Abstract:
A method and an apparatus for metering a reducing agent in which the reducing agent is delivered, via a line and a final control element that regulates the metering, in particular a metering valve, to a catalytic converter assembly for removing nitrogen oxides from the exhaust gases, in particular of a Diesel engine; a pressure drop in the line dictated especially by gas inclusions is detected, and the line is ventilated via the final control element.

Description:
CROSS-REFERENCE TO RELATED APPLICATIONS 
   This application is a 35 USC application of PCT/DE 01/03621 filed on Sep. 20, 2001. 

   BACKGROUND OF THE INVENTION 
   1. Field of the Invention 
   The invention is based on a method and an apparatus for metering a reducing agent, in particular a urea or a urea-water solution, within the context of catalytic exhaust gas posttreatment. 
   2. Description of the Prior Art 
   To attain a reduction of NO x  components in exhaust gases, reduction catalytic converters have been developed especially for Diesel engines; they are typically classified as either so-called SCR catalytic converters (for “Selective Catalytic Reduction”) and storage catalytic converters. The so-called SCR catalytic converters are regenerated by the delivery of a urea and/or ammonia reducing agent, while the so-called storage catalytic converters are regenerated with hydrocarbons from the entrained internal combustion engine fuel, in so-called rich exhaust gas phases. 
   From German Patent Application, serial number 19946 900.8, an apparatus is known which for removing nitrogen oxides from exhaust gases, for instance from a Diesel engine, adds urea as a reducing agent in metered fashion. The metering is done via a valve that releases urea doses that are determined via the electrical triggering of the metering valve, its throttling cross section, and the pressure difference prevailing at the throttle valve. The metering apparatus has a return line for returning excess reducing agent as well as a ventilation line for eliminating gas bubbles made up of air or evaporated reducing agent. 
   SUMMARY OF THE INVENTION 
   The method of the invention and the metering apparatus of the invention have the advantage over the prior art of furnishing simple ventilation and a compact design, with a reduced number of components, of a metering apparatus. A separate ventilation valve is no longer necessary, and the additional lines for such a valve are also dispensed with, making the line course simpler, and correspondingly the volume of fluid that must be heated in the metering device if correct operation is to be achieved is less, which in turn saves both energy and expense. Furthermore, the metering accuracy is improved, since pressure drops in the supply line, for instance from air inclusions or inclusions of evaporated urea-water solution, can be compensated for by adapted metering. Omitting a separate ventilation valve not only saves component costs and time in assembly, but also the entire metering apparatus can be disposed on a smaller housing block. 
   It is especially advantageous to provide an electrically triggerable metering pump, for instance with a stepping motor, as a feed means; this assures need-specific pumping, and by means of only a short bypass that connects the outlet of the metering pump to the suction inlet, a return of excess pumped quantities of fluid can already be assured, so that a separate return line to the urea tank can be omitted. This further simplifies the line course and correspondingly reduces the volumes of fluids that have to be heated for correct operation in the metering apparatus. The omission of a separate return line to the urea tank not only saves component costs and time in assembly, but also the entire metering apparatus can be disposed on a smaller housing block and is simpler to mount in the vehicle, since now only a single connection to the urea tank, that is, the supply line, has to be produced. 

   
     BRIEF DESCRIPTION OF THE DRAWING 
     Exemplary embodiments of the invention are explained in further detail in the ensuing description, taken with the drawing, in which: 
       FIG. 1  shows a metering apparatus put together from a water tank, urea tank, and catalytic converter assembly. 
   

   DESCRIPTION OF THE PREFERRED EMBODIMENTS 
   In  FIG. 1 , reference numeral  1  indicates a urea tank, from which a urea-water solution is carried via a urea line  1   a  to a filter  3  embodied as a filter screen. The filter  3  communicates via a line  12  with a check valve  2 , through which the urea-water solution is aspirated by a feed pump  4 , embodied for instance as a diaphragm pump, and pumped to a metering valve  7  of a mixing chamber  8 . The pump  4  is rpm-controlled via a control motor  4   a , in order to minimize the overflow quantity. An excess quantity pumped is returned to the intake side of the pump via a pressure limiting valve  11 . Compressed air can be introduced from a compressed air tank  20  into the mixing chamber via a compressed air line  2   a , which has a filter screen  21 , a 2/2-way valve  22 , a throttle  23 , and a check valve  24 . An aerosol line  25  leads from the mixing chamber  10  to the catalytic converter  30 , which has an exhaust gas inlet  29  on one side and an exhaust gas outlet  31  on the opposite side. The urea tank  1  is provided with a fill level sensor  52  and a temperature sensor  51 . Between the metering pump  4  and the metering valve  7 , a pressure sensor  50  is disposed in the line  12 . Temperature sensors  53  and  54  measure the temperature of the exhaust gas at the inlet and outlet, respectively, of the catalytic converter  30 . A pressure sensor  55  is also disposed between the 2/2-way valve  22  and the throttle  23 . A temperature sensor  56  measures the temperature of a metal housing block  41 , on which or with which the components outlined by the dashed line carrying this reference numeral are disposed or integrated. A control unit  40  is also mounted on the housing block  41  and is connected electrically to the sensors  50 - 56 , the control motor  4   a  and the metering valve  7 . The housing block  41  is grounded, and the control unit  40  draws the electrical potential of the housing block  41  as its reference potential. Via a CAN data line  39  (CAN stands for “Controlled Area Network”), the control unit  40  is connected to the voltage supply and other electronic components in the motor vehicle, in particular the engine control unit. 
   The metering valve  7  meters the requisite urea-water solution into the mixing chamber  8 . In the mixing chamber, by subjecting the urea-water solution to the compressed air, an aerosol and a wall film are created, which are introduced into the catalytic converter  30  via the aerosol line  25 . To that end, the control unit  40  detects signals on engine operating data, which are received from a higher-order engine control unit via the CAN data line  39 , and also detects the signals of the pressure, temperature and fill level sensors  51 - 56 , which are known per se and will not be explained further here. The control unit  40  furthermore receives an electrical signal from the pressure sensor  50 , from which the course of the pressure over time in the line  12  between the metering pump  4  and the metering valve  7  is obtained. From the sensor information, the control unit  40  calculates a urea metering quantity, which is to be added to the exhaust gas flowing through the catalytic converter  30 . After evaluation of the information, taking the actual pressure values obtained from the sensor  50  into account, the control unit  40  controls the urea-water solution pressure and the pressure in the compressed air line, with the aid of the metering valve  7  and the valve  22 . The pressure limiting valve  11  acting as an overflow valve returns any excess quantity of reducing agent pumped through the pump  4  to the intake side of the pump. In an rpm-controlled feed pump or metering pump, the overflow quantities are as a rule small, since these pumps can pump fluids relatively well on demand, so that only small tolerances have to be compensated for, optionally by means of the bypass formed by the overflow valve. If the pressure in the system drops, for instance because of air inclusions, then the control unit opens the metering valve  7 , so that ventilation can be done via this valve. If this ventilation operation takes place during catalytic converter operation, then an overly small quantity of fluid will be metered because of the overly low system pressure. The missing quantity can be made up for by suitable triggering of the metering valve, via corrective data stored in memory in the control unit. Accordingly, if a pressure drop is recorded via the pressure sensor  50 , the control unit can call up a data performance graph stored in memory in it, which for instance assigns a suitably lengthened opening time of the metering valve, for assuring the injection of a correct quantity of reducing agent, to each value of a pressure difference between the actual pressure value and the set-point pressure value. 
   Alternatively, the metering apparatus can also be used without compressed air reinforcement, or in other words without using the components  20 - 24 . The pressure sensor  50  can also be replaced by a mass flow sensor. The data performance graph stored in a memory of the control unit must in that case naturally be adapted to the altered input variable (that is, the mass of a defined volume rather than its pressure), so that if this alternative sensor is used it can still perform injection corrections in the event of pressure drops. The mass measured in a mass sensor correlates in every case with the pressure prevailing in the line, so that gas inclusions and thus pressure drops can also be detected by means of a mass sensor. The pressure limiting valve  11  can also be installed in such a way that its inlet, oriented toward the outlet of the pump  4 , is disposed directly at the line  12 ; as a result, the line segment shown in  FIG. 1  between the pressure limiting valve  11  and the line  12  can be omitted. 
   The foregoing relates to preferred exemplary embodiments of the invention, it being understood that other variants and embodiments thereof are possible within the spirit and scope of the invention, the latter being defined by the appended claims.