EP4226032A1 - Method for operating an internal combustion engine, computing unit, and computer program - Google Patents

Abstract

The invention relates to a method (200) for operating an internal combustion engine (110), comprising providing and combusting an air-fuel mixture of a first composition, determining (210) a current composition of a combustion exhaust gas produced during the combustion, determining (220) an emission collective, which comprises a total amount emitted over a predefined interval for at least one component of the combustion exhaust gas, from multiple successively determined current compositions of the combustion exhaust gas, and setting (250) a second composition of the air-fuel mixture depending on the emission collective determined. The invention also relates to a computing unit and a computer program product for carrying out such a method.

Description

description

title

Method for operating an internal combustion engine, computing unit and computer program

The present invention relates to a method for operating an internal combustion engine and a computing unit and a computer program for its implementation.

State of the art

In order to clean exhaust gases from pollutants, catalytic converters and sensors, in particular exhaust gas sensors such as lambda sensors, are usually installed in the exhaust systems of vehicles with internal combustion engines. Since these components are absolutely necessary for compliance with the specified limit values, they are usually monitored by various diagnostics.

In order to keep pollutant emissions low, a stoichiometric air-fuel ratio (lambda=1) can generally be aimed for, particularly in systems with a spark-ignition engine. This means that there is just as much oxygen as is necessary to completely burn the fuel into carbon dioxide and water. There are also operating strategies for other engine concepts that make operation with an exhaust gas lambda of 1 necessary (e.g. regeneration of particle filters, heating strategies, ...).

For diagnostic purposes, it may be necessary to actively adjust the target value of the combustion lambda in order to evaluate the reaction of the components in the exhaust system to the lambda adjustment. For example, it can be here Dynamic diagnoses or offset diagnoses for lambda sensors or, in the case of the catalytic converter, a diagnosis of the oxygen storage capacity.

Disclosure of Invention

According to the invention, a method for operating an internal combustion engine and a computing unit and a computer program for its implementation are proposed with the features of the independent patent claims. Advantageous configurations are the subject of the dependent claims and the following description.

A method according to the invention for operating an internal combustion engine includes providing and burning an air-fuel mixture with a first composition, determining a current composition of a combustion exhaust gas generated during combustion, determining an emission collective that has a value for at least one component of the combustion exhaust gas total quantity emitted at a predetermined interval, from a plurality of current compositions of the combustion exhaust gas determined one after the other, and setting a second composition of the air-fuel mixture as a function of the collective emissions determined. As a result, when controlling the internal combustion engine, not only is the current emission behavior taken into account, as is usual in conventional methods, but compliance with limit values is monitored over an entire operating or driving cycle, thus enabling an overall reduction in emissions.

Advantageously, the emission spectrum relates to a work performed by the internal combustion engine and/or an operating time of the internal combustion engine and/or a distance covered by a vehicle that is driven by the internal combustion engine. These are used as a basis, for example, for legal requirements relating to maximum emissions and are therefore particularly important reference values. The adjustment of the second composition comprises in particular a reduction in the proportion of fuel in the air-fuel mixture if rich gas components predominate in the emission spectrum and/or an increase in the proportion of fuel if lean gas components predominate in the spectrum of emissions.

In this way, a shift in the emission behavior in the direction of a component that is already overrepresented on average can be avoided.

In the context of this invention, rich gas components are any chemical compound that is produced by burning a fuel with a substoichiometric amount of oxygen, i.e. in particular hydrocarbons or partially oxidized hydrocarbons (e.g. mono- or polyhydric alcohols, aldehydes, ketones, carboxylic acids and their respective derivatives and combinations thereof), carbon monoxide, ammonia and hydrogen. Lean gas components, on the other hand, include those compounds that are formed in particular when fuel with a superstoichiometric amount of oxygen is burned, in particular various nitrogen oxides.

A predominance of one component is characterized in particular by the fact that a proportion of the predominant component in the collective emission has a smaller distance from a threshold value assigned to it than all proportions of other components from a threshold value assigned to them. This offers the advantage that different threshold values can be assigned, for example as a function of a hazard potential emanating from the respective component. The distance mentioned can be calculated in particular in the form of a relative distance from the respective threshold value.

The setting of the second composition is preferably carried out depending on the necessity of at least one of several measures. As a result, an emission-optimal composition can in principle be selected and the composition is only shifted if there is a need. The measures include in particular a diagnosis and/or maintenance of at least one element of the internal combustion engine and/or an exhaust gas aftertreatment system connected downstream of it. Examples of such measures are, in particular, a catalytic converter diagnosis, a lambda probe diagnosis, what is known as catalytic converter cleaning, regeneration of a particle filter, what is known as catalytic converter heating and the like.

In particular, the measures are carried out one after the other and the method also includes specifying an order in which the multiple measures are carried out on the basis of the predominant component. As a result, for example, a storage capacity of a catalytic converter can be optimally utilized and overall emissions of pollutants downstream of the catalytic converter can be avoided or at least reduced.

In general, by using sensors and models in the exhaust system, it is possible to draw conclusions about the currently occurring emissions. Examples of such emissions are nitrogen oxides (NO _X ), ammonia (NH3), carbon monoxide (CO), hydrocarbons (HC), hydrogen (H2) and, as a measure of fuel consumption, carbon dioxide (CO2).

The present invention enables, in particular, an early detection of an (imminent) exceeding of legal exhaust gas limits. By integrating the current emission values over a particular time interval and possibly weighting the integration values over the route traveled in the current driving cycle, the currently accumulated emissions (ie the collective emissions) can be compared with applicable threshold values. With the help of the information obtained about the accumulated emissions, a general lambda target value and a lambda value in the case of unavoidable active adjustments can be specifically influenced in such a way that the emissions of exhaust gas components with an already high accumulated value or emission collective do not increase further and that all emission specifications in the current driving cycle be fulfilled. The target value of the lambda control is preferably selected in such a way that the emission of certain exhaust gas components is avoided in a targeted manner. For example, a slightly rich target value (i.e. less oxygen content in the air-fuel mixture than would be necessary for complete combustion of the fuel) is selected if the previous nitrogen oxide emissions were high, or a rich target value is specifically avoided if, for example, hydrocarbons and/or carbon monoxide (or other exhaust gas components that are increasingly formed due to a lack of oxygen during combustion or in downstream exhaust gas treatment processes, for example ammonia) have high emission collectives in relation to the threshold value.

Furthermore, it is envisaged in refinements that the sequence strategy of the diagnosis of the exhaust gas components be adapted in a targeted manner, taking into account the accumulated emissions. For example, in markets where only symmetrical dynamic errors of lambda probes are required to be found, it can be decided whether the dynamic diagnosis should be carried out with rich preconditioning and a subsequent measurement jump to lean or vice versa.

Sensors are preferably installed in such a system, which provide information about the current exhaust gas composition. Such sensors can be, for example, lambda sensors, nitrogen oxide sensors, temperature sensors, etc.

In addition, (mathematical) models are preferably present, which convert measurement data into the actual raw emissions at the outlet of the internal combustion engine, or into the actual emissions downstream of a catalytic converter. Such a model is described in DE 10 2016222418 A1, for example.

In addition to the distance covered in the driving cycle and the lambda value of the exhaust gas, other measured or modeled variables can be used to weight the results or to increase accuracy. Examples of such quantities are, in particular, temperatures, mass flows and pressures. It should be emphasized that although an application of the invention in a vehicle is particularly advantageous, since particularly strict legal requirements apply in such cases with regard to permissible emissions, this is not the only possible application. Rather, other applications are also provided, in particular with regard to stationary internal combustion engines. The internal combustion engine used can in principle be any type of internal combustion engine, for example an Otto engine, a diesel engine, a lean-burn engine with spark ignition, a rotary piston engine or the like. An application of the invention in connection with several internal combustion engines, in particular with a coupled exhaust system, can also be advantageous.

A computing unit according to the invention, e.g. a control unit of a motor vehicle, is set up, in particular in terms of programming, to carry out a method according to the invention.

The implementation of a method according to the invention in the form of a computer program or computer program product with program code for carrying out all method steps is advantageous because this causes particularly low costs, especially if an executing control device is also used for other tasks and is therefore available anyway. Suitable data carriers for providing the computer program are, in particular, magnetic, optical and electrical memories, such as hard drives, flash memories, EEPROMs, DVDs, etc. It is also possible to download a program via computer networks (Internet, intranet, etc.).

Further advantages and refinements of the invention result from the description and the attached drawing.

The invention is shown schematically in the drawing using an exemplary embodiment and is described below with reference to the drawing. Brief description of the drawings

FIG. 1 shows an arrangement with an internal combustion engine for carrying out an advantageous embodiment of a method according to the invention in the form of a schematic block diagram.

FIG. 2 shows an advantageous embodiment of a method according to the invention in a simplified representation in the form of a flow chart.

embodiment(s) of the invention

FIG. 1 shows an arrangement with an internal combustion engine 110, which can be used to carry out an advantageous embodiment of a method according to the invention, shown schematically in the form of a block diagram and denoted overall by 100.

The arrangement 100 comprises, in addition to the internal combustion engine 110, which can be configured as a gasoline engine, diesel engine or rotary piston engine, for example, an injection system 120, an exhaust gas catalytic converter 130 and a computing unit 140 (so-called engine control unit, ECU).

The internal combustion engine 110 includes a plurality of combustion chambers 1-6, which are supplied with fuel by the injection system 120 when the internal combustion engine 110 is in operation. The number of combustion chambers is irrelevant to the present invention. The injection system can be a direct injection system, for example, but the invention is also suitable for intake manifold injection systems. The arithmetic unit 140 monitors and controls the operation of the arrangement 100 and receives control signals from outside the arrangement 100, for example via an operating unit such as a pedal, a switch, etc. For example, the arithmetic unit can be set up to, depending on a received control signal Induce injection system to meter fuel into each or certain of the combustion chambers 1-6, adjust ignition times for the combustion chambers 1-6 of the internal combustion engine, receive signals from components of the arrangement 100 and / or operating parameters of the internal combustion machine 110, the injection system 120 and/or the catalytic converter 130 to be determined.

The injection system 120 is in turn set up to supply fuel individually to each of the combustion chambers 1-6 in a quantity defined by the control signals and at a defined point in time as a function of control signals which it receives from the computing unit 140 . In principle, this can be done in any way that is suitable for such a defined metering. For example, a fuel pump can supply fuel at a specific pressure to one or more rails, each supplying a plurality of combustion chambers 1-6, which pressure can be predetermined or controlled. The quantity and time of the respective metering can then be controlled via controlled injection valves specific to the combustion chamber. Another example would be an injection arrangement assigned to only one combustion chamber, for example in the form of a conventional pump-nozzle combination or a combustion-chamber-specific injection pump. This list expressly only represents exemplary embodiments and does not claim to be complete.

Exhaust gas catalytic converter 130 is set up to cause exhaust gas components generated during operation of internal combustion engine 110 to react with one another in order to convert pollutants into less harmful compounds. For example, the exhaust catalyst 130 may be provided as a conventional three-way catalyst. In particular in cases in which internal combustion engine 110 is designed as a diesel engine, an oxidation catalytic converter and/or SCR catalytic converter can also be used as exhaust gas catalytic converter 130 . For purposes of explanation, the use of a three-way catalyst is assumed below.

In principle, the exhaust gas catalytic converter 130 is particularly effective in particular in a defined catalytic converter window, with the catalytic converter window describing a range of exhaust gas compositions. In particular, the components oxygen, fatty gas components and carbon monoxide play an important role here. In normal operation, therefore, the operation of the combustion Engine 110 is controlled to produce an exhaust gas having a composition corresponding to an air ratio of 1. However, if internal combustion engine 110 is operated, for example, in so-called overrun mode, i.e. in such a way that it exerts a decelerating torque on a downstream drive train, in particular on a clutch input shaft and/or a transmission, the rich gas components and carbon monoxide are usually absent in the exhaust gas, since little or no fuel is injected into the combustion chambers 1-6 of the internal combustion engine 110. In such an operating phase, this reduces the fuel consumption and also the corresponding exhaust gas emissions, but subsequently has a negative effect on the conversion capacity of the exhaust gas catalytic converter 130 since the latter then has stored too much oxygen. Conventionally, a rich air-fuel mixture can therefore be injected into the combustion chambers 1-6 of the internal combustion engine 110 after the end of such an overrun phase in order to produce a rich exhaust gas. In this way, the exhaust gas catalyst 130 can be brought back into the catalyst window relatively quickly. This represents a conventional measure for quickly resuming catalytic converter operation after an overrun phase.

During operation of internal combustion engine 110, the composition of the exhaust gas generated by internal combustion engine 110 and by the Exhaust catalyst is converted, determined. For this purpose, signals from the sensors 142, 144, 146 are transmitted to the computing unit 140 and evaluated by it. The composition of the air-fuel mixture injected into the combustion chambers 1-6 of the internal combustion engine 110 is controlled as a function of the signals received. For this purpose, for example, throttle valves can be set in an air path of the injection system 120 or a delivery capacity of a fuel pump can be controlled accordingly. Such control of the composition of the air-fuel mixture is a conventional measure for controlling the composition of the exhaust gas. Within the scope of the present invention, the processing unit also logs how the current composition of the exhaust gas develops over time or the current compositions are added up or averaged and/or over a (e.g. time or work or route-related) Interval integrated. In this case, an emission collective is determined for at least one, preferably several components of the exhaust gas, which includes, for example, the total quantity of the exhaust gas components emitted in an operating cycle, for example a current stage of a route. The components nitrogen oxides, hydrocarbons and carbon monoxide are particularly relevant, since these are regularly subject to particularly strict legal regulations. The emission collective is then compared with threshold values for the respective exhaust gas components. The threshold values can be stored in the control unit 140 itself, for example, or can be retrieved or received from outside the arrangement, in particular via a wireless connection. In the latter case, currently valid limit values (locally or temporally) can be taken into account.

During the comparison, for example, for each monitored exhaust gas component, a difference between the total quantity determined in the collective emission and a maximum quantity permissible according to the threshold values can be determined. The further control of the internal combustion engine 110 or the injection system 120 can then take these distances into account in such a way that the composition of the air-fuel mixture is adjusted in one direction only, causing a change in the exhaust gas composition in such a way that the components that are already close to their permissible limit are produced to a lesser extent, while components whose total quantity is still far from the respective maximum quantity can be produced to a greater extent.

This is particularly advantageous in connection with diagnostic or maintenance functions in relation to individual elements 130, 142, 144, 146. Such diagnostic and maintenance functions often require a non-stoichiometric composition of the air-fuel mixture. For example, a so-called catalyst sweep may require a rich exhaust, while for some Diagnostic functions that are intended to detect malfunctions in a lambda probe when lean exhaust gas is required. Depending on how the emission spectrum is constituted at a specific point in time during the operation of internal combustion engine 110, a diagnostic function that requires lean exhaust gas can be carried out, for example, when the total quantity of rich gas components in the emission spectrum is just close to the associated threshold value , while nitrogen oxides (a typical lean component), for example, play a minor role in terms of quantity. In this way, compliance with limit values can be ensured over the entire operating period without having to do without the necessary diagnostic functions. Conversely, of course, a measure requiring a rich exhaust gas can only be carried out when lean gas components predominate in the collective emissions, as explained at the outset.

FIG. 2 shows an advantageous embodiment of a method according to the invention in the form of a simplified flowchart and is labeled 200 overall. References, in particular to device components, in the description of FIG. 2 can also refer to reference symbols in FIG.

In a first step 210 of method 200, a current exhaust gas composition downstream of internal combustion engine 110 is determined. For this purpose, in particular the signals from lambda probes and/or nitrogen oxide sensors 142, 144, 146 described with reference to FIG. 1 can be evaluated by control unit 140.

In a step 220, an emissions collective is determined from the current composition of the exhaust gas in conjunction with compositions determined beforehand. For this purpose, the respective current compositions can be integrated, for example, over a period of time or a distance covered.

Furthermore, in step 220, the respective total amounts of exhaust gas components that are summarized in the collective emissions can be compared against one or more corresponding threshold values. For example relative distances between the currently determined total emitted quantity of a component and its respective threshold value or maximum permissible quantity can be determined.

In a step 230 it is determined whether an adjustment of the composition of the air-fuel mixture is required. If not, the method 200 returns to step 210 and continues recording the exhaust gas composition.

If, on the other hand, it is determined in step 230 that the composition of the air-fuel mixture and thus also the composition of the exhaust gas must be changed in order to carry out one or more measures, the method continues with step 240, in which a sequence of the necessary measures or An implementation mode of the required measure is defined as a function of the collective emissions determined in step 220 (or in particular of the determined distances of the component quantities from their respective threshold values).

In a subsequent step 250, the measures are or are carried out in accordance with the order specified in step 240 or in the implementation mode specified therein. Thereafter, the process may return to step 210.

It should be expressly emphasized here that the method explained with reference to FIG. 2 is an exemplary embodiment of the invention, from which it is entirely possible to deviate within the scope of the invention. In particular, some steps can be carried out in a different, for example reversed order. If necessary, some of the steps can also be carried out or combined in parallel with one another.

It should also be expressly pointed out here again that the arrangement 100 in FIG. 1 is shown only schematically and can also contain other or additional elements, for example one or more additional catalytic converters, sensors, particle filters or the like. These additional or alternative elements can optionally also be controlled within the scope of the invention or signals provided by them can be used to determine the collective emission (step 220) or to determine the measures to be carried out or their sequence (step 250).

Claims

Expectations

1. Method (200) for operating an internal combustion engine (110) comprising providing and burning an air-fuel mixture with a first composition, determining (210) a current composition of a combustion exhaust gas generated during combustion, determining (220) a Emissions spectrum, which includes a total quantity emitted over a predetermined interval for at least one component of the combustion exhaust gas, from a plurality of current compositions of the combustion exhaust gas determined one after the other, and setting (250) a second composition of the air-fuel mixture as a function of the emissions spectrum determined.

2. The method (200) according to claim 1, wherein the emissions spectrum is based on a work done by the internal combustion engine (110) and/or an operating time of the internal combustion engine (110) and/or a vehicle driven by the internal combustion engine (110). is covered distance relates.

3. The method (200) according to claim 1 or 2, wherein the adjustment (250) of the second composition comprises a lowering of the fuel proportion in the air-fuel mixture if rich gas components predominate in the emission collective, and/or an increase in the fuel proportion comprises, if lean gas components predominate in the emission collective.

4. The method (200) according to claim 3, wherein a predominance of a component is characterized in that a proportion of the predominant component in the collective emission has a smaller distance from one assigned to it assigned threshold value than all other components' shares of a threshold value assigned to them.

5. The method (200) according to any one of the preceding claims, wherein the setting (250) of the second composition takes place depending on a requirement (230) at least one of a plurality of measures (250).

6. The method (200) according to claim 5, wherein the measures (250) include a diagnosis and/or maintenance of at least one element of the internal combustion engine and/or an exhaust gas aftertreatment system (130) connected downstream of it.

7. The method (200) according to claim 5 or 6, wherein the measures are carried out sequentially and the method further comprises a determination (240) of an order in which the plurality of measures (250) are carried out on the basis of the predominant component.

8. Arithmetic unit (140) which is set up to carry out all method steps of a method (200) according to one of the preceding claims.

9. Computer program that causes a processing unit (140) to carry out all method steps of a method according to one of claims 1 to 7 when it is executed on the processing unit (140).

10. Machine-readable storage medium with a computer program stored thereon according to claim 9.