EP1190167A1 - Method and device for operating an internal combustion engine with direct gas injection - Google Patents

Abstract

The invention relates to a method and a device for operating an internal combustion engine with direct gas injection which has at least two cylinder banks or cylinder groups. The internal combustion engine is controlled on the basis of at least one specified value. The specified value for one cylinder bank or cylinder group differs from the specified value for at least one second cylinder bank or cylinder group in at least one operating mode.

Description

Method and device for operating an internal combustion engine with gasoline direct injection

State of the art

The invention relates to a method and a device for operating an internal combustion engine with gasoline direct injection.

A method and a device for operating an internal combustion engine with gasoline direct injection is described in DE 43 32 171 AI (US Pat. No. 5,483,934). In the control system shown there, the entire operating range of the internal combustion engine is divided into different ranges according to speed and load and, depending on the current operating range, the fuel is injected either during the intake stroke or during the compression stroke. In the case of an injection during the intake stroke, the time available until the ignition and due to the swirling of the injected fuel by the intake air flow result in a largely homogeneous fuel distribution (homogeneous operation), while in the case of injection in the compression stroke, stratified charge occurs (stratified operation) . In homogeneous operation, the internal combustion engine is operated throttled, ie the air supply is limited by a throttle valve, in stratified charge operation it is almost operated throttled, ie the air supply through the throttle valve is almost unlimited. Switching between these operating modes depends on the operating parameters mentioned and / or on other predetermined criteria, for example with regard to the performance requirements by the driver.

It is an object of the invention to further optimize the operation of an internal combustion engine with direct gasoline injection.

This is achieved by the characterizing features of the independent claims.

Advantages of the invention

In the prior art mentioned at the outset, a switch is always made between the individual operating modes of the internal combustion engine for the entire internal combustion engine. Furthermore, all cylinders contribute equally to the torque of the internal combustion engine. This gives flexibility and degrees of freedom when designing the control system.

A further optimization of the drive of a motor vehicle is achieved by an asymmetrical operation of an internal combustion engine with direct petrol injection, in particular if the internal combustion engine has at least two cylinder banks that can be controlled independently of one another.

It is particularly advantageous that in operating states in which the driver's desired output can no longer be provided by the low-consumption stratified charge operation, only part of the internal combustion engine, for example a cylinder bank, is operated in the comparatively consumption-intensive homogeneous operation. The other cylinder bank continues to be operated in the low-consumption stratified charge mode. On the one hand, this can te driver's power requirement are provided, on the other hand, the consumption can be minimized. This advantage is already achieved in that the contribution of individual cylinder banks or groups to the total torque is specified differently.

Another advantage that such an asymmetrical operation of the internal combustion engine is achieved is an improvement in the noise emission or generally the comfort of the internal combustion engine. In this context, it is particularly advantageous that when a storage catalytic converter is cleared out, not all banks are switched over at idle or in the partial-load range. The noise emission is optimized by alternating switching.

It is also of particular importance that the asymmetrical operation of the internal combustion engine with gasoline direct injection provides more degrees of freedom in the design of the exhaust gas concepts. For example, the driver's power requirement is implemented in such a way that part of the internal combustion engine is operated in an exhaust-gas-optimized operating mode and in an exhaust-gas-optimal operating point, while the driver's actual performance request is carried out by controlling the operating point and, if appropriate, the operating mode of another part of the internal combustion engine.

The use of asymmetrical operation in an internal combustion engine with gasoline direct injection, which has at least two cylinder banks with at least two throttle valves that can be controlled independently of one another, is particularly advantageous. In an advantageous manner, however, this idea can also be applied to internal combustion engines with only one throttle valve, the air filling being set such that a part of the cylinders of the internal combustion engine are homogeneous, the other is operated in a shift mode. The latter leads to an overall increased air filling, so that the throttle losses are reduced compared to homogeneous operation of the entire internal combustion engine.

In addition to switching between the operating modes with stratified charging and with homogeneous fuel mixture formation, the principle of asymmetrical operation of the internal combustion engine is also used between operating modes such as homogeneous stoichiometric, homogeneous lean or mixed operating modes such as an operating mode with double injection, in which both homogeneous and stratified fuel mixture is produced . Here, too, the advantages achieved by asymmetrical operation are achieved as shown above.

Further advantages result from the following description of exemplary embodiments or from the dependent patent claims.

drawing

The invention is explained below with reference to the embodiments shown in the drawing. Figure 1 shows an overview circuit diagram of a control device for controlling an internal combustion engine with gasoline direct injection. FIG. 2 shows a flowchart based on an exemplary embodiment, which represents the principle of asymmetrical operation of such an internal combustion engine. Finally, FIG. 3 shows a further exemplary embodiment, which outlines a preferred embodiment as a flow chart.

Description of exemplary embodiments Figure 1 shows a block diagram of a control device for controlling an internal combustion engine with gasoline direct injection. A control device 10 is provided which has as components an input circuit 14 at least one microcomputer 16 and an output circuit 18. A communication system 20 connects these components for mutual data exchange. The input circuit 14 of the control device 10 is supplied with input lines 22 to 26, which in a preferred exemplary embodiment are designed as a bus system and via which the control device 10

Feed signals which represent operating variables to be evaluated for controlling the internal combustion engine. These signals are detected by measuring devices 28 to 32. Such operating variables are accelerator pedal division, engine speed, engine load (e.g. air mass), exhaust gas composition, engine temperature, etc. Via the output circuit 18, the control unit 10 controls the output of the internal combustion engine with gasoline direct injection. This is symbolized in FIG. 1 on the basis of the output lines 34, 36 and 38, which actuate at least the fuel mass to be injected, the ignition angle of the internal combustion engine and at least one electrically operated throttle valve for adjusting the air supply to the internal combustion engine. The representation selected in FIG. 1 means that the injection valves of a certain number of cylinders of the internal combustion engine are actuated via the symbolic output line 34, i.e. the fuel mass to be injected is supplied to these cylinders, the ignition spark is triggered in these cylinders at the predetermined point in time via the output line 36, and an electrically actuable throttle valve is controlled, which influences the air supply to these cylinders.

In internal combustion engines with at least two cylinder banks or groups, in which the air is supplied to each cylinder bank via an electrically controllable throttle valve, essentially two versions are provided, which are shown in broken lines in FIG. On the one hand, the second cylinder bank, there at least the fuel mass to be injected, the ignition angle and the air supply, is analogous to the first cylinder bank via the output circuit 18 and output lines 34a, 36a and 38a, which correspond to the output lines 34, 36 and 38, by the control device 10 controlled. This means that a control unit controls at least two cylinder banks. In another exemplary embodiment, instead of the lines 34a to 38a, a second control device 10b is provided, which is constructed analogously to the control device 10 and which adjusts the fuel mass, ignition angle and air supply of at least one further cylinder bank via the output lines 34b, 36b and 38b. The two control devices 10 and 10b are connected to one another via a communication system 40 connecting them for mutual data exchange. Via this communication system, depending on the exemplary embodiment, at least one of the control units, or all of the operating variable signals detected by the other or operating variables derived therefrom, become further

Evaluation submitted. In another exemplary embodiment, input lines 22b to 26b are supplied not only to the control device 10 but also to the control device 10b, so that there is an alternative to the transmission via the communication system or additionally the operating variable signal.

The basic procedure for the control of the internal combustion engine running in the microcomputer 16 of the control device 10 is outlined using the flow chart according to FIG. The accelerator pedal position β as well as operating variables such as engine speed NMOT, air mass MHFM and target torques from other control systems, for example from traction control and / or transmission control, are supplied to the microcomputer 16 as essential operating variables. In the driver request images 100, the accelerator pedal position tion signal ß determines a driver's desired torque MIFA of the internal combustion engine at least taking into account the engine speed, possibly a correction quantity of an idle speed control, etc. In the preferred exemplary embodiment, this is done by means of a map and subsequent calculation steps. Setpoint torques of other control systems, for example a setpoint torque of a traction control system MIASR, a transmission control MIGS, etc. are also supplied to the microcomputer 10. These setpoint torques and the driver's setpoint torque are fed to a selection stage 102, in which a resultant setpoint torque MISOLL for controlling the internal combustion engine is determined from the setpoint torques supplied. In the preferred embodiment, the selection is made by selecting the minimum or maximum. The resulting setpoint torque MISOLL determined in this way is fed to a further coordinator 104, in which the specifications for an asymmetrical operation of the internal combustion engine described below with reference to the flow chart according to FIG. 3 are determined. The coordinator 104 converts the total setpoint torque MISOLL into individual setpoint torques MISOLL1 to MISOLLN for the individual cylinder banks or for individual cylinder groups and / or in desired operating modes BASOLLI to BASOLLN of the individual cylinder banks or cylinder groups. The division of the target torque and the specification of desired operating modes by the coordinator 104 is carried out according to predetermined strategies.

In normal operation with small and medium loads, all cylinder banks or all cylinder groups are operated in stratified charge mode for reasons of consumption. Normally, the target torques are divided evenly between the individual banks. If an increased power requirement for the engine is recognized from the target torque MISOLL, which can not only be provided by stratified charge operation of all the cylinder banks, the target torque is increased for one of the cylinder banks or the cylinder groups. If necessary, the operating mode changes and / or the desired operating mode is set to homogeneous operation. In comparison to a complete switchover, this optimizes consumption since the other cylinder banks or cylinder groups are still operated in a lean stratified charge mode which is optimal in terms of consumption. The same applies to the other operating modes, for example lean operation with homogeneous mixture formation or mixed operating modes with double injection, in which both homogeneous and stratified fuel mixture formation takes place. Here too, if there is an increased power requirement, individual cylinder banks or groups are operated as far as possible in a more fuel-efficient mode and another bank or group is switched over to a performance-optimized operating mode to provide the torque.

Another strategy, which is implemented in the coordinator 104 in one exemplary embodiment, is comfort optimization, according to which the switching of individual cylinder banks or cylinder groups from one to the other operating mode is never specified simultaneously, but in chronological succession. This reduces the noise emissions associated with the switchover.

In particular in the case of storage catalytic converters, in order to clear the catalytic converter, it is necessary to switch from stratified charge operation to operation with homogeneous mixture formation from time to time. In this context too, the procedure described for asymmetrical operation of the internal combustion engine can be used successfully, since at least when idling and

Partial load range, both banks do not have to be switched over simultaneously in order to clear the catalytic converter, but can be switched over in succession or, in the case of only one catalytic converter for all banks or cylinder groups, only the alternating switchover of a cylinder bank or cylinder group is sufficient. This will result in a significant improvement in comfort, in particular a reduction in noise emissions.

In addition to a strategy that optimizes consumption and comfort, it is also particularly advantageous to use a strategy that optimizes emissions (e.g. in the area of low power requirements). The torque is divided and / or the desired operating mode is specified in such a way that the lowest possible exhaust gas pollution occurs. So e.g. tries to provide the total target torque by means of lean operation in stratified and / or homogeneous operation as long as this torque can be set with the respective operating mode. Only then is a cylinder bank or group specified by specifying a different one

Set torque and / or a desired operating mode, a less exhaust-optimal working point.

The individual target torques MIS0LL1 to MISOLLN as well as the corresponding desired operating modes are fed to the respective control signal images 106 to 108 for the individual cylinder banks or cylinder groups, in which, taking into account operating variables such as engine speed, relative air filling (derived from the supplied air mass), etc. respective target torque can be converted into a fuel mass to be injected, an ignition angle and a throttle valve position, taking into account the desired operating mode. It may happen that the desired operating mode cannot be met, for example if there is an emergency running situation, if the target torque cannot be adjusted, for special operating functions such as start, warm-up, heating, etc.

FIG. 2 shows a system in which a separate throttle valve is actuated for each cylinder bank or group. is cash. In this case, the operating mode can be freely selected for each bank and the torque requirements can be distributed among the banks in such a way that an optimal efficiency of the internal combustion engine or, depending on the strategy, optimal operation of the internal combustion engine results. If the internal combustion engine has only one throttle valve, this must be set in such a way that there is an air charge which, by corresponding calculation of the fuel mass, allows one cylinder bank to be operated homogeneously and another cylinder bank stratified. As a result, an overall increased air filling compared to the homogeneous operation of the internal combustion engine is set, as a result of which throttle losses are reduced. It is possible to quickly change the operating mode of the cylinder banks by controlling the fuel mass.

An exemplary embodiment of the coordinator 104 is outlined in greater detail on the basis of the flowchart in FIG. 3 using the example of an internal combustion engine with two independently controllable cylinder banks or groups. The program will run at predetermined time intervals.

In the first program step 200, the total target torque MISOLL is recorded. In the subsequent step 202, it is checked on the basis of this target torque whether there is an increased power requirement. In a preferred exemplary embodiment, this is the case when the target torque exceeds a predetermined limit value. This threshold value is dimensioned such that it roughly corresponds to a limit line above which the internal combustion engine with homogeneous mixture formation would be operated for performance reasons. If an increased power requirement was recognized in step 202, it is checked in step 204 whether the power requirement is so high that all cylinder banks or groups are to be switched over. This is the case if a target torque value is required that is close to the ximal values. If this is the case, according to step 206, homogeneous operation is first output as the desired operating mode of the first bank or cylinder group BASOLLI and a setpoint torque value MISOLL1 is determined for this cylinder bank or group. In a preferred exemplary embodiment, this setpoint torque value is formed on the basis of the total setpoint torque value which is read in in step 200. In particular, a percentage of this target torque value> 50% is specified. Then, in step 208, it is checked, if necessary, on the basis of a transmitted mark whether the switchover has ended. If this is the case, according to step 210 the homogeneous mode is also output as the desired operating mode for the second cylinder bank or cylinder group and the target torque of this cylinder bank or group is determined on the basis of the total target torque and the target torque of the first cylinder bank or group. If the switchover of the first cylinder bank according to step 208 has not yet been completed, the desired operating mode of the second cylinder bank for stratified charge mode is recorded according to step 212 and the difference between the total target torque value and the target torque value of the first bank is determined as the target torque value in accordance with step 210. After steps 210 and 212, the setpoint values formed are output in step 214 and are realized if there are no superordinate specifications, for example emergency operation, lack of realizability of the setpoint torque value in the desired operating mode, etc. The program section is then ended and run through again at the next time interval.

If, in accordance with step 204, a power request has been recognized which does not require all banks to be switched over, in step 216 the target operating mode of one bank is set to the homogeneous mode and that of the other bank to the stratified charge mode. Likewise, the target torque of the one bank that is to be operated homogeneously is generated analogously to step 206. det, while the target torque of the other bank, which is operated in the stratified charge mode, is determined on the basis of the total target torque and the target torque of the first bank. This is followed by step 214. As a result of the asymmetrical operating mode of the internal combustion engine described in step 216, consumption-optimized control of the internal combustion engine is achieved with an increased power requirement since part of the internal combustion engine continues to be operated in the fuel-efficient stratified charge mode. Comfort is also improved since the banks or groups are switched one after the other, not simultaneously. The strategies mentioned, which are followed by the subsequent switchover to catalytic converter removal and exhaust-gas-optimized control, are all used together or in any combination, depending on the version.

If, according to step 202, there is no increased performance requirement, step 226 checks whether the conditions for clearing out a storage catalytic converter are present. If the conditions for clearing are fulfilled, homogeneous operation is output as the desired operating mode for a cylinder bank in accordance with step 228 and a corresponding target torque (e.g. minimum target torque for this operating mode) is determined. In the subsequent step 230, the stratified charge mode is output as the desired operating mode of the other bank and the target torque is determined on the basis of the total target torque and the target torque of the first bank. This is followed by step 214. This measure removes the storage catalytic converter without the entire internal combustion engine having to be switched over to homogeneous operation. In addition to fuel consumption, improvements in noise and thus comfort are also achieved.

If the conditions for clearing the catalytic converter are not present, the target operating mode becomes the according to step 218 first bank is set to stratified charge mode and a corresponding target torque determined from the target torque value is specified. In a preferred exemplary embodiment, this corresponds to 50% of the total target torque value read in step 200. In the subsequent step 220, it is checked whether the switchover from shift to homogeneous operation has ended, if appropriate. If this is the case, the second cylinder bank is also set to the desired stratified charge operating mode in accordance with step 222 and the corresponding target value is formed on the basis of the total target torque value and the target torque value of the first bank. If the switchover according to step 220 has not ended, ie if the system is in unsteady mode, the second bank is controlled according to step 224 as before and the setpoint torque value is formed analogously to step 222. This measure prevents the two banks from switching over simultaneously and thus reducing comfort. This is followed by step 214.

In a preferred embodiment, it is provided that the asymmetrical operation of the internal combustion engine, i.e. when the internal combustion engine is operated with two different operating modes or with two different setpoint torque values, the respective operating state of the cylinder banks of the internal combustion engine can be changed alternately, i.e. to switch the banks in a predetermined time grid, for example when operating one cylinder bank in homogeneous and the other in shift operation, in such a way that the first bank is operated in shift operation and the second bank in homogeneous operation (toggle).

In the exemplary embodiment described, two cylinder banks are provided which have two electrically actuable throttle valves which can be controlled independently of one another. In addition to such a solution, the solution according to the invention is also to be used on internal combustion engines with a plurality of cylinder banks and a plurality of throttle valves which can be controlled independently of one another (corresponding to the number of cylinder banks), in particular also in engines with single throttle valves for each cylinder.

In another embodiment, at least in certain operating situations, e.g. with high torque and performance requirements, the cylinder banks are switched over simultaneously. This will improve the dynamic

Behavior reached. In relation to the program in FIG. 3, this means that steps 208 and 212 and possibly steps 220 and 224 are omitted at least in the said operating state and steps 206 and 210 or steps 218 and 222 are combined.

In general, a cylinder bank or group is switched over when the first cylinder is operated in the new operating mode. At the same time, it is understood above that the switchover is initiated at a bank or group within a period of time between the switching signal and the injection that has taken place in the first cylinder in the new operating mode at the bank or group at which previously the operating mode has been changed. Correspondingly, successively means the initiation of the switchover at a bank outside of this time period specified by the bank or group that was switched first.

In a further exemplary embodiment, a corresponding procedure is used in an internal combustion engine with only one controllable throttle valve, one cylinder group being operated homogeneously and the other being operated in stratified fashion. In this case, the air filling is increased by the throttle valve, so that a larger proportion of the target torque value through homogeneous control of the one cylinder group with stoichiometric fresh or lean mixture composition takes place, while a smaller proportion of the target torque is carried out by stratified charge operation of the other cylinder group.

Claims

Expectations

1. A method for operating an internal combustion engine with gasoline direct injection, which has at least two cylinder banks or cylinder groups which are controlled as a function of at least one preset value, characterized in that in at least one operating state of the internal combustion engine, the one cylinder bank or the one cylinder group is dependent on a default value is controlled, which differs from the corresponding default value of the at least one other cylinder bank or group.

2. The method according to claim 1, characterized in that the default value is a target torque value or a desired operating mode.

3. The method according to any one of the preceding claims, characterized in that a total target torque value is predetermined, which is controlled a cylinder group or cylinder bank with a first portion of this total target torque, another cylinder bank or group is controlled with a second portion of the target torque, wherein the two parts of the target torque result in the total target torque.

4. The method according to any one of the preceding claims, characterized in that the internal combustion engine with little At least two different operating modes are operated, wherein in the at least one predetermined operating state, the one cylinder bank or cylinder group is operated in a first, the at least one other cylinder bank or cylinder group is operated in a second operating mode.

5. The method according to any one of the preceding claims, characterized in that the at least one operating state is the operating state of increased power requirement and / or the operating state during which a storage catalytic converter is cleared.

6. The method according to any one of the preceding claims, characterized in that a switching of the operating modes of the individual cylinder banks or groups takes place in succession.

7. The method according to any one of the preceding claims, characterized in that a desired operating mode is specified depending on the operating state, which is then realized by controlling the individual cylinder banks or groups, if this implementation does not contradict other specifications.

8. The method according to any one of the preceding claims, characterized in that an electrically operable throttle valve is provided for each cylinder bank or cylinder group, the control of which is used to switch the operating mode.

9. The method according to any one of the preceding claims, characterized in that only one electrically controllable throttle valve is provided for all cylinder banks or cylinder groups, which is controlled in asymmetrical operation with different operating modes in the sense of an increased air filling compared to the throttled operation, so that some of the cylinders can be operated in the first, another part in the second, dethrottled mode.

10. The method according to any one of the preceding claims, characterized in that the switching of the operating modes of the individual cylinder banks or groups takes place simultaneously, at least in an operating state with high power or torque requirements.

11. Device for operating an internal combustion engine with gasoline direct injection, with at least one control device which controls the internal combustion engine on the basis of at least one preset value, characterized in that the control device contains means which, in at least one predetermined operating state of the internal combustion engine, comprise a first cylinder bank or cylinder group of the Internal combustion engine with a first default value, controls at least one further cylinder bank or group of the internal combustion engine with a second default value, the two default values differing.