DE10211699A1 - Detecting vehicle misfires involves reducing valve armature kinetic energy when opening valve, detecting reduced energy, comparing with threshold, outputting comparison signal indicating misfires. - Google Patents

Abstract

The method involves determining the kinetic energy of the armature (6c) of a gas exchange lift valve (1), reducing the kinetic energy when opening the valve by an electromagnet (6a,6b) so that the kinetic energy remains below a defined value depending on the position of the valve, detecting the reduced energy, comparing with a threshold value and outputting a comparison signal that indicates misfires. AN Independent claim is also included for the following: an arrangement for detecting misfiring in a vehicle with piston internal combustion engine with at least one cylinder.

Description

The invention relates to a method and a device for recognizing Misfiring in a motor vehicle according to the preamble of claim 1 or claim 4.

In piston internal combustion engines with spark ignition in a motor vehicle, it can misfires that have negative consequences for the smooth running of the Have internal combustion engine and for fuel consumption. Countermeasures to be able to seize or at least be able to warn the driver Misfires can be detected quickly and reliably.

The working medium is passed through in each piston of the piston internal combustion engine exchanged at least two gas exchange globe valves. While this Gas exchange globe valves previously with the output shaft of the piston internal combustion engine were connected and thus mechanically controlled, the gas exchange Lift valves are now controlled electronically by the engine control. Be moved they by springs and electromagnets, which are fixed with a valve connected anchor work together.

The sequence of movements of the armature and thus of the gas exchange stroke valve will optimized by energizing the electromagnets. So is from DE 198 32 196 Process for reducing the speed of impact of an anchor electromagnetic actuator known, in particular for actuating a Gas exchange stroke valves of an internal combustion engine, the armature oscillating between two electromagnetic coils each against the force of at least one Return spring moved by alternating energization of the solenoid coils is, and with an approach of the armature to the initially energized coil during the so-called catching process, those catching the anchor Coil applied electrical voltage is reduced. This joins the Catch phase of the catching process starts a braking phase in which until it hits the armature is applied to the coil at this clocked electrical voltage, where the respective switching times and the voltage-pulse ratio of a controller based on a target trajectory describing the anchor target movement be determined.

DE 198 36 297 describes a method for controlling the movement of an armature electromagnetic actuator for actuating a gas exchange globe valve Internal combustion engine known, the armature oscillating between two Electromagnetic coils each against the force of at least one return spring alternating energization of the solenoid coils is moved, and the on the coil closer to the armature and consequently energized electrical voltage is regulated clocked and the voltage-pulse ratio of a controller based on a target trajectory describing the anchor target movement is determined. Different target trajectories are for different ones Movements of the armature and / or the gas exchange valve provided.

The use of electronically controlled gas exchange globe valves opened up new possibilities in the detection of misfires one Piston internal combustion engine. DE 198 60 197 describes a method for detection of misfires on a piston internal combustion engine with spark ignition and a motor controller for controlling electromagnetic actuators Actuation of the gas exchange valves known, in each of which as the actual value Time difference between that specified by the engine control Opening time and the actual opening time of an exhaust valve recorded, compared with a predetermined tolerance time difference as the target value and a signal is generated if the value falls below this target value.

A disadvantage in the detection of misfires according to this state of the art It is technology that influences external factors such as aging and dispersion Actuators cannot be considered as there is no uniform physical model of the actuator there.

Furthermore, from the pending patent application DE 102 05 382 is a method known with which a force depending on the deflection of the valve can be specified for setting a desired middle layer speed.

The object of the present invention is to provide a method and a To create device with which regardless of parameters such as aging and Scattering of mechanical components ensures reliable misfire detection is possible.

This object is achieved according to the invention by the method according to claim 1 or the device according to claim 4. Preferred embodiments of the Invention are the subject of the dependent claims.

As described above, the anchor should hit the Put on the opening magnet at the end of the movement to reduce noise to minimize when switching the valves. To do this, the anchor and the valve to achieve the desired middle layer speed accordingly braked. Without gas back pressure in the cylinder, the brakes must be applied more strongly, d. H. more energy must be extracted from the system by a braking device become. With (high) gas back pressure in the cylinder when opening the valve Work done against the gas pressure in the cylinder, which already made the system energy is withdrawn by the gas counterpressure ("energy destruction"). The Braking device for the armature / valve uses less energy to the system revoke.

By integrating the force curve along the valve path, for example after the method from DE 102 05 382 can be determined, there is a measure for the energy extracted from the system until the middle position is reached. For the Misfiring is therefore recognized by the potential energy of the valve due to the spring force, the kinetic energy of the valve, and the work performed by the valve must be performed against the magnetic force and the gas back pressure, considered. The difference between the potential energy of the valve due to the Spring force in its initial position and the kinetic energy of the valve at Passing through the middle position results in the work the valve does against the gas force and must exert the magnetic force between the starting position and the middle position. The The valve's work against the gas force thus results from the consideration of potential and kinetic energy of the valve and that of the magnetic force brought in energy. Based on the size of this gas work, a statement can be made whether or not there was a misfire.

The energy of the valve in the force field of the springs and the magnetic field as Use the basis for the assessment of whether there was a misfire or not, compared to the check of passage times of the valve State of the art advantage that the energy is independent of measurement setups can be determined.

From this, the following rule for misfire detection can be derived: must If a lot of energy is removed from the system, no combustion has taken place; less energy needs to be withdrawn from the system, has a normal one Combustion took place. One can consequently withdraw from the system Indicate energy whether there was a misfire or not.

The actual gas pressure in the piston of the piston engine is not constant for all load ranges of the piston internal combustion engine. In a preferred one The embodiment is therefore the expected gas pressure values and thus the expected deceleration values (energy consumption values) in a map in Dependent on the load range of the piston internal combustion engine.

An advantage of the invention is that the method according to the invention without much additional effort in the existing engine control can be implemented. In addition, the misfire detection according to the Invention very robust against external disturbances, since it is based on the same physical models is based like the regulation of the movement of the Valve itself.

Further features and advantages of the invention will appear from the following Description of preferred embodiments, reference being made will refer to the attached drawings.

FIGS. 1A and 1B schematically show an actuator with an associated poppet valve in the two possible end positions of the lift valve and the actuator anchor according to the prior art.

Figs. 2A and 2B show the known division of the forces acting on the armature with or without misfiring relative to its deflection.

Fig. 3 shows a schematic block diagram with the main components of an embodiment of apparatus for carrying out the method according to the invention.

In Fig. 1A and 1B, a gas exchange poppet valve 1 is illustrated a known type, respectively. The valve 1 is held by an opening spring holder 2 and serves to open and close an inlet or outlet opening in a cylinder wall 3 . The valve is driven on the one hand by return springs 4 a and 4 b, which are generally of the same strength and which act between the opening spring holder 2 or cylinder wall 3 and a spring holder 5 on the stem of the valve 1 , and on the other hand by an actuator 6 with electromagnets in connection with a Anchor. In the in Fig. 1A and Fig. 1B embodiment shown, there is a first electromagnet 6a above and a second electromagnet 6b below the armature 6 c. The two electromagnets 6 a and 6 b each comprise a winding, which is shown in gray in the drawing, and an iron yoke, which is shown with double hatching in the drawing. The armature 6 c of the gas exchange stroke valve is, for simplification in FIGS. 1A and 1B, firmly connected to the plunger or shaft 6 d of the valve.

If the upper electromagnet 6 a is energized, the armature 6 c is attracted, and the valve stem with its elements 6 c, 6 d and 6 e moves upward against the force of the return spring 4 a, so that the opening in the cylinder wall 3 is closed by a valve foot 6 e at the shaft end. This situation is shown in Fig. 1A. The upper electromagnet 6 a is also called the closing magnet of the gas exchange globe valve.

If the circuit is interrupted by the upper electromagnet 6 a and instead the lower electromagnet 6 b is energized, the armature 6 c is pulled down against the force of the return spring 4 b, and the shaft 6 d moves in this direction, the Opening in the cylinder wall 3 through the valve foot 6 e is released. This situation is shown in Fig. 1 B, arrows indicating the outflow of the working medium from the cylinder. The lower electromagnet 6 b is also called the opening magnet of the gas exchange valve.

The energization of the magnets 6 a and 6 b depends in each case on the desired valve stroke and the desired closing or opening duration of the valve. A method is known from DE 102 05 382 for determining a force profile with which a desired middle layer speed can be set. The integration of the force curve along the valve path results in the energy which is extracted from the valve / armature system by the magnetic force.

In order to detect the valve path, the deflection of the valve is detected by a motion sensor 7 , which in the embodiment shown in FIGS. 1A and 1B is an inductive sensor. (A capacitive sensor or an optical sensor can also be used as the motion sensor 7 instead of a magnetic sensor.) Its sensor coil, shown in cross section, is located at the top of the opening spring holder 2 .

In Fig. 2A and Fig. 2B acting on the plunger force F is plotted against the distance x. The force F is composed of a magnetic component 8 and a gas pressure component 9 . It decreases linearly in the manner shown here in a simplified manner with the deflection of the tappet. Shown is adaptation of the force component of the electromagnet to the force component that is exerted by the gas pressure.

Fig. 2A shows a case that a normal ignition process has occurred in the cylinder. Both force components are approximately the same size. The force on the plunger is very large at the start of the movement (left). However, the further the tappet clears the opening in the cylinder wall 3 , the lower the force that the gas pressure exerts on the tappet. On the other hand, the air gap between the closing magnet and armature widens, so that the braking force 8 should also be smaller. The steady decrease in the force shown in FIG. 2A is thus obtained.

Fig. 28 shows the case that normal ignition has not taken place. The gas pressure force 9 is now significantly smaller than in FIG. 2A. Due to the lack of resistance, the armature 6 c would pass the middle position too quickly in order to ensure that the armature is placed on the opening magnet in a controlled manner. The lack of resistance due to the gas in the cylinder must therefore be compensated for by the make magnet 6 a. The closing magnet 6 a brakes the armature on its way to the middle position by energizing it so that the armature 6 c only "slowly" releases from it. Magnetic component 8 in FIG. 2B is larger than that in FIG. 2A.

The reduced energy, ie the braking energy or the energy fed into the closer magnet 6 a, is recorded and compared with a predetermined threshold value. A comparison signal is then output, which indicates misfiring.

To determine the braking energy, either the magnetic power over time or the magnetic force can be integrated along the way. The is preferred Integration of strength is carried out via the path, which is described below becomes.

The area under the force curve represented by curve 8 or 9 over the path of the valve corresponds to the braking energy. The difference in the areas of curve 8 and curve 9 is compared with a comparison value or threshold value, and a decision is made on the basis of the comparison result as to whether there was an ignition misfire or not.

In Fig. 3 is a perspective drawing of the valve and an embodiment of an apparatus is schematically shown, with which the method described above can be implemented. The sensor 7 sends the location signal x to a device 10 which calculates the necessary braking force F _{brake in} order to achieve a desired middle position speed. This braking force is now converted into a magnetic current supply I _brake by a force-current converter device 11 . At the same time, this force is integrated in an integrator 12 via the path x and compared with a threshold value. As soon as it is recognized that the energy extracted from the armature 6 c is greater than expected, a misfire signal is output by the integrator 12 .

In the embodiment shown, the threshold value for the integrator 12 is output by a map memory 13 , from which it is read as a function of the current engine load. The detection of misfires can thus be adapted to the actual load, so that an incorrect misfire signal is not output. The load specification for the map memory 13 comes in particular from an engine control (not shown). Reference number 1 gas exchange stroke valve
2 valve holder
3 cylinder intake-exhaust port
4 spring, 4 a valve closing spring = (first) return spring, 4 b valve opening spring = (second) return spring
5 spring holder on shaft
6 actuator, 6 a closing magnet, 6 b opening magnet, 6 c armature, 6 d shaft, 6 e valve base
7 motion sensor, sensor coil
8 power of electromagnet
9 Force from gas back pressure
10 Brake force calculation
11 power-current converters
12 integrator with comparator function
13 load-dependent threshold value specification
F force
x position of the anchor

Claims (7)

1. Method for detecting misfires of a piston internal combustion engine with at least one cylinder, the working medium of which is exchanged for at least two gas exchange lift valves ( 1 ), each of which has an armature ( 6 c), which is connected to at least one electromagnet ( 6 a, 6 b) interacts to actuate the respective gas exchange poppet valve, said armature between an open position of the gas exchange lifting valve and a closed position of the gas-change poppet valve is moved (6 c) in each case against the force of at least one return spring (4 b 4 a,), characterized by
Determining the kinetic energy of the armature ( 6 c) using a motion sensor ( 7 ),
Reduce the kinetic energy of the armature ( 6 c) when the gas exchange lift valve ( 1 ) is opened by the at least one electromagnet ( 6 a, 6 b), so that the kinetic energy of the armature as a function of the position of the gas exchange lift valve under one predetermined value remains, and
Detection of the reduced energy and comparison with a predetermined threshold value and output of a comparison signal which indicates misfiring by a braking control device ( 10 , 11 , 12 ). 2. The method according to claim 1, characterized in that for determining the kinetic energy of the armature ( 6 c), a spatial coordinate (x) of the armature is recorded in time by the motion sensor ( 7 ) and for reducing the kinetic energy of the armature ( 6 c) an electromagnet ( 6 a, 6 b) is energized. 3. The method according to claim 1 or 2, characterized in that the threshold value is stored as a function of the load range of the piston internal combustion engine in a map memory ( 13 ). 4. Device for detecting misfires of a piston internal combustion engine with at least one cylinder, the working medium of which is replaced by at least two gas exchange lift valves ( 1 ), each of which has an armature ( 6 c) which is connected to at least one electromagnet ( 6 a, 6 b) interacts to actuate the respective gas exchange valve, the armature ( 6 c) being moved against the force of at least one return spring ( 4 a, 4 b) between an open position of the gas exchange valve and a closed position of the gas exchange valve by
a motion sensor ( 7 ) for determining the kinetic energy of the armature ( 6 c),
a braking control device ( 10 , 11 , 12 ) for reducing the kinetic energy of the armature ( 6 c) when the gas exchange lift valve ( 1 ) is opened by the at least one electromagnet ( 6 a, 6 b), so that the kinetic energy of the armature in Depending on the position of the gas exchange valve remains below a predetermined value, and for detecting and comparing the reduced energy with a predetermined threshold value and for outputting a comparison signal which indicates misfiring. 5. The device according to claim 4, characterized in that
the motion sensor ( 7 ) detects a location coordinate (x) of the armature in time to determine the kinetic energy of the armature and
an electromagnet ( 6 a, 6 b) is supplied with current to reduce the kinetic energy of the armature ( 6 c). 6. The device according to claim 4 or 5, characterized in that the movement sensor ( 7 ) is a magnetic sensor. 7. Device according to one of claims 4 to 6, characterized in that a map memory ( 13 ) for storing the threshold value as a function of a load range of the piston internal combustion engine.