EP3286422A1 - Method and device for the model-based optimization of a technical apparatus - Google Patents

Abstract

The invention relates to a method for the model-based optimization, in particular calibration, of a technical apparatus, in particular an internal combustion engine. The method comprises the following work steps: sensing at least one first parameter in relation to the technical apparatus to be optimized, which at least one first parameter characterizes a physical quantity; performing a first determination of at least one second parameter in relation to the technical apparatus to be optimized by means of at least one first physical model, which characterizes at least one known physical relationship and for which the at least one first parameter is an input parameter; performing a second determination of at least one third parameter by means of at least one first empirical model, which is based on measurements performed on a plurality of already known technical apparatuses of the same type, in particular internal combustion engines, and for which at least the at least one second parameter is an input parameter, wherein the at least one third parameter is suitable for characterizing the technical apparatus to be optimized and/or for making a change to the technical apparatus to be optimized on the basis of the at least one third parameter, in particular for adjusting the control of the technical apparatus to be optimized; and outputting the at least one third parameter.

Description

 Method and device for model-based optimization

 a technical facility

The invention relates to a method and a device for model-based optimization of a technical device, in particular an internal combustion engine.

In order to meet future legislation and the conflict between fuel consumption and emissions, internal combustion engines with all their components are generally optimized as a complete system.

Knowledge of the transient engine behavior with regard to consumption and emissions at a very early stage of development is of great importance for efficient engine development, which is to be made possible, inter alia, by the use of simulation tools.

An increasing number of manipulated variables and stricter statutory emission and diagnostic requirements significantly increase the effort of engine development and calibration. At the same time, however, development times should be reduced in order to enable ever faster product cycles.

In order to handle the increasing development and calibration effort in engine development with reasonable effort, model-based development methods have become an important part of the calibration process. In order to be able to use such model-based development methods efficiently in the engine development process, the methods must be able to calculate transient processes of the internal combustion engine in real time.

Targeted, model-based overall system optimization requires the possibility of transient engine model operation. That way you can Using efficient and fast engine models, concepts can be examined cost-effectively and, if necessary, optimized in a short time.

Various approaches for model-based optimization of technical facilities are known from the prior art. Particularly in the field of optimization in the development or calibration of internal combustion engines, processes are used as follows:

EP 1 150 186 A1 relates to a method for automatically optimizing an output variable of a system dependent on several input variables, for example an internal combustion engine, while maintaining secondary conditions, wherein a theoretical value for the output variable and the secondary conditions is based on a model function with the input variables as variables be determined and thereby in each case one of the input variables within a variation space is changed in successive individual steps. Corresponding values for output variables and secondary conditions corresponding to the respective input variables are determined directly at the system and used to correct the model functions until the model functions fulfill the secondary conditions and achieve optimum values for the output variable. WO 2013/131836 A2 relates to a method for optimizing internal combustion engines, in particular for optimizing emissions and consumption, in which at least one of the secondary influencing variables is set via correction functions in their control units in each operating point given by the parameters temperature, load and speed such that The emission limit values are complied with in different load speed ranges and in different temperature ranges. In a first step, a test strip for the operating points and secondary factors is created using mathematical models of the control unit function and the internal combustion engine with respect to the size to be optimized and driven on the test stand, in a second step from the measured data on the test bench a model for each size to be optimized is created, and in a third step, based on this model, the optimal values of the secondary variables are determined in compliance with the emission limit values and these values are used by the control unit for the initial correction functions. EP 1 703 1 10 A1 relates to a method for optimizing the calibration of internal combustion engines taking into account dynamic state changes of the engine and using a neural network, wherein the calibration test starts from a start condition and changes of the parameters defined for the calibration are set.

DE 10 201 1 013 481 A1 relates to a method for controlling an internal combustion engine and an internal exhaust gas recirculation. The internal exhaust gas recirculation is adjustable via a variable valve control of valves of the internal combustion engine. In the method, a total gas mass and an oxygen content in a combustion chamber of the internal combustion engine is determined. Furthermore, a desired total gas mass and a desired oxygen content in the combustion chamber are determined for a given operating point of the internal combustion engine. Depending on the total gas mass, the oxygen content and the target total gas mass and the desired oxygen content, an actuator of the internal combustion engine is set.

US 2014/0326213 A1 relates to a controller that predicts a predicted value of turbocharging pressure based on a predicted value of a throttle opening degree using a physical model of the turbocharged engine. The controller also calculates a correction amount. To this end, a measured value of the turbocharging pressure is detected by a turbocharged pressure sensor, and an estimated value of the turbocharging pressure is calculated based on a measured value of a throttle opening degree using a physical model of the turbocharged engine. A difference between the measured value and the estimated value of the turbocharging pressure is calculated, and the difference is used as a correction amount for the predicted value of the turbocharging pressure. On the basis of the corrected predicted value of the turbo boost pressure and a predicted value of the degree of throttle opening, the controller calculates a predicted value of the amount of cylinder intake air. It is an object of the invention to provide a method and a device for model-based optimization of a technical device, in particular an internal combustion engine, which make it possible to move further development tasks of the device from a real to a virtual test bench. With respect to internal combustion engines, it is a further task here to perform the power and emission calibration, but preferably also an application under non-standard environmental conditions on the virtual test bench. Another object is preferably to enable a real-time capable overall system simulation of the technical device.

This object is achieved by a method, a device according to the independent claims. Advantageous embodiments are claimed in the subclaims. The wording of the claims is incorporated herein by express reference.

An inventive method for model-based optimization, in particular calibration of a technical device, in particular an internal combustion engine, preferably has the following steps: detecting at least a first parameter with respect to the technical device to be optimized, which is suitable to characterize a physical quantity; first determining at least one second parameter with respect to the technical device to be optimized by at least one first physical model suitable for characterizing at least one known physical relationship, and for which the at least one first parameter is an input parameter; second determination of at least one third parameter with respect to the technical device to be optimized by at least one first empirical model, which is based on measurements on a plurality of already known technical devices of the same type, in particular internal combustion engines, and for which at least the at least one second parameter is an input parameter is, wherein the at least one third parameter is suitable to characterize the technical device to be optimized and / or make on its basis a change in the technical device to be optimized, in particular to adjust their control; and outputting the at least one third parameter. In a further method according to the invention for model-based optimization, in particular calibration, of a technical device, in particular an internal combustion engine, an overall system of the technical device to be optimized is characterized by at least one first physical model which characterizes at least one known physical relationship and at least one empirical model based on measurements on a plurality of already known technical devices of the same genus, in particular internal combustion engines, simulated. The at least one physical model and / or the at least one empirical model preferably additionally depend on a machine-specific setting parameter in order to adapt the respective model to the technical device to be optimized. In a first phase of the method, at least one measuring point in the operation of the technical device to be optimized is measured and the machine-specific setting parameter is determined on the basis of the at least one measuring point by comparing measured values with values of the measuring point calculated on the basis of the models. In a second phase of the method, measurements are no longer made in the operation of the technical device to be optimized, and the overall system of the technical device to be optimized is simulated by means of the at least one physical model and the at least one empirical model, one determined by means of the at least one physical model second parameter as an input parameter is included in the at least one empirical model.

A device according to the invention for model-based calibration of a technical device, in particular an internal combustion engine, preferably has a measuring device for detecting at least one first parameter with respect to the technical device to be calibrated, which is suitable for characterizing a physical variable. The device preferably also has a memory device in which at least one first physical model of a known physical relationship and at least one first empirical model, which is based on measurements on a plurality of already known technical devices of the same type, in particular internal combustion engines, are stored are. Furthermore, the device preferably has a first allocation device in order to associate the first parameter with a second parameter on the basis of the at least one first physical model, and a second allocation device, at least allocating a third parameter to the second parameter based on the at least one first empirical model. In addition, the device preferably has an interface for outputting the at least one third parameter, the third parameter being suitable for characterizing the technical device to be calibrated and / or for making changes to the technical device to be optimized, in particular for controlling it adjust.

Detecting within the meaning of the invention is a read-in of parameter values, in particular by automatic or manual input and / or an execution of measurements for determining a parameter.

A physical quantity in the sense of the invention is a quantitatively determinable property of a physical object, process or state. It is preferably expressed as the product of a numerical value (the measure) and a unit of measure. Vector sizes are indicated by a size value and direction. Preferably, the units of measurement are defined according to the SI standard.

Determining within the meaning of the invention is an assignment of an output parameter to an input parameter, in particular on the basis of a function, function table or other assignment rule.

A physical model in the sense of the invention represents a known physical relationship, which is based in particular on basic physical functions. Preferably, physical models are generally valid at least for the type of technical equipment of which a technical device is to be optimized, but in particular for all technical devices. A physical model can consist of a physical formula or of several physical formulas or physical relationships.

An empirical model according to the invention is based on measured values at a plurality of already known technical devices in his Logic built. Preferably, methods of the compensation calculation, in particular regression models, are used.

A plurality according to the invention are at least two.

Output within the meaning of the invention is a representation for a user or provision of at least one value to a further working step of the method according to the invention. Preferably, a parameter value is further used in the output within the model-based optimization method.

A genus in the sense of the invention denotes an assignment of a technical device to a group of technical devices. As genera in particular the prime movers, internal combustion engines, petrol engines, diesel engines, etc. or any other grouping on the basis of technical similarities of technical facilities come into question.

The invention is based, in particular, on the approach of coupling individual models as submodels with one another in a model-based optimization, so that real-time-capable optimization of the technical device, for example the combustion of an internal combustion engine, is possible. In order to be able to make the most accurate statements about the behavior of the technical device, empirical models are, as far as possible, replaced by physical models that reflect a universally valid physical relationship. The calculations are preferably not crankshaft-angle-resolved, ie according to the invention values are not calculated over the entire cycle of a crankshaft revolution in cyclic intervals of the crankshaft angle. In contrast to this, only the values in certain crank angle positions, in particular in the combustion center of gravity (MFB 50%), the injection time and / or the ignition time, are preferably calculated. By employing a variety of common physical submodels, the number of empirical submodels can be significantly reduced. As a result, the input parameters in the empirical submodels can be selected so that a plurality of motors can be mapped with one and the same set of input parameters. The adaptations of the individual empirical submodels to the respective technical device to be optimized can then be done via adjustment parameters.

In this case, the adjustment parameter preferably enters the corresponding model as an additional input parameter. Particularly preferably, the machine-specific adjustment parameter is an input parameter in the empirical model. As an input parameter, the machine-specific adjustment parameter preferably has a coefficient in a polynomial model approach, as well as all other terms of the polynomial. The setting parameter of a model is preferably constant over the operating range of a single technical equipment, but varies depending on the technical equipment. In contrast, the coefficients of the model are preferably constant for the entire operating range of a technical facility, but also for all other technical facilities. Since a setting parameter is not a simple offset value, not only the position of the functions of the individual models but also its model quality changes, in particular the coefficient of determination R ² with respect to the residuals can be significantly improved.

 The particular crank angle positions at which the parameters according to the invention are calculated are executed causally one after the other in the order of the combustion process.

In an internal combustion engine, for example, starting from the start of injection of the first injection and the resulting effects on the subsequent injections, an output engine output, heat flows into the cooling water and into the exhaust gas and nitrogen oxide emissions are calculated.

Furthermore, with respect to internal combustion engines according to the invention, it is also possible to use submodels which, although they do not act directly in the cylinder during combustion, are of great importance for use in reality, eg engine friction. According to the invention, with respect to an internal combustion engine, it is also possible to calculate power losses across the cylinder walls without dissolving the combustion according to the crankshaft angle. The knowledge of the power loss over the cylinder walls is an essential prerequisite for the quasi-physical calculation of engine power and exhaust gas enthalpy. With regard to the combustion The following parameters can be calculated by the model: combustion parameters (start, center of gravity and peak pressure, heat flow, engine power, gas temperature, nitrogen oxide emissions or soot emissions). For the empirical models, a multiplicity of measurements are preferably made according to the invention to a plurality of already known technical devices, and based on the measured data, in particular by means of a regression analysis, empirical models, in particular polynomial models, are created. The quality of the empirical models is all the better, the more well-known technical devices of the type of technical equipment to be optimized are used to produce the empirical models.

In particular, the method according to the invention and the corresponding apparatus for model-based optimization can provide qualitatively and also quantitatively true statements without the presence of measured data.

If a particularly high model quality is desired for a simulation, the value of the setting parameter of an empirical submodel can be determined exactly by measuring a few operating points or even a single operating point. This adjustment parameter is consequently constant over the entire operating range of the technical device to be optimized. The adjustment parameter can be determined for example by a measurement under standard conditions on a test bench. As a result, the calibration of the technical equipment on the test bench can be continued under standard conditions on the test bench, whereas the calibration is carried out under different conditions with the model.

In an advantageous embodiment of the method according to the invention, at least the second determination of the at least one third parameter is carried out exclusively in at least one predetermined time, in particular crankshaft position, of the technical device, in particular an injection time, closing of an intake valve, ignition point and / or combustion center (MFB 50 %). By the method according to the invention or to carry out the method carried out calculations not over the entire cycle of the crankshaft, ie non- crankshaft angle resolved, can be calculated according to the invention, the computing time and the required computing power of a device according to the invention can be substantially reduced without significant loss of information. In a further advantageous embodiment of the method according to the invention, this further comprises the step of normalizing the at least one first parameter and / or the at least one second parameter and / or the at least one third parameter, preferably with respect to a power potential of the technical device to be optimized , in particular with respect to a displacement of the internal combustion engine. By normalization, it is possible in particular to represent generally valid relationships with the method according to the invention, which are not limited to a technical device. In an internal combustion engine, the parameters are preferably related specifically to the liter displacement. Based on this, if necessary, the following specific measurands can be used:

 Fuel quantity in mg / cycle / l

 Fuel energy in W / l

 Enthalpy flows into and out of the cylinder in W / l

 - Wall heat flux in W / l

 - Indexed performance of high pressure and low pressure loop in W / l.

In a further advantageous embodiment of the method according to the invention, this further comprises the steps of third determining at least one fourth parameter by a second physical model and / or by a second empirical model based on the at least one third parameter and / or on the basis at least one of a plurality of first parameters and / or at least one second parameter of a plurality of second parameters. Preferably, the at least one fourth parameter is suitable for characterizing the technical device to be optimized and / or for making a change in the technical device to be optimized on the basis thereof, in particular for setting a control of the technical device to be optimized. Further preferably, this fourth parameter is output in a further work step. With the method according to the invention for model-based optimization, the function of the technical device is processed in cascade. In this case, output parameters of submodels are systematically input as input parameters into further submodels. Inputs into the empirical submodels should be calculated using known physical relationships using physical models. In order to continue the cascade-like structure of the model-based optimization method according to the invention, a further advantageous embodiment of the method according to the invention comprises the steps of fourthly determining at least one further parameter by at least one further physical model and / or by at least one further empirical model based on the at least one a third parameter and / or on the basis of the at least one fourth parameter and / or based on at least one of a plurality of parameters and / or at least a plurality of second parameters, wherein the at least one further parameter is suitable to the to characterize technical equipment to be optimized and / or to adjust on the basis of which the control of the technical equipment to be optimized. Preferably, the method according to the invention furthermore has a working step of outputting the at least one further parameter.

In a further advantageous embodiment of the method according to the invention, the third determination of the fourth parameter and / or the fourth determination of the further parameter is performed at a different time of the technical device as the second determination of the third parameter. In this way, points of time which are relevant for the respective physical or empirical models can be processed successively in the order of the function of the technical device. Information resulting from the previously calculated submodels flows directly into the following submodels. In a further advantageous embodiment of the method according to the invention, the detection, the first determination, the second determination and optionally the third determination and the fourth determination are carried out without measurements on the technical device to be optimized. The method according to the invention has the special their advantage that an optimization after any initial adaptation of the model (s) can be made completely without further measurements on a vehicle on the test bench or in real driving conditions. In particular, tests that would have to be performed under non-standard environmental conditions can be easily executed here by a simulation.

In a further method according to the invention for model-based optimization of a technical device, in particular an internal combustion engine, an overall system of the technical device to be optimized with at least one physical model, which characterizes at least one known physical relationship and at least one empirical model based on measurements of a plurality of already known technical facilities of the same genus, in particular internal combustion engines, based, simulated. The at least one physical model and / or the at least one empirical model preferably additionally depend on a machine-specific setting parameter in order to adapt the respective model to the technical device to be optimized. Particularly preferably, only the at least one empirical model depends on a machine-specific setting parameter. Furthermore, in a first phase of the method, at least one measuring point during operation of the technical device to be optimized is measured and the machine-specific setting parameter is determined on the basis of the at least one measuring point by comparing measured values with values calculated on the basis of the models. Further preferably, no measurements are made in a second phase of the method and the overall system of the technical device to be optimized is simulated by means of the at least one physical model and the at least one empirical model. Preferably, a second parameter determined by means of the at least one physical model enters into the at least one empirical model as an input parameter. Further preferably, the machine-specific setting parameter enters the at least one physical model as a further input parameter.

In a further advantageous embodiment of the method according to the invention, at least one of the physical models used and / or at least one of the empirical models used additionally depends on a machine-specific input. Adjusting parameters to adapt the respective model to the technical device to be optimized, preferably for different models each use a different setting parameters. The respective adjustment parameters are used in the submodels in order to adapt them to the respective technical device.

For an internal combustion engine, each setting parameter for a combustion system consisting of nozzle, swirl and combustion chamber is preferably the same for all operating points. The setting parameters are not set individually for each operating point, but only for one hardware configuration at a time. Preferably, however, the adjustment parameter can also be a function which depends on further parameters. Further preferably, the adjustment parameters are based on physically based effects, but due to their complexity are difficult to consider in a model. In the case of an internal combustion engine, for example, this is the interaction between injection jet and piston recess during combustion.

Preferably, the adjustment parameters according to the invention are integrated directly into the model structure, thereby making it possible to correctly model direct or indirect effects whose influences do not have the same amount in all model inputs. With the inventive empirical submodels and their largely physically calculated input variables, it is possible, in the case of internal combustion engines combustion in new engines without adaptation of the model coefficients only by specifying the states before and after the cylinder at predetermined times, the geometric data, the fuel properties, the To calculate injection parameters from the engine control unit and by adjusting adjustment parameters. The setting parameters represent a good compromise between parameterizing effort and model accuracy and are used in particular in a diesel engine or gasoline engine in order to adapt the compression, the ignition delay, the burn-through speed as well as the power loss, in particular the friction power, engine-specific. With the same submodels, the combustion process can be calculated in this way, preferably in the case of internal combustion engines (but of the same type) not involved in the production of the empirical models. The setting parameters for the empirical submodels are chosen so that all motors with and can be mapped to the same parameter set. The use of adjustment parameters as additional model inputs into the empirical submodels has the advantage that interactions of adjustment parameters and model input parameters can occur and therefore the adjustment parameters are not constant offsets or factors.

In a further advantageous embodiment, a compression setting parameter or polytropic exponent setting parameters for a polytropic exponent model, an ignition delay setting parameter for an ignition delay model, a combustion focus setting parameter for the combustion center model (MFB 50%), a motor friction are available as setting parameters A friction power model, a residual gas adjustment parameter for a residual gas content model, a charge calculation parameter for a fresh air mass model, a high pressure power adjustment parameter for a high pressure indicated power model, and / or a charge cycle loss adjustment parameter for a charge exchange loss model. For optimizing a diesel engine, it is preferable to use the compression set parameter, the ignition delay setting parameter, the combustion focus setting parameter, and the engine friction adjusting parameter. For a gasoline engine, preferably the ignition delay adjustment parameter, the combustion focus adjustment parameter, the engine friction adjustment parameter, the fuel charge adjustment parameter, the residual gas control parameter, the charge cycle loss adjustment parameter and the high pressure power adjustment parameter are used.

In a further advantageous embodiment of the method according to the invention, a value of at least one machine-specific setting parameter is the same for all operating points of the technical device to be optimized, in particular the internal combustion engine, wherein the internal combustion engine is preferably defined by at least one of the following groups: nozzle, combustion chamber and charge movement , in particular spin or tumble; Valve characteristics and inlet geometry; Power dissipation characteristics. For a diesel engine, for example, the setting parameters for a combustion system, comprising a nozzle, swirl and combustion chamber, are preferably the same for all operating points. Thus, the setting parameters need not be set individually for each operating point but only for a hardware configuration of the motor. As base value for the calculation of new engines of which no measured data are available. For example, mean values from the setting parameters found during model creation can be used.

In a further advantageous embodiment of the method according to the invention, the machine-specific adjustment parameter is a further input parameter for the respective model, which is constant for the entire operating range of the technical device to be optimized. As already stated, the setting of the machine-specific setting parameter is dependent on the technical device to be optimized. For the simulation of a single device, the adjustment parameter is preferably constant. The method according to the invention therefore makes it possible to adapt the overall model or the respective submodels to a specific technical device in a particularly simple manner and once.

Therefore, in a further advantageous embodiment of the method according to the invention, the output value for a machine-specific setting parameter of the technical device to be optimized is determined on the basis of the values of setting parameters of the plurality of already known technical devices, in particular an average value. In a further advantageous embodiment of the method according to the invention, this further preferably has the following working steps: measuring at least one measuring point during operation of the technical device to be optimized; and determining the machine-specific adjustment parameter on the basis of the at least one measurement point by comparing measured values with calculated values of the first parameter or the second parameter with the same input parameters.

In a further advantageous embodiment of the method according to the invention, this further includes the step of detecting the at least one second parameter and determining the at least one machine-specific Einstellpa- parameter based on the at least one detected second parameter, in particular by comparing at least one detected value at least one value of the at least one third parameter determined on the basis of the first empirical model. Also preferably, the at least one third parameter is detected which determines at least one machine-specific setting parameter on the basis thereof, in particular by comparing at least one detected value with at least one value of the at least one third parameter determined on the basis of the first empirical model.

Further preferably, the at least one fourth parameter is also detected and the at least one adjustment parameter based on the detected at least one fourth parameter, in particular by comparing at least one detected value with at least one determined by the second empirical model value of the at least one fourth parameter.

Further preferably, the at least one further parameter is detected and the at least one adjustment parameter is determined on the basis of the detected at least one parameter, in particular by comparing at least one detected value with a value of the at least one further parameter found on the basis of the further empirical model. In a further advantageous embodiment of the method according to the invention, this further comprises the operating step of changing at least one first parameter of the technical device to be optimized on the basis of the at least one third parameter, the at least one fourth parameter and / or the at least one further parameter.

In a further advantageous embodiment of the method according to the invention, this has the working step of changing the at least one first parameter of the technical device to be optimized on the basis of the at least one third parameter, the at least one fourth parameter and / or the at least one further parameter. The values of the respective parameters or value curves of the respective parameters determined by the method according to the invention for model-based optimization allow conclusions to be drawn as to how the direction itself or their control must be changed in order to optimize the function of the technical device.

In a further advantageous embodiment of the method according to the invention, this further comprises the step of evaluating the at least one third parameter, the at least one fourth parameter and / or the at least one further parameter based on a reference. As a result, an evaluation of the configuration of a technical device subjected to the method according to the invention can be evaluated on the basis of various criteria. Preferably, this evaluation is also output.

In a further advantageous embodiment of the method according to the invention, the at least one first parameter is predetermined or set by a control device for the technical device to be optimized. As a result, the control function or functions stored on a control unit for the technical device can be checked. The response of the method according to the invention corresponds to the simulated reaction of the technical device.

In a further advantageous embodiment of the method according to the invention, the at least one first parameter can be influenced by a change in constructive features of the technical device to be optimized.

In a further advantageous embodiment of the method according to the invention, the at least one empirical model is a polynomial model, the coefficients of which are determined by means of a compensation calculation based on the measurements on the plurality of already known technical devices of the same type, in particular internal combustion engines, wherein the adjustment parameter is an input parameter of the empirical model, which is multiplied by at least one coefficient and which is constant for the technical device to be optimized.

In a further advantageous embodiment of the method according to the invention, at least one of the following groups is selected as the first parameter: Geometrical data, in particular bore, stroke, connecting rod length, compression ratio, number of cylinders, number of injection holes, flow rate injector and / or cylinder surface / cylinder volume ratio, crank radius, cylinder stroke volume, cylinder compression volume, effective flow area nozzle hole, nozzle hole diameter, valve lift curves, charge flap;

 Data relating to an operating point, in particular injection start of the main injection, rotational speed, main injection quantity, pilot injection quantity, post injection quantity, start of injection injection, cylinder pressure at start of injection, pressure in intake manifold, piston stroke at start of injection, stroke volume at start of injection, cylinder volume at start of injection, temperature at start of injection, Coolant temperature, oil temperature, ignition timing;

 Air path related data, in particular boost pressure, charge air temperature, exhaust manifold pressure, turbine pressure, inlet and outlet valve opening and closing times, EGR rate, degree of delivery, absolute humidity oxygen concentration in air, pressure and temperature in intake manifold, outlet manifold temperature, maximum inlet and outlet valve lift;

 Fuel system-related data, in particular hydraulic delay injection start, hydraulic delay injection end, fuel density, duration of the main injection, start of injection, preferably energization start main injection, end of injection, injection pressure, energization start pilot injection, and / or energization start post-injection, intake manifold temperature, fuel content of the tank ventilation;

 Combustion-related data, in particular lower calorific value, lambda value, cylinder surface at a crank angle of the mixture combusted to 50% (MFB 50%), volume-specific fuel power, volume-specific fuel quantity, volume-specific fuel I ei stung a post-injection.

In a further advantageous embodiment of the method according to the invention, the second parameter and / or the fourth parameter are selected from at least one of the following groups, which are determined on the basis of a physical model: Fuel mass flow, in particular, this can be calculated from consumed in a measuring time volume and the known fuel density, wherein at least one parameter is selected from the following group as the input parameter for a physical model for determining the fuel mass flow in the cylinder

 Fuel density;

 pre-injection;

 Main injection amount;

 post-injection;

In-cylinder gas composition, in particular oxygen concentration in the cylinder, wherein as input parameter for a physical model for determining the gas composition in the cylinder at least one parameter is selected from the following group:

 lambda;

 EGR rate or residual gas content in the cylinder;

 Humidity;

mass-related amount of heat, wherein at least one parameter from the following group is selected as the input parameter for a physical model for determining the mass-related heat quantity:

 Fuel mass flow;

 total cylinder mass flow including residual gas;

 lower calorific value;

 Piston movement, in particular mean piston speed, piston speed at the start of injection, cylinder volume at the start of injection and / or compression ratio at the start of injection, in particular effective compression ratio at start of injection, cylinder volume at intake valve closing, cylinder volume at ignition timing, piston speed at intake valve closing, piston speed at ignition timing, being used as input parameter for a physical model for determining piston movement is selected at least one parameter from the following group:

 Rotation speed;

stroke; Crank radius;

 connecting rod;

 Crankshaft angle at start of injection;

 polytropic;

 Cylinder pressure at start of injection;

 Pressure in the intake manifold;

 Stroke volume of a cylinder;

 Compression volume of a cylinder;

 Piston stroke at start of injection;

 Drilling;

 Stroke volume at start of injection;

 Piston stroke at ignition timing;

 Stroke volume at ignition time;

 Piston stroke when closing the inlet valve;

 Displacement when closing the inlet valve;

thermodynamic state in the cylinder at the start of injection, with at least one parameter selected from the following group as input parameter for a physical model for determining the thermodynamic state in the cylinder at the start of injection:

 Cylinder pressure at start of injection;

 Temperature at start of injection;

 total mass in the cylinder;

 ideal gas constant;

thermodynamic state in the cylinder at intake valve closing, with at least one parameter selected from the following group as the input parameter for a physical model for determining the thermody- namic state in the cylinder at intake valve closing:

 Pressure in cylinder with intake valve closing;

 Gas mixture temperature in cylinder with intake valve closing;

Air mass in the cylinder (fresh air and residual gas);

 Fuel mass in the cylinder;

Gas constant of the air / fuel mixture in the cylinder; thermodynamic state in the cylinder at the ignition point, wherein at least one parameter from the following group is selected as the input parameter for a physical model for determining the thermodynamic state in the cylinder at the ignition time:

 Pressure in the cylinder at the time of ignition;

 Gas mixture temperature in the cylinder at the time of ignition;

Air mass in the cylinder (fresh air and residual gas);

 Fuel mass in the cylinder;

 Gas constant of the air / fuel mixture;

Exit velocity from a nozzle and / or droplet diameter, wherein at least one parameter from the following group is selected as the input parameter for a physical model for determining the exit velocity from a nozzle:

 Cylinder pressure at start of injection;

 Injection pressure;

 Fuel density;

 Flow injectors, especially according to the manufacturer;

 Number of nozzle holes;

 effective flow cross section nozzle hole;

 Nozzle hole diameter;

Properties of the fuel, in particular surface tension of a fuel and / or kinematic viscosity of the fuel;

 Charge density at start of injection;

 Cylinder pressure at start of injection;

 average drop diameter;

Drop diameter, where at least one parameter from the following group is selected as the input parameter for a physical model for determining the droplet diameter:

 Injection pressure.

 effective flow cross section nozzle hole;

Nozzle hole diameter; Start of combustion, wherein at least one parameter from the following group is selected as the input parameter for a physical model for determining the start of combustion:

 Start of injection or ignition point;

 ignition delay;

 Exhaust gas temperature at the cylinder outlet, wherein at least one parameter from the following group is selected as the input parameter for a physical model for determining the exhaust gas temperature at the cylinder outlet:

 Power loss via cylinder walls;

 Indexed mean pressure;

 Chemically bound energy of the fuel

 Einlassenthalpie.

In a further advantageous embodiment of the method according to the invention, at least one of the following groups is selected as third parameter, fourth parameter and / or further parameters, which are determined on the basis of an empirical model:

 • In-cylinder pressure at intake valve closing, with at least one parameter selected from the following group as the input parameter for an empirical model for determining in-cylinder pressure at intake valve closing:

 Time intake valve closing;

 Pressure and temperature in the intake manifold:

 Piston speed at intake valve closing;

 Fuel quantity in cylinder at time intake valve closing; - Differentiation criterion intake valve closing before or after

 Charge change top dead center;

 Polytropic exponent, in particular the temperature and pressure at the start of injection, wherein at least one parameter from the following group is selected as the input parameter for an empirical model for determining the polytropic component:

 Rotation speed;

Gas mixture temperature in cylinder at intake valve closing; Base polytropic exponent;

 Start of injection;

 Intake manifold temperature;

 Mass-related amount of heat;

 Cylinder volume at the time of ignition;

 Lambda value;

 Polytropic exponent setting parameters

Ignition delay, with at least one parameter selected from the following group as the input parameter for an empirical model for determining the ignition delay:

 Rotation speed;

 Gas temperature and / or pressure in the cylinder at the beginning of the injection or at the ignition point;

 intake valve;

 Position of the charge movement flap;

 Droplet diameter;

 Oxygen concentration;

 Piston speed at start of injection;

 Ignition delay setting parameters;

 Residual gas content in the cylinder;

 Mean piston speed;

 Lambda value:

 ignition timing;

 Fuel quantity equivalent for fuel quantity in the cylinder;

Combustion focus, where at least one parameter from the following group is selected as input parameter for an empirical model for determining the combustion center of gravity:

 Rotation speed;

 Residual gas content in the cylinder;

 intake valve;

 Injection duration;

ignition delay; Exit velocity from injector;

 Oxygen concentration in a combustion chamber;

 ignition timing;

 lambda;

 Mean piston speed;

 Position of the charge movement flap;

Power loss over the cylinder walls, wherein at least one parameter from the following group is selected as the input parameter for an empirical model for determining the power loss across the cylinder walls:

 Volume-specific fuel output of the main injection;

 Surface-to-volume ratio of a combustion chamber;

 Piston speed;

 Residual gas content in the cylinder;

 1 / lambda;

 Combustion center and / or cylinder surface at combustion center of gravity;

 AG R rate;

 Start of combustion;

 Temperature at start of injection;

 Volume-specific fuel performance of a post-injection;

 Start of injection of post-injection;

 Distinguishing criterion Power loss calculation for high and low engine loads;

 Pressure in the cylinder at the time of ignition;

 Gas mixture temperature in the cylinder at the time of ignition; indicated mean pressure of the high-pressure loop, wherein at least one parameter from the following group is selected as the input parameter for an empirical model for determining the indicated mean pressure of the high pressure loop:

 Volume-specific fuel performance;

 Volume specific wall heat flux;

Start of combustion; Focus of combustion, in particular combustion duration up to combustion center of gravity;

 Volume-specific fuel performance of a post-injection;

 Start of injection of a post-injection;

 Distinguishing criterion Invoice output power for high and low engine loads;

 setting parameters;

 Lambda value;

 Piston speed;

Peak cylinder pressure, where at least one parameter from the following group is selected as the input parameter for an empirical model for determining the peak cylinder pressure:

 Pressure at start of injection of the main injection;

 Start of combustion;

 By burning time;

 Specific fuel mass, in particular from fuel mass flow;

 Friction loss, whereby at least one parameter from the following group is selected as the input parameter for an empirical model for determining the frictional loss:

 Peak cylinder pressure;

 Mean piston speed;

 Coolant temperature;

 Oil temperature;

 Setting parameter engine friction;

 High pressure performance;

Charge exchange losses

 Pressure in the intake manifold;

 Pressure in the outlet collector;

 Drilling;

 Sucked fresh air quantity:

intake valve; setting parameters;

 Nitrogen oxide emissions, with at least one parameter selected from the following group as input parameter for an empirical model for the determination of nitrogen oxide emissions:

 Oxygen concentration at the start of burning (from gas composition);

 Burning start of the main injection;

 MFB50%;

 setting parameters;

 Scavenging parameters;

 Burning time Start of combustion until center of combustion;

Rotation speed;

 1 / lambda;

 Temperature at the start of injection of the main injection; Mean piston speed;

 Gas mixture temperature in the cylinder at the time of ignition;

Lambda equivalent;

 Amount of fresh air in the cylinder;

 Residual gas content in the cylinder;

 Burn time parameters.

Hydrocarbon emissions, with at least one parameter selected from the following group as input parameter for an empirical model for the determination of hydrocarbon emissions:

 Average piston speed

 Fresh air quantity in the cylinder

 lambda equivalent

 Burning time start to MFB50%

 Indexed medium pressure

 Cylinder wall temperature

 Residual gas content in the cylinder

 Scavenging parameters

Burn time parameters. Carbon monoxide emissions, wherein as input parameter for an empirical model for determining the carbon monoxide emissions at least one parameter is selected from the following group:

 Lambda equivalent;

 Mean piston speed;

 Amount of fresh air in the cylinder;

 Temperature of the sucked exhaust gas;

 Start of injection and duration of the first and further injections;

 Residual gas content in the cylinder;

 Burning time parameter;

 Scavenging parameters.

 Soot emission, with at least one parameter selected from the following group as input parameter for an empirical model for the determination of nitrogen oxide emissions:

 lambda;

 AG R rate;

Injection pressure. In a further advantageous embodiment of the method according to the invention, the at least one first, the at least one second and / or the at least one third empirical model from the measurements of a plurality of already known technical devices determined by a method of limited squares. In a further advantageous embodiment of the method according to the invention, at least four different empirical models, preferably at least six different empirical models, more preferably eight different empirical models, most preferably eleven different empirical models, are included in the calibration. In a further advantageous embodiment of the method according to the invention, a machine-specific setting parameter is entered in each of the at least four different empirical models as the input parameter. In a further advantageous embodiment of the method according to the invention, the empirical models determine a polytropic exponent, an ignition delay, a combustion centroid and a frictional power.

The features and advantages described in relation to the method according to the invention and its advantageous embodiments also apply to the further method according to the invention and the device according to the invention correspondingly and vice versa. In an advantageous embodiment of the further method according to the invention, at least one first parameter with respect to the technical device to be optimized, which characterizes a physical quantity, is an input parameter of the at least one physical model and a third parameter determined by the at least one empirical model which is suitable in order to characterize the technical device to be optimized and / or to make a change of the technical device to be optimized based thereon, in particular to set a control of the technical device to be optimized, is output.

The aspects of the invention described above and the associated features disclosed for the development of the method according to the invention also apply correspondingly to the aspect of the device according to the invention.

Other features, advantages and applications of the invention will become apparent from the following description taken in conjunction with the figures. At least partially schematically show:

FIG. 1 shows a block diagram of an embodiment of the method according to the invention for model-based optimization of a technical device;

Figure 2 is a block diagram illustrating the flow of information relating to the physical models in an optimization of a diesel engine; Figure 3 is a representation of the flow of information relating to the empirical models in an embodiment of the method according to the invention in relation to a diesel engine; Figure 4 is a representation of the flow of information between the empirical models of an embodiment of the method according to the invention in relation to a diesel engine;

FIG. 5 shows a representation of the information flow between the empirical models of an embodiment of the method according to the invention in relation to a gasoline engine;

FIG. 6 shows a flow chart for the creation of a model based on the method according to the invention;

Figure 7 is a diagram of an operating range of an engine;

Figure 8 is a parity diagram for an empirical model; Figure 9 is another illustration of the parity diagram of Figure 8;

Figure 10 is an illustration of an operating range of three motors;

Figure 1 1 is a parity diagram for an empirical model based on the three motors;

FIG. 12 shows a parity diagram according to FIG. 11, wherein adjustment parameters are taken into account in the empirical model; FIG. 13 shows an interaction diagram for individual input parameters in an empirical model of the ignition delay; Figure 14 is a Pahtätsdiagramm, wherein an empirical model provides different offsets for the individual engines;

FIG. 15 shows the sequence in the model creation of the individual empirical models for an overall simulation of an internal combustion engine in chronological order;

Figure 16 is several diagrams of parameters characterizing the operation of an internal combustion engine, both from values measured on a real engine and values calculated with one embodiment of the invention; and

17 shows a comparison of measured values with those calculated according to the invention of some of the parameters from FIG. 16.

In the following, the invention will be described with reference to an internal combustion engine as a technical device, in particular with reference to a diesel engine. However, the invention can also basically be applied to the optimization of other technical devices which have modes of operation which allow a division into measured physical quantities, physical models and empirical models. The course of a method for model-based optimization according to the invention will be explained with reference to the block diagram from FIG.

In this model-based optimization come on the one hand physical models, which characterize at least one known physical context, and on the other hand empirical models, which are created by means of a compensation calculation, in particular a regression analysis, based on a plurality of already known technical facilities of the same genus used.

The process can be divided into two phases. In a first phase (phase 1), the empirical models, which reflect the dependencies which are generally valid for a type of internal combustion engine, are adapted to the respective internal combustion engine to be optimized. For this purpose, the smallest possible number of measuring points during operation of the internal combustion engine to be optimized, for example on the test bench, measured 10A.

In addition, the empirical model or models are subjected to the same input parameter values as the engine on the test bench, i. the simulation is carried out for the same measuring point. Measured values of output parameters, i. Operating parameters of the internal combustion engine, which are set as a result of the specification of input parameters, are compared with values which were determined on the basis of the empirical model to be adapted or the models for the measuring point. The setting parameter of the empirical model or the setting parameters of the empirical models are finally selected in such a way that the greatest possible agreement with the measured values of the output parameters is achieved 10B. For this purpose, in particular methods of the compensation calculation such as the regression analysis or the method of the smallest error squares can be used.

The second phase can in turn be divided into three functional sections A, B, C. In Section A, physical quantities are detected, in particular input or measured, which serve as input parameters in the models or submodels used according to the invention

Section B summarizes the physical models used in the method according to the invention which on the one hand receive physical quantities as input parameters and on the other hand pass on the basis of the physical models determined output parameters to empirical models in section C as input parameters. The empirical models in section C optionally also have physical variables as input parameters which are directly detected quantities and have not passed through a physical model. Output parameters of the empirical models in Section C can in turn be used as input parameters for the physical models in Section B or other empirical models in Section C. In this way, the combustion process of an internal combustion engine is simulated cascade-like, wherein in particular the sequence of the empirical submodels used in the invention follows the course of the combustion.

In order to be as globally valid as possible, the largest possible parts of the state of the art in the empirical models contained physical relationships are outsourced to physical models. This can reduce the number of input parameters in the empirical models. In this way, it is easy to change geometric boundary conditions in an existing technical device and to determine the changes caused thereby.

The method steps preferably follow the order indicated by the sequence of the individual working steps in the claims, which is also found in FIG. However, the work steps can also run in a different order as long as it is possible to map the functional dependencies:

At the internal combustion engine to be optimized, physical variables are preferably detected in order to characterize the internal combustion engine 101.

The physical quantities in this case characterize the technical device and / or its genre in general and can essentially be subdivided into two categories: On the one hand, these may be physical variables which are predetermined or set by a control device of the technical device to be optimized, for example, the throttle position, etc.

Alternatively or additionally, these physical quantities may be design features of the technical device to be optimized, which are either known as design data or can be measured. Examples include nozzle geometry, combustion chamber and charge movement, in particular swirl or tumble, valve characteristics, inlet channel geometry and / or power dissipation characteristics. Preferably, more detailed statements about the function of the internal combustion engine can be made on the basis of the detected physical quantities. The first parameters thus acquired are preferably selected in such a way as to supply the physical models in section B and / or the empirical models in section C with the necessary input parameters.

The acquired physical quantities are preferably normalized in a further working step in order to make the physical variables comparable with respect to internal combustion engines, rather genus, but for example different power stage 102. In a subsequent working step, at least one of the acquired physical quantities is used to calculate the physical sub-model 103. The output parameter (s) derived from the physical model are in turn used to calculate an empirical sub-model 104 in a subsequent operation. It is also preferably possible to use a plurality of physical models in order to calculate the in Step 104 supplied empirical submodel with input parameters. Further preferably, also detected physical variables can be incorporated directly into the calculation 104 of the empirical submodel.

In a further working step, the output parameter or the output parameters of the calculated empirical model is passed 105 to a physical model in section B or an empirical model in section C. Preferably, these further submodels indicate relationships which chronologically follow in the sequence of the combustion process the empirical submodel calculated in step 104. If the output parameter or the output parameters from operation 104 are transferred to a physical model, then by means of this in a further operation 106a preferably a further output parameter is calculated, which in turn is output to a third physical model or to a second empirical model 107a.

In a further working step, the second empirical model is preferably calculated 106b, wherein the output parameter from the first empirical model, the Output parameters from the second physical model and / or a further physical variable preferably serve as input parameters. The output parameter output by the second empirical model serves as an input parameter for the third physical model and / or a third empirical model, and is therefore preferably outputted to it 107b. Preferably, in the third physical model, a further output parameter is calculated 108a, preferably based on the output parameter output by the second physical model, the output parameter output by the second empirical model, and / or another detected physical quantity 108a. The output value of the third physical model is passed to the third empirical model and the third empirical model is calculated 108b and preferably output 109b based on this parameter, the output parameter of the second empirical model and / or another physical quantity. The cascaded procedure of a combination of information from acquired physical quantities, from physical models and from empirical models presented above with reference to FIG. 1 may preferably be repeated as often as is also indicated in FIG. 1. Preferably, each output parameter can be displayed to a user or can also be used by a comparison with a reference value for the evaluation of the internal combustion engine to be optimized. Finally, obtained parameter values can be used for optimization by means of a change in the configuration of the internal combustion engine 1 10, 11.

FIG. 2 shows, purely by way of example, dependencies of the physical models (in the middle) on the multiplicity of physical variables as well as dependencies with respect to a diesel engine. In the exemplary embodiment shown here, preferably the polytropic exponent proceeds from an empirical model into the thermodynamic state Cylinder as a physical model. The second parameter calculated using an empirical model is, furthermore, the ignition delay in the physical model for the start of combustion. FIG. 3 shows exemplary dependencies of the empirical models (in the middle) of physical models on the left and physical values on the right in a diesel engine. In addition to the parameters calculated on the basis of physical models, a small number of physical variables preferably also enter directly into the empirical models.

Preferably, the piston movement enters as an input parameter in the calculation of the ignition delay and the friction power. The fuel mass flow preferably enters as an input parameter in the calculation of the cylinder peak pressure. The mass-related amount of heat preferably enters the calculation of the polytropic exponent as an input parameter. The drop diameter is preferably used as an input parameter in the calculation of the ignition delay and the exit velocity at the nozzle. The exit velocity at the nozzle preferably enters as an input parameter in the calculation of the focal point of combustion. The thermodynamic state in the cylinder at the start of injection is preferably used as an input parameter in the calculation of the power loss over the cylinder walls, the ignition delay, the peak cylinder pressure and the nitrogen oxide emission. The gas composition is preferably used as an input parameter in the calculation of the nitrogen oxide emission. In the calculation of the polytropic exponent, the compression setting parameter is preferably used as another input parameter. In the calculation of the ignition delay, the ignition delay setting parameter is preferably entered as a further input parameter. In the calculation of the combustion center, the combustion rate setting parameter is preferably input as a further input parameter. In the calculation of the friction power, the engine friction adjustment parameter preferably enters as another input parameter.

FIG. 4 shows the cascade-like dependence of the individual empirical submodels on each other with respect to a diesel engine. It can be seen from FIG. 4 that a preferred exemplary embodiment of the invention, which has proved to be particularly suitable for optimizing a diesel engine, has a five-stage optimization cascade. The start of combustion is not in itself an empirical model in the true sense, but shows that the ignition delay has an indirect influence on four further submodels. Also, the thermodynamic state in the cylinder is not based of an empirical model, but also shows the indirect influence of the polytropic exponent on four further submodels.

The polytropic exponent, via the thermodynamic state as input parameter, preferably enters the calculation of the ignition delay and the peak pressure of the cylinder. The ignition delay is preferably included in the calculation of the center of combustion and the start of combustion as input parameters in the calculation of the power loss over the cylinder walls, the indicated mean pressure, the peak cylinder pressure and the nitrogen oxide emission. The power loss via the cylinder walls is preferably used as an input parameter in the calculation of the indicated mean pressure. The focal point of combustion is preferably included as an input parameter in the calculation of the peak cylinder pressure and the nitrogen oxide emission. The peak cylinder pressure is preferably used as an input parameter in the calculation of the friction power. FIG. 5 shows by way of example an embodiment of the cascading according to the invention of empirical models, which has proved to be particularly advantageous for the optimization of a gasoline engine. Here, the cascading preferably has six levels. The polytropic exponent is preferably used as input parameter in the calculation of the ignition delay and the power loss over the cylinder walls. The ignition delay is preferably included in the calculation of the combustion center, the power loss across the cylinder walls, the carbon monoxide emission, the indicated mean pressure and the hydrocarbon emission. The residual gas content is preferably used as an input parameter in the calculation of the power loss across the cylinder walls, the ignition delay, the combustion center, the nitrogen oxide emission, the carbon monoxide emission and the hydrocarbon emission. The cylinder pressure at IVC is an input parameter preferably in the calculation of the fresh air mass in the cylinder and the ignition delay. The combustion focus is preferably included in the calculation of power dissipation across the cylinder walls at low and high load, indicated mean low and high load, hydrocarbon emission, carbon monoxide emission, and nitrogen oxide emission. The power loss across the cylinder walls at high load is preferably used as input parameter in the calculation. tion of the indicated medium pressure at high load. The indicated mean low pressure at low load is preferably used as input parameter in the calculation of the hydrocarbon emission and the friction power. The indicated medium pressure at high load is preferably used as input parameter in the calculation of the hydrocarbon emission and the friction power.

EMBODIMENT Optimization of a Diesel Engine

Input parameters in procedures

If the method according to the invention is used to optimize a diesel engine, the physical variables used as input parameters (first) can preferably be divided into five categories. These are geometric data relating to the internal combustion engine, operating point-relevant data for defining the respective operating point of the internal combustion engine, air path-relevant data, i. Data that characterize the air flow and the condition of the ambient air. Another category are preferably fuel system-relevant data, which in particular define the injection and combustion-relevant data, which define the control of the combustion in the affected internal combustion engine.

Physical models

When optimizing a diesel engine, the physical relationships used can preferably be essentially divided into nine physical models, the fuel mass flow, the gas composition in the cylinder, the mass-related heat quantity, the piston movement, the thermodynamic state in the cylinder, the exit velocity from a nozzle, the droplet diameter , indicate the start of combustion and the exhaust gas temperature. In the following, exemplary embodiments for the calculation of some of these physical models are given at least in the basic features. Gas composition in the cylinder

The knowledge of the correct gas composition in the cylinder, in particular the oxygen concentration, is an important influencing variable for the calculation of the nitrogen oxide emission of the charge, for example.

In order to take into account the influence of air humidity approximately in the models, the oxygen concentration is preferably given not only as a function of the EGR rate and the excess air, but also on the air humidity.

The oxygen concentration is preferably calculated as a function of lambda, EGR rate, and humidity as follows, and is further used as an input to various models:

X ₀₂ = f (, AGR, x)

Here are:

X. Ol

 Volume fraction of oxygen

 4-] excess air

 EGR [%] EGR rate

4-] Humidity

Mass-related amount of heat

In particular, the mass-related amount of heat designates the chemically bound energy of the fuel used based on the total cylinder mass. In the course of the empirical modeling for the polytropic exponent, this parameter is used approximately as a substitute parameter for the temperature level prevailing during the combustion of the preceding cycle. The larger the charge mass with the same amount of fuel, the lower the temperature level. The mass-related heat quantity is calculated according to the following equation: KS

q equation (I) m g "it

 Here are:

Fuel mass flow total cylinder mass flow including residual gas lower calorific value mass-released amount of heat released

Piston motion The physical model of the piston movement consists essentially of three submodels, which indicate the average piston speed, the piston speed at the start of injection and the compression ratio in the cylinder volume at the start of injection. The average piston speed is preferably an input to the model for calculating engine friction and is calculated as follows:

_ n - s

V ^{m ~} 30000

 Here are:

n [l / min] speed

s [mm] stroke mean piston speed The piston velocity is also input parameter in at least one empirical model. It is calculated according to the following formula:

VkEB = 2 - n * n * r - sm <p EB • sin2 <p EB

 2 - 1

 Here are:

rM crank radius

 connecting rod

 m

^V kEB

 s Piston speed at start of injection

ΨΕΒ Crank angle at start of injection Thermodynamic state in cylinder

The effective compression ratio, which is necessary in particular for determining the thermodynamic state in the cylinder, is calculated according to the following formulas:

K

or V ^v -

(e - 1)

Here are:

Stroke volume of a cylinder

v _c W \ compression volume of a cylinder

ΑΛ Compression ratio If the compression volume is known, cylinder volume and effective compression ratio can be calculated at the start of the main injection. The cylinder volume It is necessary to calculate the temperature assuming an ideal gas by means of the ideal gas equation at the start of injection:

kEB [m] Piston stroke at start of injection d ² · π

 HEB kEB

Here are:

Stroke volume at start of injection

drilling v _TotalEB W \ Cylinder _volume at start of injection

This results for the effective compression ratio at the start of injection as follows:

^• EB v _hEB + v _c

SEB [-] Effective compression ratio at start of injection

The thermodynamic state in the cylinder, shown below at the start of injection, is defined by pressure and temperature. With a known volume at the start of injection, the mass in the cylinder can be calculated by the measured air mass and the measured EGR rate, assuming an ideal load change without rinsing and with a constant residual gas content. By reshaping the gas equation and By assuming an ideal gas, the formal relationship for the temperature at the start of injection is obtained as follows:

Pzyl_ EB TotalEB

^' Zyl EB

 m * R

 Here are:

Pzyl_E _B Pressure at start of injection

l Cyl _EB Temperature at start of injection total mass in cylinder ideal gas constant To accurately reflect the effect of different flow rates of the injector in different number of spray holes on the individual internal combustion engines, specific sizes are used. The characteristic of the injection jet is described by the exit velocity of the fuel from the nozzle and the droplet diameter. These are preferably calculated as a function of the pressure in the cylinder, the injection pressure and the hole diameter according to the following formulas. The exit velocity of the fuel from the nozzle is calculated approximately lossless according to Bernoulli for an incompressible stationary flow:

 Here are:

Pzyl_E _B Cylinder pressure at start of injection

Ρκα fuel injection pressure

 kg

 P KS

m ³ fuel density exit speed Droplet diameter

For the calculation of the droplet diameter, the nozzle hole diameter is required, which is determined on the basis of the effective nozzle hole area. The value for a typical flow coefficient for the nozzle holes is preferably determined by assumption, wherein the nozzle hole area and the nozzle hole diameter are preferably calculated as follows.

 Here are:

A e nozzle hole area Nozzle flow according to manufacturer Number of nozzle holes

It follows

A _r ,, =

 Here are:

 W \ effective flow cross section or nozzle hole diameter a flow coefficient

It follows:

d _DL [m] nozzle hole diameter

The drop diameter is finally calculated as follows:

 Droplet diameter

Nozzle hole diameter Fuel density

 kg

 'KS

 Surface tension of the fuel

kinematic viscosity of the fuel

Charge density at start of injection Cylinder pressure at start of injection

Fuel injection pressure

d _T [m] mean drop diameter

Empirical models:

In the optimization of a diesel engine with the method according to the invention, a cascade of empirical submodels of section C of FIG. 1 preferably contains eleven different empirical models and five cascade stages, as shown in FIG. 4. If the frictional loss, which does not belong to the original combustion process, is excluded, then a combustion process can be imaged essentially completely by six empirical submodels in only four cascade stages. In the following, for some of these empirical models it is explained which input parameters are included in these empirical models. The input parameters can essentially be divided into three groups. Physical quantities which directly enter the empirical models, parameters which are calculated on the basis of physical models, parameters which are calculated on the basis of other empirical models. net and possibly machine-specific setting parameters. These are preferably introduced since a correction of the model outputs, which takes place only via factors or constants, is in many cases inappropriate. The adjustment parameters are preferably based on physically based effects, but they are difficult to take into account due to their complexity. An example of this is the interaction between injection jet and piston recess during combustion.

An exemplary creation of physical models is explained below with reference to FIG. 6.

In the construction of the empirical models, an attempt is first made to calculate as many input parameters as possible by means of physical models in order to keep the number of inputs in the empirical models small. This increases the generality of the method of optimization, since the based on experiments with other internal combustion engine empirical submodels can be kept as limited as possible. Furthermore, all input parameters in the empirical models are preferably chosen so that all the internal combustion engines to be examined can be imaged with one and the same parameter. In a first step, measured data from a set of different already calibrated engines, preferably with the same combustion method (different rates for diesel engines and gasoline engines) and similar engine geometry, are recorded in test bench tests. For example, one set of diesel engines may include nine different engines with a cylinder spread of 0.51 / cylinder to 2.51 / cylinder. An appropriate number of measurement points for the preparation of the empirical models is approximately. 10,000 measuring points, each measuring point, which is preferably defined by speed and torque, having a plurality of measured variables to be measured.

In a second step, the model outputs required for the optimization are defined, which can not be calculated by physical models, for example nitrogen oxide emissions, power, exhaust gas temperature, etc. For each of these model outputs empirical models, preferably by means of regression analyzes, are created, for example on the basis of polynomial model approaches. In this case, polynomial models of the second order are preferably used. The coefficients of these regression models are preferably formed by determining the smallest error squares. The models essentially have the following structure:

2 2

y- x ₁ · u _{l trans} + x ₂ · u _{2 trans} + ... + x _{1 2} · u _{l trans} · u _{2 trans} + ... + c

The model inputs are transformed according to the following equation (Student Transformation).

Var _i - var _i

 i, trans

 Here are:

U i, t ₁ rans transformed model input ^Var 'model input

Average of all readings of this model input

 ° Var Standard deviation of the measured values of this model input

Due to the transformation of the model inputs all model coefficients have the same order of magnitude - therefore the amount of the coefficients gives information about the influence on the model output. The larger the coefficient the greater the influence. This can preferably be used to determine the important model inputs.

The coefficients xi, x ₂ , Xi _{, 2} are determined so that all motors of the considered set can be modeled with the same coefficients.

In order to be able to calculate the behavior of different motors with the same coefficients xi, x ₂ , Xi _{, 2} , the model inputs ui, u _{2 are made} comparable. par- In addition, the model inputs are normalized by a physical conversion into motor-independent variables. As a normalization factor, for example, the respective displacement size of the individual engines in question. The following is a preferably empirical model for calculating the volume-specific indexed high pressure performance. First the model inputs are transformed and subsequently the volume specific high pressure power is calculated. The variables A to K represent the transformed model coefficients. Vol. spec. Fuel output_trans = (vol. Spec. Fuel output-47.6) /24.3 start of combustion HE_trans = (start of combustion HE - (- 1.6)) / 5.1

Burning time_trans = (burn time-17.7) /5.0

vol. spec. Wall heat flux_trans = (vol., Specific wall heat flux-8.1) /4.1 vol. Spec. indicated high pressure power = vol. spec. Fuel output_trans ^Λ 2 ^* Α + start of combustion HE_trans ^Λ 2 ^* Β + burn time_trans ^A 2 ^* C + vol. spec. Fuel output_trans ^* Start of combustion HE_trans ^* D + vol. spec. Fuel capacity_trans ^* vol. spec. Wandwärmestrom_trans * E + burning start HE_trans * burning time_trans * F + burning start HE_trans ^* vol. spec. Wandwärmestrom_trans ^* G + burn time_trans ^* vol. spec. Wall heat flux_trans ^* H + vol. spec. Fuel output_trans ^* l + start of combustion HE_trans ^* J + burn time_trans ^* K + vol. spec. Wall heat flux_trans * L + const

The model quality of the empirical models found is preferably statistically evaluated in a further step, in particular by calculating the coefficient of determination. If a sufficient model quality results, the plausibility of the models is checked again, as explained below.

If there is no sufficient model quality, it is checked whether the model quality can be improved to a satisfactory level by introducing a motor-specific setting parameter EP as a further model input. If this is the case, an adjustment parameter EP is added to the empirical model.

If the model quality or the coefficient of determination can not be significantly increased by a motor-specific adjustment parameter EP, the selection of the model inputs and / or the mathematical formulation of the model approach must be checked. In this case, additional and / or other model inputs are preferably used for the empirical modeling.

By defining an adjustment parameter EP as an additional model input, some of the empirical models used can be engine-specifically adapted. Engine-specific characteristics can be taken into account by means of the adjustment parameters EP. These peculiarities result, for example, from physical effects, e.g. the engine-specific interaction between injection jet and piston recess or also the injection jet behavior as a function of the nozzle hole geometry.

Empirical polynomial models then have the following form, for example:

Υ ^{= x} l ^'u l, trans Ί ^"x 2 ^{' u} 2, trans Ί ^{" x} l, 2 ^'u l, trans ^{' u} 2, trans + "" + ^ 3 ¹ EP + C (II) Using the Setting parameters as additional model input into the polynomials has the great advantage that interactions of adjustment parameters and model input parameters can occur, and therefore the adjustment parameters are not pure offsets or factors. They make it possible for the optimization method according to the invention to easily match the models to new motors.

Due to the low mathematical complexity of these models, especially fast computation times can be realized.

In a subsequent plausibility assessment of the empirical models found, in particular the model dependencies of the individual parameters are investigated; in this case, the effective directions must preferably be consistent with known phenomena from the literature or in accordance with the experience of already performed optimizations. Returns the plausibility rating that the model output in the case of vanation of one or more model inputs, as known from the literature or changes in accordance with experience, the inputs or the formulations of the empirical models themselves are preferably also changed here. Finally, when a satisfactory model quality is achieved, it is examined whether the model inputs used can be determined directly from known parameters or whether a further upstream submodel must be used to determine the model inputs. This can be physical or generic empirical.

The generation of a generic semi-physical combustion model according to the invention is completed when the combustion model only has model inputs whose values are known or predetermined, for example parameters which are conditioned by the design of the internal combustion engine or are predetermined by its control. This completes the build.

Parameterization of the combustion model for the engine to be optimized

The output value for the setting parameters in the case of a motor to be optimized is preferably the arithmetic mean of the setting parameters used in the model creation for the individual motors 1, 2, 3.

For the further adaptation of the adjustment parameters to the machine to be optimized, at least one measuring point consisting of different measured variables is required. In this case, for each empirical model which has an adjustment parameter as a model input, a comparison between calculated and measured value is carried out and the installation parameter is adapted such that the deviation between measurement and calculation is minimal. A new determination of the coefficients xi, x ₂ , x-1, 2 is not necessary.

In the following, nine different empirical models with their input parameters are described for the illustrated embodiment of an optimization method for a diesel engine, which is particularly suitable for the description of the combustion process in diesel engines, namely empirical models for the polytropic exponent, the ignition delay, the combustion center of gravity, the power loss over the cylinder walls or Wandwärmestrom, the induced medium pressure of the high pressure loop, the friction, the peak cylinder pressure, the nitrogen oxides and soot emissions.

polytropic

The thermodynamic state in the cylinder at the start of injection and thus the polytope exponent has an influence on ignition delay, the temperature level and the peak pressure of the combustion. The calculation of temperature and pressure at the start of injection is therefore essential. These depend crucially on heat transfer during compression, compression ratio and pressure and temperature at the beginning of compression and therefore on the state in the inlet header. The determination of the exact temperature when closing the intake valve is difficult to achieve, since even small deviations in the measured cylinder pressure mean a large error of the temperature. However, the indexing is calibrated for the measurement of high cylinder pressures, which degrades the measurement quality at low. The pressure at the start of injection is therefore calculated directly from the pressure in the intake manifold and not from the pressure at intake valve closing. The effects of flowing through the valves are taken into account, as already mentioned, by the compression set parameter.

Due to computation time requirements, crankshaft angle resolved approaches are not applicable for calculating wall heat losses in the channels and during compression. The compression of an internal combustion engine is a polytropic state change, for which reason an empirical model for the polytropic exponent of the polytropic relationship is compiled for the calculation of the pressure at the start of injection. A larger polytropic exponent leads to a higher pressure at the end of the compression.

For a physical representation as possible, the assumption of a constant polytropic exponent is not suitable, since the temperature would be equal to 10 ° CA before top dead center and 10 ° CA after top dead center. In reality, both Temperature and pressure after top dead center by the higher wall heat losses to be lower, which is taken into account by the modeling.

The selection of the input parameters for a preferred empirical model for the polytropic exponent is preferably carried out as follows. The heat transfer during compression influences the charge state at the start of injection and therefore the polytropic exponent. The heat flow can be described with the following relationship:

Q = a * A * AT

Here are:

heat flow

 W

α

m ² - K heat transfer coefficient

A [m ² ] surface

 AT [K] temperature difference

 At [s] time step

It can be seen that the heat flow at Δί-> 0 also approaches zero. Therefore, as the speed increases, the heat transfer must be lower and thus the polytropic exponent must be larger. At constant speed, the injection time, as already mentioned, also influences the time, which is available for the heat transfer. For this reason, the polytropic exponent increases even at very early start of injection. From these considerations, the first two preferred parameters for the model for the polytropic exponent, namely speed and start of injection, are given.

Furthermore, higher gas temperatures result from the compression than the surface temperatures of the combustion chamber walls. For this reason, wall heat loss increases due to a higher inlet header temperature and the resulting larger temperature difference, resulting in a reduction in the polytropic exponent Has. Therefore, preferably, the inlet header temperature is defined as an input.

The surface temperature level is, on the one hand, preferably taken into account as a further input variable by the mass-released amount of heat released, which is calculated according to equation (I). On the other hand, this is taken into account by a polytropic exponent setting parameter, which is introduced into the empirical model.

This adjustment parameter is directly integrated into the empirical model for the polytropic exponent and maps different wall heat losses during compression as well as flow losses in the channels and / or blow-by effects. The thermodynamic state at the start of injection is still not calculated with the effective compression ratio from the inlet closing, but with the compression from the bottom dead center. This error is also compensated with the polytropic exponent setting parameter.

Zündverzuq

The ignition delay influences the combustion process by the time available for mixture preparation. The proportion of premixed combustion and the burning time up to the center of gravity of combustion therefore depend crucially on ignition delay. While the ignition delay at high load is short and reasonably easy to estimate, this becomes more difficult in the partial load range. For an estimation of misfires that can not be calculated directly with a mean value model, the calculated ignition delay is also important. Exceeds the calculated ignition delay a limit of about 3 milliseconds, it can be assumed that the introduced fuel quantity is no longer completely burned.

The ignition delay is preferably defined as the time difference between the start of injection and the start of combustion. The ignition delay model created here outputs this in degrees crank angle. In order to establish the correlation with the time difference and as a measure of the turbulence at the start of injection in the combustion chamber speed is preferably an input parameter in an empirical model for the ignition delay. An important influence parameter on the ignition delay is the gas temperature in the cylinder prevailing during the injection of the fuel. The higher this is, the faster the fuel evaporates and the self-ignition can take place. Therefore, the gas temperature in the cylinder is preferably also an input parameter.

The quality of the mixture preparation, and thus the droplet size, also has an influence on the ignition delay. Smaller droplet diameters increase the ratio of surface to volume, which accelerates the evaporation of the fuel and thus the self-ignition. Therefore, the drop diameter is preferably an input parameter.

The lower concentration of oxygen in the cylinder due to the exhaust gas recirculation delays the start of combustion. In reality, however, a shortening of the ignition delay can be observed with an increase in the EGR rate. This is due to the fact that higher exhaust gas recirculation rates are usually associated with an increase in the temperature level, the influence of which may be greater than that of the lower oxygen concentration. Therefore, the oxygen concentration is preferably an input parameter. Another influencing factor is the temporal change of the state in the cylinder at the beginning of the fuel injection. While in an injection before the top dead center, the ignition conditions to the top dead center are getting better, the ignition conditions deteriorate at injection after top dead center with increasing crank angle. The higher the speed, the faster the condition changes. In a crankshaft angle-resolved calculation of the ignition delay, this is taken into account by integrating the individual time steps. As a substitute for this size, the piston speed is preferably used according to the invention as the input parameter at the beginning of the injection. In addition to the state prevailing in the cylinder, the jet breakup is also dependent on the hole geometry of the injection nozzle. A detailed calculation of the beam conditioning is not possible without a multi-zone model and this in turn for reasons of computing time for the application according to the embodiment not appropriate. Therefore The influence of the jet break-up when leaving the injection nozzle is set by the setting parameter for the ignition delay. Also, fuel properties such as cetane number or the boiling behavior as well as differences in the flanks of the injection curve can be considered preferably via the Zündverzug setting parameters.

Verbrennunqsschwerpunkt

The combustion focus is a commonly used parameter in the development of internal combustion engines to characterize combustion. In order to ensure the usability of the combustion model in practice, the focus of combustion should preferably be determined. Furthermore, this is an intermediate result on which other parts of the combustion model preferably build.

The first phase of combustion is generally almost unaffected by boost pressure. This implies that the air ratio λ has only a small influence on the position of the combustion center of gravity. However, this does not apply for the entire duration of the combustion, on which the air ratio has very good influence. A higher air ratio results in a shorter duration of the total combustion. Following the course of the combustion, preferably the combustion focus is not calculated directly, but the duration of combustion from the start of combustion to the focal point of combustion. This is calculated analogously to the ignition delay in degrees crank angle. The engine speed is therefore preferably the first input parameter and is a measure of the turbulence generated by the charge cycle.

One of the major influences on the duration of the diffusion combustion is the duration of injection itself, since the rate of diffusion combustion does not depend on the fast chemical reaction rate but on the mixture preparation operations - and is therefore preferably the second input parameter. During injection, this is an important quantity and the gas composition takes a back seat. In premixed combustion, unlike diffusion combustion, the rate of combustion does not depend on mixing processes of the spray but purely on the chemical reaction rate. This in turn is a function of the thermodynamic state and the gas composition in the cylinder. Especially with the mainly premixed combustion of the partial load, the injection duration is less significant and the gas composition is more important. The proportion of the premixed combustion and the burn-through time accordingly depend on the ignition delay, which is therefore preferably one of the input parameters. Mixture conditioning operations are largely determined by the energy introduced by the jet and droplet size. For this reason, the exit velocity of the fuel from the nozzle is preferably used as another input parameter. A higher exit velocity leads to faster combustion with a constant injection duration.

The EGR rate and thus the oxygen concentration also influence the burn-through time. Due to the exhaust gas recirculation, the availability of oxygen is lower and the combustion slower. Therefore, the oxygen concentration is preferably an input parameter.

The burn-through time depends not only on the gas state in the cylinder (for example: EGR rate) but also on the combustion chamber geometry and the interaction of the combustion chamber with the injection jet. Different combustion chamber / nozzle combinations differ in their burn - through speed, which has effects on emissions and efficiency of the internal combustion engine (eg interaction of the injection jet with the piston recess). This influence, as well as differences in injection profile or beam cone angle, are preferably mapped with the combustion focus adjustment parameter since the interaction in a 0-dimensional model can not be calculated. The parameter is preferably integrated directly into the model to properly reflect the different effects depending on the operating point.

The post-injection of fuel results in a shift of the combustion center in the direction of late. The shift is due to the difference between measured and the calculated focus of combustion for the main injection and will be modeled subsequently. Input parameters to the model for the combustion centroid shift are preferably the burning time of the first part of the main combustion, the speed and the specific fuel quantity of the post-injection.

Wall heat flux

The calculation of the amount of heat emitted via the combustion chamber walls, i. Loss of power over the cylinder walls or wall heat flow, is necessary in order to be able to calculate, for example, in a subsequent model, the indicated mean pressure of the high-pressure loop. The model output is preferably a specific or standardized amount of heat in kW per liter of displacement. According to the basic principle of the internal combustion engine, the magnitude of the emitted energies, such as power, exhaust gas enthalpy and wall heat flow, depends on the introduced volume-specific fuel output, preferably the first input parameter of the empirical model. The surface to volume ratio is critically responsible for the efficiency of an internal combustion engine. Large engines have significantly higher efficiencies than small passenger car diesel engines. Among other things, this is due to the lower heat transfer due to the lower surface-to-volume ratio in large-volume engines. In order to be able to calculate the combustion of passenger car engines with the same empirical model as that of large commercial vehicle engines, the surface-volume ratio is therefore preferably another input parameter.

The wall heat flow depends not only on the surface and the heat transfer coefficient, but also on the temperature difference between the gas and the combustion chamber wall. Therefore, the temperature level of this average combustion model is of crucial importance. In addition to the location of the combustion, this is also dependent on the mass-related amount of heat. The same amount of fuel at different charge masses in the cy- Linder leads to different levels of combustion temperatures. This results in the lambda influence on the wall heat transfer, which consequently also preferably enters as input parameter. Greater excess air leads to lower wall heat losses with the same EGR and fuel mass flow. For mathematical reasons, it is recommended to use the reciprocal of lambda to avoid values near infinity.

The surface of the cylinder at the time of the maximum average combustion chamber temperature also has an effect on the wall heat losses. This temperature has its maximum shortly after the center of gravity. Since its location is known, the surface of the cylinder at the center of gravity (MFB50%) is preferably used as the input parameter to calculate the surface effect on the wall heat losses. An increase in the EGR rate at a constant lambda is associated with an increase in the charge mass. This increase and the change in material properties change the wall heat flux. Therefore, the EGR rate is preferably an input parameter. An earlier combustion position increases the peak temperature, which is associated with an increase in the temperature difference. Also, the duration for the heat dissipation through the combustion chamber wall is longer when the injection time goes to early. For this reason, an earlier start of injection results in an increase in wall heat losses. Therefore, the start of combustion is preferably an input parameter.

An increase in the temperature at the start of injection is associated with an increase in the temperature level during combustion under otherwise identical boundary conditions, which in turn leads to greater wall heat losses. Therefore, the temperature at the start of injection is preferably an input parameter.

The determination of the wall heat losses of the post-injection directly from the measurement results is not possible. However, the wall heat losses of the main injection can be calculated with the model described above. The difference between the wall heat flow calculated from the main injection and the wall heat flow determined from the measured data with post-injection gives the wall heat losses caused by the post-injection. Measured by the introduced fuel energy only a very small part is lost over the cylinder wall. The following input parameters are preferably used in the empirical model for the wall heat losses of the post-injection: Volume-specific fuel power of the post-injection and start of injection of the post-injection.

The conversion of the chemically-bound fuel energy to the high-pressure loop performance, together with the landing work and engine friction, is responsible for the effective engine performance. The charge exchange work is calculated by a charge exchange model, which will not be discussed here, and can therefore be taken for granted. There is a separate empirical model for engine friction.

Indexed performance of the high pressure loop

To describe a preferred model of the indexed power of the high-pressure loop, the first law of thermodynamics can be used:

 Here are:

V [m ³ ] volume

dQ _B J

 άφ ° KW_ converted fuel energy

dQ _w J

 ° KW wall heat loss

 J

 Ε, Α

Specific enthalpy inlet and outlet Mass flow inlet and outlet dm _leak kg

 άφ mass flow leakage

U [J] inner energy

Thus, for the volume change work of a work cycle, neglecting leakage and the energy supplied through the inlet, the following relationship arises. dV _ dQ _B dQ _w dm

P άφ άφ άφ ⁿ A άφ

This yields the input parameters for the indicated high pressure loop performance model. The introduced into the combustion chamber fuel energy is mainly responsible for the output usable power of the internal combustion engine. The fuel energy introduced has by far the greatest influence on the indicated power. Therefore, the volume-specific fuel performance at the start of injection is preferably an input parameter.

Furthermore, it can be seen from the above equation that a lower wall heat loss results in a higher proportion of usable fuel energy introduced. Therefore, the volume-specific wall heat flow at the start of injection is preferably an input parameter.

In addition to these two model input variables, the position and burning time of the combustion also influence the indicated volume-specific power. The later the combustion and the longer the reaction lasts, the higher the specific enthalpy emitted via the exhaust gas. This results in a reduction in indicated performance. This results in the last two input variables in the model for the calculation of the volume-specific high pressure performance, namely the start of combustion and the duration of combustion up to the combustion center, preferably. It should also be noted in the indicated performance that the post-injection can not burn with the same efficiency as in the main injection due to its partial late position, which is used to increase the temperature or the hydrocarbon emissions. For this reason, it is important to explicitly model the indicated performance of the post-injection. This model is by far not as big in complexity as that of the main combustion; however, the main influences are taken into account.

The determination of the indicated power of the post-injection also takes place via the difference between the measured and the high-pressure power calculated for the main injection. The following input parameters are preferably used in analogy to the heat flow model of the post-injection: volume-specific fuel power of the post-injection and injection start of the post-injection.

The introduced burning fuel quantity has a major influence on the indicated power caused by the post-injection, and of course the non-combustible portion must be deducted. How high their thermodynamic efficiency is depends for the most part on their position relative to top dead center. A later injection indicates a lower power analogous to the main injection.

Motorreibunq

Although the engine friction is not directly related to the combustion process, it is necessary for the calculation of the engine output. The engine friction strongly depends on the operating condition. In addition to the speed, the load also has an influence on engine friction due to the directly dependent gas power.

The friction model preferably has only two input parameters. Since passenger car and commercial vehicle engines have different speeds, the speed is not a suitable input to the friction model. Consequently, for the calculation of the friction, preferably the average piston speed, which is comparable regardless of the engine type, is used as the input parameter. As a load dependence of the cylinder peak pressure is preferably used as the input parameter, since this is directly related to the maximum gas power.

Since engine friction is highly dependent on design variables, the number and dimensions of the main bearings, oil, water, fuel pump or piston / ring package generally have a major influence on the power loss. This is preferably taken into account via the power loss setting parameter.

Peak cylinder pressure

For the mechanical stress of a diesel engine, the cylinder tip pressure is of great importance. For this reason, an empirical model is preferably created for this too. At a given compression ratio, the same amount of fuel and the same injection timing of the boost pressure is significantly responsible for the pressure level during combustion. However, in order to be able to map differences in the compression ratio, the pressure at the start of injection of the main injection is preferably used as an input parameter for the calculation of the cylinder spray pressure. The pressure increase due to the combustion is influenced by the position of the combustion and by the amount of fuel supplied. With a constant amount of fuel, the start of combustion and the burning time determine the pressure increase. Earlier combustion or rapid burning rate is known to cause an increase in peak combustion pressure. Therefore, start of burning and duration of burning are preferably input parameters.

The change in the fuel mass has almost linear influence on the cylinder peak pressure under otherwise identical boundary conditions. Increase in the introduced fuel energy naturally also increases the temperature level and thus the peak pressure. Therefore, the specific fuel mass is preferably an input parameter.

nitrogen oxide emissions In the diesel engine, nitrogen oxide emissions and soot emissions are the most unpleasant pollutant components. Their reduction is of paramount importance for achieving future legislation. Therefore, the prediction of nitrogen oxide emissions is essential for the successful application of a combustion simulation. The nitrogen oxide emissions are preferably calculated fuel specific in the optimization process. In addition to good modelability, this also has the advantage that no emissions can occur without the injection of fuel.

Since the introduction of exhaust gas recirculation, nitrogen oxide emissions have been greatly reduced, as they have been able to achieve low NOx emissions even without a late start of injection. The reason for the reduction in nitrogen oxide emissions is a reduction in the temperature in the flame due to the increased proportion of inert gas and the resulting higher specific heat capacity of the filling. In this case, the NOx reduction potential of the exhaust gas recirculation depends not only on the rate but also on the reduced oxygen concentration of the cylinder charge. This in turn depends on the EGR mass and its lambda, which corresponds to the air ratio of the combustion in stationary operation. The influence of humidity is considered approximately by reducing the oxygen concentration, whereby the reduction of the oxygen concentration by the humidity is weighted equally as by EGR. This results in the first input parameter in the nitrogen oxide model, preferably as an oxygen concentration at the start of combustion.

Position and burning time also have an influence on the temperature, which is the main factor influencing the formation of NOx. The sooner the combustion starts, the higher are the resulting combustion temperatures. Consequently, the earlier combustion leads to an increase in nitrogen oxide emissions. Another input parameter is therefore preferably the start of combustion of the main injection. At the same speed an increased degree of equalization of the combustion, an approximation to the equal combustion also leads to an increase in the temperature, since the same amount of fuel is converted in a shorter time. In reality, this happens, for example, by raising the injection pressure and the associated shorter Burning time. Another input parameter is therefore preferably the combustion period from the beginning of combustion to the center of combustion.

The formation of NOx does not equilibrate during a work cycle. The longer the combustion lasts at higher temperatures, the more NOx is formed. The higher the speed, the faster the gas in the combustion chamber cools, and the lower the NOx emission. For this reason, the speed is preferably an input to the empirical NOx model. The ratio between injected fuel mass and air mass, ie the air ratio lambda, also has an influence on the nitrogen oxide emission. Rising Lambda promotes the better availability of oxygen its dissociation, which is a prerequisite for the formation of nitrogen oxides. This also increases the rate of formation of NOx. On the other hand, there is the cooling effect on combustion with large excesses of air. With very small amounts of fuel, the relatively large air mass has a cooling effect on the combustion, and the nitrogen oxide emissions are low. For this reason, the nitrogen oxide emission is very small for very small quantities, such as in pre-injection processes. Starting with low lambda, the NOx emission increases up to an air ratio between 1, 6 and 2.2 depending on the operating point. From this air ratio, the effect of the available oxygen loses importance, the cooling effect of the excess air outweighs, and the nitrogen oxide emissions decrease. Again, for reasons of modeling not lambda but its reciprocal is preferably used as an input parameter. Another influence on the temperature level of combustion is the temperature at the start of injection. Both inlet manifold temperature and compression ratio have a known influence on the nitrogen oxide emission. For this reason, the previously calculated temperature at the start of injection of the main injection is preferably used as the input to the model. As a result, both the influence of a changed intake manifold temperature and of the compression ratio on the nitrogen oxide emission are mapped. Furthermore, it can also be used to model Miller or Atkinson processes and the associated reduction in NOx emissions. soot emissions

Three preferred input parameters in an empirical soot model are described below. The soot mass actually ejected from the cylinder depends, on the one hand, on the soot formation rate and, on the other hand, on the soot oxidation rate. It should be noted that the oxidation does not start only at the end of the combustion, but also occurs during soot formation.

Both low soot formation rates and oxidation of soot require oxygen. In low air conditions more soot is formed, and the oxidation of soot is possible only to a small extent due to the low oxygen concentration. For this reason, the fresh air mass or the lambda value is preferably an input parameter for the formation and oxidation of soot. Due to the poorer conditions for the soot oxidation due to the low oxygen concentration and the lower temperatures, the soot emission usually increases with the EGR rate, which is therefore preferably a further input parameter.

Of course, the formation of soot in addition to the mixture preparation also depends on the temperature level of the combustion. The higher the temperature, the more soot is formed. For the oxidation but temperatures of at least 1300K are necessary. Therefore, the formation and oxidation of carbon black are in contradiction. The increase of the injection pressure leads to a better mixture preparation, but due to higher temperatures and the faster fuel injection also to increase the soot formation rate. However, this is overcompensated by the high temperature and turbulence level, which leads to better oxidation, and the actual soot emission decreases. Therefore, the injection pressure is also preferably an input parameter for an empirical model for the soot emissions. Figures 7 to 9 show how a combustion model for a single engine (engine 1) according to the prior art is determined. As shown in FIG. 7, the operating range which is stationary for this engine and is possible under given ambient conditions (pressure, temperature) is measured. The parameters x and y, which characterize the operating range of the engine, are, for example, boost pressure and air mass. When measuring a particular engine, only a certain operating range can be covered stationarily due to physical limitations (eg pressure and temperature limits of engine components).

With the measurement data of the stationary measurement, a combustion model can be created that has a good prediction quality within the measured range. Outside this range the model is extrapolated, this is indicated by the two arrows in the diagram. The forecasting quality in the extrapolation decreases sharply. The extrapolation of the model is necessary for the same engine if it is not stationary but transient or the environmental conditions change.

For example, a polynomial model can be used to construct the combustion model, as shown in formula (I) above. The coefficients xi, x _2, x-1, 2 are chosen so that the best possible match between the measured operating points determined in parameter values and the particular means of the combustion model parameter values is established.

A corresponding parity diagram for evaluating the model quality of such a combustion model is shown in FIG. The coefficient of determination R ² in this case is 0.888. An equivalent representation of the parity diagram of FIG. 8 is shown in FIG. The data cloud from measuring points of FIG. 8 is indicated here by the hatched area. The combustion model developed according to FIGS. 7 to 9 is valid only for the one internal combustion engine used to create the model. If another, unknown engine is also to be mapped with a combustion model, then as a rule a renewed measurement of the operating range of this engine must be carried out. a new determination of the coefficients of the polynomial model, for example, by a compensation calculation, be made.

FIGS. 10 to 12 show by way of example how a generic combustion engine model according to the invention can be developed for a whole class of engines.

As shown in FIG. 10, for generating a generic combustion model, a plurality of different engines of a generic type, in particular a combustion type and a specific displacement range are used, in the example shown the three engines engine 1, engine 2 and engine 3. For example, engine 1 has four Cylinder on, engine 2 three cylinders and engine 3 five cylinders on. In addition, if necessary, the cylinder displacements of the individual engines also differ.

For each of these engines, parts of its respective operating range are measured. Ideally, however, the measured operating ranges of the individual motors 1, 2, 3 merely overlap and in each case also additionally cover different operating points. Based on these measurements, a combustion model valid for this type of engine is to be created. As shown in Fig. 10, the measurements of the various motors cover a wider operating range. As a result, those operating areas in which the model has to be extrapolated are reduced, as indicated by the arrows.

To generate the empirical model, not only the measured data of a single motor but of all three motors 1, 2, 3 are now used. This means that when using a polynomial model approach, the coefficients of the polynomial are determined on the basis of the measurement data of all three motors ,

The model quality of the thus found empirical model is shown in relation to the measurement data of the individual motors in FIG. 11. Since the empirical model developed covers all three engines, the model quality is different with respect to each of the engines, as evidenced by the location and extent of the individual data clouds of the measurements (hatched areas) with respect to the individual engines 1, 2, 3 , Overall, this results in a coefficient of determination of 0.75. For a combustion model according to the invention, which preferably consists of a multiplicity of physical models and empirical models, some of the empirical models achieve only relatively small model qualities, as can be seen from FIG. 11. This is mainly due to the fact that in the generic modeling of the empirical models physical effects, such as the engine-specific interaction between injection jet and piston recess or the injection behavior as a function of the nozzle hole geometry can not be sufficiently taken into account by the generic model. Even integrating these dependencies with an additional physical model is normally not possible.

However, in the present example of an empirical model for the operating range of all three engines 1, 2, 3, the model quality can be increased by introducing an adjustment parameter EP as shown above with reference to equation (II). The adjustment parameter EP receives its own coefficient in a polynomial model approach. In carrying out the compensation calculation for determining the coefficients, the coefficient associated with the adjustment parameter EP is also set to a value for all three motors 1, 2, 3, and a value for the adjustment parameter EP for each motor 1, 2, 3 is determined at the same time ensures the best possible agreement of the measured values of the respective engine with the empirical model.

The correspondence between the measured values of the data clouds to the individual motors 1, 2, 3 and the empirical submodel is shown after modeling with the adjustment parameter in FIG. Now a coefficient of determination of 0.97 is achieved between the measurements and the model, which represents a very good model quality.

By introducing the adjustment parameter, not only the position of the respective measurement point distribution in the parity diagram can be improved, as shown in FIG. 12, but also the scatter of the measurement points in the parity diagram can be reduced with respect to the respective empirical model, as by the two double arrows is indicated (the longer double arrow corresponds to the dispersion without adjustment parameter with respect to motor 2 of FIG. 1 1). If the empirical model is now used in a generic combustion model for a new unknown engine X, for which there is still no measurement of the operating range, but which belongs to the same class as the engines 1, 2, 3, then the respective empirical model can only be adapted by adapting the adjustment parameter EP to the unknown motor X.

In a combustion model according to the invention for a diesel engine, these are in particular the empirical models for the polytropic exponent, the ignition delay, the center of combustion and the friction power.

The determination of the adjustment parameters EP can first be made on the basis of empirical values of development engineers. In order to determine the setting parameter EP exactly, however, at least one operating point on the unknown motor X must be measured. On the basis of the comparison of this at least one operating point with the values calculated by means of the generic combustion model, the setting parameters EP of the individual empirical models can be determined. If the setting parameter EP is determined, a motor-specific combustion model is available for the new, unknown engine X, with which a very high agreement with the real operation is achieved, as can be shown with reference to FIGS. 16 and 17. FIG. 13 shows by way of example a so-called interaction diagram for an empirical model of the ignition delay. The interaction diagram indicates the effective direction of the individual input variables or input parameters in the empirical model of the ignition delay. Such an interaction diagram can be used in particular for the knowhow-based evaluation of the model quality in the plausibility assessment.

As is apparent from the example shown in Fig. 13, the dependence between the ignition delay and the adjustment parameter in this case is a curved function second grade. For a single motor 1, 2, 3, X, however, the adjustment parameter for the respective empirical model is selected only once and remains constant for the entire operating range of the respective motor. The difference between the influence of a constant offset value C in a polynomial model on the engine-specific adjustment parameter according to the invention is shown with reference to FIG. Also, FIG. 14 is based, like FIG. 12, on the parity diagram of FIG. The individual data clouds of the measuring point distributions of the motors 1, 2, 3 were shifted by introducing a constant offset value for each motor. Since the location of the individual distributions of the motors has improved in the parity diagram, although the coefficient of determination has increased slightly, it is still in an unsatisfactory area of model quality. In particular, by introducing an offset value into the polynomial model approach, no reduction of the variance in the parity diagram can be achieved. Thus, the width of the distribution cloud with respect to motor 2 in FIG. 14 is identical to that in FIG. 11.

The use of a generic combustion model for the simulation of a whole genus of internal combustion engines according to the inventive method is therefore not possible by the simple introduction of offset values or correction factors.

As shown in FIG. 15, when creating a combustion model which forms the basis of the method of the invention, the procedure is essentially the reverse order in which the dependence of the individual submodels on each other is given; in the reverse direction of the information flow between the individual submodels, as shown for example in Fig. 4. Modeling is started on those models that provide the desired outputs and so many models are used until the desired outputs can be determined from the existing or predetermined inputs.

In the exemplary embodiment of the model creation process for a diesel engine shown in FIG. 15, on the one hand, the indicated high pressure power and the wall heat losses and, on the other hand, the nitrogen emission and the peak pressure are to be calculated. the. From this it follows that models for the center of gravity of combustion, the ignition delay and the compression or the polytropic exponent as well as any other physical models are necessary in order to be able to carry out a simulation on the basis of the input variables normally supplied by a control.

In the following, an application example of the invention for determining parameters which characterize the operation of an internal combustion engine in the transient test cycle for off-road engines (NRTC) is explained in conjunction with an air path model and an exhaust aftertreatment model with reference to FIGS. 16 and 17.

The knowledge of transient engine behavior in terms of thermodynamic quantities as well as emissions of great importance in order to be able to investigate concepts in the early stages of development or to define optimal operating strategies. In the example shown, the diesel particle filter (DPF) regeneration intervals of an industrial engine at different load profiles were investigated using the method according to the invention and the operating strategy was subsequently optimized.

In a first step, the method according to the invention has been validated by means of the legal transient test cycle for off-road engines (NRTC). The engine model is operated with a software control unit, in which the most important functions of the real ECU are mapped. The controllers of the virtual ECU were tuned so that the transient behavior of the virtual engine corresponds to that of the real engine. This type of model application is called Model in the Loop (MiL). In a second step, the industrial engine was subjected to the NRTC cycle in real operation on a test bench.

In addition to the values (B) determined using the method according to the invention, the measured transient curves (A) of rotational speed, torque and air mass are shown normalized in FIG. 16. In addition, the temperature before turbine, the nitrogen oxide emission and the soot emission in transient operation are shown. The curves determined by means of the method according to the invention agree with the measured progressions except for small deviations. Figure 17 shows a relative comparison of the cycle results of the transient emission test. It can be seen that the deviations of the cycle results for NOx, soot and fuel consumption are significantly less than 10%. Therefore, the inventive method is well suited for optimizing an internal combustion engine, without the experiments with the actual to be optimized technical device must be performed.

In particular, it is also possible with the method and the device according to the invention to carry out optimizations in intermediate stages or steps, in which measurements on the test bench with optimization by means of the method according to the invention go hand-in-hand. In this way, it can be ensured that the processed empirical models do not move too far from reality. Preferably, the empirical models can also be changed in intermediate steps and adapted to real measurements.

Claims

claims

Method (100) for model-based optimization, in particular calibration, of a technical device, in particular of an internal combustion engine, having the following working steps:

 Detecting (101) at least a first parameter with respect to the technical device to be optimized, which characterizes a physical quantity;

 First determining (103) at least one second parameter with respect to the technical device to be optimized by at least one first physical model, which characterizes at least one known physical relationship, and for which the at least one first parameter is an input parameter;

 Second determining (104) at least one third parameter by at least one first empirical model, which is based on measurements on a plurality of already known technical devices of the same type, in particular internal combustion engines, and for which at least the at least one second parameter is an input parameter, wherein the at least a third parameter is suitable for characterizing the technical device to be optimized and / or for carrying out a modification of the technical device to be optimized, in particular for setting a control of the technical device to be optimized; and

Outputting (105) the at least one third parameter.

Method (100) according to claim 1, wherein at least the second determination of the at least one third parameter is carried out exclusively in at least one predetermined time, in particular a predetermined crankshaft position, of the technical device, in particular an injection time, ignition point and / or combustion center of gravity (MFB50%).

The method (100) of claim 1, further comprising the following operation: Standardization (102) of the at least one first parameter, preferably with respect to a power potential of the technical device to be optimized, in particular with respect to a displacement of the internal combustion engine and / or normalization of the at least one second parameter and / or normalization of the at least one third parameter.

Method (100) according to one of claims 1 to 3, further comprising the following steps:

 Third determining at least one fourth parameter by a second physical model (106a) and / or by a second empirical model (106b) based on the at least one third parameter and / or on the basis of at least one of a plurality of first parameters and / or at least one second parameter from a plurality of second parameters, wherein the at least one fourth parameter is suitable for characterizing the technical device to be optimized and / or for carrying out a modification of the technical device to be optimized, in particular a control of to adjust the optimization of the technical equipment; and

 Outputting (107) the at least one fourth parameter.

The method (100) of claim 4 further comprising the following steps:

Fourth determining at least one further parameter by at least one further physical model (108a) and / or by at least one further empirical model (108b) on the basis of the at least one third parameter and / or on the basis of the at least one fourth parameter and / or on the basis of at least one of a plurality of first parameters and / or at least one of a plurality of second parameters, wherein the at least one further parameter is suitable for characterizing the technical device to be optimized and / or on the basis of which a change of the to be optimized make technical equipment, in particular set a control of the technical equipment to be optimized; and Outputting (109) the at least one further parameter.

Method (100) according to one of claims 4 or 5, wherein the third determining (106a; 106b) of the fourth parameter and / or the fourth determining (106a; 106b) of the further parameter at a different time, in particular a different crankshaft position, the technical Means for performing the second determination (104) of the third parameter.

Method (100) according to one of the preceding claims, wherein the detecting (101), the first determining (103), the second determining (104), and optionally the third determining (106a, 106b) and the fourth determining (108a, 108b) be carried out without measurements on the technical equipment to be optimized.

Method for model-based optimization, in particular calibration, of a technical device, in particular of an internal combustion engine,

wherein an overall system of the technical device to be optimized is based on at least one first physical model, which characterizes at least one known physical relationship, and at least one empirical model which is based on measurements on a plurality of already known technical devices of the same type, in particular internal combustion engines , is simulated,

wherein at least one physical model and / or at least one empirical model additionally depends on a machine-specific setting parameter in order to adapt the respective model to the technical device to be optimized,

wherein in a first phase of the method at least one measuring point is measured in the operation of the technical device to be optimized and the machine-specific setting parameter is determined on the basis of the at least one measuring point by comparing measured values with values of the measuring point calculated on the basis of the models,

whereby in a second phase of the method no further measurements are made and the overall system of the technical equipment to be optimized is tion is simulated by means of the at least one physical model and the at least one empirical model, wherein a second parameter determined by means of the at least one physical model enters into the at least one empirical model as input parameter.

Method according to claim 8,

wherein at least a first parameter with respect to the technical device to be optimized which characterizes a physical quantity is an input parameter of the at least one physical model and wherein a third parameter determined by the at least one empirical model is suitable for the technical To characterize device and / or on the basis of making a change in the technical equipment to be optimized, in particular to set a control of the technical equipment to be optimized.

Method (100) according to one of claims 1 to 7, wherein at least one of the physical models used and / or at least one of the empirical models used additionally depends on a machine-specific adjustment parameter in order to adapt the respective model to the technical device to be optimized, wherein preferably Different models each use a different setting parameters.

The method (100) of any one of claims 8 to 10, wherein as the adjustment parameter, a compression adjustment parameter, an ignition delay adjustment parameter, a combustion duration / MFB50 adjustment parameter and an engine friction adjustment parameter, a delivery degree adjustment parameter, charge calculation adjustment parameter, residual gas adjustment parameter, Charge cycle loss adjustment parameters and a high pressure power adjustment parameter are available.

Method (100) according to one of Claims 8 to 11, wherein a value of at least one machine-specific setting parameter for all operating points of the technical device to be optimized, in particular of the internal combustion engine, is the same, the internal combustion engine preferably being defined by a) nozzle, combustion chamber and charge movement, in particular swirl or tumble, and / or

 b) Valve characteristics and inlet duct geometry and / or

 c) power dissipation characteristic.

Method (100) according to one of Claims 8 to 12, wherein the value of the machine-specific setting parameter is the same for a group of technical devices of the same type.

Method (100) according to one of claims 8 to 13, wherein the machine-specific adjustment parameter is a further input parameter into the respective model, which is constant for the entire operating range to be optimized technical device.

Method according to one of claims 8 to 14, wherein the output value for a machine-specific setting parameter of the technical device to be optimized is determined on the basis of the values of setting parameters of the plurality of already known technical devices, in particular as an average value.

The method (100) of any one of claims 8 to 15, further comprising the steps of:

 Measuring (10A) at least one measuring point during operation of the technical device to be optimized; and

 Determining (10B) the machine-specific adjustment parameter on the basis of the at least one measurement point by comparing measured values with calculated values of the first parameter and / or second parameter with equal input parameters. 17. The method (100) according to any one of claims 8 to 16 further comprising the following steps:

Detecting (10A-a) the at least one second parameter; and Determining (10B-a) the at least one machine-specific adjustment parameter based on the at least one detected second parameter, in particular by comparing at least one detected value with at least one value of the at least one third parameter determined from the first empirical model; and or

Detecting (10A-b) the at least one third parameter; and

Determining (10B-b) the at least one machine-specific adjustment parameter based on the at least one detected third parameter, in particular by comparing at least one detected value with at least one value of the at least one third parameter determined from the first empirical model; and or

 Detecting (10A-c) the at least one fourth parameter; and

Determining (10B-c) the at least one adjustment parameter based on the detected at least one fourth parameter, in particular by comparing at least one detected value with at least one value of the at least one fourth parameter determined from the second empirical model; and or

 Detecting (10A-d) the at least one further parameter; and

Determining (10B-d) the at least one adjustment parameter on the basis of the detected at least one further parameter, in particular by comparing at least one detected value with at least one value of the at least one further parameter determined on the basis of the further empirical model.

The method (100) of any one of the preceding claims, further comprising the following operation:

 Modifying the at least one first parameter of the technical device to be optimized on the basis of the at least one third parameter, the at least one fourth parameter and / or the at least one further parameter.

The method (100) of any one of the preceding claims, further comprising the following operation: Evaluating the at least one third parameter, the at least one fourth parameter and / or the at least one further parameter based on a reference; and

Issuing the rating.

Method (100) according to one of the preceding claims, wherein the at least one first parameter is predetermined or set by a control device for the technical device to be optimized.

Method (100) according to one of the preceding claims, wherein the at least one first parameter can be influenced by a change in constructive features of the technical device to be optimized.

Method (100) according to one of the preceding claims, wherein the at least one empirical model is a polynomial model whose coefficients are determined by the measurements on the plurality of already known technical devices of the same kind by a compensation calculation, wherein the adjustment parameter is an input parameter of the empirical model is, which is multiplied by at least one coefficient and which is constant for the technical device to be optimized.

A computer program containing instructions which, when executed by a computer, cause it to execute a method according to any one of claims 1 to 22.

A computer-readable medium having stored thereon a computer program according to claim 23.

Device for model-based optimization, in particular calibration, of a technical device, in particular of an internal combustion engine, comprising: at least one measuring device for detecting at least one first parameter with respect to the technical device to be optimized, which is suitable for characterizing a physical variable, a memory device, in which at least a first physical model of a known physical relationship and at least a first empirical model, which is based on measurements on a plurality of already known technical devices of the same kind, are stored, a first allocation device in order to match the first parameter on the Assign the basis of the at least one first physical model to a second parameter,

second allocation means for allocating a third parameter to at least the second parameter based on the at least one first empirical model, and

an interface for outputting the at least one third parameter, the third parameter being suitable for characterizing the technical device to be optimized and / or for making a change to the technical device to be optimized, in particular setting a control of the technical device to be optimized ,