Patent Application
20110047996
The invention is based on known methods and apparatuses for posttreatment of exhaust gases, in particular exhaust gases of internal combustion engines, for instance in the automotive field, in energy generation, or in similar fields in natural science and technology. From such fields, techniques are known in which various pollutant-reducing media, especially fluid media (such as liquids or gases) are metered, for instance injected into the exhaust gas. Various techniques and various types of pollutant-reducing media are employed. Examples of such pollutant-reducing media are urea-water solutions, which as a reducing agent reduce nitrogen oxides selectively. Such methods are often also called SCR methods (SCR: selective catalytic reduction).
Other methods are based on the injection of hydrocarbons, as pollutant-reducing media, into exhaust gases. Such methods, which are often also called HCI methods (HCI: hydrocarbon injection), can serve various purposes. For one, an injection of fuel, such as diesel fuel, as a reducing agent can be for instance serve to reduce nitrogen oxides. Other methods are based on a reaction of the injected fuel in an oxidation catalytic converter, which for instance leads to a brief temperature increase in the exhaust tract. This temperature increase can be employed for instance for regenerating an exhaust gas posttreatment apparatus, for instance for regenerating a diesel particle filter by burning off soot.
Without limiting the further possibilities for embodying the pollutant-reducing medium, reference will be made hereinafter essentially to HCI systems. However, it will be pointed out that other types of pollutant-reducing media, especially liquids, can also be employed.
Various apparatuses for introducing the pollutant-reducing medium into the exhaust gas are known from the prior art. For instance, German Patent Disclosure DE 10 2005 040 918 A1 describes a system in which fuel is diverted from a low-pressure part of a reservoir-type injection system and metered into the exhaust gas. The low-pressure part has a pressure maintenance valve, for maintaining a minimum pressure in the low-pressure part.
In the system shown in DE 10 2005 040 918 A1, the low-pressure reservoir, with its liquid volume, ensures a certain calming of pressure fluctuations. Nevertheless, pressure fluctuations in the low-pressure circuit of an injection system of that kind can only seldom be avoided. In other types of furnishing the pollutant-reducing medium as well, such pressure fluctuations occur. Pressure fluctuations can also, depending on the injection system, also be generated by the return from the injectors in the fuel injection system or as a result of pumping.
To avoid these problems of pressure fluctuations, German Patent Disclosure DE 10 2005 034 704 A1 discloses an apparatus and a method for regenerating particle filters. In the apparatus proposed there as well, a calming volume of fuel is employed in order to ensure a certain compensation for pressure fluctuations. It is also proposed that a pressure control valve, which opens and dissipates the pressure if the supplied fuel exceeds a certain value, be disposed in a branch line from the calming volume.
Despite these calming provisions known from the prior art, it has been demonstrated that under some circumstances, there can nevertheless be a potential for improvement. For instance, pressure peaks can still occur and influence the injection of the pollutant-reducing medium. Moreover, cavitation in the supply line of the pollutant-reducing medium, for instance in the low-pressure circuit, can also occur. Such pressure peaks and cavitation can even lead to damage of the components of the system, such as the HCI components, and the hydraulic behavior can be adversely affected.
An apparatus for metering at least one pollutant-reducing medium into an exhaust system is therefore proposed which at least largely avoids the above-described disadvantages of known apparatuses and systems and which ensures that the injection of the pollutant-reducing medium is made uniform. With regard to the embodiment of the pollutant-reducing medium, the above descriptions of known systems can for instance be referred to, especially HCI systems. Especially preferably, the apparatus can be used for regenerating a diesel particle filter, the apparatus being used such that diesel fuel is injected and catalytically combusted into an exhaust tract, for instance upstream of an oxidation catalytic converter. As a result, the temperature in the exhaust system is actively raised, until the burnoff temperature for the soot deposited in the diesel particle filter has been reached.
The proposed apparatus includes at least one injection valve, in particular a pressure-regulated injection valve, for injecting the pollutant-reducing medium into the exhaust system. This can for instance involve a pressure-regulated injection valve, for instance pressure-regulated injection valves, which is already being used on a mass production basis for injecting fuels into combustion chambers of internal combustion engines, and/or for modifying such valves.
The apparatus furthermore includes at least one supply line for supplying the pollutant-reducing medium to the injection valve.
To this extent, the system can largely correspond for instance to the systems described in DE 10 2005 040 918 A1 and/or DE 10 2005 034 704 A1. However, still other designs are also possible. In contrast to the systems known from the prior art, however, in the proposed system at least one pressure damper is received in the supply line, upstream of the injection valve. The term “pressure damper” is to be understood here to mean a device, which damps pressure peaks in the pollutant-reducing medium in the supply line by providing that the excess energy from these pressure peaks is dissipated to and at least partly absorbed by an element, acting as an energy absorber, that is different from the pollutant-reducing medium and that differs from conventional provisions on the inlet side, such as pressure control valves or simple throttle bores. This additional element that receives the excess energy can, as described below, for instance include a solid, porous, or elastic, or (although this is less preferable) a plastic element. Various possibilities are discussed below as examples.
By means of the at least one pressure damper provided according to the invention, the pressure is accordingly efficiently made uniform, and thus an improvement is brought about in the process of injecting the pollutant-reducing medium. Dissipating excess pressure through an additional pressure control valve can be dispensed with, which can bring about a cost saving as well as simplification. Such pressure control valves, however, can, as described below, be provided as additional safety provisions, or provisions for making the pressure uniform. It is also possible to dispense with a calming volume of the kind provided in DE 10 2005 034 704 A1 or also, in the form of the low-pressure reservoir, for instance in DE 10 2005 040 918 A1, or else such a calming volume may be provided as an additional damping measure.
It is especially preferred if the pressure damper has at least one porous element received in the supply line. The porous element can for instance include a highly porous material of open porosity, that is, a material in which the pores form continuously open pore ducts. In particular, a porous element of this kind can be integrated upstream of components of the apparatus that do not resist high pressure peaks. The pressure damper can for instance include a ceramic material, a metal material, a metal alloy, or a combination of that and/or other materials as the porous element. In particular, sintered metals, sintered metal alloys, or sintered ceramics can be used, optionally also in combination.
The pressure damper and/or the porous element may have various geometries. The porous element can for instance be solidified by compaction or molding and ensuing drying and sintering of ceramic slips and/or metal slurries. The damping properties can be adapted to the various most frequently occurring operating conditions, that is, for instance liquid properties, pressures, temperatures, and/or the like that frequently occur during operation. An adaptation to the component geometry, for instance to spatial installation conditions, can also be purposefully made. By means of a purposeful choice of porosity, pore size, or similar parameters of the porous element and/or of a rib thickness of the porous element and/or a length of the porous element or of the pressure damper, the lowering of the pressure level can be optimized in a purposeful way.
Alternatively or in addition to the porous element, the pressure damper can also include at least one hydraulic pressure damper. This hydraulic pressure damper should preferably be arranged in such a way that it includes at least one hydraulic volume of the pollutant-reducing medium. For instance, this hydraulic volume can be a closed-off hydraulic volume, which is received in a widened portion (for instance a pressure vessel). This pressure vessel can be in communication with the supply line via an inlet and an outlet, for instance, or integrated with the supply line.
The hydraulic pressure damper further includes at least one energy reservoir that is different from the hydraulic volume and is in operative communication with the hydraulic volume. While in the case of the use of the porous element, the porous element itself acts as an additional element absorbing the excess energy or excess pressure in the case of pressure peaks, in the case of the hydraulic pressure damper, the energy reservoir acts as an additional element for absorbing the excess energy contained in the pressure peaks and thus for making the pressure uniform.
The energy reservoir may for instance include a mechanical energy reservoir, such as an at least partly elastically deformable plastic or some other elastic element, for instance a spring element. Alternatively or in addition, the energy reservoir can also contain at least one compressible closed-off fluid volume, in particular a gas volume, in particular air. Still other kinds of energy reservoirs are conceivable. The energy reservoir may also be designed such that while it absorbs brief pressure peaks, nevertheless the excess energy of these pressure peaks is returned to the pollutant-reducing medium again once the pressure peak has faded. In this way, besides pressure peaks, pressure incursions, for instance, can also be reduced. The pressure damping properties can optionally be adapted using throttle elements (such as inflow throttles and outflow throttles) received in the supply line, with the pressure level prevailing at the time, and optionally with an overflow valve or a pressure control valve and/or an overpressure valve.
As discussed above, it is especially preferred if the supply line connects a low-pressure system of a fuel system, in particular a reservoir-type injection system (such as a diesel common rail system) with the injection valve.
Furthermore, upstream of the injection valve in the supply line, at least one metering unit can also be received, and the metering unit has at least one valve for controlling a procedure of injection of the pollutant-reducing medium. This metering unit can for instance be controlled by a separate controller and/or by a controller integrated with an engine control unit.
The metering unit can for instance include a shutoff valve, which as a whole turns the injection operation on or off. Alternatively or in addition, the metering unit can include a metering valve which is operated for instance in clocked fashion and subjects the injection valve to pressure in clocked fashion, so that the injection procedure takes place in clocked fashion as well.
Moreover, the metering unit can include one or more pressure measuring devices. For instance, one pressure measuring device can be provided for determining a metering quantity, for instance between a shutoff valve and a metering valve. Alternatively or in addition, one pressure measuring device can be provided between the metering valve and the injection valve, for instance in the form of a pressure sensor for detecting leaks. If at least one such pressure measuring device is provided, then the pressure damper can in particular be disposed upstream of this at least one pressure measuring device, for instance upstream of a pressure measuring device for a metering quantity. In particular, the pressure damper can be integrated entirely or in part in the metering unit, or it may also be provided entirely or in part upstream of the metering unit.
As described above, in addition to the pressure damper, further devices can optionally be provided for making the pressure in the apparatus uniform. In particular, at least one overpressure valve may for instance be provided, which is received in a branch line branching off from the supply line upstream of the pressure damper. Alternatively or in addition, a damping supply of the pollutant-reducing medium can also be received upstream of the pressure damper in the supply line, for instance in a widened part of the supply line and/or in a vessel communicating with the supply line, such as a pressure vessel. To this extent, the apparatus can for instance be supplemented with the additional provisions described in DE 10 2005 034 704 A1.
Exemplary embodiments of the invention are shown in the drawings and described in further detail in the ensuing description.
Shown are:
In
In this exemplary embodiment, an oxidation catalytic converter 128, symbolically represented in
An injection valve 132 is provided between the turbocharger 118 and the oxidation catalytic converter 128. By means of this injection valve, which is subjected to pollutant-reducing medium, such as diesel fuel, via a supply line 134, pollutant-reducing medium 136, which in the HCI process is for instance diesel fuel, is injected into the exhaust tract 116. The diesel fuel is catalytically combusted by the oxidation catalytic converter 128, as a result of which the temperature in the exhaust tract 116 is actively raised until the burnoff temperature for the soot deposited in the diesel particle filter 130 is reached. In this way, regeneration of the diesel particle filter 130 can be accomplished.
A metering unit 138 is also disposed in the supply line 134. This metering unit 138, like the supply line 134 and the injection valve 132, is a component of an apparatus 140 for metering the pollutant-reducing medium 136. This apparatus 140 is shown schematically in further detail in
Furthermore, in the exemplary embodiment shown in
In
Inside the metering unit 138, the shutoff 152, at regeneration intervals, initially interrupts the inflow of pollutant-reducing medium 136. Optionally, an overpressure valve 162 can be received in the branch line 164, similarly to the embodiment in DE 10 2005 034 704 A1, for example, which valve connects the supply line 134 with the tank 166. In this way, a pressure level can be reduced, and pressure fluctuations can also be compensated for to a limited extent.
In the metering unit 138, downstream of the shutoff valve 152, is the first pressure sensor 146, whose signal can be used for instance for calculating the clocking of the metering valve 156 and thus for increasing the metering quantity precision. This metering quantity is then made available via the metering valve 156 and delivered to the injection valve 132. A second pressure sensor 148, as a pressure measuring device, for instance for detecting leaks, can optionally be disposed between the injection valve 132 and the metering valve 156.
The injection valve 132 may for instance be a structurally adapted fuel injection valve, which opens at a defined supply pressure and injects pollutant-reducing medium 136 into the exhaust tract. A structurally adapted “K-Jetronic” valve can for instance be used for this.
The apparatus 140 shown in
Exemplary embodiments of pressure dampers 168 according to the invention that can be provided for instance in an apparatus 140 as in
The porous element 170 may for instance have nonlinear properties with regard to the permeability for the pollutant-reducing medium 136, so that there is a disproportionate ratio exists for example between the pressure difference at the inlet 174 and outlet 176 and the delivered quantity of pollutant-reducing medium 136. This means that pressure peaks can be intercepted especially effectively by the pressure damper 168. The excess energy contained in the pressure can be absorbed by the porous element 170, for instance.
In
| Number | Date | Country | Kind |
|---|---|---|---|
| 10 2008 013 406.6 | Mar 2008 | DE | national |
| Filing Document | Filing Date | Country | Kind | 371c Date |
|---|---|---|---|---|
| PCT/EP09/50653 | 1/21/2009 | WO | 00 | 10/26/2010 |
