This application claims priority from European patent application No. 04425398.7, filed May 31, 2004, which is incorporated herein by reference.
The present invention relates generally to a soft-computing method for establishing the heat dissipation law in a diesel Common Rail engine, and relates in particular to a soft-computing method for establishing the heat dissipation mean speed (HRR).
More in particular, the invention relates to a system for realizing a grey box model, able to anticipate the trend of the combustion process in a Diesel Common Rail engine, when the rotation speed and the parameters characterizing the fuel-injection strategy vary.
For several years, the guide line relating to the fuel-injection control in a Diesel Rail engine has been the realization of a micro-controller able to find on-line, i.e., in real time while the engine is in use, through an optimization process aimed at cutting down the fuel consumption and the polluting emissions, the best injection strategy associated with the load demand of the injection-driving drivers.
Map control systems are known for associating a fuel-injection strategy with the load demand of a driver which represents the best compromise between the following contrasting aims: maximization of the torque, minimization of the fuel consumption, reduction of the noise, and cut down of the NOx and of the carbonaceous particulate.
The characteristic of this control is that of associating a set of parameters (param1, . . . , paramn) to the driver demand which describe the best fuel-injection strategy according to the rotational speed of the driving shaft and of other components.
The analytical expression of this function is:
(param1, . . . , paramn)=f(speed, driver demand) (1)
The domain of the function in (1) is the size space ∞2 since the rotational speed and the driver demand can each take an infinite number of values. The quantization of the speed and driverDemand variables (M possible values for speed and P for driverDemand) allows one to transform the function in (1) (param1, . . . , paramn) into a set of n matrixes, called control maps.
Each matrix chooses, according to the driver demand (driverDemandp) and to the current speed value (speedm), one of the parameters of the corresponding optimal injection strategy (parami):
{tilde over (ƒ)}(i)m,p={tilde over (ƒ)}(i)(speedm,driverp)=parami (2)
where i=1, . . . , n, m=1, . . . , Mep=1, . . , , P
The procedure for constructing the control maps initially consists of establishing map sizes, i.e., the number of rows and columns of the matrixes.
Subsequently, for each load level and for each speed value, the optimal injection strategy is determined, on the basis of experimental tests.
The above-described heuristic procedure has been applied to a specific test case: control of the Common Rail supply system with two fuel-injection strategies in a diesel engine, the characteristics of which are reported in
The map-injection control is a static, open control system. The system is static since the control maps are determined off-line through a non sophisticated processing of the data gathered during the experimental tests; the control maps do not provide an on-line update of the contained values.
The system, moreover, is open since the injection law, obtained by the interpolation of the matrix values among which the driver demand shows up, is not monitored, i.e., it is not verified that the NOx and carbonaceous particulate emissions, corresponding to the current injection law, do not exceed the predetermined safety levels, and whether or not the corresponding torque is close to the driver demand. The explanatory example of
A dynamic, closed map control is obtained by adding to the static, open system: a model providing some operation parameters of the engine when the considered injection strategy varies, a threshold set relative to the operation parameters, and finally a set of rules (possibly fuzzy rules) for updating the current injection law and/or the values contained in the control maps of the system.
It is to be noted that a model of the combustion process in a Diesel engine often requires a simulation meeting a series of complex processes: the air motion in the cylinder, the atomization and vaporization of the fuel, the mixture of the two fluids (air and fuel), and the reaction kinetics, which regulate the premixed and diffusive steps of the combustion.
There are two classes of models: multidimensional models and thermodynamic models. The multidimensional models try to provide all the fluid dynamic details of the phenomena intervening in the cylinder of a Diesel, such as: motion equations of the air inside the cylinder, the evolution of the fuel and the interaction thereof with the air, the evaporation of the liquid particles, and the development of the chemical reactions responsible for the pollutants formation.
These models are based on the solution of fundamental equations of preservation of the energy with finite different schemes. Even if the computational power demanded by these models can be provided by today's calculators, we are still far from being able to implement these models on a micro-controller for an on-line optimization of the injection strategy of engine.
The thermodynamic models make use of the first principle of thermodynamics and of correlations of the empirical type for a physical but synthetic description of different processes implied in the combustion; for this reason these models are also called phenomenological. In a simpler approach, the fluid can be considered of spatially uniform composition, temperature and pressure, i.e. variable only with time (i.e. functions only of the crank angle). In this case, the model is referred to as “single area” model, whereas the “multi-area” ones take into account the space uneveness typical of the combustion of a Diesel engine.
In the case of a Diesel engine, as in general for internal combustion engines, the simplest way to simulate the combustion process is determining the law with which the burnt fuel fraction (Xb) varies.
The starting base for modelling the combustion process in an engine is the first principle of the thermodynamics applied to the gaseous system contained in the combustion chamber. In a first approximation, even if the combustion process is going on, the operation fluid can be considered homogeneous in composition, temperature and pressure, suitably choosing the relevant mean values of these values.
Neglecting the combustible mass that Q flows through the border surface of the chamber, the heat flow dissipated by the chemical combustion reactions
is equal to the sum of the variation of internal energy of the system
of the mechanical power exchanged with the outside by means of the piston
and of the amount of heat which is lost in contact with the cooled walls of the chamber
By approximating the fluid to a perfect gas of medium temperature equal to T, E=mcVT, wherefrom, in the absence of mass fluids, it results that:
The power transferred to the piston is given by
By finally exploiting the status equation, the temperature can be expressed as a function of p and V:
By differentiating this latter:
By suitably mixing the previous expressions, the following expression is reached for the dissipation law of the heat:
By measuring the pressure cycle, being known the variation of the volume according to the crank angle and by using the status equation, it is possible to determine the trend of the medium temperature of the homogeneous fluid in the cylinder.
This is particularly useful in the models used for evaluating the losses of heat through the cooled walls
By finally substituting V(θ), p(θ) and
in the previous equation the dissipation law of the heat is obtained according to the crank angle
The integral of
between θi and θf, combustion start and end angles, provides the amount of freed heat, almost equal to the product of the combustible mass mc multiplied by the lower calorific power Hi thereof.
This approximation contained within a few % depends on the degree of completeness of the oxidation reactions and on the accuracy of the energetic analysis of the process. Deriving with respect to θ the logarithm of both members of the previous equation, one obtains the law relating how the burnt combustible mass fraction xb(θ) varies.
The combustible mass fraction xb(θ) has an S-like form being approximable with sufficient precision by an exponential function (Wiebe function) of the type:
with a suitable choice of the parameters a and m. The parameter a, called efficiency parameter, measures the completeness of the combustion process. Also m, called form factor of the chamber, conditions the combustion speed. Typical values of a are chosen in the range [4.605; 6.908] and they correspond to a completeness of the combustion process for (θ=θf) comprised between 99% and 99.9% (i.e. xb ε[0.99; 0.999]). From
In synthesis, the simplest way to simulate the combustion process in a Diesel engine is to suppose that the law with which the burnt-fuel fraction xb varies is known. The xb can be determined either with points, on the basis of the processing of experimental surveys, or by the analytical via a Wiebe function. The analytical approach has several limits. First of all, it is necessary to determine the parameters describing the Wiebe function for different operation conditions of the engine. To this purpose, the efficiency parameter a is normally supposed to be constant (for example, by considering the combustion almost completed, it is supposed a=6.9) and the variations of the form factor m and of the combustion duration (θf−θi) are calculated by means of empirical correlations of the type:
m=mr(τa,r/τa)0.5(p1/p1,r)(T1,r/T1)(nr/n)0.3
θf−θi=(θf−θi)r(φ/φr)0.6(nr/n)0.5 (12)
where the index r indicates the data relating to the reference conditions, p1 and T1 indicate the pressure and the temperature in the cylinder at the beginning of the compression and τa is the hangfire. An approach of this type covers however only a limited operation field of the engine and it often requires in any case a wide recourse to experimental data for the set-up of the Wiebe parameters. A second limit is that it is often impossible for a single Wiebe function to simultaneously take into account the premixed, diffusive step of the combustion. The dissipation curve of the heat of a Diesel engine is in fact the overlapping of two curves: one relating to the premixed step and the second relating to the diffusive step of the combustion. This limit of the analytic model with single Wiebe has been overcome with a “single area” model proposed by N. Watson:
xb(θ)=βf1(θ, k1, k2)+(1−β)f2(θ, a2, m2) (13)
In this model β represents the fuel fraction which burns in the premixed step in relation with the burnt total whereas f2(θ, a2, m2) and f1(θ, k1, k2) are functions corresponding to the diffusive and premixed step of the combustion. While f2(θ, a2, m2) is the typical Wiebe function characterized by the form parameters a2 and m2, the form Watson has find to be more reasonable for f1(θ, k1, k2) is the following:
Also in this approach, a large amount of experimental data is required for the set-up of the parameters (k1; k2; a2; m2) which characterize the xb(θ) in the various operating points of the engine.
Both the model with single Wiebe and that of Watson are often inadequate to describe the trend of xb in Diesel engines supplied with a multiple fuel injection.
This HRR, acquired in a test room for a speed=2200 rpm and a double injection strategy (SOI; ON1; DW1; ON2)=(−22; 0.18; 0.8; 0.42), is in reality a medium HRR, since it is mediated on 100 cycles of pressure. Both in the figures and in the preceding relations, while the SOI parameters (Start of Injection) is measured in degrees of the crank angle, the parameters ON1 (duration of the first injection, i.e. duration of the “Pilot”), DW1 (dead time between the two injections, i.e. “Dwell time”) and ON2 (duration of the second injection, i.e. duration of the “Main”) are measured in milliseconds as schematized in
From a first comparison between
The second one develops between about −5 and 60 crank angle and it relates to the combustion part primed by the “Main”. In each one of these two steps it is possible to single out different under-steps difficult to be traced to the classic scheme of the pre-mixed and diffusive step of the combustion process associated with a single fuel injection.
Moreover the presence of the “Pilot” step itself is not always ensured, and if it is present, it is not sure that it is clearly distinguished from the “Main” step.
In conclusion, the models used for establishing xb in a single injection Diesel engine are often inadequate to describe the combustion process in engines supplied with a multiple fuel injection.
When the number of injections increases, the profile of the HRR becomes more complicated. The characterizing parts of the combustion process increase, and the factors affecting the form and the presence itself thereof increase. Under these circumstances, a mode, which effectively establishes the xb trend, should first be flexible and general.
That is, it adapts itself to any multiple fuel-injection strategy, and thus to any form of the HRR. In second place, the model reconstructs the mean HRR, relating to a given engine point and to a given multiple injection strategy, with a low margin of error. In so doing, the model could be used for making the map injection control system closed and dynamic.
Therefore, a need has arisen for a virtual combustion sensor for a real-time feedback in an injection management system of a closed-loop type for an engine (closed loop EMS).
An embodiment of the invention is development of a “grey box” model able to establish the combustion process in a diesel common rail engine taking into account the speed of the engine and of the parameters which control the multiple injection steps.
More specifically, a model based on neural networks, which, by training on an heterogeneous sample of data relating to the operation under stationary conditions of an engine, succeed in establishing, with a low error margin, the trend of some operation parameters thereof.
Characteristics and advantages of embodiments of the invention will be apparent from the following description given by way of indicative and non-limiting example with reference to the annexed drawings.
A much used tool in the automotive field for the engine management are the neural networks which can be interpreted as “grey-box” models. These “grey-box” models, by training on an heterogeneous sample of data relating to the engine operation under stationary conditions, succeed in establishing or anticipating, with a low error margin, the trend of some parameters.
This is not the only case wherein neural networks are used in the engine management. In some schemes, neural networks RBF (Radial Basis Function) are trained for the dynamic modelling (real time) and off-line of different operation parameters of the engine (injection angle, NOx emissions, carbonaceous particulate emissions, etc.).
In other schemes neural networks RBF are employed for the simulation of the cylinder pressure in an inner combustion engine. In the model constructed for the simulation of xb, neural networks MLP have an active role.
The realization of the model, according to an embodiment of the invention for establishing the mean HRR, comprises the following steps:
In the first step, the number of Wiebe functions is chosen whereon the HRR signal is to be decomposed. In the second step, similarly to the analysis by means of wavelet transform of a signal, a transform is sought which can characterise the experimental signal of a mean HRR by means of a limited number of parameters:
Ψ(HRR(θ))=(ck1, . . . , ck2, cks) k=1, 2, . . . , K (15)
In the previous relation HRR(θ) is the mean HRR signal acquired in the test room for a given fuel multiple injection, strategy and for a given engine point whereas (ck1, . . . , ck2, cks) with k=1, 2, . . . , K are the strings K of coefficients s associated by means of the transform Ψ with the examined signal.
In the third step, through a homogeneity analysis (clustering), the “optimal” coefficient strings are determined, taking the principles of the theory of the Tikhonov regularization of non “well-posed” problems as reference.
The last steps of the design are dedicated to the designing, to the training, and to the testing of a neural network MLP which has, as inputs, the system inputs (speed, param1, . . . , paramn) and as outputs the corresponding coefficient strings selected in the preceding passages.
The final result is a “grey-box” model able to reconstruct, in a satisfactory way, the mean HRR associated with a given injection strategy and with a given engine point.
The network reproduces the coefficients which, in the functional chosen set (set of Wiebe functions), characterize the HRR signal. FIGS. 15 and 16 describe the block scheme and the data flow of the model according to an embodiment of the invention.
The transform Ψ, present in the block scheme of
In this case, we have used an ES−(1+1) as an evolutive algorithm and the mean quadratic error as the error function associated with the fitting of the experimental signal on the overlap of Wiebe functions. These functions are the reference functional set for the decomposition of the HRR signal.
For this example functional set, the number s of coefficients (ck1, . . . , ck2, cks) is equal to 10; i.e. for each Wiebe function, the parameters that the evolutive algorithm determines are the following five parameters: a-efficiency parameter of the combustion, m-chamber form factor, θi and θf-start and end angles of the combustion, and finally mc-combustible mass. These parameters relate only to the combustion process part, which is approximated by the examined Wiebe function.
By increasing the number of Wiebe functions whereon the experimental HRR are to be decomposed, the space sizes of the parameters whereon the evolutive algorithm operates increase with a corresponding computational waste in the search for the K strings of coefficients satisfying a given threshold condition for the fitting error.
Under these circumstances, it is suitable to increase the starting population of the evolutive algorithm P and the minimum number of strings satisfying the threshold condition, K. P indicates the number of coefficient strings randomly extracted in their definition range, K indicates instead the minimum number of strings of the population which must satisfy the threshold condition before the algorithm ends its execution.
If the algorithm converges without the K strings having reached the threshold condition, it is performed again with an increased P. The process ends when coefficient K strings reach the threshold condition imposed at the beginning, see
From carried-out tests it is evinced that reasonable values for P. K and ΔP are:
P=50 Wn
Kε[5 Wn; 10 Wn]
ΔP=0.1 P (16)
In the previous relation, Wn indicates the number of the chosen Wiebe functions whereon the HRR signal is to be decomposed. An evolutive algorithm, e.g. the ES−(1+1), converges when all the P strings, constituting the population individuals for a certain number of iterations tmin, do not remarkably improve the fitness thereof, i.e. when
|Δƒt,t+1j|ƒtj|≦Erconv j=1, 2, . . . P (17)
In the previous Δft,t+1j describes the fitness variation of the j-th individual of the population between the step t and t+1 of the algorithm, Erconv represents instead the maximal relative fitness variation which the j-th individual must undergo so that the algorithm comes to convergence.
Both from the relation (15) and from
In the second step of the design of the model, the matrixes of coefficients (ck1, . . . , cks) with k=1, . . . , k, associated, by means of the transform, with the input data (speed, param1, . . . , paramn) are analyzed by a clustering algorithm.
The aim is that of singling out “optimal” coefficient strings (ckopt1, . . . , ckopts), in correspondence wherewith similar variations occur between the input data and the output data (output data mean the coefficient strings).
The “grey-box” model, effective to simulate the trend of the mean HRR for a diesel engine, is, in practice, a neural network MLP. This network trains on a set of previously taken experimental input data and of corresponding output data (ckopt1, . . . , ckopts), in order to effectively establish the coefficient string (ck1, . . . , cks) associated with any input datum.
These strings are exactly those which, in the chosen functional set, allow an easy reconstruction of the HRR signal. For better understanding of what has been now described, we have to take into account that the realization of a neural network is substantially a problem of reconstruction of a hyper-surface starting from a set of points.
The points at issue are the pairs of input data and output data whereon the network is trained. From a mathematical point of view, the cited reconstruction problem is generally a non well-posed problem. In fact, the presence of noise and/or imprecision in the acquirement of the experimental data increases the probability that one of the three conditions characterising a well-posed problem is not satisfied.
In this regard, we recall the conditions which must be satisfied so that, given a map f(X)→Y, the map reconstruction problem is well posed:
In the previous conditions, the symbol ρx(..,..) indicates the distance between the two arguments thereof in the reference vectorial space (this latter is singled out by the subscript of the function ρx). If only one of the three conditions is not satisfied, then the problem is called non well-posed; this means that, of all the sample of available data for the training of the neural network, only a few are effectively used in the reconstruction of the map f.
However a theory exists, known as regulation theory, for solving non well-posed reconstruction problems.
The idea underlying this theory is that of stabilizing the map f(X)→Y realised by means of the neural network, so that the Δx is of the same meter of magnitude as Δy.
This turns out by choosing those strings (copt1k, . . . , coptsk) in correspondence wherewith:
where
Δxij=|(speed(i),param1(i), . . . ,paramn(i))−(speed(j),param1(j), . . . ,paramn(j))| (19)
Δyijk,h=|(c1k,(i), . . . ; csk,(i))−(c1h,(j), . . . ; csh,(j))| (20)
By fixing a set of input data (speed(i), param(i), . . . , paramn(i)) with i=1, . . . , Ntot the number of possible coefficient strings which can be related, by means of the transform Ψ, to the input data, is of KNtot. Thus, the least expensive way, at a computational level, for finding the minimum of the sum in the preceding relation is that of applying an evolutive algorithm.
The generic individual whereon the evolutive algorithm works is a combination of Ntot strings of s coefficients, chosen between the KNtot being available. As it is evinced from
The last step of the set-up process of the model coincides with the training of a neural network MLP on the set of Ntot input data and of the corresponding target data. These latter are the coefficient strings (copt1k, . . . , coptsk) selected in the previous clustering step. The topology of the used MLP network has not been chosen in an “empirical” way.
Both the number of neurons of the network hidden state and the regularization factor of the performance function have been chosen by means of the evolutive algorithm. As a target function of the algorithm, we have considered the mean of the mean quadratic error in the testing step of the network, on three distinct testing steps.
That is, for the topology current of the network (individual of the evolutive algorithm) we have carried out the random permutations of the whole set of input-target data and for each permutation the network has been trained and tested. The error during the testing step, mediated on the three permutations, constitutes the algorithm fitness.
The final result is a network able to establish, from a given fuel multiple injection strategy and a given engine point, the coefficient string which, in the Wiebe functional set, reconstructs the mean HRR signal.
The above described “grey-box” model of simulation of the HRR, has been applied to the following test case: diesel common rail engine supplied with double fuel injection; the characteristics of the engine are summarised in
The error of fitting, of the HRR and of the associated pressure cycle, are remarkably low. This demonstrates the fact that the proposed model has a great establishing capacity.
The calibration procedure of the characteristic parameters of the Wiebe functions, which describe the trend of the heat dissipation speed (HRR) in combustion processes in diesel engines with common rail injection system, consists in comprising the dynamics of the inner cylinder processes for a predetermined geometry of the combustion chamber.
Each diesel engine differs from another not only by the main geometric characteristics, i.e. run, bore and compression ratio, but also for the intake and exhaust conduit geometry and for the bowl geometry.
Therefore, in one embodiment, models for establishing the HRR are valid through experimental tests in the factory for each propeller geometry in the whole operation field of this latter.
The control parameters of the above-described common rail injection system according to an embodiment of the invention are: the injection pressure and the control strategy of the injectors (SOI, duration and rest between the control currents of the injectors). A first typology of experimental tests is aimed at measuring the amount of fuel injected by each injection at a predetermined pressure inside the rail and for a combination of the duration and of the rest between the injections.
The second typology of the tests relates to the dynamics of the combustion processes. These are realized in an engine testing room, through measures of the pressure in the cylinder under predetermined operation conditions. The engine being the subject of this study is installed on an engine testing bank and it is connected with a dynamometric brake, i.e. with a device able to absorb the power generated by the propeller and to measure the torque delivered therefrom.
Measures of the pressure in chamber effective to characterize the combustion processes when the control parameters and the speed vary are carried out inside the operation field of the engine. The characterization of the processes starting from the measure of the pressure in chamber first consists in the analysis and in the treatment of the acquired data and then in the calculation of the HRR through the formula 8, 9, 10.
Once the experimental HRR are obtained, the steps relating to the realization of the model for establishing the HRR are repeated. The number of data to acquire in the testing room depends on the desired accuracy for the model in the establishment of the combustion process and thus of the pressure in chamber of the engine.
Embodiments of the above-described techniques may be implemented in engines incorporated in vehicles such as trucks and automobiles.
From the foregoing it will be appreciated that, although specific embodiments of the invention have been described herein for purposes of illustration, various modifications may be made without deviating from the spirit and scope of the invention.
Number | Date | Country | Kind |
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04425398.7 | May 2004 | EP | regional |
Number | Date | Country | |
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Parent | 11142914 | May 2005 | US |
Child | 11527012 | Sep 2006 | US |