DE102016224233A1 - Reductant injection device - Google Patents

Abstract

A reducing agent injection device (2) for injecting a fluid reducing agent (34, 38) into an exhaust line (4) of an internal combustion engine (6) has a tank (8) adapted to store the fluid reducing agent (34, 38); a metering device (10) which is designed to meter in fluid reducing agent (34, 38) into the exhaust line (4); a pumping device (12) which is adapted to remove reducing agent (34) from the tank (8) and to supply it by means of a pressure line (22) to the metering device (10) under increased pressure; and a return line (24) connected to the pressure line (22) for returning excess reducing agent not metered by the metering device (10) into the exhaust line (4) into the tank (8). At a in the tank (8) arranged end of the return line (24) has a nozzle (30) is formed.

Description

The invention relates to a reducing agent injection device, which is designed for injecting a fluid reducing agent into the exhaust gas line of an internal combustion engine.

State of the art

To de-sting the exhaust gases of internal combustion engines, especially diesel engines, the SCR technology ("selective catalytic reduction") has proven itself. For this purpose, systems have been developed which allow compliance with the required exhaust emission limits by a defined addition of a denoxing liquid, in particular aqueous urea solution ("AdBlue®"), as a reducing agent in the exhaust line of the internal combustion engine and the reduction of nitrogen oxides in a subsequent SCR catalyst. Such systems essentially comprise a tank for storing the urea solution, a delivery module with a filter and pump unit, which is provided to remove the denoxing liquid from the tank and feed it to a metering module, a metering module, which is arranged on the exhaust line of the internal combustion engine, and a control unit.

Aqueous urea solution freezes at temperatures below -11 ° C. The freezing point of the aqueous urea solution can not be lowered further without impairing the functionality as a reducing agent.

The operation of the exhaust gas purification system at temperatures below the freezing point of the denoxing liquid is therefore problematic.

A heating element possibly present in the filter and pump unit merely thaws the fluid within and in the immediate vicinity of the filter and pump unit, so that the fluid within the filter and pump unit and in its suction region is liquid. Wide areas of the sometimes highly fissured interior of the tank are not reached by the heat of the heating element, so that the denoxing remains frozen in these areas.

One possible solution for designing the tank with heating mats is very expensive, and there is no standardized interface for making electrical contact with the filter and pump unit.

It is an object of the invention to provide an improved solution for thawing frozen denoxing fluid in the tank of a reductant injector.

Disclosure of the invention

According to an embodiment of the invention, a reducing agent injecting device provided for injecting a fluid reducing agent ("denoxing liquid") into an exhaust passage of an internal combustion engine includes a tank configured to store the fluid reducing agent; a metering device, which is designed to meter the reducing agent into the exhaust gas line; a pumping device configured to remove the reducing agent from the tank and supply it to the metering device through a pressure line at elevated pressure; and a return line connected to the pressure line for returning excess reducing agent not metered into the exhaust line by the metering device into the tank. At a disposed within the tank end of the return line, a nozzle is provided, which makes it possible to introduce the recycled into the tank fluid reducing agent at an increased speed and in a predetermined direction in the tank.

A method for thawing of reducing agent in the tank of a reducing agent injection device according to the invention comprises, according to an embodiment of the invention, to operate a pumping device to remove reducing agent from the tank and deliver it under increased pressure in the pressure line. The method further comprises returning at least a portion of the reductant from the pressure line through a return line and a nozzle formed at the end of the return line into the tank.

According to a basic idea of the invention, an overpressure safety device of the pressure line is used to return heated fluid under increased pressure to the tank where it is distributed so that specifically frozen areas of the tank are streamed and thawed.

In one embodiment, the nozzle is heatable. This makes it possible to thaw frozen reducing agent in the nozzle to allow reducing agent flow through the nozzle from the beginning.

In one embodiment, the nozzle is formed integrally with the return line. An integrally formed with the return line nozzle allows a particularly simple and inexpensive production and installation of the reducing agent injection device.

In one embodiment, the nozzle is designed as an attachment to the return line. This makes it possible to manufacture the nozzle independently of the return line and the respective needs select, dimension and / or set up accordingly.

In one embodiment, the spray direction of the nozzle is adjustable, so that the outlet direction of the reducing agent from the nozzle can be easily changed and adapted to the particular needs, in particular to the geometry of the tank.

In one embodiment, a return line check valve is formed in the return line. The return line check valve is in particular designed so that it only opens when a predetermined pressure in the pressure line and / or in the return line is exceeded. In this way it is achieved that the reducing agent is compressed to a predetermined pressure and thereby heated, before it is returned to the tank.

Alternatively or additionally, a flushing pump may be formed in the return line. By a rinsing pump arranged in the return line, the pressure of the fluid reducing agent in the return line can be increased, so that the fluid reducing agent can always be introduced into the tank with sufficient pressure, in particular also in an operating state in which the dosing module is open.

In one embodiment, a pressure line check valve is formed in the pressure line to prevent unwanted return of reducing agent into the pumping device.

In one embodiment, the method comprises closing the metering device and not metering a reducing agent from the pressure line through the metering device into the exhaust gas line. In this way, all the reducing agent delivered by the pumping device is used to thaw frozen reducing agent in the tank. Frozen reductant in the tank can be thawed so effectively and quickly.

In one embodiment, the method comprises dosing a portion of the reducing agent from the pressure line through the metering device into the exhaust gas line. In this way, frozen reductant in the tank can be thawed in parallel with the operation of the reductant injector. The reducing agent injection device can thus already be used for exhaust gas purification before the entire reducing agent stored in the tank has been thawed.

figure description

In the following, a possible embodiment of the invention will be described in more detail with reference to the accompanying figure.

The figure shows schematically an embodiment of a reducing agent injection device 2 according to an embodiment of the invention.

The reductant injector 2 comprises a metering device 10 at an exhaust system 4 an internal combustion engine 6 attached to fluid reducing agent 34 . 36 . 38 in the exhaust system 4 of the internal combustion engine 6 inject.

That in the exhaust system 4 to be injected reducing agent 34 . 36 . 38 is in a tank 8th saved.

A pumping device 12 is provided, reducing agent 34 . 36 . 38 through a fluid extraction line 20 from the tank 8th to remove and the metering device 10 through a pressure line 22 under increased pressure.

The pumping device 12 includes one of a motor 14 driven pump 15 as well as two one-way valves 16 . 18 , one of each one upstream and downstream of the pump 15 is arranged.

The pumping device 12 may comprise a filter, not shown in the figure, in particular upstream of the pump 15 is arranged to help prevent the debris from the tank 8th into the pump 15 and / or the metering device 10 penetrate and clog and / or damage.

The pumping device 12 is schematically outside the tank in the figure 8th shown. The pumping device 12 can, in particular as an integrated filter and pump unit, which the pump 15 and a filter, even inside the tank 8th , especially at the bottom of the tank 8th be arranged.

In addition, there is a control device 28 , in particular an electronic control device 28 , provided, which is designed, the engine 14 the pump 15 and the metering device 10 to control that a desired amount of reducing agent 34 . 36 . 38 in the exhaust system 4 of the internal combustion engine 6 is injected.

Downstream of the pumping device 12 , in particular between the output of the pumping device 12 and the metering device 10 , branches a return line 24 from the pressure line 22 from.

That of the pressure line 22 opposite end of the return line 24 ends in the tank 8th , At this inside the tank 8th arranged end of the return line 24 is a nozzle 30 trained to that through the return line 24 in the tank 8th recycled reducing agents 34 . 36 . 38 to compress and targeted into the tank 8th contribute.

In the return line 24 is a one-way return valve 26 so arranged that reducing agent 34 . 36 . 38 from the pressure line 22 in the tank 8th but not from the tank 8th in the pressure line 22 can flow.

Within or in the vicinity of the fluid intake point, ie the end of the fluid removal line 20 in the tank 8th , and / or the nozzle 30 is an electric heater 32 intended. The electric heater 32 is also controlled by the controller 28 controlled to at the beginning of operation frozen reducing agent 36 located in the vicinity of the sampling point and / or the nozzle 30 is thawing. The electric heater 32 can be at least partially directly in the nozzle 30 be arranged to from the beginning of a fluid flow through the nozzle 30 to enable.

As soon as, for example, by the electric heater 32 , some reducing agent 34 at the intake of the fluid removal line 20 may have thawed, the promotion may begin.

In this case, the metering device 10 initially remain closed, so none of the pumping device 12 promoted reducing agent 34 . 38 in the exhaust system 4 is injected. This increases the pressure in the pressure line 22 indicating the output of the pumping device 12 with the dosing device 10 connects until the return valve 27 opens. That of the pumping device 12 subsidized reducing agents 34 . 38 is now through the return valve 26 and the return line 24 back to the tank 8th guided.

By compressing (increasing the pressure) the energy in the reducing agent becomes 34 . 38 increased, as well by the relaxation at the outlet of the return line 24 inside the tank 8th , The outlet of the return line 24 is as a nozzle 30 formed or with a nozzle 30 Mistake. Thereby, the flow rate of the recirculated fluid reducing agent 38 further increased.

By suitable alignment of the nozzle 30 can the direction of the reducing agent jet 38 in the tank 8th be aligned so that it is as far as possible in the tank 8th extends.

Due to the high viscosity of the reducing agent 34 . 36 . 38 at low temperatures, the reducing agent jet breaks 38 also reducing agents 36 . 38 in its environment with, so that the reducing agent 34 . 36 . 38 in the entire volume of the tank 8th mixed well and thawed.

Claims (10)

Reducing agent injection device (2) for injecting a fluid reducing agent (34, 38) into an exhaust line (4) of an internal combustion engine, (6) with: a tank (8) adapted to store the fluid reducing agent (34, 38); a metering device (10) which is designed to meter in fluid reducing agent (34, 38) into the exhaust gas line (4); a pumping device (12), which is adapted to remove reducing agent (34) from the tank (8) and to supply the dosing device (10) through a pressure line (22) under increased pressure; and a return line (24) connected to the pressure line (22) for returning excess reducing agent, which is not metered by the metering device (10) into the exhaust line (4), back into the tank (8); wherein at a in the tank (8) arranged end of the return line (24) has a nozzle (30) is formed. Reductant injector (2) according to Claim 1 , wherein the nozzle (30) is heatable. Reductant injector (2) according to Claim 1 or 2 wherein the nozzle (30) is formed integrally with the return line (24). Reductant injector (2) according to Claim 1 or 2 , wherein the nozzle (30) is designed as an attachment to the return line (24). Reducing agent injection device (2) according to one of the preceding claims, wherein the spray direction of the nozzle (30) is adjustable. Reducing agent injection device (2) according to one of the preceding claims, wherein in the return line (24) a return line check valve (26) is formed, and / or wherein in the pressure line (22) a pressure line check valve (18) is formed. A method of thawing reductant in the tank (8) of a reductant injector (2) according to any one of the preceding claims, the method comprising: operating the pumping device (12) to remove reductant (34) from the tank (8) and deliver under increased pressure in the pressure line (22); and at least a portion of the reducing agent (34) from the pressure line (22) through the return line (24) and the nozzle (30) in the tank (8) due. Method according to Claim 7 wherein the method comprises heating the nozzle (30). Method according to Claim 7 or 8th wherein the method comprises dosing a portion of the reducing agent (34, 38) from the pressure line (22) through the metering device (10) in the exhaust line (4). Method according to Claim 7 or 8th wherein the method comprises closing the metering device (10) and not metering reducing agent from the pressure line (22) through the metering device (10) into the exhaust line (4).

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