The invention relates to a method for the characteristic map-based obtention of values for at least one control parameter of an installation, particularly an internal combustion engine, whereby support points for the control parameter, which provide a value for the control parameter, are defined across a range of operational parameters within a characteristic map in accordance with operational parameters of the installation.
For installations, in particular for internal combustion engines, it has long been known to store control parameters in characteristic maps so that an optimal value can be obtained for the control parameter for a current operating point according to the most varied input quantities, such as, for example, speed, load, operating temperature, oil temperature.
For internal combustion engines that can be run in different discrete operating modes, i.e. where one can choose between different operating modes, it is usual to have a characteristic map ready for each operating mode, which map is specific to and optimized for the respective mode. Then when an operating mode is changed, there is a switch over to the characteristic map specific to the operating mode, so that this characteristic map will be accessed in the further operation of the internal combustion engine, in any event as long as the assigned operating mode continues. An example for such an operating mode change can be found in internal combustion petrol engines, which can be run in stoichiometric or various lean operating modes. Normally there are three known operating modes for such internal combustion engines, that is to say, stoichiometric, uniform-lean and stratified-lean.
A further internal combustion engine type which allows several operating modes, are internal combustion diesel engines, whereby fuel is injected from a high pressure reservoir (common-rail injection system). There, the fuel quantity injected for a work cycle can be distributed practically at will into single (shot) injections. In this context, one talks about pre, main and post injections. The flexibility of the design of an injection process effects very many different operating modes for such internal combustion engines, each modes being characterized by the distribution of the fuel quantity per work cycle in the above mentioned injections. As each operating mode must have its own characteristic map held ready, the memory requirement for operating control units of internal combustion engines of this type is greatly increased. Furthermore the application, i.e. the adaptation of an internal combustion engine control structure to a current internal combustion engine model, becomes relatively complex with the plurality of characteristic maps.
The object of the invention is therefore to provide a method for the characteristic map-based obtention of values for at least one control parameter of an installation of the type cited above, whereby the memory requirement can be kept as low as possible even if there are many different operating modes.
This task is achieved according to the invention by a method for the characteristic map-based obtention of values for at least one control parameter of an installation, particularly an internal combustion engine, whereby support points for the control parameter, each of which provide a value for the control parameter, are defined across a range of operational parameters within a characteristic map in accordance with operational parameters of the installation, the range of operational parameters covered in said characteristic map is divided into a first and a second subdomain which comprises several of the support points, and the value for the control parameter is obtained by extrapolation when a boundary of the first subdomain is reached before the value for the control parameter is obtained by accessing support points of the second subdomain.
Thus the invention departs from the previous approach of providing a specific characteristic map for each operating mode and instead uses subdomains in characteristic maps. As a change from one subdomain to the next corresponds in prior art to the switching between individual characteristic maps, but regularly involves a non continuous change in the value of the control parameter, which change is, it is not possible to simply change from one subdomain to the next, as that would result in a jump. When operating at the boundary of the subdomain, this would lead to continual jumps, this being incompatible with smooth control of the installations.
A hysteresis is achieved by means of the extrapolation according to the invention across the subdomain, which nevertheless results in a continuous, uniform and fault free installation operation despite the transition of the control parameter values at the subdomain boundaries not being constant, even when there are operating points at boundaries of subdomains over a longer period of time. The obtention of values for the control parameter within the subdomains is carried out by the standard method, i.e. by evaluating the support points and possibly suitable interpolation.
Thus the invention carries out a standard interpolation between support points within a subdomain, and in the case of support points at subdomain boundaries, i.e. in the case of support points that are adjacent to other subdomains, the invention carries out an extrapolation based on that support point. By means of the extrapolation, the transitions between the subdomains are cleanly separated and at the same time a memory, in which the characteristic map is held ready, is optimally utilized.
The hysteresis provided for the transition between the two subdomains is in principle already achieved by the fact that an extrapolation occurs starting from a subdomain. A particularly large hysteresis, and hence one resulting in stable operating behavior of the installation, is achieved, however, by effecting an initial extrapolation also after a change of subdomain. It is therefore preferable that when a certain distance from the last support point of the first subdomain is reached, the value is obtained by extrapolation from support points of the second subdomain.
In principle the number of subdomains can be chosen at will, a person skilled in the art will select this in accordance with the operating behavior of the installation. It is particularly preferable for internal combustion engines in particular, that a (discrete) operating mode of the installation is assigned to each subdomain. A one-to-one correspondence between subdomain and operating mode then makes it possible for a single characteristic map to suffice for all operating modes of the installation.
The method according to the invention is especially advantageous with the internal combustion engine type mentioned above, in which engine fuel is injected directly into combustion chambers and the discrete operating modes are differentiated by the number of injections per work cycle. The internal combustion diesel engines mentioned that have direct injection from high pressure reservoirs provide an example of such internal combustion engines.
In the case of internal combustion engines with direct injection, the quantity of fuel that is introduced into the combustion chambers with the main injection is an important parameter for controlling the operation of the internal combustion engine. A further injection parameter is the time of the injection. Therefore, it is especially preferred that the characteristic map contains values of injection parameters in accordance with speed and load of the internal combustion engine, whereby the injection parameters can include injection quantity and/or injection angle.
The 1:1 assignment mentioned, between subdomains of the characteristic map and operating modes of the internal combustion engine, has the advantage that an application, i.e. an adaptation of a control structure to an internal combustion engine model, is especially simple. It then possible to control the internal combustion engine in such a way that when the stated specific operating state is reached, i.e. when a boundary of a subdomain is reached, simultaneously a change of the operating mode is carried out. Then, the subdomain of the characteristic map which is assigned to the respective operating mode is always accessed in order to obtain the values of the at least one control parameter.
The invention is described in more detail below with reference to the drawing by way of example in which;
A control device 3 controls both the internal combustion engine 1 and the injection system 2, said control device being connected to these units via lines (not shown in detail). The control device 3 has a characteristic map 4 and a control core 5, which control the operation of the internal combustion engine. Values for the duration of injection as function of the speed and load of the internal combustion engine are stored in the characteristic map 4 (which is detailed further later), the characteristic map having several support points, each of which provide a value for the injection quantity for a specific combination of load/speed.
The control device 3 naturally has other characteristic maps and control elements, which are, however, of no further relevance for the following description for the characteristic map-based obtention of values for a control parameter.
The control device 3 controls the injection system with respect to the duration the injectors are active. Thereby, as already mentioned, different injection discharge rates can be set for a work cycle. For example, the control device 3 of the internal combustion engine 1 can realize the injection discharge rates illustrated in
A further reduction in noise is produced in a mode M3, illustrated in
The great flexibility that the injection system supplied from a pressure reservoir allows is shown in
As can be clearly seen, in the operation of the internal combustion engine 1, only one of the modes M1 to M4 can be executed at a time. The control device 3 therefore effects an appropriate mode switch, which is triggered by control core 5, which has recourse to the characteristic map 4 and ensures that the internal combustion engine 1 is always running in the most appropriate operating mode M1 to M4. Thereby, the control core 5 accesses the characteristic map 4, schematically represented in
The characteristic map 4 has four subdomains T1 to T4, which are allocated to the respective operating modes M1 to M4. The diagrammatic view in
To achieve a smooth running of the internal combustion engine when the internal combustion engine 1 is operated near or in the vicinity of one of the transition areas 15 to 18, the transition areas 15 to 18 are used to execute a hysteresis, as represented in
First in a step S0, the internal combustion engine is started with defined subdomain and defined mode, for example, subdomain T3 and mode M3. The values for the fuel quantity 8 are then obtained within this subdomain by an interpolation between the support points; this occurs in step S1. By interpolation it is also understood, of course, that in the event that speed N and torque TQI are exactly at a support point, exactly the value supplied by the support point is used for the fuel quantity 8. Thereby, the internal combustion engine is operated in the operating mode M3, i.e. two pre-injectors 9 and 11 are executed and the main injection 7 lasts so long that the fuel quantity supplied by the subdomain T3 of the characteristic map 4 is delivered by the fuel quantity 8.
After each obtention of a value for the fuel quantity 8, in a step S2 it is queried whether the operating point is in a transition area. This query can be carried out by checking whether there is a further support point within the subdomain for the active mode, beyond the current operating point, i.e. in the direction in which the dynamic of the operation of the internal combustion engine indicates a development of speed N and torque TQI. If this is not the case, there is an operation in the transition area. If there is no transition area (N branch) then a jump back is made before step S1.
If, on the other hand, there is a transition area (J branch) step S3 is continued with, in which step there now occurs an extrapolation with recourse to the support points of the subdomain T3 to find the value for the fuel quantity 8 of the main injection 7.
After each extrapolation, a step S4 queries whether a hysteresis distance H exceeds a threshold value SW. In this way a check is made as to whether the distance from the last support point of the active subdomain, which is valid for the current mode, exceeds the threshold value SW, i.e. it is checked whether there is (still) an operation in the transition area. If this is not the case (N branch) a jump back is made before step S2.
Nevertheless if the hysteresis distance H has exceeded the threshold value SW, i.e. if a certain minimum distance from the nearest support point of the active subdomain is reached, then step S5 (J branch) is continued with, said step effecting a change of the operating mode. Thereby, the change occurs into the mode which has the nearest support point in relation to speed N and torque TQI. Exceeding the threshold value of the hysteresis distance H, thereby ensures that this query delivers an unequivocal result and hence the determination of the operating mode now to be used.
After the operating mode and thus also the relevant subdomain was changed in step S5, step S1 comes in again, i.e. the determination of the fuel quantity 8 is made again by interpolation in the now current subdomain of the characteristic map 4. If an interpolation is not possible, an extrapolation can possibly also be carried out analogously to step S3.
The choice of the threshold value SW for the hysteresis distance H ensures that, in any case, support points of the now current subdomain are closer than those of the subdomain that has just been left.
Operating points B1 to B9 are drawn in
In the process illustrated in
By dint of a further torque increase, the internal combustion engine reaches the operating point B3, which now lies in the transition area 15. Thus now (for the first time) the query in step S2 leads to the J branch. From now on, the fuel quantity 8 is obtained by extrapolation, and hence there is an extrapolated data point E3a in
In operating mode M2, the obtention of the value for the fuel quantity 8 is made by extrapolation with recourse to the values of the subdomain T2 of the characteristic map, so that now an extrapolated data point E3b provides the value for the fuel quantity 8 in the operating mode M2. The torque increases further and brings the internal combustion engine to the operating point B4, for which a read-out data point D4 gives the value for the fuel quantity 8 of the main injection 7, and possibly does so by interpolation.
In subsequent torque increases, operating points B5 and B6 are reached in operating mode M2, and (read-out) data points D5 and D6 are allocated to said operating points. The torque TQI continues to rise, this results in an operating point B7, which operating point is in a transition area, in this case in the transition area 16. Here the description given for the transition area 15 applies analogously, i.e. the next value for the fuel quantity 8 is obtained by extrapolation at a data point E7a, whereby the support points of the subdomain T2, which is allocated to the operating mode M2, are used for the extrapolation.
In the moment in which the hysteresis distance exceeds the threshold value (J branch of step S4), there is a mode change 20, and when the internal combustion engine is operated in mode M4, now in addition post injector 13 is delivered. The valid fuel quantity 8 of the main injection 7 for this operating mode is obtained from subdomain T4 by extrapolation, so that there is an extrapolated data point E7b. Further torque increases bring the internal combustion engine to operating points B8 and B9, at which the value for the fuel quantity 8 is obtained using data points D8 and D9.
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102 43 146 | Sep 2002 | DE | national |
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PCT/DE03/02982 | 9/12/2003 | WO | 00 | 3/17/2005 |
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WO2004/027240 | 4/1/2004 | WO | A |
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