EP0306839A1 - Method and device for driving solenoids, particularly in injection valves - Google Patents

Abstract

A process and a device are disclosed for driving wired electromagnets (3a to 3n), in particular in injection valves (2a to 2n) for internal combustion engines. In order to optimize the drive, in particular reducing the starting delay, a short, high-voltage pulse is sent through the electromagnet, calculated to avoid thermal overloads. Afterwards the electromagnets (3a to 3n) are supplied only with minimal maintenance power, for example a constant holding current. This drive allows the starting delay to be considerably reduced in comparison with usual drives, the closing delay is considerably shorter as well.

Description

The invention relates to a method and a device for controlling switching electromagnets, in particular in injection valves according to the preambles of the independent claims.

In modern motor vehicles, the fuel is supplied to the combustion chamber of the engine via electrically controlled injection valves. The fuel metering and the map ignition takes place here via a central computer system, which calculates system data from various measured values supplied by sensors and delivers corresponding pulse-width-modulated control signals to an electromagnet of the valve. Air flow meters, cooling water temperature meters, air inlet temperature meters, which measure the inlet temperature of the air at the entrance to the combustion chamber, air temperature meters, revolution mark transmitters, speed transmitters and throttle valve switches serve as sensors. Mixing the fuel into the air flow during the intake process of the associated cylinder gives the best technical results. The short, available times and the considerable idle times of the injection valves at a given maximum fuel volume make it necessary to compromise not to spray the fuel as a package in one single operation, but in four sub-volumes, each time the internal combustion engine cycles. With this compromise, however, the advantages of good air-fuel mixing of an injector are largely eliminated.

In a four-stroke four-cylinder engine, two successive ignition processes take place after a 180 ° crankshaft revolution. The opening time of the injection valve between two successive injection processes per 180 ° crankshaft revolution is referred to as the injection angle. In this cycle, the pulse width modulated control pulses are also delivered by the process computer.

When metering fuel with injection valves in such intermittent operation, the ratio between the amount of fuel and the above-mentioned duty cycle of the pulse duration modulated signals or the injection angle should be as constant as possible. If the metered amount of fuel is plotted against the engine speed, with the duty cycle or injection angle as a parameter, the characteristic curves should be as linear as possible in the ideal state and have the same value for the metered fuel amount for all engine speeds for a given injection angle. The measurements that were carried out with known injection valves, however, showed considerable deviations from this ideal course. In known injection valves, the characteristic curves drop in the direction of higher engine speeds, these characteristic curves not only showing a linear but an irregular course.

In the meantime, there are new injection valves on the market that no longer have series resistors. This is possible because the winding of the electromagnets consists of a kind of insulated resistance wire. The series resistor is therefore integrated in the magnetic winding. The measurements carried out with such injectors showed a significantly better course of the characteristic curves: the characteristic curves show a more linear course than those of the previously mentioned injectors and do not drop so noticeably towards higher speeds. Nevertheless, these characteristics are also removed from the ideal course.

The main components of conventional electrical injection valves are the nozzle part with the nozzle assembly, the winding of the electromagnet, the magnetic core, the armature, the return spring and the housing with force fabric line connections. A constant fuel pressure is constantly present at the inlet of the injection valve, the return spring pressing against the nozzle assembly with such force that the injection valve is reliably closed. When an electrical voltage is applied to the winding of the electromagnet, a magnetic field builds up in a linear manner in this, so that the spring force is overcome at a certain point in time and the armature made of soft magnetic material is pulled axially to the core of the electromagnet. The movement distance of the armature and thus of the associated nozzle assembly is mechanically limited by a disc. The current in the winding of the electromagnet continues to increase linearly until the core is saturated and is now only limited by the series resistance of the injection valve or the resistance of the winding wire. The field strength in the electromagnet is proportional to the product of the current and the number of turns divided by the length of the magnetic path.

The parameters for optimal control of the electromagnets have a diametrical course. A large inductance is required for a given mechanical force in order to keep the current low and not to require complex control circuits.

With increasing inductance at constant voltage, however, the rate of current rise and the dead time to the through current decrease, which is given by the ratio of the inductance and the resistance.

It is also of particular importance that the armature is removed from the core at the moment of switch-on and therefore a considerably higher field strength for the movement of the armature due to the degressive field density as a function of the distance is required than in the steady state. On the other hand, the magnetic energy in the winding of the electromagnet, which reached its maximum at the moment of switching off, must be reduced. If the dismantling takes place quickly, high voltage peaks are the result. If the degradation is damped, the counter-EMF causes a switch-off delay. The switch-on delay due to the linear increase in current and the switch-off delay due to the stored magnetic energy are the two main disturbance parameters that are responsible for non-linear relationships in fuel metering.

The problem with the control of switched electromagnets has only been described in the above in connection with electromagnetic injection valves for internal combustion engines. However, these considerations apply in particular with regard to the switch-on and switch-off delay for all switched electromagnets in other types of application.

The invention has for its object to provide a method and a device of the type in question, with which in particular the switch-on and switch-off delay of switched electromagnets, in particular in electrically controlled injection valves, can be reduced so that the switching characteristics are as optimal as possible.

This object is achieved according to the invention by the characterizing features in the independent claims.

Accordingly, the guiding principle of the invention is to be seen in this, by means of a specific control circuit without change or to change the component switched by the electromagnet to influence component-specific parameters and to reduce or eliminate the two above-mentioned interference parameters and thus to ensure the operation of the component in the permissible characteristic field. The switching characteristics show approximately the desired horizontal course.

The electromagnet, for example of an injection valve, is consciously overridden in the start-up phase within a defined and very short time frame, in particular independent of the switch-on duration, with an initial pulse of high voltage amplitude, the windings of the electromagnet not being thermally overloaded due to the short time of the initial pulse. In order to achieve the specified low switch-on delay, the unregulated supply voltage is transformed up to a regulated high voltage level, which generally corresponds to a multiple of the supply voltage. The anchor moves very quickly in this way to the other position, which, for. B. is the open position of an injection valve. The current rise is practically linear. The switching movements of the armature can also be clearly reproduced over time. After the switch-on override, the electromagnet is provided with only a minimum energy necessary for securely holding the armature, which is preferably done by means of a minimal and preferably constant holding current.

Overriding in the switch-on phase improves the switch-on delay by about a power of ten. Is the switch-on delay z. B. conventional injection valves at about 2 msec, values between 0.1 and 0.3 msec are achieved according to the invention.

The switch-on override takes place with high voltages, which are between 40 and 80 V for injection valves in motor vehicles. These voltages cannot be reached in vehicle electrical systems, so that they have to be generated in separate circuit stages. A preferred way of doing this is to convert the vehicle electrical system voltage from usually 12 V to the desired value using a transformer, as described in German patent application P 35 46 410.0.

Likewise, with a control of an electromagnet according to the invention, the switch-off delay is reduced, since only a small amount of magnetic energy has to be dissipated.

The initial pulse of high voltage amplitude can in principle be generated in several ways using the vehicle electrical system voltage available in motor vehicles. The generation of the initial pulse would thus be realized in a similar way to the generation of the ignition pulse. However, this solution is not recommended, since then currents of approx. 20 amperes would occur on the primary side in a corresponding pulse transformer. The necessary reinforced cross sections of the supply lines and large filter capacities are also disadvantageous. In addition, there is a high level of electromagnetic interference radiation. Semiconductors that can withstand high peak currents would have to be used as circuit breakers. Overall, a complicated control with high circuit complexity is required.

There would also be the possibility of using electrolytic capacitors. For such high pulse powers, however, conventional and inexpensive capacitors are not available. In addition, electrolytic capacitors are only of limited suitability for such pulse applications, e.g. B. due to their high volume, their unfavorable temperature behavior and poor electrical switching behavior due to the inductance.

Preferably, therefore, a storage capacitor is kept continuously at a high state of charge by means of a fast converter having a transformer, said storage capacitor delivering its charge to the injection valve in a pulsed manner via a switching device controlled by the control circuit. A semiconductor is used as the circuit breaker. This solution is considerably simpler and less expensive than the ones mentioned above.

A certain amount of energy is required to switch the electromagnet through quickly using the high voltage start pulse. Since the storage capacitor provides a relatively high intermediate voltage, only relatively small currents occur in the windings of the electromagnet, which are values between 2 to 4 times the continuous load current and due to the short-term nature of the initial pulse, there is no thermal overloading of the winding of the electromagnet result. With a predetermined permissible charge on the storage capacitor, a considerably smaller capacitance is permissible, which is of the order of a few microfarads. Such capacitors are available inexpensively in a polypropylene version. This type of capacitor has an extremely good pulse behavior, so that overall better values can be achieved than with electrolytic capacitors. The capacitor is charged relatively slowly by the fast converter and then releases its charge to the respective electromagnet when it is switched through.

A constant current source is preferably used to provide the low holding energy for the electromagnet.

If several electromagnets are controlled sequentially, e.g. B. the electromagnets of injectors of an engine, the converter, the switching device and the constant current source can be used in common for all injectors of an engine. A separate circuit breaker is then available for each injection valve. This solution considerably simplifies the control circuit, since a separate control circuit is not necessary for each injection valve.

Regardless of the implementation of the control of the injection valves, these injection valves are not changed in terms of design, so that existing control circuits can also be converted in the sense of the invention.

A number of advantages are achieved with the invention, including:

The corner frequency of the injector, i.e. H. the frequency at which the injection valve no longer opens despite a control signal has been raised significantly.

The error in fuel metering caused by the switch-on delay is considerably reduced, so that the injection quantity can be controlled much better in comparison with conventionally controlled injection valves at all injection angles and engine revolutions per minute that occur in practice.

The amount of fuel added can be dispensed in a single cycle instead of in several portions as in the prior art.

The characteristics of an injection valve controlled according to the invention show a much better linear one Course as those of conventionally controlled injection valves.

Due to the precise fuel metering possible with the invention, the power of the engine is increased, the consumption is reduced, the fuel is better utilized and, in particular, a substantially lower pollutant emission is achieved than previously. The last-mentioned advantage makes it possible to reduce the pollutant emissions from engines to values that are otherwise only possible with other aids, such as. B. catalysts can be reached.

• Fig. 1 ein schematisches Blockschaltdiagramm einer Ein­richtung gemäß der Erfindung zum Ansteuern von mehreren Einspritzventilen;
• Fig. 2 Diagramme für die Steuerspannung, den Stromverlauf durch einen Elektromagneten des Einspritzventils und für die Einspritzmenge, jeweils aufgetragen über der Zeit, einerseits für eine herkömmliche Ansteuerung und andererseits für eine erfindungsge­mäße Ansteuerung eines Einspritzventiles;
• Fig. 3 zwei Kennliniendiagramme für die Einspritzmenge pro Zeit über der Drehzahl einer Brennkraftma­schine pro Minute mit dem Einspritzwinkel als Parameter, und zwar ein Kennliniendiagramm für herkömmlich angesteuerte und ein weiteres Kennli­niendiagramm für erfindungsgemäß angesteuerte Einspritzventile;
• Fig. 4a und b Diagramme für die errechneten Fehler in Prozent bei der Kraftstoffdosierung bei herkömmlicher Ansteuerung bzw. erfindungsgemäßer Ansteuerung eines Einspritzventiles.

Further embodiments of the invention emerge from the subclaims. The invention is explained in more detail in an exemplary embodiment with reference to the drawing. In this represent:

• Figure 1 is a schematic block diagram of a device according to the invention for driving a plurality of injection valves.
• 2 shows diagrams for the control voltage, the current profile through an electromagnet of the injection valve and for the injection quantity, in each case plotted over time, on the one hand for conventional control and on the other hand for control of an injection valve according to the invention;
• 3 shows two characteristic diagrams for the injection quantity per time versus the speed of an internal combustion engine per minute with the injection angle as a parameter, namely a characteristic diagram for conventionally controlled and another characteristic diagram for injectors controlled according to the invention;
• 4a and b diagrams for the calculated errors in percent in the fuel metering with conventional control or control according to the invention of an injection valve.

1 shows a block diagram of an injection system 1 for an internal combustion engine. The injection system has a plurality of electromagnetically actuated injection valves 2a to 2n, each with an electromagnet 3a to 3n, which are controlled with the aid of a computer 4 with control signals modulated by pulse duration, the computer calculating this control signal in a conventional manner on the basis of measured values which are supplied by a plurality of sensors . The control signals of the computer 4 are fed via a pulse shaper 5 to a pulse source 6, the output pulses of which are fed via a circuit breaker 7a to 7n for each injector to the associated electromagnet 3a to 3n, with a respective one between the feed lines to the respective electromagnets 3a to 3n Filter network 17a to 17n is provided to reduce peak values of the supplied signals. The circuit breakers are controlled via a decoder 8, which in turn receives control signals from the computer 4. Furthermore, a data converter 9 controlled by the computer 4 is also provided, which is connected to the pulse shaper 5 and the decoder 8.

The pulse source 6 is with an input terminal 10 to the voltage U of an electrical system of a motor vehicle and with another input terminal 11 to a basic potential, for. B. mass. The input terminal 10 is the same in a first branch of the pulse source 6 voltage / DC converter 12 and a pulse switch 13 as well as a constant current source 14 connected in parallel in another branch. A filter capacitor or a capacitor arrangement 15 is also provided between the input terminals 10 and 11. A storage capacitor 16 is located between the ground potential line connected to the input terminal 11 and a connection point between the converter 12 and the pulse switch 13.

The DC / DC converter 12 converts the on-board voltage U from z. B. 12 V in a higher voltage of z. B. 80 V around. For this purpose, a transformer with a primary winding of 9 turns and a secondary winding of 72 turns is provided in the converter 12. A demagnetization winding with 12 turns is also provided on the primary side.

The function of the described injection system is as follows:

The computer 4 outputs a pulse-width-modulated control signal to the pulse shaper 5 and the data converter 9 on the basis of the measured values calculated by the sensors and also a marking signal to the decoder 8. The marking signal is used to control and switch the corresponding power switches 7a to 7n of the individual injection valves 2a to 2n closed for the time period specified by the pulse-width-modulated control signal. The pulse shaper 5 in turn controls the pulse switch 13, which thereby closes a predetermined period of time, in this case 250 microseconds. The charge of the storage capacitor 16 is supplied to the electromagnet 3a in a pulsed manner via the power switch 7a during this period. Due to this short-term high voltage pulse, the respective injection valve becomes only opened with a slight switch-on delay of approximately 0.25 msec. Following the high voltage pulse, the constant-current source 14 supplies a small holding current to the respective electromagnet 3a to 3n, which holds the injection valve in the open position. If the circuit breaker 7a is opened when the control signal drops, the injection valve is moved back into the closed position by a compression spring (not shown here), this being done with only a slight delay. During the open position of the respective injection valve 2a and 2n, a predetermined amount of fuel determined by the duration of the control signal is injected from the injection valve. By controlling the injection valves via the data converter 9 and the decoder 8, it is ensured that fuel is only injected into the cylinder of the engine whose piston is in the intake stroke. Spraying in several portions, as in the prior art, can be avoided, so that the advantages of the injection are fully exploited.

2 shows a signal diagram for a conventional control of an injection valve on the left-hand side, and a signal diagram for a control of the same injection valve according to the invention on the right-hand side. The top line a shows part of a pulse duration modulated train of the control voltage supplied by the computer. In line b for the conventional control it can be seen that the current course through the electromagnet increases linearly until the current reaches a value at which the armature of the electromagnet overcomes the force of the compression spring in the injection valve and the injection valve is thereby opened. The delay time between the first edge of the control voltage and the start of the opening is approximately 2 msec. The switching current then rises further and falls with the end edge of the control voltage. At this moment the armature starts to move, which is initiated by the pressure spring of the injection valve. The injection valve is completely closed again after a short delay. This cycle is repeated according to the course of the control voltage.

In the control according to the invention, the sudden discharge of the storage capacitor 16 causes the current through the electromagnet of the respective injection valve to increase very rapidly and already reaches the switching current value after a delay time of approximately 0.25 msec, so that the injection valve is opened. The opening process started shortly before, due to the high current values. During the short pulse over 250 µsec, currents of up to 3 amperes flow in the primary winding of the respective electromagnet in the injection valve. Due to the short duration of 250 µsec, however, this does not lead to a thermal overload of the winding. At the end of this short current pulse, the constant current source 14 supplies a small holding current which holds the armature of the respective electromagnet 3a to 3n in the open position of the valve. The value of this holding current is significantly lower than the switching current necessary to initiate the switching of the valve. With the end flank of the control voltage, only the magnetic energy in the electromagnet, which is also low due to the low holding current, then needs to be dissipated, so that the valve is closed again after a very short delay time.

The instantaneous value of the field strength is the relevant parameter for opening the injection valve. This instantaneous value is a function of the time constant, ie the ratio ses between the inductance and the resistance as well as the supply voltage. The switch-on delay is therefore a function of these three variables. While the supply voltage in a control according to the prior art is a constant, it is a variable according to the invention, with the aid of which the switch-on delay also becomes variable. The values for the switch-on and switch-off delay can be optimized by appropriate dimensioning of the amplitude of the initial pulse and its duration.

In the last lines c of FIG. 2 it can be seen that the amount of injection in conventional control differs significantly from the course of the control voltage due to the long delay time when the injection valve is switched on. Since the delay time when switching on is constant regardless of the course of the control voltage, it is obvious that there is no proportionality between the time course of the control voltage and the time course of the injection quantity. In contrast to this, according to the invention, the short delay time when switching on ensures an approximately optimal proportionality between the time course of the injection quantity and the control voltage.

In Fig. 3, a characteristic diagram for the flow rate per unit of time plotted against the engine revolution per minute with the injection angle as a parameter in a conventional control and with broken lines in a control according to the invention of the same injection valve are shown with solid lines. It can clearly be seen that with injection angles of up to 144 ° the characteristic curves drop in the direction of higher speeds with conventional control and only with one injection angle of 162 ° above about 4000 revolutions per minute. The desired linear, horizontal course is not achieved. It can be seen that, however, this is approximately the case for all the characteristic curves in the case of a control according to the invention. The characteristic curves have good linearity, which brings the advantages mentioned above.

4a shows the theoretically determined error in percent in fuel metering with conventional control of an injection valve with a determined switch-on delay of 2 msec, in FIG. 4b the error in percent with fuel metering when controlling the same injector according to the invention, each with the Injection angle as a parameter. This error is essentially due to the switch-on delay of the injection valve. It can be seen that the error with a conventional control has considerable values even at low revolutions per minute, while this error is significantly smaller with a control according to the invention and assumes noticeable values only for small injection angles up to approximately 40 °.

Claims (8)

1. A method for controlling high-frequency switching electromagnets, in particular in injection valves for internal combustion engines, the switching of the electromagnet being acted upon by a signal generated from a supply voltage of a DC voltage source, which signal consists of an initial pulse and a subsequent, essentially safe one Holding force for an armature of the electromagnet ensuring the holding signal is composed and the supply voltage supplied by the DC voltage source is above the operating voltage permissible for continuous operation of the electromagnet, characterized in that the initial pulse is generated as a voltage pulse by transforming up the supply voltage and is dimensioned in terms of its amplitude, that a predetermined switching time of the electromagnet is reached, that this initial pulse is switched is supplied to the electromagnet, and that a current signal of constant amplitude is supplied to the electromagnet as a hold signal. 2. The method according to claim 1, characterized in that the initial pulse is generated by stepping up the unregulated supply voltage to a regulated higher voltage. 3. The method according to claim 1 or 2, characterized in that the amplitude of the initial pulse is additionally dimensioned so that the current profile in the electromagnet during the initial pulse is substantially linear. 4. The method according to any one of the preceding claims, characterized in that the stop signal is supplied to the electromagnet already during the initial pulse. 5. The method according to claim 4, characterized in that the initial pulse and the hold signal start simultaneously. 6. Device for carrying out the method according to one of the preceding claims for switching an electromagnet having an armature, in particular for actuating a valve body for opening and closing an injection valve, with a DC voltage source which provides a supply voltage greater than the operating voltage of the electromagnet, and with a control circuit that connects the electromagnet with the Controlled DC voltage source connects so that first a brief initial pulse and then a substantially secure holding force for the electromagnet is given a stop signal to the electromagnet, characterized in that the DC voltage source (10) is connected to a pulse source (6), the one Feed voltage high-transforming voltage source (12) for providing a high voltage level and a constant current source (14) for providing the hold signal, and that from the control circuit (4, 5, 6, 9) operable switches (13, 7a to 7n) are provided to first connect the voltage source (12) with the high voltage level briefly and then the constant current source (14) with the electromagnet (3a to 3n). 7. Device according to claim 6, characterized in that the pulse source (6) in a first branch with the supply voltage supply of the DC voltage source (U) connected DC / DC converter (12) with a parallel storage capacitor (16) and one of of the control circuit (4, 5, 8, 9) actuable switching device (13) and in a second, parallel branch, the constant current source (14), and that the two branches via a common, by the control circuit (4, 5, 8, 9) controlled circuit breakers (7a to 7n) are connected to the electromagnet (3a to 3n). 8. Device according to claim 6 or 7, characterized in that when using several, successively switched electromagnets (3a to 3n), a common pulse source (6) is provided for all electromagnets, which by the control circuit (4, 5, 8, 9) is controlled with one electromagnet (3a to 3n) each.

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