DE4117393A1 - DEVICE FOR CONTROLLING THE FUEL INJECTION OF AN INTERNAL COMBUSTION ENGINE - Google Patents

Abstract

A device comprises two processors 11, 21, for example for controlling the injection of fuel into an internal combustion engine. Variables are detected (2) and at least one of the two processors calculates a manipulated variable for supplying (6) to a peripheral unit and controlling the fuel injection. The first processor 11 determines the manipulated variable in dependence on data, more particularly numerical data, calculated by the second processor 21. Each processor 11, 21 may comprise first and second computers 12,13; 22, 23 and a monitor computer 14, 24. The processors may be connected by a data line having a dual-port RAM 8. The manipulated variable calculated by the first computer 12 may be compared in the monitor computer 24 with the manipulated variable calculated by the second computer 23 to detect faults and actuate a warning light 10.1. A defective processor may be switched off and the other allowed to continue operation. Anti-skid braking systems and robots may alternatively be controlled by the device. <IMAGE>

Description

The invention relates to a device with two processes sensors for controlling the fuel in particular injection of an internal combustion engine according to the preamble of claim 1.

From the prior art (DE-OS 35 39 407) is a Rech nersystem with two processors known to control (or control) of parameters of a burner engine is used. Based on captured sizes such as speed, performance requirements for the Internal combustion engine and position of a brake pedal generated a quantity control a setpoint for the injected Amount of fuel, this setpoint with a Control rod recorded actual value in control point position, the represents the amount of fuel injected becomes. Depending on the determined difference, a Control value to an output stage for setting the control rod given. For the target, actual and Control values are pure voltage values that disadvantageously subject to fluctuations, so that these lead to incorrect settings of the control rod con nen. Due to the use of several switches in the Sig Signal processing is prone to errors. That be Known computer system also has the disadvantage that  the encoders that measure the size are duplicated, which is time-consuming and expensive to assemble. The one Guide the monitoring devices provided in the event of a fault in the event of a fault, only a complete shutdown the final stage, so that emergency functions are not available.

The invention has for its object a device to provide with two processors compared to the State of the art reliable signal processing and ensures a quick determination of the manipulated variable.

The task is carried out by the in the defining part of Pa Features specified 1 solved.

By calculating the manipulated variable in the first process compute sor depending on in the second processor th data is advantageously a quick Ermit telegram of the manipulated variable depending on the detected quantities guaranteed. Due to the processing of alphanumeri data is also a reliable signal processing given because this data in an example wise fluctuating supply voltage is not affected will. When using the device according to the invention to control the fuel injection of an internal combustion engine machine are advantageously operating sizes of Internal combustion engine, such as pressure, temperature, speed and especially supply voltage (battery voltage) sums up. In addition, other sizes, such as Example of a power request (accelerator pedal position) be grasped. In a special embodiment of the Erfin is based on these detected quantities from the second Processor calculates a basic data record, which via ent speaking means (for example data line) the first Processor is forwarded on the basis of this basic data  set the manipulated variable to be supplied to the peripheral unit determined to control the fuel injection. At the peripheral unit is, for example at least one output stage to control one or more rer injectors (solenoid valves) or in general a the fuel injection (especially injection start, end, injection quantity) controlling (influencing) Facility.

In a further development of the invention, that of the first Processor determined manipulated variable to the second processor a data line, especially with an intermediary an input / output unit. This has the intent part that the position determined by the first processor size of the second processor internally for plausibility is checked so that the reliability of the signal processing processing is increased. When the two processors ver binding input / output unit, for example wise around a central storage, on which both processes have access and write and read data can.

In a development of the invention, both processors have at least one a primary function and one a second Calculator performing the function of calculating the position size up. This has the advantage that if one of the both processors, the functional processor calculates the manipulated variable. To this end perform the computers arranged in the first processor at least partial functions in the second processor orderly calculator and vice versa. This guarantees does that if the first processor fails Primary computer performing the second processor the basic data set is calculated and the secondary  function executing computer of the second processor leads, which calculates the manipulated variable that the peripheral ren unit is supplied. In the event that the second If the processor fails, the calculation is carried out the manipulated variable analog in the first processor. At the same time like training in the two processors Neten computers it is possible to operate the internal combustion engine machine if one of the two processors fails restricts to maintain. Run the computers of one Processor only partial functions of the other processor, there is still an emergency operation of the internal combustion engine.

In a further development of the invention is the two processors monitoring that influences the manipulated variable in this way direction assigned, one of the two processors of the peripheral unit that of the functional processor calculated manipulated variable leads. By the assigned to the two processors Monitoring device, it is possible that in particular the peripheral unit is affected so that the off defective processor (or the input the peripheral unit) and the output of the functional processor on which the correctly calculated nete manipulated variable is pending, directed to the peripheral unit switches or this input is activated. This makes it possible that one of the in the event of a fault processors of operation of the internal combustion engine is maintained and incorrect controls are avoided.

In a further development of the invention there is one in each processor Monitoring computer integrated, which the output signals of the computer performing the secondary function of one Processor and the output signals of the primary function exercising computer of the other processor who supplied  the. The monitoring computers supplied signals that the represent calculated manipulated variable are on plausibi identity or similarity checked. in the In the event of a discrepancy, one of the monitors a corresponding control signal to the monitor surrendered device, which in turn the peripheral Control unit accordingly. In addition, the Use of only one monitoring computer in one of the two processors conceivable to simplify the structure.

Processing takes place in a development of the invention of the input variables supplied to the processors by at least one of the two processors in timed Distances, especially according to the multiplex technique. This has the advantage that the processing of the inputs of the processors pending input variables to desired Points in time.

It should also be noted that the invention Two processor setup not only in the field the control of fuel injection of an internal combustion engine machine is used, but also everywhere there can find where reliable signal processing and quick determination of a manipulated variable is required is. Such an area of application can, for example brake pressure control in an ABS system or entirely are generally in the field of robot control. If the device according to the invention for controlling the Fuel injection used in an internal combustion engine (Main area of application), it is for both diesel and can also be used with Otto internal combustion engines.

A special embodiment of the invention direction and how it works is shown in the drawing  tion and the following description: It shows

Fig. 1 shows a device according to the invention for controlling the fuel injection of an internal combustion engine,

Fig. 2 signal processing in a processor with a switching device.

Fig. 1 shows an inventive device for controlling the fuel injection of an internal combustion engine. The device essentially consists of a first processor 11 and a second processor 21 , which are supplied via sensor inputs identified by 2, which are detected. The detected variables in the device for controlling the fuel injection are operating variables of the internal combustion engine, such as, for example, pressures, temperatures, speeds, position information (for example that of the crankshaft) and, in a particularly advantageous manner, the supply voltage (battery voltage), a to ensure safe and reliable control of the fuel injection of the internal combustion engine. In addition, other variables such as a variable representing the idle speed or the position of a kick-down switch can be detected and processed.

The first processor 11 has a first computer 12 , which performs a primary function of the first processor 11 , and a second computer 13 , which performs a secondary function of the first processor 11 . Furthermore, a monitoring computer 14 is integrated in the first processor 11 . Analogously to the first processor 11 , the second processor 21 is constructed, which likewise has a first computer 22 and a second computer 23 . Likewise, a monitoring computer 24 is integrated in the second processor 21 . The two processors 11 and 21 are connected in a signal-transmitting manner to a peripheral unit 4 , the peripheral unit 4 being, for example, at least one output stage for controlling solenoid valves. The control of the solenoid valves or other elements influencing the amount of fuel takes place via at least one output line 6 , which can be designed as a data line or as an electrical line. Furthermore, the two processors 11 and 21 are connected to one another via an input / output unit 8 , in particular a DUAL-PORT-RAM, signal-transmitting. In addition, the two processors 11 and 21, a monitoring device 10 with a downstream diagnostic device 10.1 is assigned. The monitoring device 10 is connected to the peripheral unit 4 (connection between points A and B). In the case of the diagnostic device 10.1 , it can be a simple design of a warning lamp that is activated in the event of a fault. As an alternative to this, the diagnostic device 10.1 can also be a non-volatile memory, in which the corresponding fault messages are written and which can be read out later via an interface.

In the special embodiment of the invention, as shown in FIG. 1, the individual components are connected as follows:
The first computer 12 calculating the manipulated variable receives as input signals the data written into the input / output unit 8 and the basic data (basic data set) calculated by the second computer 13 . On the output side, the first computer 12 is connected to the peripheral unit 4 and to the monitoring computer 24 of the second processor 21 . The second computer 13 of the first processor 11 is connected on the input side to the sensor inputs 2 and on the output side switches to an input of the first computer 12 as well as to an input of the monitoring computer 14 . The first computer 22 of the second processor 21 receives the signals from the sensor inputs 2 on the input side and outputs signals to the second computer 23 and to the input / output unit 8 on the output side. The second computer 23 is connected on the output side to the monitoring computer 24 and to the peripheral unit 4 . The in conjunction with the two processors 11 and 21 in connection with the monitoring device 10 is connected to the two monitoring computers 14 and 24 .

The explained device for controlling the fuel injection of an internal combustion engine works as follows:
The quantities detected via the sensor inputs 2 are fed to the first computer 22 of the second processor 21 , which calculates a basic data set which is fed to the first computer 12 of the first processor 11 via the input / output unit 8 . Based on the basic data set, this first computer 12 calculates a manipulated variable which controls the fuel injection (for example, start of delivery and duration) and is supplied to the peripheral unit 4 . In trouble-free operation, the basic data set calculated by the first computer 22 is fed to the second computer 23 , the function of which at least partially corresponds to that of the first computer 12 of the first processor 11 . Analogously to the first computer 12 , the second computer 23 also calculates the manipulated variable which is fed to the monitoring computer 24 on the output side. This calculated by the second calculator 23 is compared with the control value calculated by the first calculator 12 in the manipulated variable surveil monitoring computer 24 and, if a deviation unzulässi gene activated the monitoring device 10th If a malfunction of the first computer 12 is determined in this comparison, the output 10 of the first processor 11 is switched off by the monitoring device 10 and the manipulated variable calculated by the second computer 23 of the second processor 21 is supplied to the peripheral unit 4 . Correspondingly, the second processor 21 is deactivated when the monitoring computer 14 detects an impermissible deviation when comparing its input signals. In this case, the manipulated variable is then calculated via the first computer 12 , to which the basic data set calculated by the second computer 13 is fed.

On the basis of the procedure described, it is possible, in the event of a fault in one of the two processors, to at least partially maintain the operation of the internal combustion engine with the aid of the functional processor. With a similar configuration of the computers 12 , 13 and 22 , 23 integrated in the two processors 11 and 21 , the full operation of the internal combustion engine is maintained.

Fig. 2 shows the signal processing in a processor with a switching means. In addition to the components shown in FIG. 1 and provided with the same reference numerals, in FIG. 2 the first computer 12 of the first processor 11 is preceded by a switching device 15 , which on the input side with the monitoring device 10 , the input / output unit 8 and the output of the second computer 13 is connected. So that the output signals of the input / output unit 8 are fed to the first computer 12 in trouble-free operation. In the event of a fault, the switching device 15 switches over to the output signals of the second computer 13 , the calculated basic data set of which is then fed to the first computer 12 .

In addition to the input signals shown in FIG. 2 of the switching device 15 , further input signals, or less than the input signals shown, are conceivable. By designing the switching device 15 as a multiplexer, the first computer 12 of the first processor 11 is supplied with the input signals in time-interlocked states so that it can process the input signals one after the other. In addition, the use of other multiplexers is conceivable elsewhere in the device according to the invention.

The diagnostic device 10.1 assigned to the monitoring device 10 in FIG. 1 is assigned to the input / output unit 8 in FIG. 2 and performs the same function as described for FIG. 1. In addition, it is conceivable that the se diagnostic device 10.1 is assigned to one or both processors 11 , 21 (in particular the monitoring computer 14 or 24 ). This makes it possible, for example, to store plausibility errors from sensor or control signals in this memory with the aid of a non-volatile memory, and to read and evaluate these detected errors from the memory, for example after a maintenance interval has expired. It is also possible that errors or faults that occur in the first processor 11 , its components, in the second processor 21 or in its components, to be recorded by location, type and frequency and stored in the non-volatile memory.

It is also conceivable to avoid faulty controls that the output signals are limited by a corresponding hardware design, for example, the peripheral unit 4 . This can be done, for example, in such a way that the output signals in particular (start of delivery, delivery rate) of the peripheral unit 4 are limited so that with the earliest possible start of delivery and the maximum possible delivery rate, only the highest possible speed can be set, so that the internal combustion engine does not can go through or overwind. This is useful, for example, if the manipulated variable calculated by the first processor 11 (or by the processor 21 in the event of a fault) was falsified during the signal transmission in such a way that this would result in an impermissible speed of the internal combustion engine.

As a further embodiment of the invention, which is essential to the invention, it is possible for all computers ( 12 , 13 , 22 , 23 ) or some computers and / or the monitoring computers ( 14 and / or 24 ) to be software-based, ie for their function or partial function in a program (for example as at least one subroutine of the main program of one of the two processors or as an interrupt routine).

Claims (8)

1. Device with two processors, in particular for controlling the fuel injection of an internal combustion engine, sizes being detected and at least one of the two processors determining a control variable for controlling the fuel injection to be supplied to a peripheral unit, characterized in that the first processor ( 11 ) determines the control variable as a function of data calculated in the second processor ( 21 ), in particular alphanumeric data. 2. Device according to claim 1, characterized in that the manipulated variable determined by the first processor ( 11 ) can be fed to the second processor ( 21 ) via a data line, in particular with the interposition of an input / output unit ( 8 ). 3. Device according to claim 1 or 2, characterized in that both processors ( 11 , 21 ) have at least one a primary function and a secondary function computer ( 12 , 13 , 22 , 23 ) for calculating the manipulated variable. 4. Device according to one of the preceding claims, characterized in that the computer ( 12 , 13 ) of the first processor ( 11 ) perform at least partial functions of the computer ner ( 22 , 23 ) in the second processor ( 21 ) and vice versa. 5. Device according to one of the preceding claims, characterized in that the processors ( 11 , 21 ) is assigned such a control value, in particular a monitoring unit ( 10 ) influencing the peripheral unit ( 4 ), in the event of a fault one of the two Processors ( 11 , 21 ) of the peripheral unit ( 4 ) are fed the manipulated variable calculated by the functional processor. 6. Device according to one of the preceding claims, characterized in that a monitoring computer ( 14 , 24 ) is integrated in each processor ( 11 , 21 ). 7. Device according to one of the preceding claims, characterized in that at least the processor ( 11 ) has a switching device ( 15 ). 8. Device according to one of the preceding claims, characterized in that the processing of the pro cessors ( 11 , 21 ) supplied input variables from at least one of the processors ( 11 , 21 ) in time-interlocked conditions, in particular according to the multiplex technology .