DE102008042954A1 - Dosing system for a liquid medium, in particular urea-water solution - Google Patents

Abstract

A dosing system for a liquid medium, in particular a liquid reducing agent, is proposed, in which a first suction lance 37 and a second suction lance 39 are jointly guided through a heating pot 31 and the first suction lance 37 is subsequently led out of the heating pot 31 again. In the heating pot 31 is an electric heater 45. The inventive arrangement, it is possible with relatively low electric power to thaw the frozen reducing agent located in the heating pot 31 quickly and at the same time to ensure that the first suction lance 37 is activated only when a sufficient amount of reducing agent has already been liquefied.

Description

State of the art

The Above all, emission limits for nitrogen oxides require Exhaust after-treatment devices for heavy vehicles, the Selective Catalytic Reduction (SCR) of the raw emissions Make the internal combustion engine contained nitrogen oxides. This so-called SCR process for the exhaust gas cleaning is from the state of Technique known, so on a detailed explanation the chemical processes occurring in this process can be waived.

An example of such an exhaust aftertreatment device is from the DE 10 2006 012 855 A1 known. There, an aqueous urea solution is stored in a tank and injected by a metering pump and with the aid of a metering valve as needed in an exhaust pipe of the internal combustion engine.

The Freeze today customary liquid reducing agent depending on the added protective agents at temperatures between -11 ° C and -40 ° C. Because even at low temperatures Pollutants must be reduced, the reducing agent thawed first. At cars will be for this purpose an electric heater used in the tank of the dosing system.

There the SCR system due to the legal requirements even at low Temperatures must be ready within a given time, is a heater that helps thaw the frozen reductant is achieved quickly, indispensable.

Disclosure of the invention

There However, the on-board electrical system only a limited electrical power is an efficient thawing of the reducing agent in the tank is particularly important, at the same time the intake of air into the dosing reliably prevented become.

These Object is according to the invention in a metering system for a liquid medium, in particular a liquid Reducing agent, such as an aqueous urea-water solution (HWL), with a tank, with a dosing pump and with a dosing valve, wherein the metering pump and the metering valve by a first line connected to each other, wherein the tank and the metering pump by a second line are connected to each other, wherein the tank has a Heating pot includes an electric heater, the second Line at its tank-side end a first suction lance and a second suction lance, wherein the first suction lance outside the heating pot opens into the tank and wherein the second suction lance opens into the heating pot, solved by the first lance is passed through the heating pot.

By the installation / guide according to the invention the suction lance through the heating pot is ensured that the frozen reducing agent located in the first suction lance defrosts. Furthermore, this results in a simplification of production and assembly, since it is possible according to the invention is, the first suction lance and the second suction lance of an extruded tube or pipe with two parallel channels inexpensive and easy to manufacture. This extruded Raw material with two parallel channels will be at different Cut to length, leaving the channel, which is the first Suction lance forms, is longer and through the heating pot can be led into the tank. The channel which the second suction lance forms is correspondingly shorter, so that the suction opening of the second suction lance into the heating pot empties.

By this arrangement on the one hand ensures that in the heating pot Reducing agent is thawed and liquefied and also the first and second suction lances are reliably thawed become. Because the first suction lance but again from the heating pot is led out, the suction port of the first Suction lance still much longer of frozen reducing agent closed, so first exclusively the thawed reducing agent in the heating pot through the second suction lance sucked and conveyed to the metering valve.

By a suitable adjustment of the lengths of the first suction lance and second suction lance and a suitable positioning of the suction opening the first suction lance in the tank is outside the heating pot It is possible to delay the time between thawing of the reducing agent in the heating pot and thawing located at the suction port of the first suction lance Reductant according to the application within wide limits to design.

If namely the first suction lance thawed too early and thus activated, the case may occur that in the tank insufficiently liquefied reducing agent is present is and the first suction lance sucks in air ,. This will make the dosing system is at least impaired in its function.

Since in modern cars usually the space is very scarce, it is necessary, the tank and the internals therein, such as heating pot, suction lances and electric heating, kom kom as possible train the pact. At the same time, of course, the safe operation of the metering system should be guaranteed under all circumstances and even at the lowest outside temperatures. For this reason, an additional suction cup is provided in a further inventive embodiment of the dosing below the heating pot, wherein the first suction lance opens into the suction cup.

By This additional suction cup can reduce the volume of frozen Reducing agent, which is in the immediate vicinity of Suction opening of the first suction lance is clearly defined become. This makes it possible to target in three steps first the reducing agent in the heating pot and the suction lances Thaw in a second step in the suction cup Part of the first suction lance and the reducing agent in the suction cup Then, in a third step Thawing the remaining tank reducing agent. On the one hand, this three-step approach becomes an efficient one Thawing achieved and on the other hand ensured that the delay between thawing the activation of second suction lance and first suction lance is sufficiently large.

By the inventive thermal decoupling between Heating pot and suction cup is another parameter for control the delay between activating second suction lance and first suction lance available. This thermal decoupling Naturally, by choosing a suitable Container material for both the heating pot as also be taken for the suction cup. For example This may be a poorly heat-conducting plastic. This is particularly useful when heating pot and suction cup be made in one piece.

A further advantageous possibility for thermal decoupling of heating pot and suction cup is an inlet opening provided in the suction cup, which is spaced in the installation position of the tank in a vehicle to the highest point in the vertical direction of Saugtopfvolumens is arranged. This inventive arrangement the inlet opening allows an air cushion form at the upper end of the suction cup, which serves for thermal insulation.

To if one uses the frequently carried out deaeration process of the metering after stopping the engine off. For this purpose, the conveying direction of the metering pump is reversed and the metering valve is opened so that from the exhaust pipe of the Internal combustion engine sucked air or exhaust gases and through conveyed the first line and the second line in the suction lances become. This exhaust gas displaced in the inventive arrangement the inlet opening that above the inlet opening located reducing agent and thereby forms an air cushion. This air cushion serves as an elastic element, which when freezing the reducing agent yields and thereby bursting prevents the suction cup. Furthermore, this gas cushion is used as thermal insulation between the heating pot and the in the suction cup located frozen reducing agent. in further advantageous embodiment of the invention Dosing system opens the suction line in a filter housing with a filter inlet opening, wherein in the filter housing and / or a filter element is provided in the filter inlet opening is. This can ensure that no impurities or partially frozen particles of reducing agent in the first suction line to be sucked and this suction line possibly clog. Because the heater is located in the heating pot, this will do so cause the reducing agent in the heating pot is heated quickly and with high heat output and after the thawed reducing agent was thawed in the heating pot, the heating power reduced becomes. This thaws the thawing of the suction cup located reducing agent, so that the inventive desired delay time between thawing the second suction lance and the activation of the first suction lance on increases.

In further advantageous embodiment of the invention Heating can be provided, the heating as so-called self-regulating or PTC heating (PTC = positive temperature coefficient) may be provided be that the power of the heater is reduced when the reducing agent in the immediate vicinity of the heating is fluid, and that the electric heater is turned off when the heater surrounded by air.

The funded by the dosing pump excess Reducing agent is via a return line in the tank, preferably in the heating pot of the tank, returned. This ensures that there is always a sufficient amount of liquid Reducing agent is present in the heating pot and only if the Heating pot is filled by an overflow still available liquid reducing agents in the Tank flows and there thaws the existing reducing agent.

Around to ensure that in normal operating condition, the means, if only liquid Reducing agent is present in the tank and in the suction cup, the first Suction lance prefers the reducing agent sucks, which promotes the metering pump, is a throttle element in the first suction lance and / or the second Suction lance arranged.

This makes it possible, the Strömungswi the resistance of the first suction lance to make smaller than the flow resistance of the second suction lance, so that it is ensured in the simplest way that the first suction lance substantially sucks the reducing agent. For this reason, it is also particularly effective to provide a filter with a filter element on the first suction lance, which draws in the majority of the reducing agent during normal operation.

A particularly cost-effective variant for the preparation of the invention first and second suction lance is to make a pipe or a hose to extrude or otherwise form a plastic, wherein in this hose or tube two parallel channels available. These channels are in different places cut to length and thereby give suction lances with different Length.

Further Advantages and advantageous embodiments of the invention are the subsequent drawing, the description and the claims removable. All in the drawing, the description and the claims disclosed features can be used both individually and in Any combination with each other essential to the invention.

It demonstrate:

1 the schematic structure of a metering system according to the invention and

2 . 3 Embodiments of metering systems according to the invention.

In 1 is an internal combustion engine 1 with an exhaust aftertreatment device 3 greatly simplified and shown schematically. The exhaust aftertreatment device 3 includes an exhaust pipe 5 , an oxidation catalyst 7 and an SCR catalyst 11 , Not shown is a particulate filter, which is usually downstream of the oxidation catalyst 7 is arranged. The flow direction of the exhaust gas through the exhaust pipe 5 is indicated by arrows (without reference numerals).

To the SCR catalyst 11 to supply reductant is upstream of the SCR catalyst 11 at the exhaust pipe 5 a metering valve 13 arranged for the reducing agent. The metering valve 13 if necessary, injects reductant upstream of the SCR catalyst 11 in the exhaust pipe 5 one. In some applications, there is a metering valve 13 and SCR catalyst 11 nor provided an unillustrated mixer.

The metering system according to the invention comprises the metering valve 13 , a dosing pump 15 as well as a storage tank 17 , The metering valve 13 is shown schematically as a spring-loaded valve. Between the dosing pump 15 and the metering valve 13 is a first line 19 intended. Between the tank 17 and the dosing pump 15 is a second line 21 intended. The Tank 17 is in 1 shown as a "black box". Details of the tank according to the invention 17 will be described below on the basis of 2 and 3 explained.

From the first line 19 branches a return line 22 with a throttle 24 from. About the return line 22 will excess reducing agent in the tank 17 recycled.

Of course, the return line could 22 also from the dosing valve 13 or the dosing pump 15 branch.

The sake of completeness is still on the arranged in the exhaust system sensors, namely a NOX sensor 25 , as well as temperature sensors 23 and 27 pointed. These sensors 23 . 25 and 27 are via signal lines (no reference numeral) with a control unit 29 the internal combustion engine connected. This controller 29 controls the internal combustion engine 1 and also the dosing pump 15 , The signal connection between the control unit 29 and the dosing pump 15 is in 1 represented by a dashed arrow (not numbered).

In 2 is a first embodiment of an inventively designed tanks 17 cut and shown schematically.

In the tank 17 There is a heating pot 31 and a suction cup 33 , The heating pot 31 and the suction cup 33 can be made of one piece, such as plastic. Alternatively, it is also possible to produce the two parts separately and then to connect to each other, for example by a snap connection or by welding.

Through the heating pot, a specially shaped tube with two channels is passed from top to bottom. This hose 35 forms a first suction lance 37 with a channel and a second suction lance 39 with the other channel. In the left part of the 2 is a section along the line AA through the hose 35 shown. By cutting off the channels, which the first suction lance 37 and the second suction lance 39 At different altitudes it is possible to make the suction openings 41 the first suction lance 37 and the suction opening 43 the second suction lance 39 spaced from each other. This ensures that the suction opening 43 the second suction lance 39 in the heating pot ends and the suction opening 41 the first suction lance 37 by doing Saugtopf 33 empties.

In the lower part of the heating pot is an electric heater 45 intended. The electrical connections of this heater 45 are not shown. Only indicated is an electrical winding 45.1 around the hose 35 is wound and thereby reliably thawing the suction lances 37 and 39 guaranteed over the entire length within the heating pot. The suction opening 41 the first suction lance 37 is from a flexible filter screen 47 surrounded, so no impurities on the suction lance 37 can be sucked.

How out 2 can be seen, the return line opens 22 in the heating pot 31 so that the excess reducing agent is first in the heating pot 31 is promoted back. When the heating pot 31 is full, the excess liquid reducing agent through an overflow opening 47 in the tank 17 directed.

In 3 is another embodiment of a tank according to the invention 17 shown. Identical components are provided with the same reference numerals and it is the case with respect to the figures said accordingly.

Significant differences between the two embodiments according to 2 and 3 consist in that an inlet opening 51 of the suction cup in the embodiment according to 3 below a lid 53 of the suction cup 33 is arranged. The suction cup 33 is in a swamp 50 of the tank 17 arranged.

The upper end of the inlet opening 51 has a distance S to the lid 53 of the suction cup 33 , This means that if, during the venting of the metering system, exhaust gases or air from the intake tract of the internal combustion engine via the lines 19 and 21 in the suction lances 31 and 39 blown a bubble on the lid 53 of the suction cup is formed. This air cushion is in 3 represented by indicated bubbles. The thickness of this air cushion depends on the distance S. On the one hand, this air cushion serves to form an elastic buffer volume, so that the increase in volume which takes place during the solidification of the reducing agent does not cause the suction cup to burst 33 leads. Furthermore, this air cushion forms a thermal insulation and thus supports the thermal decoupling between the heating pot 31 and suction cup 33 ,

Another difference is that in the embodiment according to FIG 3 the first suction lance 37 in a filter housing 55 empties. In this filter housing 55 is a filter element 47 and a suction opening 57 intended. The distance of the suction opening 41 the first suction lance 37 and the inlet opening 57 in the filter housing 55 is another parameter with the help of which the time delay between the second suction lance 39 in the heating pot 31 opens and the first suction lance 37 in the suction cup 33 flows to control.

QUOTES INCLUDE IN THE DESCRIPTION

This list The documents listed by the applicant have been automated generated and is solely for better information recorded by the reader. The list is not part of the German Patent or utility model application. The DPMA takes over no liability for any errors or omissions.

Cited patent literature

• DE 102006012855 A1 [0002]

Claims (12)

Dosing system for a liquid medium, in particular a liquid reducing agent, such as an aqueous urea-water solution (HWL), with a tank ( 17 ), with a metering pump ( 15 ), with a metering valve ( 13 ), whereby the metering pump ( 15 ) and the metering valve ( 13 ) by a first line ( 19 ) and the tank ( 17 ) and the dosing pump ( 15 ) by a second line ( 21 ), the tank ( 17 ) a heating pot ( 31 ) with an electric heater ( 45 ), wherein the second line ( 21 ) at its tank-side end a first suction lance ( 37 ) and a second suction lance ( 39 ), wherein the first suction lance ( 37 ) outside the heating pot ( 31 ) in the tank ( 17 ), and wherein the second suction lance ( 39 ) in the heating pot ( 31 ), characterized in that the first suction lance ( 37 ) through the heating pot ( 31 ) is passed. Dosing system according to claim 1, characterized in that the tank ( 17 ) below the heating pot ( 31 ) an additional suction cup ( 33 ), and that the first suction lance ( 37 ) in the suction cup ( 33 ) opens. Dosing system according to claim 2, characterized in that the heating pot ( 31 ) and the suction cup ( 33 ) are thermally decoupled. Dosing system according to claim 2 or 3, characterized in that in the suction cup ( 33 ) at least one inlet opening ( 51 ) is provided, and that the at least one inlet opening ( 51 ) in the installation position the tank ( 17 ) in a vehicle (S) to the highest vertical point ( 53 ) of the suction cup ( 33 ) is arranged. Dosing system according to one of the preceding claims, characterized in that the first suction line ( 37 ) in a filter housing ( 55 ) with a filter inlet opening ( 57 ) and that in the filter housing ( 55 ) and / or in the filter inlet opening ( 57 ) a filter element ( 47 ) is provided. Dosing system according to one of the preceding claims, characterized in that the electrical heating ( 45 ) in the heating pot ( 31 ) extending portions of the first suction lance ( 37 ) and second suction lance ( 39 ) heated directly. Dosing system according to one of the preceding claims, characterized in that the electrical heating ( 45 ) is designed as a self-regulating heating, in particular as a PTC heating (PTC = Positive Temperature Coefficient) Dosing system according to claim 7, characterized in that the power of the electric heating ( 45 ) is reduced when the heating is surrounded by liquid medium, and that the electric heating ( 45 ) is switched off when the heating is surrounded by air. Dosing system according to one of the preceding claims, characterized in that a return line ( 22 ) in the tank ( 17 ) and that excess of the metering pump ( 15 ) conveyed liquid medium by means of the return line ( 22 ) in the tank ( 17 ) is promoted back. Dosing system according to one of the preceding claims, characterized in that in the first suction lance ( 37 ) and / or the second suction lance ( 39 ) A throttle element is arranged. Dosing system according to one of the preceding claims, characterized in that a flow resistance of the first suction lance ( 37 ) is smaller than a flow resistance of the second suction lance ( 39 ). Dosing system according to one of the preceding claims, characterized in that the first suction lance ( 37 ) and the second suction lance ( 39 ) are made of a tube or hose with two parallel channels.