim to introduce additional heating power into regions of the reductant tank that are not reached by the tank heater at the tank removal unit. This results in additional costs and a need for additional electrical connections. Depending on the concept of additional heating, the situation may even arise that even the auxiliary heater thaws only one cavity and then no longer is in direct contact with the HWL. In this case, it can reach an excess temperature. Due to the technical realization of the additional heating, which must have a rigid positioning at a predetermined location, it is not ensured that the additional heating can actually be positioned in the area in which a positive thermal effect can be achieved.

In the DE 10 2008 061 471 A1 describes how to heat already flowable HWL outside of the reducing agent tank with an electrically operated auxiliary heater and then to return it to the reducing agent tank. However, this additional heating, which is designed as a reduction medium line heating, also leads to additional costs and requires additional electrical connections.

Disclosure of the invention

The apparatus for heating the contents of a reducing agent tank of an SCR catalyst comprises a tank heater and an auxiliary heater. The tank heater is disposed in the reducing agent tank, and the auxiliary heater is disposed at an outlet of a reducing agent return pipe leading into the reducing agent tank. The auxiliary heater is connected to the tank heater so that it can be supplied by the tank heater with heat energy. This offers over conventional electrical booster heaters the advantage that no additional electrical heating element is needed and the additional heating can be inexpensively installed and installed with little cabling. By not only a single point of the tank interior, but in the reducing agent back-fed reducing agent solution can be heated by means of additional heating, a fast and uniform heat distribution in the reducing agent tank and thus a complete thawing of its contents is possible.

Preferably, a delivery module with permanent return conveyor is arranged on the underside of the reducing agent tank. The return line is guided through the underside of the reducing agent tank. This allows removal and return of reducing agent solution at close to each other points of the tank bottom, so that a simple connection between tank heating and auxiliary heating is possible. The permanent return feed ensures that a large volume of heated reducing agent solution is introduced into the reducing agent tank.

Preferably, a temperature sensor is arranged outside of the reducing agent tank in the reducing agent line. This can, for example, in the delivery module, in particular within a return pump of the delivery module or in a tank flange between the delivery module and the Reductant tank be arranged. The temperature sensor allows monitoring of the temperature of reductant solution being returned to the reductant tank. The additional heating can then be controlled as a function of this measured temperature.

Downstream of the additional heater, the return line within the reducing agent tank is preferably designed as a slot tube. This allows a uniform distribution of preheated reducing agent solution in the reducing agent tank even with complex tank geometries. At the beginning of the thawing process of the tank contents, only the slits close to the outlet at which the additional heating is arranged initially thaw. Thus, only a small amount of reducing agent solution can be pumped through the slot hose.

As soon as more slits of the slit tube have thawed, the return amount can be raised. For this purpose, it is particularly preferred that in the delivery module, a pressure sensor is arranged, by means of which the progress of the building process can be monitored.

The method for thawing the contents of a reducing agent tank is performed by the apparatus. In this case, a reductant solution conveyed back through the reducing agent return line into the reducing agent tank is heated by means of the additional heating when the content of the reducing agent tank is at least partially frozen.

It is preferred that the recycled reductant solution be heated to a temperature in the range of greater than 0 ° C to a maximum of 60 ° C. Returned reducing agent solution whose temperature is in this temperature range, causes a rapid thawing of the tank contents, without it would come to an accelerated aging of the reducing agent solution due to the increased temperature.

Furthermore, it is preferable for the volume flow of the reducing agent solution conveyed back into the reducing agent tank to be regulated when the additional heating is switched on in such a way that a predefinable system pressure of the reducing agent solution is achieved. This may differ from the system pressure of the reducing agent solution during operation when the auxiliary heater is switched off. In a normal operation of an SCR catalyst system, even if a delivery module with permanent return delivery is provided, only a small volume flow is returned in the reducing agent tank. In order to achieve a rapid thawing of the tank contents, the volume flow of the return conveyor during the thawing process can be increased. It can even be provided that even if no metering of HWL is requested in the exhaust line, a promotion from the reducing agent tank is carried out to completely promote the subsidized reducing agent solution volume in the reducing agent tank and thus to achieve maximum heating of the tank contents by means of additional heating.

The computer program is set up to perform every step of the method, in particular when it runs on a control unit or computing device. It allows the implementation of the method in a conventional electronic control unit without having to make any structural changes. For this purpose, the computer program is stored on the machine-readable storage medium.

By loading the computer program on a conventional electronic control unit, the electronic control device according to the invention is obtained, which is adapted to thaw the contents of a reducing agent tank by means of the method according to the invention.

Short description of the drawing

An embodiment of the invention is in the figure and will be explained in more detail in the following description.

The figure shows schematically an SCR catalyst system which is arranged in the exhaust line of an internal combustion engine and whose reducing agent tank comprises a device according to an embodiment of the invention.

Embodiments of the invention

The exhaust system 10 an internal combustion engine 11 of a motor vehicle is in 1 shown. In the exhaust system 10 is an SCR catalyst 12 arranged. The SCR catalyst 12 is by means of a dosing 13 from a reducing agent tank 20 supplied with AdBlue ^® as a reducing agent solution. The dosing module 13 is via a pressure line 14 with a conveyor module 15 connected, which means of a feed pump (not shown) reducing agent solution from the reducing agent tank 20 promotes. This is the conveyor module 15 by means of a delivery line 151 with the interior of the reducing agent tank 20 connected. A return line 152 allows recirculation of reductant solution into the reductant tank in a permanent recirculation mode 20 , The return flow rate is in the range of 2 kg / h to 15 kg / h. A temperature sensor 153 in the conveyor module 15 measures the temperature of the recycled reductant solution. About a pressure sensor 154 in the conveyor module 15 can that into the reducing agent tank 20 back-funded Reducing agent volume can be determined. The conveyor module 15 is at the bottom 21 of the reducing agent tank 20 arranged, which is designed as a tank flange with welding contour. Two tank-side welding contours 221 . 222 connect the tank flange to the tank wall 23 , In an embodiment of the invention, not shown, the temperature sensor 153 in the tank flange instead of in the delivery module 15 be arranged. At the bottom of the reducing agent tank 20 is a suction point 24 arranged. This contains a filter and is with the delivery line 151 connected. The return line 152 flows into an outlet 25 inside the reducing agent tank 20 , This is designed as a return pipe. At the outlet 25 is an ice pressure resistant slit hose 251 attached, which extends the return line into the tank interior inside. To the content 30 of the reducing agent tank 20 to heat is at the bottom of the reducing agent tank 20 a tank heater 26 arranged. This is about a connection 261 so with an additional heating 27 connected to that of the tank heater 26 Heat controlled to the additional heating 27 can be delivered. The additional heating 27 encloses the outlet 25 , A control unit 16 is provided to the dosing module 13 , the conveyor module 15 , the tank heating 26 and the additional heating 27 to control.

If it is determined that the tank contents 30 is completely or partially frozen, for example by means of a temperature sensor, not shown, in the suction 24 integrated, so is the tank heater 26 put into operation. Once enough of the content 30 of the reducing agent tank 20 was liquefied to liquid reducing agent solution through the suction point 24 to suck in, the delivery module 15 put into operation. This sucks reducing agent solution via the suction point 24 and the support line 151 on and metered, if this from the control unit 16 is requested, a portion of the sucked reducing agent solution via the pressure line 14 and the dosing module 13 in the exhaust system 10 one. The remaining reducing agent solution is returned via the return line 152 into the reducing agent tank 20 conveyed back. In this case, their temperature in one embodiment of the method according to the invention by means of the temperature sensor 153 measured. Depending on the measured temperature, the tank heating 26 and the additional heating 27 so controlled that the tank heating 26 enough of their heat energy on the auxiliary heater 27 transfers to the reductant solution as it passes the outlet 25 to heat to a temperature in the range of more than 0 ° C to a maximum of 60 ° C. Subsequently, the heated-up reducing agent solution continues to flow into the slot tube 251 , Through this, the reducing agent solution is so in the reducing agent tank 20 Distribute that as completely as possible back to the suction point 24 running. At the beginning of the thawing process, only the slots are close to the outlet 25 thawed, leaving little solution of reducing agent through the slit tube 251 can be pumped. Accordingly, the return amount by suitable control of the pump in the delivery module 12 limited. As soon as more slots of the slit tube 251 are thawed, the return amount is increased and the heated reducing agent solution may be in more remote areas of the reducing agent tank 20 be distributed. The amount of return is via the pressure sensor 154 and so monitors the progress of the thawing process. This regulation takes place depending on the shape of the reducing agent tank 20 in the control unit 16 is deposited.

In an embodiment in which the reducing agent tank 20 designed as a two-part injection molding tank, the laying of the slit hose 251 from above within the reducing agent tank 20 respectively. Is the reducing agent tank 20 a blow-molded tank, so the slit hose 251 also be laid blind. It is also possible in an embodiment of the invention, not shown, on the slot tube 251 to renounce. The preheated reductant solution is then passed through the outlet 25 as a fountain against the tank wall 23 injected. This will be through the tank heater 26 generated cavity in the frozen content 30 of the reducing agent tank 20 continuously enlarged. The waiver of the slit hose 251 However, it is only recommended for simple tank geometries.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 102008061471 A1 [0004]

Claims (10)

Device for heating the content ( 30 ) of a reducing agent tank ( 20 ) of an SCR catalyst ( 12 ), comprising a tank heater ( 26 ) and an additional heating ( 27 ), whereby the tank heating ( 26 ) in the reducing agent tank ( 20 ) and the auxiliary heating ( 27 ) at an outlet ( 25 ) one into the reducing agent tank ( 20 ) leading reducing agent return line ( 152 ), characterized in that the auxiliary heating ( 27 ) so with the tank heater ( 26 ) is connected to the tank heater ( 26 ) can be supplied with heat energy. Apparatus according to claim 1, characterized in that a conveyor module ( 15 ) with permanent recirculation at the bottom of the reducing agent tank ( 20 ) wherein the return line ( 152 ) through the bottom ( 21 ) of the reducing agent tank ( 20 ) is guided. Device according to claim 1 or 2, characterized in that a temperature sensor ( 153 ) outside the reducing agent tank in the reducing agent line ( 152 ) is arranged. Device according to one of claims 1 to 3, characterized in that the return line ( 152 ) downstream of the auxiliary heater ( 27 ) within the reducing agent tank ( 20 ) as a slit tube ( 251 ) is executed. Method for defrosting the content ( 30 ) of a reducing agent tank ( 20 ) by means of a device according to one of claims 1 to 4, wherein a through the reducing agent return line ( 152 ) into the reducing agent tank ( 20 ) back-promoted reducing agent solution by means of the additional heating ( 27 ) is heated when the content ( 30 ) of the reducing agent tank ( 30 ) is at least partially frozen. A method according to claim 5, characterized in that the back-fed reducing agent solution is heated to a temperature in the range of more than 0 ° C to a maximum of 60 ° C. A method according to claim 5 or 6, characterized in that the volume flow into the reducing agent tank ( 20 ) back-promoted reducing agent solution with activated auxiliary heating ( 27 ) is regulated so that a predeterminable system pressure of the reducing agent solution is achieved. A computer program adapted to perform each step of the method of any of claims 5 to 7. A machine-readable storage medium on which a computer program according to claim 8 is stored. Electronic control unit ( 16 ), which is set up, the content of a reducing agent tank ( 20 ) by means of a method according to any one of claims 5 to 7 thaw.

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