The invention concerns a procedure for the regeneration of a particle filter and for the desulfurization of a NOx storage catalytic converter in an exhaust gas aftertreatment system of an internal combustion engine, whereby for the regeneration of the particle filter in contrast to a normal operation, the temperature of the particle filter in at least one mode of operation “DPF-heating” is elevated and whereby for the desulfurization of the NOx storage catalytic converter in at least one mode of operation “NOx storage cat heating” (λ≧1), the NOx storage catalytic converter is heated up, and a subsequent mode of operation “NOx storage cat desulfurize” a Lambda value is set in the exhaust gas of λ<1.
In the case of diesel motors, reinforced combined exhaust gas aftertreatment systems with a particle filter (DPF) and NOx storage catalytic converters (NSC) are planned, respectively already deployed, due to the demands with regard to lower emission threshold values.
Particle filters have, however, a limited storage capability and must be regenerated within certain intervals for the restoration of the purification effect. This occurs typically every 250 to 1000 km. In the case of sooty particle filters, the regeneration occurs by means of an elevation of the exhaust gas temperature to typically 550° C. to 650° C. This can result from steps taken in the mixture preparation of the motor or by means of steps taken in the exhaust system. In so doing, an exothermic reaction is set into action, which causes a burnout of the sooty particles, and within a short time (for example 20 minutes) the particle filter is regenerated.
In the case of systems with a NOx storage catalytic converter (NSC), a differing amount of sulfur will be lodged in the NOx storage catalytic converter depending upon the sulfur content of the fuel and motor oil used. This sulfur reduces the number of NOx storage locations in the catalytic converter and thereby diminishes the efficiency of the NOx storage catalytic converter (NSC). Also for this reason a regular desulfurization of the NOx storage catalytic converter must in this instance be implemented. Typically this occurs every 2000 to 5000 km. In so doing, the exhaust gas system and with it the NSC are likewise heated up to a high temperature level (typically 600 to 750° C.). Additionally the sulfur is preferably discharged as sulfur dioxide (SO2) by means of phases with a rich exhaust gas mixture (λ≦1) i.e. with a surplus of CO/HC and H2 with respect to O2.
Both procedures are energy intensive and require in contrast to the normal operation of the engine an additional amount of fuel.
From the German patent DE 19945336 A1 a procedure is known for the open-loop control of a regeneration of a particle filter and a desulfurization of a NOx storage catalytic converter, whereby the particle filter and the NOx storage catalytic converter are part of an emission control system of a diesel internal combustion engine. In order to desulfurize the NOx storage catalytic converter, a minimum temperature as well as a work mode of the diesel internal combustion engine to generate an exhaust gas of λ≦1 must be present. For the regeneration of the particle filter a regeneration temperature must be exceeded. This application characterizes itself, in that on the one hand a desulfurization necessity of the NOx storage catalytic converter exists when a first threshold value S1kat for a degree of sulfation is exceeded, and on the other hand a regeneration necessity of the particle filter exists when a first threshold value S1par for a charge value exists. Additionally the desulfurization and the regeneration are then first introduced, if both of the first threshold values S1kat, S1par have been exceeded, provided that the degree of sulfation does not lie above a second threshold value S2kat or the charge value above a second threshold value S2par.
The patent application mentioned above refers to the triggering of the desulfurization, if certain threshold values are exceeded for the sulfur in the particle filter, respectively in the NOx storage catalytic converter, and for the particle loading, respectively the sulfur absorption. In fact, it is also cited in this text that initially the regeneration of the particle filter is implemented; and thereafter if need be, the temperature is raised to a minimum temperature and subsequently the work mode of the diesel internal combustion engine is regulated in a closed-loop to λ≦1. A strategy for the targeted complete combination of both procedures is, however, not indicated in the State of the Art.
For this reason, it is the task of the invention to provide a procedure for the regeneration of a particle filter and for the desulfurization of a NOx storage catalytic converter. This procedure is optimized with regard to the reduction of the additional fuel consumption and with regard to a high efficiency for the desulfurization of the NOx storage catalytic converter.
The task of the invention is thereby solved, in that a combined, complete or partial regeneration of the particle filter as well as a desulfurization of the NOx storage catalytic converter is triggered when a desulfurization for the NOx storage catalytic converter is requested. In so doing, in contrast to the State of the Art, the regeneration of the particle filter can also be selectively implemented during the desulfating, whereby in cases with a high particle loading if need be, a short lead time for the particle filter regeneration can be required. By means of this coupling, the required heat energy and the fuel consumption associated with it can be significantly reduced. Furthermore, an increase in efficiency of the NOx storage catalytic converter occurs because the average sulfur absorption is reduced by the greater frequency of the desulfurization phases, whereby the NOx emissions after the NOx storage catalytic converter can be further reduced.
If initially starting from the normal operation in a mode of operation “DPF-heating”, the particle filter is heated to the temperature required for regeneration and maintained at this temperature by a temperature regulator, the advantage results, in that an optimal temperature can be maintained for the burnout of sooty particles. For the closed-loop control of the temperature, provision can be made for the deployment of a temperature sensor in the area of the particle filter.
A preferred procedural variation makes provision during the mode of operation “DPF-heating” to switch to the operational mode “NOx storage cat heating” and to specify a new set point temperature. In so doing, an optimal temperature for the desulfurization, which is generally higher than the optimal temperature for the burnout of sooty particles, can be set.
In order to avoid temperature spikes, which can have adverse effects on the longevity of the particle filter, provision can be made for the conditions for the new set point temperature to be tested before switching to the mode of operation “NOx storage cat heating”. In this manner, conditions, for example, like “sooty particle mass threshold value has been undershot” and/or “weakening of the exothermic reaction across the particle filter”, can also be evaluated. In so doing, an adaptive regeneration system for the particle filter can be implemented.
If a Lambda value of λ>1 is set in the exhaust gas during the mode of operation “NOx storage cat heating”, an additional burnout of sooty particles can be observed during this phase.
Provision is made in a preferred procedural variation for the mode of operation to change between “NOx storage cat heating” and “NOx storage cat desulfurization” after the new set point temperature has been reached. During this desulfurization phase a significant expulsion of the sulfur from the NOx storage catalytic converter by means of the short enrichment of the exhaust gas (λ<1) can on the one hand be observed. In fact, an enrichment of the exhaust gas during this phase is also mentioned in the previously cited State of the Art; however, this occurs only as a function of the charge value and the exhaust gas temperature downstream from the particle filter. During the phases with λ>1, an additional burnout of sooty particles is registered at this temperature level. Additionally it is advantageous in the case of this mixing operation within the desulfating phase that an H2S build-up can be avoided by way of the relatively short phases with λ<1. In the interruption phases with λ>1, it is necessary again to fill the NOx storage catalytic converter with oxygen to avoid an H2S build-up and if need be to again adjust the optimal process temperature.
In the process it has turned out to be advantageous for the change between the mode of operation “NOx storage cat heating” and “NOx storage cat desulfurization” to be specified alternately for certain time intervals, which, for example can depend upon the operational point of the internal combustion engine or the conditions in the NOx storage catalytic converter.
If the time period for the desulfurization is firmly established and terminated after this time has run out, a complete desulfating can be achieved independently of the period of deployment for the NOx storage catalytic converter and the operational conditions of the internal combustion engine, provided a sufficiently long period of time for the desulfurization exists. It can be advantageous to continue the desulfurization process for a certain time period after the particle filter regeneration has been completed. This time period is dependent on the degree of sulfation.
It can also be advantageous to end the desulfurization phase in the case of the particle filter being totally or partially regenerated and the degree of effective desulfurization abating as a sign that the desulfurization has been (almost) successfully completed. In so doing, excessive fuel consumption can be avoided.
A similar advantage results if the desulfurization phase is terminated in the case of a completely or partially regenerated particle filter and a simultaneous undershooting of a firmly established threshold value for the sulfur content in the NOx storage catalytic converter.
It can also be advantageous if the desulfurization phase is terminated, when the particle filter is completely or partially regenerated and simultaneously a firmly established accumulated time period is achieved for the desulfurization. As the accumulated time period for the desulfurization is a measurement for the summary desulfurization capacity and therewith by means of the knowledge of the sulfur being embedded during the normal operation, unnecessarily long desulfurization phases can be avoided.
Provision is made in a procedural variation for the conditions to conclude the desulfurization phase to be combined. As a result an adaptive procedure can also be implemented for the desulfurization, which orientates itself on the actual sulfur content in the NOx storage catalytic converter and on the operating state of the internal combustion engine.
If the desulfurization phase is terminated and the operation mode “DPF-heating” is continued, when a firmly established threshold value is undershot for the sulfur content in the NOx storage catalytic converter and when a regeneration of the particle filter is still not fully completed, the advantage occurs during this combined procedure, in that the regeneration of the particle filter as well as the desulfating of the NOx storage catalytic converter can in each case be optimally implemented.
The invention is explained in detail below using the examples of embodiment depicted in the figures. The following are shown:
The closed-loop control of a work mode of the internal combustion engine 1 can result using selected operating parameters. It is therefore conceivable to determine a composition of the exhaust gas by means of Lambda probes 60 and/or NOx sensors 100 disposed in the exhaust gas duct 50. An exhaust gas temperature can, for example, be additionally determined in the area of the emission control system, for example between the particle filter 70 and the NOx storage catalytic converter 90 by means of one or several temperature probes 80. From the signals of the different probes 60, 80, 100, which are connected to the engine control unit 110, as well as from the data of the incoming air measurement device 20, the mixture can be calculated and the fuel metering mechanism 30 can be correspondingly actuated to meter the fuel.
Provision is made in the procedure according to the invention for the regeneration of the particle filter 70 as well as the desulfurization of the NOx storage catalytic converter 90, in that in the case of a regeneration request for the particle filter 70 or a desulfurization request for the NOx storage catalytic converter 90, a combined regeneration of the particle filter 70 as well as the NOx storage catalytic converter 90 is initiated. A desulfurization request can, for example, be initiated in the case of an improper fueling or in the case of the diesel fuel containing a high content of sulfur.
Initially the particle filter 70 starting from the normal operation 141 in a mode of operation “DPF-heating” 142 is heated up to the temperature (for example 550 to 650° C.) required for regeneration, and it is maintained at this temperature by a temperature regulator. After a threshold for sooty particles has been undershot during the DPF-regeneration (regeneration of the particle filter 70), the operation is switched to the mode of operation “NOx storage cat heating” 143; and a new set point temperature (for example 600 to 750° C.) is specified, whereby in order to avoid temperature spikes before switching to the mode of operation “NOx storage cat heating” 143, conditions for this new set point temperature are tested. During the mode of operation “NOx storage cat heating” 143, a Lambda value of λ>1 is set in the exhaust gas. If sooty particles are still present in the particle filter 70, burnout is consequently also continued during this phase.
After the new set point temperature has been achieved, changeover occurs between the mode of operation “NOx storage cat heating” 143 and the mode of operation “NOx storage cat desulfurize” 144, whereby the changeover alternating between the mode of operation “NOx storage cat heating” 143 and the mode of operation “NOx storage cat desulfurize” 144 is specified (typically for, for example, 10 s at a time).
The conditions for a completion of the desulfurization can be different according to the subsequent list, whereby these can also be deployed in combination. The desulfurization can be terminated, if
Provision is furthermore made in the procedure according to the invention for the desulfurization phase to be terminated and the “DPF-heating” 142 to be continued when a firmly established threshold value for the sulfur content in the NOx storage catalytic converter 90 has been undershot, and the regeneration of the particle filter 70 has not been completely concluded.
In
As can be recognized in
With the indicated procedure the necessary heating energy and with it the associated fuel consumption can be significantly reduced. Furthermore, an increase in efficiency of the NOx storage catalytic converter 90 results, because the average sulfur absorption is reduced by the greater frequency of the desulfurization phases, whereby the NOx emissions after the NOx storage catalytic converter 90 can further be reduced.
Number | Date | Country | Kind |
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10 2006 034 805 | Jul 2006 | DE | national |
Number | Name | Date | Kind |
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20050022506 | Nishizawa et al. | Feb 2005 | A1 |
20060191257 | Goralski et al. | Aug 2006 | A1 |
20070271902 | Noirot et al. | Nov 2007 | A1 |
Number | Date | Country |
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199 45 336 | Mar 2001 | DE |
WO 2005052331 | Jun 2005 | WO |
Number | Date | Country | |
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20080022655 A1 | Jan 2008 | US |