EP1766210A1 - Method for controlling an internal combustion engine - Google Patents

Abstract

The invention relates to a method for controlling an internal combustion engine with a motor control system that adjusts the exhaust-gas temperature by influencing the air-fuel mixture. Said motor control system has a temperature model so as to determine a preset temperature for a component in the exhaust manifold, which is achieved after a longer period of time while maintaining current operating and driving conditions. The motor control system regulates the exhaust-gas temperature depending on the preset temperature for the purpose of component protection.

Description

Hospitality

Method for controlling an internal combustion engine

The present invention relates to a method for Steue¬ tion of an internal combustion engine with an engine control that ein¬ provides the exhaust gas temperature on the air / fuel mixture and has a temperature model.

In internal combustion engines, catalysts are used in the exhaust gas tract for purifying the exhaust gases in order to comply with emission regulations. To monitor the temperature of the catalysts, a temperature model is used in the engine control, which calculates the exhaust gas and / or catalyst temperature. Depending on the calculated temperature, cooling measures to protect the catalyst are initiated if the temperature is too high. Such cooling measures consist of a change in the air / fuel ratio in the direction of a fuel overflow, so-called enrichment of the mixture. The enrichment is taken over by a regulator, at the input of which the difference between simulated and maximum permissible catalyst temperature is applied. In this approach, the problem arises that the real catalyst temperature only reacts to the enrichment with a considerable delay. The controller therefore has a long controlled system. The temperature model in the engine control system takes into account this long control path and simulates the delayed behavior of the catalytic converter. Depending on the selected control parameters, this leads either to a vibration state of the regulator or to an overshooting of the catalyst temperature during the first activation of the regulator.

From DE 102 01 465 B4 a method for controlling a component protection function for a catalyst is known. For this purpose, the modulated exhaust gas temperature is taken as a function of the lambda value and other variables. With the help of the inverse function is then for a maximum temperature value Lambda setpoint calculated for component protection. If the component protection is activated during operation of the internal combustion engine, the lambda value is set to the lambda desired value thus calculated. The problem with this method is that the exhaust gas temperature model can only be implemented under certain assumptions. If the temperature change in the catalyst is also taken into account in the temperature model due to the exothermic chemical reactions, then there is no simple connection permitting the inversion of the function. At most, then, there is a piecewise bijective relationship between temperature and lambda value.

The invention has for its object to provide a reliable method for controlling an internal combustion engine, which provides effective component protection in a short time without much computational effort for the engine control.

According to the invention the object is achieved by a method having the features of claim 1. The features of the subclaims form preferred embodiments.

The inventive method relates to the control of an internal combustion engine with a motor control. The engine control adjusts the exhaust gas temperature via the air / fuel mixture and has a temperature model which preferably calculates the temperature for a component to be protected in the exhaust gas tract. Such a component may be, for example, the catalyst arranged in the exhaust tract and / or the turbine of an exhaust gas turbocharger. The temperature model determines a predicted temperature for the component arranged in the exhaust tract. The predicted temperature is the temperature that sets itself after a longer time while maintaining the current operating and Fahrbe¬. As a rule, a predicted component temperature requires a longer time until the predicted temperature is reached than a predicted exhaust gas temperature. Nevertheless, for example, during cold start, the actual value and the predicted value for the exhaust gas temperature differ from each other. In the following, the predicted component temperature or the predicted exhaust-gas temperature or both temperatures is / are always designated with the predicted temperature. The temperature model of the engine control system according to the invention thus also calculates, alternatively or in addition to the current temperature, the temperature which will occur in continuous operation. The engine control regulates the component protection according to the invention, the exhaust gas temperature depending on the predicted temperature. One or more other sizes can still be used in the control. The problem of the long controlled system, as occurs in the prior art, is effectively avoided by using the predicted temperature. Also, the inaccuracy occurring in the inversion of the temperature model is avoided according to the invention, as well as the neglect of certain dependencies such as, for example, the exothermicity.

In a preferred embodiment of the method according to the invention, the control takes place as a function of the predicted temperature and a maximum permissible temperature value. During the control process, the currently occurring predicted temperature value is always determined and applied to the controller as an input variable. Preferably, an integral controller is provided as the controller, in which the manipulated variable results as the sum of the actual value and a weighted difference between the predicted temperature and the maximum permissible temperature value.

In a preferred embodiment, the component to be protected is deposited on the catalyst. In this case, the predicted temperature is the catalyst temperature. Alter¬ natively or additionally, it is possible to turn off a turbocharger or another component in the exhaust system. In the turbocharger is turned off on the exhaust gas temperature in front of the turbocharger and their value predicts. In a preferred embodiment, the temperature control according to the method of the invention starts when the current actual value of the component temperature exceeds a predetermined threshold value. The predetermined threshold value is smaller than the maximum permissible temperature value.

In a preferred embodiment of the method according to the invention, the value for the predicted temperature is recalculated at predetermined time intervals during the control process. Preferably, the regulation of the temperature takes place at a maximum permissible temperature value.

The inventive method will be explained in more detail with reference to two drawings.

It shows:

FIG. 1 shows the behavior of an I controller for the catalyst protection using a predicted catalyst temperature and FIG

Fig. 2 shows the behavior of two differently set I-controller for the catalyst protection using the current catalyst temperature.

FIG. 1 shows a plurality of variables which are decisive for the method according to the invention over a common time axis t. At the time Ti, the air mass flow in the engine 10 increases abruptly. The temperature model calculates the predicted temperature 12 for the increased value of the air mass flow 10, which will be set for the catalyst in continuous operation at the increased air mass flow. The current catalytic converter temperature 14 subsequently increases in response to the load jump in Ti and reaches a switch-on threshold 16 for the catalyst protection function at time T2. Subsequent to T ₂ , the I-controller is used to control the exhaust gas temperature by enriching the air / fuel mixture. The signals of the I-controller are marked 18 in FIG. Input variables to the controller is the predicted catalyst temperature 12 and a maximum permissible temperature value 28 for the catalyst. In a subsequent interval 22, the controlled variable 18 has already fallen since the predicted temperature value 12 has continued to approach the target variable, the maximum permissible temperature value 28. The actual value 14 also approaches the temperature value 28.

In the subsequent interval 24, the predicted value 12 for the catalyst temperature has already fallen by approximately half, so that the control intervention 18 is further reduced. FIG. 2 shows the temperature profile 26 arising on the catalyst due to the control intervention. The temperature 26 approaches the marked temperature value for the permissible maximum catalyst temperature without excessive overshooting. For comparison, the temperature curve 30 shown in FIG. 1, which would have resulted without a control intervention. In this case, as expected, the approaching

Temperature 30 of the catalyst to the immediately after the Last¬ jump predicted temperature value 12 at.

FIG. 2 shows, by way of example, the course of the catalyst temperature, as it results when two different I controllers are used, using the current catalyst temperature. Again at the time Ti, a load jump takes place, which is represented by the suddenly rising air mass flow 32. The current actual temperature 34 of the catalytic converter rises to Ti and cuts at time T2 the predetermined switch-on threshold 36 for the catalyst protection function. Subsequently, in the example, an I controller is used, which performs enrichment of the air / fuel mixture depending on the current actual temperature 34 of the catalytic converter and a predetermined desired value 38. The temperature curve 40 oscillating about the setpoint value 38 with the associated control variables 42 of the controller is produced when a fast-reacting I-damper is selected. In this case, vibrating controller states 40 may occur in which the maximum permissible value for the catalyst temperature 38 is repeatedly exceeded. If a slow-reacting I controller is used, the temperature profile marked 44 and the associated control variable 46 appear. The temperature profile 44 shows a clear overshoot, which requires a longer time until decay. For comparison, the unregulated temperature profile is indicated at 48.

A preferred embodiment has been described above for the component protection of a catalyst. Other components in the exhaust system can also be effectively protected by using the predicted temperature. In an exhaust gas turbocharger, for example, the exhaust gas temperature is turned off in front of the turbine.

Claims

claims:

1. A method for controlling an internal combustion engine with a motor control, the exhaust gas temperature over the

Sets air / fuel mixture and which has a temperature model that determines a predicted temperature (12) for a component in the exhaust system, which adjusts to Beibe¬ pose the current operating and driving condition (10) after a longer period of time, the Engine control for component protection regulates the exhaust gas temperature depending on the predicted temperature.

2. The method according to claim 1, characterized in that the control depends on the predicted temperature

(12) and a maximum permissible temperature value (28) er¬ follows.

3. The method according to claim 1 or 2, characterized in that an integral controller is provided as a controller.

4. The method according to any one of claims 1 to 3, characterized ge indicates that a catalyst is provided in the exhaust tract as Bau¬ part.

5. The method according to any one of claims 1 to 4, characterized ge indicates that a turbocharger is provided in the exhaust tract as Bau¬ part.

6. The method according to any one of claims 1 to 5, characterized ge indicates that a control of the exhaust gas temperature er¬ follows when the current actual value of the temperature exceeds a predetermined temperature value (16).

7. The method according to any one of claims 1 to β, characterized ge indicates that during the control process in pre- At times, the value for the predicted temperature is recalculated.

8. The method according to any one of claims 1 to 7, characterized ge indicates that the temperature is regulated to a permissible maximum temperature value (28).