EP0250873A2 - Automotive vehicle driving speed adjustment device - Google Patents

Abstract

In the case of a driving speed adjustment device of a motor vehicle with a set point pickup, which is connected to an accelerator pedal, and with an adjustment device, which is controllable by the set point pickup and acts on an element influencing the ratio of the fuel-air mixture fed to the motor vehicle's engine, preferably an engine throttle valve, a load cycle device is fitted between the set point pickup and the adjustment device to reduce the bucking of the motor vehicle's engine during the load cycle of the motor vehicle's engine, said load cycle device adjusting the element step-by-step in delayed stages for any change in the set point corresponding to a load cycle of the motor vehicle's engine. <IMAGE>

Description

The. The invention relates to a device for adjusting the driving speed of a motor vehicle with a setpoint generator which is coupled to an accelerator pedal and with an adjustment device which can be controlled by the setpoint generator and which influences an element, preferably an element, which influences the ratio of the fuel-air mixture supplied to the motor vehicle engine Engine throttle valve, works.

In order to prevent the transmission of vibrations of the motor vehicle engine to the body in motor vehicles, the motor vehicle engines are usually now elastically mounted in the body. However, this elastic mounting of the motor vehicle engine in the body enables the relative movement of the motor vehicle engine with respect to the motor vehicle body, which is particularly stimulated by a load change of the motor vehicle engine from overrun to train operation or vice versa.

This relative movement due to a change in the load of the motor vehicle engine, in particular together with the additional elasticity of the power transmission from the motor vehicle engine to the driven wheels of the motor vehicle and together with the slippage of the driven wheels relative to the ground, can lead to the so-called jerking of the motor vehicle. The jerking of the motor vehicle, especially when the motor vehicle is accelerating and decelerating strongly, can result in a great loss of comfort for the vehicle occupants. This problem can also occur in motor vehicles which are equipped with a generic device for adjusting the driving speed.

Such a device for adjusting the driving speed of a motor vehicle is known from DE-OS 32 09 463, in which measures are also taken to prevent the motor vehicle from jerking when the load on the motor vehicle engine changes. For this purpose, an electrical filter is connected in the connection line between the setpoint generator and the element influencing the fuel-air mixture of the motor vehicle engine, which is intended to suppress the forwarding of setpoint changes in the region of the jerking frequency. This is to prevent the vehicle body from rocking due to periodic actuation of the accelerator pedal when jerking occurs.

However, this generic device has the particular disadvantage that the cause of the jerking, namely in particular when the motor vehicle is accelerating or decelerating strongly, the relative movement of the motor vehicle engine relative to the motor vehicle body is not eliminated. That is, z. B. the element influencing the fuel-air mixture of the engine actuates in the sense of an acceleration of the motor vehicle engine, and the motor vehicle engine changes its operating state from overrun to train operation, so the motor vehicle engine is put into a relative movement to the body even when using the known device . Due to its mass, the motor vehicle engine moves beyond the equilibrium position of the motor vehicle engine, which occurs after the setpoint value change and the acceleration process and corresponds to the respective throttle valve end position, and then swings into this equilibrium position in a damped oscillation around the equilibrium position. In the best case, the known device can only prevent the rocking of this vibration and thus the vibration of the body. However, the occurrence of the damped vibration and so that the loss of comfort is prevented. In particular, it is possible with the generic device that the overshoot of the motor vehicle engine beyond the equilibrium position leads to the motor vehicle engine striking body parts and thereby damaging the engine and / or body parts. The elastic mounting of the engine in the body can also be damaged by such strong vibrations. The previously known device does not take into account the mechanical properties of the respective motor vehicle engine, coupled with the respective motor vehicle body. An adaptation to mechanical engine / body characteristics is not possible.

The object of the invention is to improve the generic device in such a way that the jerking of the motor vehicle when the load changes on the motor vehicle engine is causally reduced.

This object is achieved in that a load change device is arranged between the setpoint generator and the adjusting device, by means of which the element can be adjusted in steps and with a delay in the stages when there is a change in the setpoint value, which corresponds to a load change of the motor vehicle engine.

A change in the setpoint is an actuation of the accelerator pedal such that a new setpoint, the end setpoint, is set, starting from an initial setpoint. This setpoint change is detected by the load change device and the element influencing the fuel-air mixture supplied to the motor vehicle engine is adjusted accordingly. If the change in setpoint corresponds to a change in position of the element in which there is no load change of the motor vehicle engine, the element is immediately adjusted to the new end position when the change in setpoint occurs. However, corresponds to the Setpoint change of a change in position of the element, in which a load change of the motor vehicle engine occurs, the element is adjusted in stages and in the stages with a delay, the end position of the element being reached with the adjustment in the last position. The change in position of the element corresponds to a load change of the motor vehicle engine if the initial position of the element corresponds to the pulling operation of the internal combustion engine and the end position of the element to be reached corresponds to the overrun operation of the internal combustion engine or vice versa.

The device according to the invention has the particular advantage that with the occurrence of a change in the setpoint value, which corresponds to a load change of the motor vehicle engine, the element is not immediately adjusted to the new end position, as in the prior art, but rather that the element is adjusted in stages. As a result, the deflection of the motor vehicle engine relative to the motor vehicle body is substantially less than in the prior art, and the vibration of the motor vehicle engine is relative to the motor vehicle body. at least significantly reduced in amplitude.

The solution according to the invention has the further advantage that the vibration of the motor vehicle engine also decays significantly faster than in the prior art. Overall, the jerking of the motor vehicle engine during load changes can thus be considerably reduced with the device according to the invention, and no loss of comfort when accelerating or decelerating the motor vehicle has to be accepted when using the device according to the invention. The device according to the invention can be constructed simply and inexpensively and — by choosing the number of stages, by choosing the amplitude of the stages and by changing the delay times, simply and effectively on different ones Motor vehicle engines coupled with various motor vehicle bodies are adapted.

Further advantageous refinements and developments of the subject matter of the invention result from the subclaims.

An embodiment of the subject matter of the invention is shown in the drawings and is explained in more detail below with reference to the drawings.

• Figur 1 grobschematisch eine Vorrichtung zum Einstellen der Fahrgeschwindigkeit eines Kraftfahrzeugs,
• Figur 2 ein Struktogramm der Lastwechselfünktion, die in der erfindungsgemäßen Vorrichtung nach der Figur 1 abläuft und
• Figur 3 ein Diagramm zur Verstellung der Motordrosselklappe durch die erfindungsgemäße Vorrichtung nach der Figur 1 in Abhängigkeit von der Zeit beim Auftreten eines Lastwechsels.

Show it:

• FIG. 1 shows a rough schematic of a device for adjusting the driving speed of a motor vehicle,
• FIG. 2 shows a structure diagram of the load change function which takes place in the device according to the invention according to FIG. 1 and
• 3 shows a diagram for adjusting the engine throttle valve by the device according to the invention according to FIG. 1 as a function of the time when a load change occurs.

In FIG. 1, an accelerator pedal (F) is mechanically coupled to a setpoint generator (S), which converts the rotational position of the accelerator pedal (F) relative to the motor vehicle, to which the accelerator pedal is rotatably attached, into a proportional electrical variable. The electrical output variable of the setpoint generator is fed to a load change device (LWE) which, depending on the output signal of the setpoint generator (S), in turn generates an output signal which is fed to an adjusting device (V). Depending on the output signal of the load change device (LWE), the throttle valve (DK) is used as the ratio of the fuel supplied to the motor vehicle engine (not shown in FIG. 1). Air mixture influencing element adjusted. The respective position of the throttle valve (DK) is detected by a feedback device (R) which generates an output signal which is fed to the load changing device (LWE).

The setpoint generator (S) advantageously generates an electrical resistance value as an output signal, which is proportional to the position of the accelerator pedal (F). The adjusting device (V) can be a simple electric motor which is mechanically coupled to the throttle valve (DK) and whose rotational position can be changed by changing the motor current supplied to the motor. The adjusting device (V) can also be a pneumatic servomotor which is mechanically coupled to the throttle valve (DK) and whose position can be changed by changing the application of overpressure or underpressure. However, the adjustment device (V) can also be an electrical adjustment device which additionally has the function of known speed controllers. The feedback device (R) can be an electrical potentiometer that is mechanically coupled to the throttle valve (DK) and changes its resistance value depending on the position of the throttle valve (DK). This resistance value can then be queried and evaluated by the load changing device (LWE).

The load change device (LWE) is advantageously designed as part of a microcomputer, consisting of a microprocessor, non-volatile memories, random access memories and input and output modules, in order to change the load change function performed by the load change device (LWE), e.g. B. due to changes to the motor vehicle engine, simply having to change the program stored in the non-volatile memory of the microcomputer for processing the load change function.

The function of the device according to the invention according to FIG. 1 will now be explained using the structure diagram in FIG. 2. The structure diagram of FIG. 2 shows the procedural steps of the load change function that takes place in the load change device (LWE) of the device according to the invention according to FIG. 1. This load change function is stored as a microcomputer program in the non-volatile memory of the microcomputer of the load change device (LWE) and is continuously processed by the microcomputer as a loop. That is, if the setpoint is passed on to the adjustment device according to FIG. 2, the microcomputer starts anew with the query whether the load change function is already effective.

In a first procedural step of the load change function, it is queried whether the load change function is already effective. If the load change function is not yet effective, you are asked whether an accelerator pedal movement in the direction of full throttle has been determined. An accelerator pedal movement in the direction of full throttle means that the motor vehicle driver presses the accelerator pedal (F) harder to accelerate the motor vehicle. The setpoint generator (S) coupled to the accelerator pedal (F) generates a corresponding electrical output signal which is fed to the load changing device (LWE).

If an accelerator pedal movement in the direction of full throttle has taken place, the corresponding amplitude of the first stage in which the throttle valve (DK) of the motor vehicle engine is to be adjusted and the value for the delay time in which the throttle valve (DK) is to be held in the first stage , loaded from a memory of the microcomputer. The amplitude of the first stage is dependent on the strength of the pedal movement in the direction of full throttle, that is to say on the size of the change in the setpoint. You can also determine the amplitude of the first stage from the engine speed before Depending on the actuation of the accelerator pedal and / or the driving speed and / or the engine temperature. The duration of the delay time also depends on the size of the setpoint change, the engine speed, the. Driving speed and / or the engine temperature selectable.

If the accelerator pedal movement and thus the associated setpoint change is greater than a predefined load change threshold in the case of accelerator pedal movement in the direction of full throttle, the setpoint value supplied by the load change device (LWE) to the adjusting device (V) is kept at the amplitude of the first stage and a counter for counting down the specified delay time started. If the accelerator pedal movement when moving in the direction of full throttle is smaller than the predefined load change threshold, then the setpoint delivered by the setpoint generator (S) to the load changeover device (LWE) becomes direct without holding the setpoint in a first stage and without a delay time by the load changeover device to the adjusting device (V) passed on.

The load change threshold mentioned in FIG. 2 is a value which can be determined in various ways by the load change device (LWE). On the one hand, the position of the motor vehicle engine can be measured by a position meter relative to the motor vehicle body by z. B. arranges a linear potentiometer between the motor vehicle engine and vehicle body, the grinder z. B. is attached to the engine block of the motor vehicle engine and the housing is fixed to the motor vehicle body. The resistance of the position potentiometer is then dependent on the position of the motor vehicle engine relative to the motor vehicle body and enables a statement to be made as to whether the motor vehicle engine is in overrun mode or in train mode. Depending on whether and how the motor vehicle engine is in overrun or train operation, is through the load change device (LWE) the load change threshold mentioned in Figure 2 can be determined, with further parameters such as. B. the speed of the motor vehicle engine, the driving speed or the engine temperature can be taken into account.

This load change threshold is then comparable with the value and the direction of the setpoint change of the setpoint generator (S); either by means of a comparator or by means of a corresponding comparison operation which is designed as part of the microcomputer program stored in the microcomputer.

To determine the setpoint change, it is advantageous to store an initial setpoint before the accelerator pedal movement in a second memory of the microcomputer of the load change device (LWE) and to measure the new setpoint value of the setpoint generator (S) that occurs after the accelerator pedal movement. Then z. B. the difference between the newly applied final setpoint and the initial setpoint are formed by a subtractor and this difference is compared with the load change threshold mentioned in FIG.

To obtain the value of the load change threshold, however, it is also possible to store an idling characteristic of the motor vehicle internal combustion engine in a first memory of the microcomputer of the load change device (LWE). This idling characteristic of the motor vehicle engine is a function which, depending on the speed of the motor vehicle engine, indicates the associated throttle valve position when the motor vehicle engine is unloaded. If the throttle position for a given engine speed greater than the corresponding to the engine speed throttle position value of the engine load characteristic, then the motor vehicle engine is in traction mode, the respective measured value of the _M otordrosselklappenstellung smaller than the value of Throttle valve position of the engine idling characteristic of the unloaded engine, the motor vehicle engine is in overrun mode. After the setpoint difference has been determined, as already explained in the previous paragraph, the setpoint change can be compared with the load change threshold, the load change threshold corresponding to the throttle valve position at a given engine speed of the unloaded motor vehicle engine.

For the last described type of determination of the load change threshold in FIG. 2 from the engine idling characteristic of the unloaded motor vehicle engine, it is necessary to supply the load change device (LWE) with the respective engine speed of the motor vehicle engine as an input signal. This can be done by the known devices and methods, which deal with the speed detection of motor vehicle engines and with their evaluation.

The value of the load change thresholds according to FIG. 2 can also be selected depending on other sizes. So you can choose the load change threshold depending on the engine temperature to z. B. to avoid extreme accelerations in a cold motor vehicle engine and thus reduce the wear of the motor vehicle engine when warming up.

If the question regarding the accelerator pedal movement in the direction of full throttle within the load change function according to FIG. 2 was answered with No, this is evaluated by the load change function as the accelerator pedal movement in the direction of the idling of the internal combustion engine and the corresponding amplitude of the first stage and the value of the delay time are loaded again . In this case, the load change function continues to query whether the accelerator pedal movement and thus the setpoint change are smaller is as a predefined load change threshold, the load change threshold of this query being the same value as when an accelerator pedal movement in the direction of full throttle. However, the value of the load change threshold can also be selected depending on the direction of the accelerator pedal movement and thus on the signs of the setpoint change. If the new pedal position or the final setpoint is less than the load change threshold or if the change in setpoint crosses the load change threshold, the setpoint for the adjusting device is set to the first level again and held there and the counter is started to count down the delay time. If, when the accelerator pedal position changes in the direction of idling of the motor vehicle engine, there has been no change in the setpoint value which corresponds to a load change of the motor vehicle engine, the setpoint value which corresponds to the new accelerator pedal position is passed on to the adjusting device without intermediate stages and without delay.

If the load change function was not yet effective and there was no change in the accelerator pedal position in the direction of full throttle or idling of the motor vehicle engine, the load change function remains ineffective.

After the described procedure, the load change device (LWE) starts again with the processing of the microcomputer program on which the load change function is based. The question whether the load change function is already effective is now answered with yes. Another query ascertains whether there has been no change in the direction of movement of the accelerator pedal. If there has been no change in the direction of movement of the accelerator pedal, the system continues to query whether the counter delay time has not yet expired. If the counter delay time has not yet expired, the counter is Delay time decremented by one more unit. If the delay time has expired, the load change function is switched off. This means that the final setpoint corresponding to the accelerator pedal position is passed on to the adjusting device, so that the engine throttle valve is adjusted accordingly by a further second stage of the new accelerator pedal position after this functional step.

If there is a change in the direction of movement of the accelerator pedal, the load change function is also switched off for safety reasons. This has the advantage that, for. B. with brief actuation of the accelerator pedal in the direction of full throttle and subsequent relief of the accelerator pedal in the direction of idling even when the load change device (LWE) takes effect after the change in the direction of movement of the accelerator pedal, the engine throttle valve is not further adjusted in the direction of acceleration and thus dangerous driving situations of the motor vehicle are reliably avoided are, the load change device (LWE) can be switched ineffective if another setpoint change occurs during the delay time.

Furthermore, it is advantageous to switch the load change device (LWE) ineffective depending on the actuation of the clutch of the motor vehicle in order to avoid a roar of the motor vehicle engine if an accelerator pedal movement which would correspond to a load change of the motor vehicle engine occurred shortly before the clutch operation.

It is also advantageous to switch the load change device (LWE) inactive when the motor vehicle is at a standstill, in order to give the motor vehicle driver z. B. while waiting at the traffic lights not to take the subjective feeling of the spontaneous response of the motor vehicle engine to accelerator pedal movement.

FIG. 3 shows the change in the throttle valve position (DK) as a function of the time when a setpoint change occurs, which corresponds to a load change of the motor vehicle engine, to illustrate the function of the device according to the invention. In FIG. 3, the throttle valve start position of the motor vehicle engine is designated by DKA. DKE denotes the throttle valve end position of the motor vehicle engine after the throttle valve (DK) of the motor vehicle engine has been adjusted by the load changing device (LWE) in accordance with the final setpoint of the setpoint generator (S).

It is assumed that the motor vehicle is operated at a constant speed and accordingly a constant throttle valve start position (DKA) until time (T1). At time (T1) there is an accelerator pedal actuation in the direction of full throttle, which corresponds to a load change of the motor vehicle engine. The load change device (LWE) is therefore effective and delivers a setpoint to the adjusting device (V), which corresponds to the first stage of the throttle valve position (DK1). The oblique increase in the throttle valve position (DK) after the time (T1) in FIG. 3 indicates the finite adjustment speed with which the adjustment device (V) opens the throttle valve. After a predetermined period of time, which essentially depends on the electromechanical properties of the adjusting device (V) and the throttle valve (DK), the corresponding throttle valve position (DK1) of the first stage is reached. The throttle valve position of the first stage (DK1) is held by the load changing device (LWE) for the duration of the delay time (TV) for approximately 100 milliseconds. After the delay time (TV), which is advantageously approximately 100 milliseconds, the throttle valve is then adjusted in a second stage in the direction of the throttle valve end position (DKE). The Throttle valve end position (DKE) then corresponds to the throttle valve position specified by the final setpoint, which is reached at time (T2). The delayed movement of the throttle valve (DK) after the delay time (TV) has elapsed until the throttle valve end position (DK _E ) has been reached at time (T2) again indicates the actuation of the throttle valve by the adjusting device (V) due to the electromechanical inertia of the adjusting device (V) and throttle valve (DK).

The step and delayed adjustment of the throttle valve (DK) in the manner described in the event of a change in the setpoint value which corresponds to a load change of the motor vehicle engine, unlike in the prior art, reliably prevents a load change of the motor vehicle engine from causing a substantial overshoot of the motor vehicle engine to the motor vehicle body due to the elastic mounting of the motor vehicle engine in the motor vehicle body. This advantageous effect of the device according to the invention is due to the fact that with the adjustment of the throttle valve (DK) to the first intermediate stage, the motor vehicle engine overshoots beyond the equilibrium position of the motor vehicle engine relative to the motor vehicle body. This overshoot can, however, be advantageously adjusted by choosing the appropriate amplitude of the first intermediate stage (DK1) and by choosing the duration of the delay time (TV) of the throttle valve end position (DKE) of the motor vehicle engine such that when the throttle valve (DK) is adjusted into the first stage (DK1) occurring maximum deflection of the motor vehicle engine has the value that occurs after the adjustment of the throttle valve (DK) in the second stage (DKE) as a static deflection and the delay time expires when the maximum deflection of the motor vehicle engine after adjustment to the first Level (DK1) occurs.

As a result of this measure, the vibration of the motor vehicle engine in the event of a change in the setpoint value, which corresponds to a load change of the motor vehicle engine, is significantly lower compared to the prior art and is hardly noticeable for the motor vehicle operator.

A loss of the spontaneity of the acceleration or deceleration of the motor vehicle engine with a corresponding change in the setpoint value cannot be measured when using the device according to the invention. A subjectively detectable loss of acceleration capability is essentially due to the fact that the motor vehicle operator misinterprets the jerking of the motor vehicle which is unavoidable in known devices as acceleration of the motor vehicle.

The device according to the invention is primarily simple and inexpensive to use, because only the load changing device (LWE) is to be switched between the setpoint device (S) and the adjusting device (V) in order to achieve the object. Additional measures for the provision and processing of additional input signals required for the function of the load changing device (LWE) are not required, or the required input signals are already available for solving other tasks. An output signal corresponding to the speed of the motor vehicle engine is available in today's motor vehicle due to the frequent use of electronic ignition devices. An output signal of a feedback device, which may be required to determine the actual throttle valve position, is often also available in devices for adjusting the driving speed for solving other tasks.

Claims (24)

1. Device for adjusting the driving speed of a motor vehicle with a setpoint generator, which is coupled to an accelerator pedal and with an adjusting device which can be controlled by the setpoint generator and which influences an element, preferably an engine, on the ratio of the fuel-air mixture supplied to the motor vehicle engine Throttle valve, acts, characterized in that between the setpoint generator (S) and the adjusting device (V) a load change device (LWE) is arranged, by the element (DK) gradually and in a change of setpoint, which corresponds to a load change of the motor vehicle engine the steps can be adjusted with a delay. 2. Device according to claim 1, characterized in that the element (DK) is adjustable in two stages by the load changing device (LWE). 3. Device according to claim 2, characterized in that the second stage (DKE) corresponds to the position of the element (DK) at the final setpoint. 4. The device according to claim 3, characterized in that the first stage (DK1) is selected so that the resulting maximum deflection of the motor vehicle engine has the value that after adjustment of the element (DK) in the second stage (DKE) as sets static deflection. 5. The device according to claim 2, characterized in that the delay time (TV) for controlling the element (DK) in the first stage (DK1) is dependent on the maximum deflection of the motor vehicle engine. 6. The device according to claim 1, characterized in that the load change device (LWE) the output signal of a position meter can be fed, which measures the position of the motor vehicle engine relative to the vehicle body. 7. The device according to claim 6, characterized in that a load change of the motor vehicle engine can be determined by the load change device (LWE) from the output signal of the position meter. 8. The device according to claim 7, characterized in that the position meter is a linear potentiometer, the housing of which is fastened to the motor vehicle body or to the motor block of the motor vehicle engine and the grinder is connected to the motor block of the motor vehicle engine or to the motor vehicle body. 9. The device according to claim 1, characterized in that the load change device (LWE) has a memory for the speed-dependent idling characteristic of the motor vehicle engine. 10. The device according to claim 9, characterized in that the load change device (LWE) has a comparator for comparing the setpoint change with the idling characteristic. 11. The device according to claim 10, characterized in that the load change device (LWE) is effective when the setpoint change intersects the idle characteristic. 12. The apparatus according to claim 9, characterized in _that the idling characteristic is an idling characteristic map, in particular of the speed of the motor vehicle engine and / or the load of the Motor vehicle engine depends. 13. The apparatus according to claim 1, characterized in that the load change device (LWE) has a second memory for holding an initial setpoint. 14. The apparatus according to claim 13, characterized in that the load change device has a subtractor for calculating the setpoint change as the setpoint difference from the initial setpoint and end setpoint. 15. The apparatus according to claim 1, characterized in that the load changing device (LWE) is ineffective depending on the clutch actuation and / or the vehicle standstill. 16. The apparatus according to claim 2, characterized in that the first stage (DK1) is dependent on the engine speed and / or the driving speed and / or the engine temperature. 17. The method according to claim 5, characterized in that the delay time (TV) is dependent on the engine speed and / or the driving speed and / or the engine temperature. 18. The apparatus according to claim 9, characterized in that the load change device (LWE) is additionally effective in the event of setpoint changes in the vicinity of the idling characteristic. 19. The apparatus according to claim 1, characterized in that the load change device (LWE) is ineffective switchable if a further setpoint change occurs during the delay time (TV). 20. The apparatus according to claim 1, characterized in that the effect of the load changing device (LWE) of depends on the direction of the load change. 21. The device according to claims 2, 5 and 20, characterized in that the value of the first stage (DK1) and the delay time (TV) in a load change of the motor vehicle engine from overrun to train operation is greater than when the load change of the motor vehicle engine from train operation to overrun operation . 22. The apparatus according to claim 1, characterized in that the load change device (LWE), the output signal of a feedback device (R) can be fed for feedback of the throttle valve position. 23. The apparatus of claim 9 and 22, characterized in that the stored idling characteristic is variable depending on a measured idle speed and the associated measured throttle valve position. 24. The device according to claim 9, characterized in that the load changing device (LWE) is designed as part of a microcomputer. `

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