DE102015015442A1 - Reducing agent system with a heated tank - Google Patents

Abstract

The invention relates to the heating concept of a reducing agent system for motor vehicles. The task is an improved heating concept for a reducing agent system, which includes the thawing of the entire tank contents, thereby eliminating sealing problems. The object is achieved by a reducing agent system in which the tank contents are not heated directly by a heating element, but with the aid of a heating fluid, which is heated in a water heater. For this purpose, the tank has a heating fluid flowing through the hose system, wherein the hose system forms a closed heating circuit with the water heater.

Description

The invention relates to the heating concept of a reducing agent system for motor vehicles. Reducing agent systems for motor vehicles, for example, with the reducing agent urea solution (AdBlue), require heating of various system components such as storage tank, metering module, filters, connecting lines, etc., since z. B. urea solution at -11 ° C freezes. On the other hand, no heating may take place above 60 ° C, because urea solution decomposes otherwise and ammonia is released.

The prior art are therefore ceramic PTC thermistors, so-called PTC heating elements, which automatically limit their temperature upwards. In order to thaw frozen urea solution as efficiently as possible in a tank, the heating element is preferably arranged in the tank interior. However, this causes problems in the sealing of the heating element, since urea solution is very aggressive and the heating element is destroyed in case of leakage of the seal. Furthermore disadvantageous brings a PTC heating element only limited local heat in a region of the tank, that is, the heating effect and thus the thawing of the urea solution is not achievable in the entire tank.

Task is therefore an improved heating concept for a reducing agent system, which includes the thawing of the entire tank contents and thereby excludes sealing problems.

The object is achieved by a reducing agent system according to claim 1. Further features and advantageous embodiments are given in the dependent claims and the following description.

According to claim 1, the tank contents are not heated directly by a heating element, but with the aid of a heating fluid which is heated in a water heater.

This has the advantage that, with the same instantaneous water heater, the respective tank heating can be individually adapted to each tank. Furthermore, advantageously, a sustainable, distributed throughout the tank flexible heating can be realized with little effort. Due to the closed heating circuit this can be tailored to the reducing agent. Thus, the heating circuit can be operated with low pressure, an adapted temperature and a reducing agent-compatible liquid. If an electric instantaneous water heater is arranged outside the tank, sealing of electrical components against the reducing agent is extremely advantageously unnecessary.

In a simple form, the hose system is designed as a heat-emitting component of at least one flexible hose, which may be attached at intervals to the tank wall. Preferably, however, the hose system is designed as a coherent flat, flexible structure made of plastic with channels for the heating fluid. The tube system can be designed as a closed surface, but also with openings or only as connected by webs structure. Most preferably, the tube system consists of a series of parallel, thin channels (ribs), each with a collecting space at the inlet and outlet.

As a result, the entire heat-dissipating hose system can be produced thinly and easily with little material expenditure. Advantageously, a large area in the tank can be heated with a small amount of fluid. As a material for the hose system, no high temperature resistant plastic must be used, but it can be used, for example, a polyolefin such as polypropylene or polyethylene. In addition, these plastics have the advantage that in the case of incorrect refueling, greater damage to the heat-indicating hose system does not immediately occur. Further advantageously, heating by the hose system can not result in overheating of the part protruding from the urea solution, as may be the case with electric heating elements.

Conceivable is the production of the hose system z. B. from endless tubular film whose ends, with the exception of inlet and outlet, and the dividing webs between the channels by z. B. Roll welding seams are closed. Alternatively, the tube system can be made by two with each other welded to the sealing points and dividing webs foils. Advantage of this variant is the free design of the outer contour of the hose system by subsequent punching the contour.

To introduce the heat-emitting tube system in the tank, the tank preferably has an opening which is large enough to the tube system in a compact form, for. B. rolled up to be stuck through. The opening is then sealed by a mounting flange having at least two openings for the supply of inflow and outflow of the heating fluid.

The water heater may be a water heater with an electric heating element. In this case, a PTC heating element is preferred because of its self-regulating property. Other heating elements such as electrically conductive plastic, Heated conductors (eg thick-film technology), stamped grid, tubular heater or the like are also possible.

Also conceivable is a water heater, which is designed as a heat exchanger between the first heating fluid for the heat-emitting tube system and a second thermal fluid, in particular the coolant of a motor vehicle. As a result, the heat from the coolant circuit of a motor vehicle can be used indirectly for thawing the reducing agent.

If coolant is used directly for heating the reducing agent in the tank, this has the disadvantage that the fluid guide in the tank must withstand the high pressure in the coolant circuit. The channel system in the tank is correspondingly massive. In addition, the cooling water may be contaminated. Thin channels would be so fast impermeable. Another disadvantage is the incompatibility of coolant and urea solution. Both contaminants of coolant through urea solution and contaminated coolant in the urea system lead to high system damage, which can be caused by small leaks.

These disadvantages prevent a heat exchanger for decoupling tank heating circuit as a low pressure system and coolant circuit as a high pressure system.

Preferably connected to a suitable temperature management (control or control with temperature detection) is in an advantageous development of the water heater both as an electric water heater and as a heat exchanger between the first heating fluid and a second heat fluid, in particular cooling liquid executed. In this case, heated in a first period after starting the electric heating element of the combined water heater, the heating fluid. If the cooling liquid has then reached a predetermined temperature, the electric heating element can be switched off and, for example by means of a valve, the flow of the cooling liquid through the flow heater can be released so that it is now operated as a heat exchanger.

The alternative circuit prevents heat transfer from the heating element to the cooling liquid, ie. H. the entire el. heating energy is used to heat the reducing agent.

In an advantageous embodiment, the water heater has a heating block of a good heat conducting material such as aluminum. This is preferably carried out with separate flow channels for the heating fluid and the second thermal fluid. For example, it can be provided that the heating block is an extruded profile, which is designed with at least three channels. In two channels, tubes are very preferably arranged for a good heat transfer between the heating block and the heating fluid or the second thermal fluid. For a good heat transfer, these are advantageously pressed or soldered in the channels. The third channel has at least one heating element, in particular a compressed PTC element.

Preferably, the heating fluid is passed through a pump in a forced circulation. It is highly preferred that the instantaneous water heater and pump are in heat-conducting contact with each other, for example in the form of a compact unit, but thermally insulated from the outside. In this case, the waste heat of the pump can contribute to the heating of the heating fluid and thus be used energetically.

In a particularly efficient development of the water heater and the heating fluid is not only used to heat the tank contents, but also for heating of other components such as filters, delivery module or reducing agent lines, in particular the dosing. For this purpose, the components have suitable channels through which the heating fluid can flow. Preferably, the heating circuits of the other components are executed parallel to the heating circuit of the tank.

Alternatively to the arrangement of the heat-emitting hose system inside the tank, the hose system can also be arranged outside the tank in heat-conducting connection to the tank wall. The thermally conductive connection can be done for example via anextruded webs and a mirror welded connection. Furthermore, the side of the hose system facing away from the tank wall preferably has a heat insulating layer.

Further details and advantages of the invention will be explained with reference to embodiments with reference to the accompanying drawings. It shows:

1 Schematic sketch of an embodiment according to the invention;

2 a reducing agent tank with hose system arranged inside

1 shows the sketch of a variant in which the water heater 1 both as an electric instantaneous water heater and as a heat exchanger between the heating fluid 13 and the coolant 12 is designed as a second thermal fluid. The water heater 1 , For example, with an aluminum extruded profile 16 , has three separate channels 3 . 4 . 5 on. The first channel 2 is the flow channel for the heating fluid 13 , the second channel 3 is the flow channel for the second heat fluid 12 , preferably coolant, and in the third channel 4 is the electric heating element 5 , Preferably, a PTC heating element arranged. In the two fluid channels 2 . 3 can separate flow tubes (not shown) in good heat conducting contact with the extruded profile 16 be arranged, for example by pressing or soldering. Also in good heat-conducting connection to the extruded profile 16 is the PTC heating element 5 clamped, for example by a spring element or also by pressing, in the third channel 4 held.

interconnectors 6 . 7 lead the heating fluid to, here arranged in the tank, hose system 8th , With the help of a pump 9 finds a forced circulation of the heating fluid 13 between water heater 1 and hose system 8th instead of. A heat transfer to the heating fluid 13 in the water heater 1 Alternatively, it can be from both the PTC heating element 5 as well as the coolant 12 respectively. A simultaneous heating on the other hand would lead to a heat input into the cooling water 12 lead and would therefore be inefficient. That's why a valve opens 10 for the coolant flow of the water heater 1 controlled by a thermal management system 14 only when the switch is open 11 , ie switched off electrical heating element 5 ,

2 shows an exemplary embodiment of a reducing agent tank 15 with a hose system arranged in the interior 8th , In this embodiment, the hose system 8th designed as a closed, flat structure that extends along the tank bottom 17 and a sloping wall 18 extends. From the connection lines 6 . 7 and the connected plenums branching out single thin channels 19 from running parallel. Parallel channels have the advantage that the total flow can be made even with thin channels without greater flow resistance, that the interruption of a single channel does not equal to the total failure and that the heat dissipation occurs more uniformly over the entire surface. The arrangement also on the wall slopes 18 is made possible because it is not harmful in contrast to an electric heating in the embodiment according to the invention with a heating fluid flowing through the hose system when a part of the hose system protrudes from the reducing agent. Nevertheless, there can be no overheating in this area. It then takes place only no heat transfer.

Outside on the tank wall is a mounting flange 20 attached, which has an opening for introducing the hose system 8th closes in the tank. In this case, the mounting flange 20 at least the two connections for the connection lines (not shown).

Claims (12)

Reducing agent system for motor vehicles with a heated reducing agent tank, characterized in that the reducing agent is heated in the tank by a heating fluid flowed through hose system with a water heater, the hose system forms a closed heating circuit with the water heater. Reducing agent system according to claim 1, characterized in that the instantaneous water heater is an electrically heated instantaneous water heater. Reducing agent system according to claim 2, characterized in that the water heater has a PTC heating element. Reducing agent system according to claim 1, characterized in that the water heater is designed as a heat exchanger between the heating fluid and a second thermal fluid, in particular the coolant of a motor vehicle. Reducing agent system according to at least one of the preceding claims, characterized in that the water heater is designed both as an electrically heated water heater and as a heat exchanger between the first heating fluid and a second thermal fluid. Reducing agent system according to claim 5, characterized in that a suitable temperature management system controls the water heater so that it is operated alternatively as an electric instantaneous water heater or as a heat exchanger with a second thermal fluid. Reducing agent system according to at least one of the preceding claims, characterized in that the tube system is designed as a flat structure with a plurality of heating fluid-flow channels arranged in parallel. Reducing agent system according to claim 7, characterized in that the hose system is made primarily of a polyolefin, in particular polypropylene or polyethylene. Reducing agent system according to claim 7, characterized in that the hose system is arranged in the tank interior and / or on the tank outside. Reducing agent system according to at least one of the preceding claims, characterized in that the heating fluid is guided by means of a pump in a forced circulation through the hose system and the water heater. Reducing agent system according to claim 10, characterized in that the flow heater and the pump are designed in a thermally conductive connection as a common structural unit. Reducing agent system according to at least one of the preceding claims, characterized in that the heating fluid in addition to the heating of other components such as filters, delivery module or reducing agent lines, in particular the dosing, is used.

Images