DE102008002467A1 - Dosing system for a liquid medium, in particular urea-water solution - Google Patents

Abstract

The invention relates to a dosing system for a liquid reduction medium enabling precise dosing of the reduction medium in the exhaust gas system of an internal combustion engine. This is carried out particularly by using a quick and safe closing of a pressure-actuated dosing valve. Simultaneously, the dosing system according to the invention also enables the dissipation of the pressure impulses resulting due to the closing movement of the dosing valve.

Description

State of the art

The Emission limit values for nitrogen oxides in motor vehicles whose weight exceeds a certain limit, exhaust aftertreatment devices, the Selective Catalytic Reduction (SCR) of the raw emissions the internal combustion engine contains nitrogen oxides. This so-called SCR process for exhaust gas purification is known from the prior art, so that For a detailed explanation of this procedure can be dispensed with ongoing chemical processes.

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 help of a metering valve as needed in an exhaust pipe of the internal combustion engine. That from the DE 10 2006 012 855 A1 known metering valve is pressure-actuated. This means that it opens as soon as a predetermined opening pressure is exceeded at the inlet of the metering valve. As soon as the opening pressure is fallen below, the dosing valve closes again.

The pressure-operated metering valve is a "passive" component, which does not require its own control. Also are signal lines or control lines from a control unit to the metering valve not mandatory.

Disclosure of the invention

Of the Invention is based on the object, a dosing of the above further developed in such a way that the functional properties, in particular the precision with the reducing agent in the exhaust pipe is injected, is improved. Furthermore should tightness of the metering valve during operation and be increased after switching off the internal combustion engine.

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, with a tank, with a metering pump and with a metering valve, wherein a pressure side of the diaphragm pump and the metering valve by a first line are connected and where the tank and a suction side of the metering pump through a second line with each other are connected, solved in that in the first line a first check valve is provided.

The first check valve prevents the first Drain between two actuations of the metering valve. This would mean that in the subsequent operation the metering pump is not specified by an engine control unit Amount of urea water solution is injected. Thereby would suffer the quality of the exhaust aftertreatment and emissions rise.

In further advantageous embodiment of the invention is provided that a stroke of the metering pump at least partially on the Transfer valve member of the first check valve becomes.

This means that, starting from a dormant state of the metering pump First, the metering pump executes a delivery and the liquid reducing agent in the first conduit promotes. This opens at a delivery stroke Valve member of the first check valve as soon as the pressure in the metering pump is greater than the opening pressure the first check valve, and the promotion from reducing agent to the metering valve begins.

By the transmission of the invention Lifting movement of the metering pump on the valve member is namely ensures that the first check valve during the suction stroke regardless of the pressure conditions remains open. As a result, a predetermined amount of urea water solution from the first line again sucked back into the dosing pump, so a controlled and rapid pressure reduction takes place in the first line and in the metering valve. As a result, the metering valve closes quickly and tightly, so that the dosage of the reducing agent with higher accuracy he follows.

Short before the dosing pump has reached its starting point and the stroke the metering pump is equal to zero, the strokes of the metering pump and the valve member decoupled, so that the first check valve can fulfill its function known from the prior art and hydraulically disconnects the first line from the metering pump.

After all is due to the coupling of valve member and stroke of the metering pump facilitates the venting of the dosing. If a compressible medium, such as air or steam, in a pumping room the metering pump is located, can through the forced opening the first check valve are ensured that located in the delivery chamber of the metering pump Air or the steam is ejected into the first line and thereby a Bleeding the metering takes place. As soon as only liquid reducing agent in the metering pump available is, promotes them fully again and pushes the in too the suction line existing vapor bubbles or air bubbles in the course the time through the metering valve from the dosing system.

Around a safe closing and a better operating behavior Achieve is further provided that the first check valve spring loaded.

In further advantageous embodiment of the invention is further provided that the first check valve as a double-acting check valve is formed, and that a second output of the first check valve with the tank via a connecting line hydraulically in Connection stands. This will cause an unwanted and reopening of the Dosing valve after switching off the metering prevented.

at the promotion of liquid reducing agent by the metering pump opens the first check valve and the reducing agent passes from the metering pump into the first Management. After the promotion and injection of the reducing agent through the metering valve in the exhaust system that closes first check valve again. By closing the metering valve creates a pressure surge in the first Line connected to a single acting check valve is reflected and runs back to the metering valve. There, the surge can be a short-term opening of the metering valve. As a result, one will not negligible amount of the reducing agent unintentionally injected into the exhaust pipe. This effect increases with increasing Closing speed of the metering valve too.

If now the first check valve as a double acting check valve is formed, then closes the check valve while conveying the dosing pump a connecting line between the first line and the tank of the dosing system. In this Position behaves the dosing system, not unlike an inventive dosing with a simple trained non-return valve.

If but the delivery stroke of the dosing pump is finished, that will Valve member of the double-acting check valve again pressed into the valve seat and the hydraulic connection between metering pump and metering valve is interrupted. simultaneously is via the connecting line a hydraulic connection made between the first line to the non-pressurized tank, so an outgoing from the metering pressure surge is not the first Check valve is reflected, but in the tank runs and is dissipated there. This will make the top described unwanted Nachspritzer due to pressure surges avoided within the dosing system.

In further advantageous embodiment of the invention is provided that in the connecting line, a pressure-holding valve, in particular an adjustable pressure relief valve is provided. The opening pressure the pressure holding valve is chosen to be lower is as the opening pressure of the metering valve, as only then reliably prevents the reflection of pressure surges can be. However, it is due to the holding pressure of the pressure holding valve possible, the vapor bubble formation within the first conduit or suppress the dosing and thereby the Function and accuracy with which the reducing agent is injected and metered, to further improve.

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 , 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.

The metering system according to the invention comprises the metering valve 13 , a dosing pump 15 as well as a storage tank 17 , The dosing pump 15 is in 1 only shown as "black box". Details are given below with reference to 2 and 3 explained.

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 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 wiring connection between the control unit 29 and the dosing pump 15 is by a dashed arrow (without reference numeral) in 1 shown.

Based on 2 a first embodiment of a metering system according to the invention is shown and explained. The same components are provided with the same reference numerals and as with respect to the 1 said accordingly. The metering valve 13 is shown schematically as a spring-loaded valve.

The dosing pump 15 is as a diaphragm pump with a membrane 31 educated. The membrane 31 the dosing pump 15 is powered by an electromagnet, comprising a coil 33 and an anchor 35 , pressed. If the coil 33 energized, the anchor moves 35 and with it the membrane 31 in 2 up and performs a delivery stroke. The stroke H is in 2 shown. In the 2 illustrated rest position of the membrane 31 and the anchor 35 corresponds to a stroke H = 0.

Between a conveyor room 37 the dosing pump 15 and the first line 19 is a first check valve 39 arranged. The first check valve 39 is in 2 as a flutter valve comprising a valve member 41 and a valve seat 43 shown. In these flutter valves, the valve member 41 as elastic membrane made of a plastic, such as EPDM, or metal. A feather 44 exerts a force in the closing direction of the first check valve 39 on the valve member 41 out.

The lifting movement of the membrane 31 is about a pestle 45 partly on the valve member 41 transfer. This happens because in the rest position of the membrane 31 and with the first check valve closed 39 the pestle 45 not on the membrane 31 rests.

Between the membrane 31 facing the end of the plunger 45 and the membrane 31 is a distance H _MIN in this state. Once the stroke H is greater than H _MIN , lift the membrane with the help of the plunger 45 the valve member 41 from the valve seat 43 from. This coupling of the valve member 41 with the stroke H of the membrane 31 the metering pump causes the first check valve 39 , regardless of the pressure conditions in the first line 19 and in the pump room 37 remains open for a long time during the suction stroke. As a result, by the suction movement of the membrane 31 part of the first line 19 located reducing agent back into the delivery room 37 sucked back. This results in a pressure reduction in the line 19 instead of and the metering valve 13 closes quickly and tightly.

Between the pump room 37 and the second line 21 is a second check valve 46 arranged, which prevents during the delivery stroke of the metering pump 15 Reducing agent from the pump room 37 in the second line 21 and the tank 17 can flow back. This second check valve 46 is usually not spring loaded. It is also often designed as a flutter valve, although it is in 2 and 3 symbolically represented as a ball valve.

In 3 is a further embodiment of a metering system according to the invention shown. In this embodiment, the first check valve 39 designed as a double-acting check valve and symbolically represented as a ball valve, although it is also usually a flutter or sniffer valve. The first check valve 39 not only has the first valve seat 43 on, but also a second valve seat 47 , whose output via a connecting line 49 and the second line 21 with the tank 17 hydraulically communicating. As soon as the dosing pump 15 begins with the promotion of reducing agent, the pressure in the pump room increases 37 over in the first line 19 prevailing pressure. As a result, the valve member lifts 41 from the first valve seat 43 off and closes the connection line 49 because it seals on the second valve seat 47 is pressed. At the same time thereby the hydraulic connection between the delivery chamber 37 and first line 19 Released and the promotion of reducing agent in the first line 19 starts. The delivery stroke is the same in the second embodiment, as in the first embodiment according to 2 explained.

Now when the promotion has ended and the membrane 31 returns to their original position, ensure the pressure conditions in the first check valve 39 for that the valve member 41 again against the first valve seat 43 is pressed and thereby the hydraulic connection between the pumping chamber 37 and first line 19 is interrupted. At the same time, a hydraulic connection between the first line 19 , Connecting line 49 , second line 21 and tank 17 open, so possibly from the metering valve 13 outgoing pressure surges in the tank 17 run and be dissipated there.

Optional is in the connection line 49 a pressure-holding valve 51 intended. The pressure holding valve 51 serves to set an adjustable minimum pressure in the first line 19 so that the boiling point of the reducing agent in the first lei tung 19 increases and the formation of vapor bubbles is suppressed. Advantageously, the opening pressure of the pressure holding valve 49 lower than the opening pressure of the metering valve 13 so that the closing movement and the sealing of the metering valve 13 through the pressure retention valve 51 can not be prevented. In addition, this can pressure surges whose amplitude is higher than the opening pressure of the pressure holding valve 51 almost unhindered in the tank 17 continue to run and be dissipated there.

In a particularly advantageous embodiment of the invention, the pressure-retaining valve 51 adjustable with respect to its holding pressure, so that it can be adjusted according to the prevailing operating conditions. This makes it possible, for example, after stopping the engine to change the holding pressure, so that the first line 19 is completely depressurized and thus the metering valve 13 is completely tight over a longer period of time. If the risk of vapor bubble formation occurs during operation of the internal combustion engine, the holding pressure of the pressure holding valve 51 be increased accordingly.

In 3b is a block diagram of the embodiment according to 3a shown. In addition, there are still different pressure sensors 53.1 . 53.2 and 53.3 shown, installed as needed and with the control unit 29 get connected.

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, 0002]

Claims (10)

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 ) and with a metering valve ( 13 ), wherein a pressure side of the metering pump ( 15 ) and the metering valve ( 13 ) by a first line ( 19 ) and the tank ( 17 ) and a suction side of the metering pump ( 15 ) by a second line ( 21 ), characterized in that in the first line ( 19 ) a first check valve ( 39 ) is provided. Dosing system according to claim 1, characterized in that a lifting movement of the metering pump ( 15 ) at least partially on the valve member ( 41 ) of the first check valve ( 39 ) is transmitted. Dosing system according to claim 2, characterized in that the dosing pump a membrane ( 31 ), and that the lifting movement (H) of the membrane ( 31 ) at least partially on the valve member ( 41 ) of the first check valve ( 39 ) is transmitted. Dosing system according to claim 3, characterized in that the valve member ( 41 ) of the first check valve ( 39 ) from a first valve seat ( 43 ) is lifted as soon as the stroke movement of the metering pump ( 15 ) exceeds a minimum lift (H _min ). Dosing system according to one of the preceding claims, characterized in that the first check valve ( 39 ) is spring loaded. Dosing system according to one of the preceding claims, characterized in that the first check valve ( 39 ) is designed as a double-acting check valve, and that a second valve seat ( 47 ) of the first check valve ( 39 ) with the tank ( 17 ) or the suction side of the metering pump ( 15 ) via a connecting line ( 49 ) communicates hydraulically. Dosing system according to claim 5, characterized in that in the connecting line ( 49 ) a pressure-holding valve, in particular an adjustable pressure-maintaining valve ( 51 ), is provided. Dosing system according to one of the preceding claims, characterized in that in the second line ( 21 ) a second check valve ( 46 ) is provided. Dosing system according to one of the preceding claims, characterized in that the metering valve ( 13 ) is pressure actuated. Dosing system according to one of the preceding claims, characterized in that the diaphragm pump ( 15 ) of an actuator of an actuator, in particular an armature ( 35 ) of an electromagnet ( 33 ) is pressed.