EP0326694A1 - Safety system for an internal-combustion engine - Google Patents

Abstract

For monitoring a (redundant) safety shut-off in the form of an ELAB solenoid shut-off valve on internal combustion engines, that is particularly diesel engines, it is proposed to separate the voltage supply for the control unit and the fuel delivery control device for the diesel injection pump on the one hand and the control of the solenoid safety shut-off valve on the other hand from one another by means of a relay with cut-out delay, so that when the vehicle is shut off it can be determined whether shutting off of the motor occurs due to interruption of the fuel supply immediately after shut-off, owing to the correct action of the solenoid safety shut-off valve, or delayed together with the subsequent currentless switching of the electrical or electronic control unit for the diesel control. …<IMAGE>…

Description

State of the art

The invention relates to a method for monitoring a safety shutdown device in the form of an electromagnetic shutoff valve (ELAB) in internal combustion engines according to the preamble of claim 1 and an apparatus for carrying out the method according to the preamble of claim 4.

In a known fuel injection pump for diesel engines (DE-OS 29 45 484), a pump piston arranged in the housing of the fuel injection pump is set into a reciprocating and at the same time rotating movement, fuel flowing from the housing interior of the injection pump forming the suction space to the pump piston. From there, depending on the quantity set, the fuel reaches the pressure lines leading to the cylinders of the diesel engine. A safety valve is arranged in the connecting line between the suction chamber and the pump piston inflow, which prevents the further fuel supply from the suction chamber to the pump piston interrupts when certain safety conditions are exceeded. Such a safety condition is exceeded, for example, when the pump delivery pressure in the housing of the fuel injection pump corresponds to a higher speed that is above idle, but on the other hand an adjusting lever actuated, for example, by the accelerator pedal is in the idle position.

Another known emergency control device for the fuel metering system, in particular a diesel engine, (DE-OS 32 38 191) has, in addition to a signal processing device with a control device for the fuel supply, a manually or also automatically switchable emergency control branch which contains at least one boost pressure regulator and whose output signal in the event of a fault a fault detection circuit is connected to the signaling device which supplies the internal combustion engine with the amount of fuel required for its operation. A minimum value selection circuit can be provided in the emergency control branch to include further operating conditions.

From DE-OS 19 62 570 a reset device for a quantity-determining member in a fuel injection system for diesel engines is known, which is activated when an error occurs, for example the control circuit itself or a supply line is interrupted by one of the existing sensors with which Consequence that the setting of the quantity-determining member then corresponds to that for small injection quantities. The problem here is that with such a protective adjustment in the direction of a smaller quantity of fuel to be supplied, the power output of the internal combustion engine can be reduced to such an extent that, for example, operation in difficult terrain can no longer be maintained.

It is generally known to use electrical interlockings (DE-OS 35 31 198) for electronic control of the operation of self-igniting internal combustion engines, that is to say diesel engines, with electrical signals, a central control unit (SG) being used instead of mechanical force metering and control systems Control signals generated. Mechanical fuel metering systems in diesel engines are reliable in terms of their reliability, but they may be increasingly less able to take into account the multitude of different operating conditions and environmental influences.

The use of electronic components in connection with an electronic diesel control (EDC) makes extensive safety, monitoring and emergency driving measures desirable even if the individual modules already have options for error detection and, if necessary, error deactivation.

Therefore, it is also known in a safety device for an internal combustion engine with self-ignition (DE-OS 33 01 742), continuously certain signals relating to the operation of the internal combustion engine, such as accelerator pedal position, calculated setpoint of the control path, speed, brake pedal position and the like. and to create a corrected control path setpoint by selecting the minimum value and supplying it to the controller of the EDC system. This corrected control path setpoint also serves to determine a control deviation, including a feedback of the actual control path signal. If the predetermined limits are exceeded, the known safety device either reacts by switching off the injection pump, de-energizing the output stage of the control regulator or introducing emergency operation. With this known safety device However, problems can arise under certain circumstances because not all possible boundary conditions are included in the recording of the safety conditions. Thus, an idle signal can indeed be obtained by a corresponding idle contact on the accelerator pedal; however, this is not valid if, for example, the internal combustion engine is equipped with a vehicle speed controller. In addition, it is conceivable that, for example during sporty driving, warning rear drivers at high speed or the like, a driver briefly depresses the brake pedal or even just taps, but on the other hand the foot pedal remains deflected, i.e. is not in the neutral position.

In view of the importance of the electromagnetic shut-off valve (ELAB) as a redundant safety shutdown in internal combustion engines, in order to ultimately switch off the engine in the event of a malfunction by interrupting the fuel supply and thereby preventing it from running away, the present invention is based on the problem of correct Monitor the function of the electromagnetic shut-off valve itself continuously.

In normal operation, the EDC control unit is able to detect a defect in the quantity signal box, for example, essentially due to a permanent control deviation in the control loop. The EDC control unit then switches off the fuel supply by means of a suitable safety logic using the electromagnetic shut-off valve. The electromagnetic shut-off valve (ELAB), as a safety device, is therefore able to switch off the engine even when the quantity control box is jammed, for example, or when the power stage is well-alloyed (in the EDC control unit). The continuous monitoring of the ELAB function is therefore absolutely necessary because of the importance of the ELAB, whereby However, difficulties arise here that the ELAB itself is part of the fuel metering device, like all other components and systems, and therefore its function cannot be checked separately. This function consists in switching off the engine; The requirement or the option to check the functionality of the ELAB for its functionality, for example in a time-controlled manner, i.e. at predetermined intervals during normal operation of the motor vehicle, is therefore forbidden for reasons of driving safety, since this check just stops the engine would lead.

A defect of the ELAB cannot be recognized by the driver either, because when the voltage supply is switched off, not only is the possibly defective ELAB switched off, but of course the voltage supply for the quantity signal box and the other components is also switched off, i.e. they become currentless. In addition, it is not to be expected that the driver or user of a motor vehicle equipped with such a system will continuously pay attention to, or even want to concern himself with, checking a certain safety component in the fuel quantity control of his vehicle.

Advantages of the invention

The invention solves the problem of monitoring the correct function of the ELAB itself by the characterizing features of claim 1 and claim 4 and has the advantage that by decoupling the power supply of the EDC control unit on the one hand (and thus the quantity signal box) and of the electromagnetic shut-off valve (ELAB), on the other hand, regular functional checks of the ELAB and by the user of the motor vehicle, for example, also inevitably take place when the internal combustion engine is switched off.

It is therefore possible to achieve a particularly safe and simple solution to this problem with very little additional effort by additionally arranging a time relay in the power supply areas for the EDC control unit and the ELAB, which ensures that when the ELAB and then the control unit (and thus the quantity signal box) are switched off.

It then only needs a few more gate circuits when implemented by hardware or an additional program part when implemented by software in order to be able to evaluate an error detection made possible by such a check if the ELAB is defective.

Advantageous further developments and improvements of the invention are possible through the measures listed in the subclaims. In systems with fault storage, it is particularly advantageous to be able to notify the driver of the defect identified on the ELAB on the next trip, either by means of a warning light or by correspondingly influencing the driving behavior, for example reducing the injection quantity or reducing the maximum speed.

drawing

An embodiment of the invention is shown in the drawing and is explained in more detail in the following description. The drawing shows a highly schematic form of hardware implementation of the invention.

Description of the embodiments

The basic idea of the present invention is to decouple the power supply of the EDC control unit to the quantity signal box connected to it and the ELAB, so that with the basic function of the electromagnetic shut-off valve (ELAB) required here, the fuel flow is released when the power supply is provided, but is interrupted in the event of a power failure. it is possible to switch off the ELAB earlier than the EDC control unit. All in all, this is only a few seconds, but is completely sufficient for checking the ELAB for correct function. Due to the earlier switching off of the ELAB, the engine must practically stop at the same time; this can be detected by suitable sensors - if this does not happen, the ELAB is malfunctioning.

In the drawing, a possible embodiment is shown in hardware; however, it is pointed out that the discrete switching stages shown in the drawing do not limit the invention, but only serve to illustrate the basic functional effect of the invention and to specify special functional sequences in this possible form of implementation (hardware). It goes without saying that individual modules and blocks can be constructed using analog, digital or hybrid technology or, in whole or in part, corresponding areas of program-controlled digital systems, for example microprocessors, microcomputers, digital or analog logic circuits and the like. can include, in particular can therefore also be stored as a program run.

The description of the invention given below is therefore only a preferred embodiment Lich to evaluate the overall functional and timing and explains the basic mode of operation based on the blocks discussed, for a better understanding of the invention.

The EDC control unit SG, which fulfills a large number of other tasks, which need not be discussed here, contains at least one safety logic circuit SLo, which can have a large number of sensors for detecting operating conditions and, as safety logic, the fuel supply via the electromagnetic Shut-off valve (ELAB) shuts off.

The control unit SG is connected to the supply voltage with two inputs E1 and E2, the input E1 serving for the power supply of the EDC components including a quantity interlocking device, not shown, and the input E2 for the power supply of the electromagnetic shutoff valve ELAB. These two inputs E1 and E2 are decoupled as follows. The input E1 is connected to a voltage supply via a relay switch r, namely the plus voltage of the battery UB, which is also referred to as terminal 30 (terminal 30) in German. The input E2 is connected to the vehicle electrical system voltage via a suitable switch S which is to be closed at the beginning of the driving operation of the motor vehicle and which is to be opened when the engine is switched off; this contact connection is referred to in German-language use as terminal 15 (terminal 15). The relay contact r is switched by a relay RA with switch-off delay, which is connected to terminal 15 together with input E2 and is therefore supplied with current by the travel switch S.

In the exemplary embodiment shown, the input E2 is used to actuate the electromagnetic shutoff valve ELAB in this case via an AND gate UG whose input is acted upon by the safety logic circuit already mentioned above. The electromagnetic shut-off valve ELAB therefore only contains power and is able to release the fuel supply, for example by pulling in a valve blocking element, when the battery signal is high at input E2 via terminal 15 and from the safety logic circuit, that is to say the other functions properly Circuit component indicating signal is present.

The following function then results. When the travel switch S is opened, i.e. when the power supply from terminal 15 is switched off, the electromagnetic shutoff valve ELAB is switched off via the AND gate UG, so if the function is correct it should immediately shut off the fuel supply.

On the other hand, the control unit SG and with it the quantity control unit for the fuel quantity metering for the time of the switch-off delay (a few seconds) of the relay RA to the supply voltage via terminal 30. By switching off the electromagnetic switch-off valve ELAB, the engine must inevitably within a short defined time can be, for example, 1 sec., so that the speed = 0 results and a signal from a needle movement sensor (sensor on the injection nozzle as an input signal for the control unit) disappears.

If this is not the case, for example if the electromagnetic shut-off valve is stuck or if its control is defective, then the control unit can now recognize this malfunction, since the engine continues to run and is not switched off via the shut-off valve ELAB and, in the simplest case, give an error message.

It goes without saying that after opening the relay RA with a switch-off delay, the machine is then switched off in the usual way by the quantity control box from the control unit.

Further configurations can follow here; the control unit SG can have a fault memory, whereby the detection of the malfunction of the shut-off valve ELAB leads to the fact that the fault display is repeated on the next trip or in addition to a reduced injection quantity or additionally to a reduced maximum speed.

The combination of the safety logic circuit SLo caused by the invention, which controls the electromagnetic shut-off valve ELAB in conventional control devices, with the input E2 (or terminal 15) acted upon via the switch S can be done in the known systems within the control device by hardware or software or outside of the control unit. The invention therefore enables a simple and reliable solution to the problem of fault detection of a redundant electromagnetic safety shut-off valve, the function or malfunction of which cannot be determined in normal operation, since the fuel supply is always (also) interrupted by the control unit via the quantity control box.

All features shown in the description, the following claims and the drawing can be essential to the invention both individually and in any combination with one another.

Claims (8)

1.Procedure for monitoring a (redundant) safety shutdown in the form of an electromagnetic shutoff valve (ELAB) in internal combustion engines, in particular diesel engines, the quantity control device of which is acted upon by an electronic diesel control (EDC) and whereby the further fuel supply to the engine is interrupted by the safety shutdown if a fault occurs is characterized in that, when the internal combustion engine is switched off, the EDC control unit is switched off with a time delay with the quantity interlocking that it controls, and a malfunction of the safety shutdown valve (ELAB) is detected by observing the transient behavior of the internal combustion engine during the shutdown process. 2. The method according to claim 1, characterized in that when the internal combustion engine is switched off, the two alternatives either go out immediately (speed = 0) under the effect of the correct functioning of the safety shut-off valve (ELAB) or continue to run until the control unit triggers a time-delayed response, be recorded and that in the event of an error if a predetermined time period (1 sec.) is exceeded by Continuation of the engine at least one error message is issued. 3. The method according to claim 1 or 2, characterized in that the malfunction of the electromagnetic safety shutoff valve (ELAB) detected by evaluating the two alternatives is stored and communicated to the driver by influencing operating parameters (reduction of the injection quantity; reduced maximum speed). 4.Device for monitoring a (redundant) safety shutdown in the form of an electromagnetic shut-off valve (ELAB) in internal combustion engines, in particular diesel engines, the quantity control device of which is acted upon by an electronic diesel control (EDC) and the safety shutdown interrupts the further fuel supply to the engine if a defect occurs, for carrying out the method according to one or more of claims 1 to 3, characterized in that when the engine is switched off (actuation of a travel switch S) a time delay element arranged in the voltage supply for the control unit (SG) of the diesel control including the quantity control box responds in such a way that If the electromagnetic safety shutdown valve (ELAB) functions correctly, the internal combustion engine comes to a standstill almost immediately within a short defined time (approx. 1 sec.) and if the electromagnetic safety shutdown valve malfunctions ( ELAB) is delayed when the control unit (SG) responds to the lack of power supply. 5. The device according to claim 4, characterized in that the timing element in the power supply line for the Control unit (SG) is the relay contact of a time relay (RA) with switch-off delay, which is activated by the line that is de-energized when the vehicle is switched off. 6. Apparatus according to claim 4 or 5, characterized in that the power supply for the control device (SG) via the relay contact of the switch-off delay relay (RA) to the battery power supply (terminal 30) and the power supply for the electromagnetic safety shut-off valve (ELAB) via an im Driving mode closed switch and open when not in use (driving switch S - corresponding to terminal 15) is connected to the vehicle electrical system voltage. 7. Device according to one of claims 4 to 6, characterized in that the electromagnetic safety shut-off valve (ELAB) is only activated to release the fuel supply when both the drive switch (S; terminal 15) has the voltage supply and a safety logic circuit (SLo) in the control unit (SG) the correct function of the remaining fuel metering components is indicated by a GOOD signal. 8. The device according to claim 7, characterized in that the control of the electromagnetic safety shutdown valve (ELAB) via an AND gate (UG) from the safety logic circuit (SLo) and from the input switch (S terminal 15) connected to the input (E2) he follows.

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