EP1979598A1 - Device for switching inductive fuel injection valves - Google Patents

Abstract

Disclosed are a method and a device for more rapidly switching inductive fuel injection valves. According to the invention, the magnetic retaining forces generated by remanence in a bistable valve comprising an opening and closing coil or by eddy currents in a standard valve comprising an opening coil and a closing spring are eliminated with the aid of a negative current that flows through the coil in a direction running counter to the direction of the operating current. Additionally, the magnetic yoke and armature that are used are made of materials having different conductivities in order to be able to close the valve even more quickly.

Description

description

Device for switching inductive fuel injection valves

The invention relates to a device for switching inductive fuel injection valves according to claim 1 or 6.

Stricter emission regulations and the need for ever better fuel efficiency have driven the introduction of high-pressure direct injection systems for diesel and gasoline engines in recent years, as this significantly improves the quality of the mixture preparation.

Characteristics of these systems are very high fuel injection pressures of more than 2000 bar (diesel) and more than 10% (gasoline), as well as the supply of fuel in several injections per injection.

By adjusting the fuel metering to the dynamics of the combustion process accumulated a wealth of functi ^¬ be achieved onsverbesserungen: the petrol engine: better efficiency, less raw emissions; with the diesel engine: less engine noise (knocking), less soot particles, lower NOx production, better cold start behavior.

In some diesel engines fuel is injected at periodic intervals even in the exhaust stroke to achieve about the regeneration of a particulate filter in the exhaust system by burning off the soot particles.

The abundance of these functions, which are possible with modern direct injection systems, has a tremendous impact on the future Tightening of the requirements for precision and dynamics of the injection valves entailed. Thus, now valve switching times of 100 to 500μs are required in order to inject at the high system pressures even the smallest amounts of fuel down to a few micrograms with high accuracy and high temporal precision.

This has ultimately piezo technology made the breakthrough light ^¬ because it significantly faster and more accurate one VEN tilbetätigung allowed compared to classical Solenoidtechnik. It has meanwhile become standard for diesel passenger car engines.

Since the piezoelectric ceramic used here responds to a change in the control voltage spontaneously with a change in volume of the injected fuel quantity, a very fast, almost lag-free actuation of the injectors mög ^¬ is Lich. In contrast to this, the classic solenoid valve first has to build up a current flow in the inductance excitation winding, which then, but only after reaching a certain current value, can actuate the valve.

However, the advantages of piezo technology go for high ^¬-pressure injectors with significant costs associated so that an urgent need exists for less demanding

High pressure direct injection systems continue to use solenoid injectors.

A typical example of this is large-volume, slow-running diesel truck engines, such as 9-liter 6-cylinder engines with maximum operating speeds of around 1800 rpm. In addition to the low engine speed, the requirements for the smallest injection quantities are also reduced because of the large displacement. Also, the number of injection pulses per injection process is lower because, for example, a pre-injection to reduce the diesel-typical "Nageins" can be omitted because of the already quite high noise of the truck engine. Investigations have now shown that although solenoid injection valves are in principle suitable for such applications, they still require some further development. Thus, for use in direct injection systems with standard solenoid valves, which have a coil (winding) for the magnetic opening and a spring for closing the valve, the closing delay must be reduced.

The main obstacle when closing such a standard sole- noidventils are the eddy currents in the magnetic material of Ven ^¬ tils, which decay after switching off the operating current only long ^¬ sam and prevent rapid closing of the valve. This behavior defines the minimum valve opening ^¬ time and thus increases the lowest possible fuel input injection quantity.

In the case of bi-stable injectors with two windings and fixation of the valve in the respective end position by means of remanence forces, a reduction of both the switch-on time for opening the valve and the switch-off time for closing the valve is required.

FIG. 1 shows a known basic circuit ^arrangement for operating a coil of a fuel injection valve with PWM (Pulse Width Modulation) operation.

There, one terminal of the coil L1 is connected to the positive pole V + of a supply voltage source V by means of a first switching transistor T1, and the other terminal is connected to reference potential GND by means of a second switching transistor T2. The source terminal of the first switching transistor Tl is connected to one terminal of the coil Ll, its drain terminal to the positive terminal V +. The source terminal of the two ^¬ th switching transistor T2 is connected to reference potential GND verbun ^¬ the and its drain terminal to the other terminal of the coil Ll. In addition, a freewheeling diode Dl of reference potential GND is arranged to conduct current to one terminal of the coil Ll and a recuperation diode D2 from the other At the end of the coil Ll, it is electrically conducted to the positive pole V + of the supply voltage source.

The circuit according to FIG. 1 functions as follows: before the start of a switch-on process, both switching transistors ^T1 , T2 are nonconductive. When switching on (opening signal EO, rising edge) both switching transistors Tl, T2 are switched electrically conductive. This applied to the Spuleninduk ^¬ tivity the supply voltage V, such as V = 48V. A current flows through the coil Ll, which rises rapidly.

Upon reaching a predetermined upper current setpoint at which the valve opens, switching transistor Tl is switched non-conducting by means of the PWM unit PWM and the coil current now flows through the coil L1 via the freewheeling diode D1 and switching transistor T2, wherein it slowly drops. If the current now reaches a lower predetermined setpoint value, switching transistor T1 is again turned on, whereupon the coil current increases again.

By repeated Leitend- and Nichtleitend switching transistor Tl so the coil current can be maintained during the duty cycle of the valve at an approximately constant value. At the end of the switch-on time (falling edge of the opening signal EO) (in a standard valve with closing spring) both switching transistors Tl and T2 are simultaneously switched non-conducting, whereupon the coil Ll discharges via the freewheeling diode Dl and the recuperation diode D2 into the supply voltage source V. and the valve closes.

As described above, FIG. 2 shows the voltage curve in the upper trace and the current trace in the opening coil L1 during the opening duration of a standard fuel injection valve in the lower trace. FIG. 3 shows the principle of a bistable fuel injection valve. The valve needle 1 is mounted ver ^¬ pushed in a housing 4 and shown in the "OPEN" position. It lies on the left iron yoke 2. The left iron return 2 encloses the opening coil AB (rectangles A and B with bevel). By a previous actuation current in the opening coil AB, the left iron yoke was magnetized, so that now, when the current subsides, it holds the valve needle 1 in the "OPEN" position.

In this position, the way is clear for the fuel under high pressure from the inlet a (in the arrow direction) to the outlets b and c and on to the valve nozzles, not shown, which are opened thereby. In the following, the term "fuel" may also be a "hydraulic medium", wherein instead of a fuel circuit, a hydraulic circuit may be provided, by means of which a fuel injection valve is controlled with hydraulic pressure over ^¬ tion.

To close the valve, an actuating current is now passed through the closing coil C-D, so that the valve needle 1 moves to the right iron yoke 3. After switching off the closing current, the valve needle 1 is held in the "CLOSED" position by the magnetization of the right-hand iron yoke 3.

This blocks the path from the inlet a to the outlets b and c. At the same time, the outlets b and c are connected to the return lines r, which are designed as a ring line, which reduce the fuel pressure between the outlets b, c and the valve nozzles, not shown, whereby the valve is closed.

Since a bistable valve has two coils, namely one

Opening and a closing coil, the circuit arrangement according to FIG. 1 is to be provided twice per valve: once for operating Ben the opening coil AB (Ll in Figure 1) and once for Be ^¬ drive the closing coil CD.

From DE 100 18 175 Al a circuit arrangement for operating a Hubanker actuator for a gas exchange valve is known, in which at the end of the actuation process to the current ^¬ current in opposite directions through the coil is sent to initiate a faster change of the switching state.

Such processes are also known, for example, from DE 199 21 938 A1, DE 195 26 681 A1 and DE 40 16 816 A1.

The object of the invention is to provide an improved device for accelerated switching of inductive fuel injection valves, which in bistable valves, the opening and the closing delay, and reduced in standard solenoid valves (with closing spring), the closing delay.

This object is achieved by a device ge ^¬ according to the features of claim 1 or 6.

Advantageous developments of the invention can be found in the dependent claims.

The valve switching times are known to be reduced when in a bistable valve, the magnetic holding forces are eliminated when activating a coil by deliberately clearing the remanence of the other coil, and in a standard valve (with closing spring) - induced by the decaying eddy currents - magnetic holding forces Disabling the coil can be eliminated.

In both cases, the impression of a negative current pulse is required in the respective coil, whose Current level and time course must correspond as closely as possible to the magneti ^¬ requirements of the valve.

Embodiments of the invention are explained below with reference to a schematic drawing.

In the drawing show:

1 shows a known, basic circuit arrangement for the PWM operation of an inductive fuel injection valve, FIG. 2 shows the voltage and current profiles during PWM operation of the fuel injection valve according to FIG. 1, FIG.

FIG. 3 shows a detailed view of a bistable fuel injection valve,

FIG. 4 shows a circuit arrangement according to the invention for the PWM operation of an inductive fuel injection valve,

FIG. 5a shows the voltage and current profile at the current mirror of the circuit arrangement according to the invention;

Figure 5b: the timing of operating current and negative current when opening and closing a bistable valve.

6 shows a control device for the negative current in a bistable fuel injection valve,

7 shows a control device for the negative current in a standard injection valve with opening coil and closing spring ^¬,

FIG. 8 shows a circuit arrangement according to the invention for operating a plurality of valve coils;

9 shows the time profile of the valve switching movements, without (9a) and with degaussing current (9b), FIG. 10 shows a further circuit arrangement, FIG.

FIG. 11 shows a control unit for the circuit arrangement according to FIG. 10,

FIG. 12 shows the signal curves in this control unit, FIG. 13 shows a control unit for the circuit arrangement according to FIG

FIG. 10. FIG. 14: a schematic representation of a standard

Solenoid injection valve, and Figure 15: the formation of transient, opposite

Field directions.

FIG. 4 shows a circuit arrangement according to the invention for the PWM operation of a coil, for example the opening coil L1 of an inductive fuel injection valve. The Steue for ^¬ tion of the valve-Be-powered current circuit part used (Tl, T2, Dl, D2) is already explained in the description of FIG. 1

As described there, the one terminal of the coil Ll, for example, the opening coil of the valve by means of Ers ^¬ th switching transistor Tl to the positive terminal V + of the supply voltage source V and the other terminal connected by means of the two ^¬ th switching transistor T2 with reference potential GND. The source terminal of the first switching transistor Tl is connected to one terminal of the coil L1 - its drain terminal to the positive terminal V +. The source terminal of the second switching transistor T2 is connected to reference potential GND, its drain terminal to the other terminal of the coil Ll.

The free-wheeling diode Dl is arranged to conduct current from reference potential GND for a terminal of the coil Ll and disposed toward the recuperated energy peration diode D2 conducting current le from the other terminal of the Spu ^¬ Ll to the positive pole V + of the supply voltage source.

In addition, the circuit is extended by five transistors T3 to T7, five resistors Rl to R5, a capacitor Cl and a Di ^¬ ode D3 and to the inclusion of existing in the vehicle on-board voltage source Vbat. The third transistor T3 is connected in parallel with the free-wheeling diode D1: its source terminal is connected to reference potential GND, its drain terminal to the connection point of freewheeling diode D1 and the one terminal of the coil L1. It serves to connect in the current-conducting state connected to the first switching transistor Tl terminal of the coil Ll with reference potential GND.

The transistors T4 to T6 together with the resistors R2 to R4 form a complementary Darlington current mirror, which supplies a negative current. This current mirror T4-T6 is connected via a first resistor Rl to the positive pole V + of the supply voltage V. The source terminal of the fourth transistor T4 is connected to the other terminal of the coil Ie L1, while the source terminal of the sixth transistor T6 is connected via the series circuit of the seventh transistor T7 and the fifth resistor R5 with Bezugspotenti ^¬ al GND. The gate terminals of the third Tran ^¬ sistor T3 and the seventh transistor T7 are connected to each other and to the output of a control device, which is shown in Figure 6 or 7, for generating a control signal negative current control NSC for the negative current.

Between the connected to the current mirror T4-T6 terminal of the first resistor Rl and reference potential GND, a capacitor Cl is connected, which is charged by the Bordspannungsquel ^¬ le Vbat via a protective diode D3 and the current mirror T4-T6 supplied with energy, which by Current source switched seventh transistor T7 is controlled.

As long as the control signal NSC at the gate terminal of the third transistor T3 has low level (OV), this transistor T3 and also the seventh transistor T7 is non-conducting, so that at the output of the current mirror, through the source terminal of the fourth transistor T4 is formed, too no electricity flows. The circuit is inactive, no current flows through the coil Ll in the negative direction (in the direction from transistor T4 to transistor T3).

The control signal NSC to high level jumps (for example, + 5V), the third transistor T3 is turned on and connects the one terminal of the coil Ll with Bezugspotenti ^¬ al GND. At the same time begins to flow through the seventh transistor T7, a current whose size by the value of the fifth resistor R5 and the base voltage (+ 5V) of the seventh

Transistor T7 minus its base-emitter voltage (5V-0.7V ~ 4.3V) is determined.

Furthermore, this current also flows through the sixth transistor T6 and the third resistor R3, at which it generates a voltage drop. According to the principle of a current mirror with emitter resistors (to negative current Kopp ^¬ lung) of the fifth transistor T5 and the second resistor R2 will develop the same voltage drop between the base terminal. If one now chooses the value of resistor R2 much lower than the value of R3, a correspondingly higher current through R3 is required for this:

The fifth transistor T5 forms, together with the fourth transistor T4, a complementary Darlington transistor. Accordingly, the principal portion of the current flowing through the two ^¬ th resistor R2, the current I _R2 flowing through the fourth transistor T4.

For static control of the fourth transistor T4, which is designed as a MOS-Fet, no current flow is ^{erforder ¬} Lich, but it must be set to the drain current and the control line corresponding gate-source voltage. If one chooses the value of the fourth resistor R4 such that I _D ( _T4 ) ⁼ I _R2 (drain current through T4 = current through the second resistor R2) the condition is:

with U _G s ₍ τ ₄₎ = gate-source voltage of the fourth transistor T4 and I _R3 = current through the third resistor R3, then flow through the two transistors T5 and T6 approximately equal currents. This improves the accuracy of Stromüberset- Zungsverhältnisses I _R2 / I _R3 at the current mirror so far that even large translations of, for example,> 1000: l can be represented stable and re ^{¬ producible} . In the example shown, with a control current of, for example, 2 mA through transistor T7, an output current of 2A is controlled by transistor T4. The supply of the current mirror takes place from the capacitor Cl.

At the beginning of a process undertaken by the signal NSC negative current pulse capacitor Cl is connected by means of the first resistance is used Rl to the potential of the supply voltage V + (at ^¬ game as + 48V) charged. As a negative current here is a current through the opening or closing coil defined in the direction of the actuating current opposite direction.

The value of R1 is selected to be so high that its current flow is substantially lower than the negative current flowing through the second resistor R2 and the fourth transistor T4. However, the value of R1 must be small enough to allow the capacitor C1 to be charged to the potential V + in the pauses between two consecutive negative current pulses.

By the (negative) current flowing through the second resistor R2 and the fourth transistor T4 through the coil L1 and the third transistor T3, capacitor C1 is now discharged and its voltage becomes lower than the on-board voltage Vbat. As a result, the protection diode D3 becomes conductive and capacitor Cl clamped on board voltage Vbat. This ensures that at the beginning of a negative current pulse enables high versor ^¬ supply voltage V + a rapid current build-up in the coil Ll and the further course is low enough to bring into being by no ne unnecessary power dissipation in the fourth transistor T4.

FIG. 5a shows the voltage and current ^profile at the current mirror T4-T6, wherein the upper track shows the voltage U _C i at the capacitor C1. With increasing negative current pulse I _L1 , the voltage U _C i decreases until it is clamped at about 11.3V. After completion of the negative current pulse, the voltage U _C i rises again to V +. The lower trace shows the negative current pulse I _L1 . The setpoint of 2A is already reached after 38μs.

In bistable valves, it has been shown that the duration of the negative current pulse is set to the time period should ^¬ to which surfaces of the current in the other coil for achievement requires its operating value. As a result, the control signal NSC can be obtained in a simple manner. Suffice it a flip-flop which is set at the start of valve activation and is the first achievement of the operating current turn Retired ^¬ can be.

Figure 6 shows a circuit of such a control device with a bistable valve for the negative current through the one coil, for example the opening coil Ll, by the closing signal of the other coil, for example the closing coil.

This circuit consists only of a flip-flop IClA. With the rising edge, for example, the closing signal ES for the closing coil, not shown, the flip-flop IClA (terminal CLK) is set so that its output Q, to wel ^¬ chem the signal NSC appears, high level assumes. The output of the PWM unit PWM (see FIGS. 2 and 4) connected to the terminal CLR-not of the flip-flop IClA receives high level at this time. Reaches the current through the closing coil its operating value, this output switches to low level and thus also clears the flip-flop ICLA, so that the output signal of NSC at the output Q to the low level reset jumps to ^¬. Thus, the base terminal of the Transisto ^¬ ren T3 and T7 of the circuit for the opening coil Ll ^¬ signal supplied NSC has high level as long as the current through the closing coil until the first achievement of its operating value.

For a bistable valve, a circuit according to FIG. 4 and FIG. 6 is required for generating the negative current for both the opening and closing coils. It should be noted that the opening of the valve associated with the PWM unit controls the negative current pulse in the coil of the closing Ven ^¬ TILs and associated with the closure of the valve PWM unit controls the negative current pulse in the coil of the valve opening. The time profile of operating current and ne ^¬ negative flow for opening and closing a bistable valve is shown schematically in Figure 5b.

For a standard valve with opening coil and closing spring, the control of the negative current of the single coil Ll at the end of the opening signal EO, as shown in Figure 7 Darge ^¬ , take place.

In the control unit according to Figure 7, the negative current is used to delete the eddy currents that continue to flow after power-off and decay in the opening coil still in Mag ^¬ netkreis of the standard valve. For this purpose, a negative current to be passed through the opening coil Ll UNMIT ^¬ telbar falling after the completion of valve activation (edge of the operating (opening) signal EO.

The circuit according to FIG. 7 contains a timer (monoflop IC2) for determining the duration of the negative current pulses through the coil Ll, which is triggered by the inverted by an inverter IC4 falling edge of the signal EO.

For a standard valve only one circuit according to Figure 4 and Figure 7 is required.

In a further advantageous embodiment of the circuit according to FIG. 4, diode D1 can be dispensed with, the substrate diode of transistor T3 assuming its function, the freewheel.

The advantages of the circuit according to the invention according to FIG. 4 are the following:

- It results in a time-varying supply voltage, whereby the power loss in the power source can be kept low;

- The supply of the Darlington current mirror is made of a capacitor, which is first charged to the potential of the supply voltage V + to achieve a rapid increase in current in the coil inductance.

For bistable valves with two actuating windings, the negative current is controlled by a signal from the drive electronics, which controls the current flow in the respective opposite coil.

For standard valves with a closing spring, the negative current is controlled by the falling edge of the actuation (opening) signal.

In the course of the negative current, a Klem ^¬ tion of the capacitor voltage to the on-board voltage Vbat.

In a further advantageous embodiment, the energy required for demagnetization can also be acted upon accelerated. This is useful when a mög ^¬ lichst faster onset of valve movement is required. There- to the negative current is not set with a predetermined, largely constant value for a certain period of time, as shown in FIG 5a, but as an approximately triangular current pulse with a predetermined maximum value (Figure 9b).

The rate of current rise is doing right by the inductance of the coil and the supply voltage V be ^¬. Also, the peak value of the current is higher than in the first embodiment because the demagnetizing energy is provided in a shorter time.

In FIG. 9, the valve switching times without (FIG. 9a) and with the demagnetizing current (FIG. 9b) are compared with one another. There each show: - the upper track: the demagnetizing current,

- the middle lane: the valve movement, and

- the lower track: the control signal (falling edge).

A circuit diagram for such a circuit arrangement is shown in FIG. The circuit corresponds essentially to the embodiment of Figure 4, but eliminates resistor Rl, capacitor Cl, diode D3 and the connection to the on-board voltage source Vbat. Also, the resistors R2 and R3 are connected directly to the positive pole V + of the supply voltage, and between the source terminal of transistor T3 and the ground terminal GND, a resistor R7 is inserted.

Furthermore, the current source T4-T6 is now designed by selecting the value ratio of the resistors R2 and R3 for a much higher constant current - for example 8A.

The associated one of the opening coil transistor T3 conducting tet geschal ^¬, simultaneously by means of transistor T7, the current source T4 to T6 - upon activation of the signal-to-current Negative Control NSC by the closing signal is - as described in FIG. 4 According to the inductance of the coil Ll (opening coil), the current through them will now increase in time (Figure 9b, upper track). This current is observable at the resistor R7 as the voltage negative current sense NSS. If this voltage NSS has reached a predetermined value, then the negative current control NSC signal is controlled to OV and the current flow is thus ended.

The valve switching time determined in a measured exemplary embodiment of the circuit according to FIG. 10 is shortened, for example, from 620 μs (without degaussing current, FIG. 9a) to 504 μs (with degaussing current, FIG. 9b). The current source T4-6 also has a protective function, since in case of a short circuit of the right terminal of the coil Ll to reference potential of the current from T6 is limited.

The valve coils are located in the injector, not shown on the engine block of the internal combustion engine out ^¬ half of the electronic control unit, and a short circuit of the leads to vehicle ground is a common mistake. However, this must not lead to damage to the electronics.

The evaluation of the voltage negative sense current NSS and the control of the signal negative current control NSC is carried out with a suitable control unit, which is described in Figure 11.

The Steue ^¬ executed for a bistable injection valve approximation unit of Figure 11 includes a monostable multivibrator IC2, a flip-flop ICLA, a comparator Compl and an AND gate having three inputs IC3A. The closing signal ES is connected to the trigger ^¬ input CK of the monostable multivibrator IC2, with an input of the AND gate IC3A and to the reset input CLR of flip-flop non ICLA.

The tapped at the resistor R7 in Figure 10 signal NSS (Ne ^¬ negative current sense) is connected to the non-inverting input the comparator Compl whose inverting input a reference voltage Vref is supplied. The output of the comparator Compl is connected to the trigger input CLK of the flip-flop IClA.

The output Q of the monoflop IC2 is connected to a second input of the AND gate whose third input is connected to the inverting Q-not output of the flip-flop IClA.

The signal NSC (negative current control) appears at the output of the AND gate IC3A, and a signal NSD (negative current diagnosis) appears at the noninverting output Q of the flip-flop IClA.

The control signal, already described in Figure 6, the closing signal as Example ^¬ It controls also the switching on of the negative current to the opening coil Ll. The negative current is switched off on reaching a vorgege- but now surrounded current value, but has to be the smaller than the target ^¬ value of the current of the current source T4-6.

The signal curves of the control unit shown in FIG. 11 can be taken from FIG. At the beginning, the closing signal ES has low levels. This level is also applied to the reset input CLR-not of the flip-flop IClA, so that at its non-inverting output Q a negative-current diagnostic signal NSD is present with a low level. Accordingly, the vertierende in ^¬ output Q-Not of the flip-flop Icla high level.

The rising edge of the control signal ES clocks the monoflop IC2 whose output Q now assumes high levels for the duration of the monoflop time. The AND gate IC3A combines the signals ES, Q of IC2 and Q-not of IClA. Since all these signals now have high levels, the signal NSC at the output of AND gate IC3A decreases with the rising edge of the control signal. nals ES also high-level. The negative current starts to increase.

As a result, the transistors T3 and T4 (FIGS. 9b and 10) become conducting, so that a current through the coil L1 (FIG. 10) begins to flow. This current also flows through resistor R7, wherein a corresponding voltage drop, signal Nega ^¬ tive-current sense NSS arises. Comparator Compl now compares this voltage NSS with the reference voltage Vref.

If NSS <Vref, the output of the comparator Compl has low level. If the value of NSS exceeds that of Vref, the output of the comparator Compl jumps to high level and sets the downstream flip-flop IClA. Its inverting output Q-Not jumps to low level and switches via the AND gate IC3A, the signal NSC to low level, whereby the negative current in the opening coil Ll is turned off. Similarly, the signal NSD jumps to non-inverting output Q to high level.

By observing the time when or if this voltage jump occurs, a possible malfunction can be detected. Likewise, the nature of the error can be detected. Be ^¬ is a short circuit to reference potential with one of the lines to ^¬ the coil, no current will flow through resistor R7 and the signal NSD remains at low level. This also applies to a line break.

It is therefore sufficient to query the signal NSD immediately before switching on the opening signal EO or closing signal ES.

The time constant of the monostable IC2 is selected so that the desired value of the negative current is reliably achieved, but a thermal overload of the power transistor T4 of the current source in the event of a short circuit to the reference potential is avoided. If the signal NSS (negative current sense) has not exceeded the value of Vref until the time constant has elapsed, then the downstream flip-flop IClA is not triggered. The Sig nal ^¬ NSD the non-inverting output Q remains at a low level. The output Q of the monostable multivibrator IC2 goes back to the low level and disables the AND gate IC3A, so that its output signal ^¬ NSC to the low level goes.

In the case of a bistable valve, a circuit according to FIG. 10 and FIG. 11 is required once again for the opening coil and for the closing coil.

For a standard valve with a closing spring, whose control ^¬ unit is shown in Figurl3, the control unit of Figure 11 is supplemented to the effect that the opening signal EO, be ^¬ before it the monoflop IC2, the AND gate IC3A and the flip-flop IClA is fed, is inverted by means of an inverter IC4, so that the monoflop IC2 is triggered only by the falling Flan ^¬ ke of the signal EO.

As shown in Figure 8 for a circuit arrangement according to Figure 4, in a further advantageous embodiment of the invention, the circuit arrangement of Figure 4 or Figure 10 for actuating a plurality of valves, ie, all (for example, four or six) fuel injectors a Internal combustion engine can be extended without having to increase the number of circuits proportionally. This is achieved by adding additional diodes D7 to DLO in series with the drain terminal of the third transistor T3, of additional diodes D4a to D6a and D4b to D6b in series with the source terminal of the transistor T4, and / or a white ^¬ teren transistor T3b, and another current mirror T4b- T7b, R2b-R5b.

However, to an additional, not shown Se ^¬ lesson circuit is required, each of the desired Current path selected by suitable control of T3, T3b, T7, T7b se ^¬ .

Major obstacle when closing, as already stated, abate the eddy currents in the magnetic material of the valve that switch to ^¬ From the operating current slow and prevent rapid closing of the valve. As a rule, steel with a low electrical conductance is used.

In order to further reduce the closing delay in standard solenoid valves, use is made of the different decay times of eddy currents in magnetic materials having different electrical conductivities, in addition to the use of a negative current pulse.

Figure 14 shows a schematic representation of a standard solenoid injector with coil S4 and closing spring S3. The coil S4 is surrounded by the iron yoke S5. The valve needle S7 and its associated armature S6 is pressed by the closing spring S3 against a valve seat, not shown, and thus blocks the valve opening ^¬ not shown. When the coil S4 is energized, the armature S6 is attracted against the force of the closing spring S3 and thus the valve is opened.

To the eddy currents possible liehst in the armature, according to the invention for the armature S6 voted against the rule described above, a material with the highest possible elekt ^¬ rischem conductance to let subside slowly. However, the iron yoke S5 still consists of material with a low electrical conductance.

This makes it possible to achieve when the valve closes with applying a negative current pulse to the coil S4 in the back iron ^¬ circuit S5 temporary field reversal, currency rend the original excitation field in anchor S6 has not quite died down.

This results in the gap between iron yoke and armature temporarily a repulsive force between Ei ^¬ senrückschluss S5 and armature S6, which significantly accelerates the beginning of the closing movement and the closing operation of the valve.

In FIG. 14, the solid field lines 14a (left) with the valve open and the dashed field lines 14b (right) in the closing process during the temporarily occurring field reversal are shown.

FIG. 15 shows, in principle, the formation of transient, opposite field directions between iron yoke S5 and armature S6.

The lower diagram shows the time course of the applied to the coil negative current pulse during the closing of the injector.

The upper diagram shows the field strengths or holding forces resulting from eddy currents. The respective value of the eddy current is associated with a magnetic field strength and thus a holding force.

The upper curve 15 shows the course of the armature S6 - wel ^¬ cher consists of material having the highest possible electrical conductance - effective field strength, while the lower curve 15b the course of the iron yoke S5 - of material of low electrical conductivity - is effective field strength.

In addition, the line 15c is still shown, which represents the holding force of the closing spring S3. At the moment in which the field strength influenced by the negative current pulse - curve 15b - becomes negative and thus reverses its direction, the repulsive force between iron yoke S5 and armature S6 begins to act. At the point indicated by a double arrow, this force is greatest.

Thus, the combination of negative current pulse at the end of the excitation current and proper choice of the magnetic material shafts results in a substantial reduction of the turn-off delay for standard solenoid valves.

Claims

claims

1. A device for switching inductive fuel injection valves, wherein in a bistable fuel injection valve (with opening and closing coil) caused by remanence magnetic holding forces which hold the valve needle (1) in the closed position, for accelerated opening of the valve gativen current are eliminated by a generated in the closing coil ne ^¬, and that the Ventilna ^¬ del be (1) firmly in the open position is eliminated to accelerate closing of the valve by a generated in the opening coil negative current; and wherein in a standard fuel injection valve (with Öff ^¬ voltage coil and closing spring), the eddy currents in Magnetma ^¬ material of the opening coil (Ll), which arise after switching off the Be ^¬ tätigungssignals (EO) and decay only slowly, by one in the opening coil generated negative current to be eliminated, wherein as a negative current, a current through the opening or closing coil in the direction of the actuating current entge ^¬ gengesetzter direction is defined, with a circuit arrangement which one of a switching signal (enable-open EO, Enable-Close ES) via a pulse width modulation unit (PWM) controlled coil (Ll) of a fuel injection valve whose one terminal by means of a first switching transistor (Tl) to the positive pole (V +) of a supply Spannungsquel- Ie (V) and their another connection by means of a second

Switching transistor (T2) is connected to reference potential (GND), wherein the source terminal of the first switching transistor (Tl) to the one terminal of the coil (Ll), its drain terminal connected to the positive pole (V +) of the supply voltage source (V), and its gate terminal is connected to the output of the PWM unit (PWM), wherein the source terminal of the second switching transistor (T2) is connected to reference potential (GND) and its drain terminal to the other terminal of the coil (Ll), wherein a freewheeling diode (D1) of reference potential (GND) current conducting to a terminal of the coil (Ll ) assigns toward be ^¬ and a recuperation diode (D2) from the other at ^¬ circuit of the coil (Ll) conducting current to the positive pole (V +) of the supply voltage source (V) through is arranged,

characterized ,

that the third, the freewheeling diode in parallel (Dl) peeled ^¬ ter transistor (T3) is provided one, its source terminal to reference potential (GND) and its drain terminal connected to the junction of Freilaufdio ^¬ de (Dl) and the a terminal of the coil (Ll) is connected to that a complementary Darlington current mirror (transistors T4 to T6, resistors R2 to R4) is provided, which via a first resistor (Rl) to the positive pole (V +) of the supply voltage source (V ), wherein the source terminal of the fourth transistor (T4) is connected to the other terminal of the coil (Ll), and the source terminal of the sixth transistor (T6) via the series connection of a seventh transistor (T7) and a fifth Resistor (R5) is connected to reference potential (GND), that the gate terminals of the third transistor (T3) and the seventh transistor (T7) are connected to each other, a control signal Negative current control (NSC) supply ^¬ bar is that parallel to the series circuit of the sixth transistor (T6), seventh transistor (T7) and fifth resistor (R5), a capacitor (Cl) is connected, and that in parallel to the capacitor (Cl) is a series circuit of a one hand Associated reference potential (GND) On-board voltage source (Vbat) and one to the capacitor (Ci; out directionally protective diode is arranged.

2. Apparatus according to claim 1, characterized in that in a bistable fuel injection valve for the He ^¬ generation of the control signal negative-current control (NSC), a control device is provided which has a flip-flop (IClA), which from the opening - or closing signal (EO, ES) of the opening or closing coil set and from

Close reset signal of this coil associated PWM unit (PWM) is reset, wherein between the setting and resetting of the flip-flop (IClA) at the non-inverting output (Q) the signal Negative current control (NSC) appears, which Circuit arrangement of the other coil is supplied.

3. Device according to claim 1 or 2, characterized marked, that for controlling a bistable fuel injection valve both for the opening coil (Ll) and for the closing coil depending on a circuit arrangement according to claim 1 and depending on a control device according to claim 2 is provided.

4. The device according to claim 1, characterized in that in a standard fuel injection valve for the generation of a control signal ^¬ negative current control (NSC), a control device is provided which comprises a series connection of an inverter (IC4) and a monoflop (IC2) has ^¬, wherein the inverted by the inverter (IC4) opening ^¬ or closing signal (EO, ES) sets the monoflop (IC2) on the ^¬ sen non-inverting output (Q) during the standing time of the monoflop (IC2), the Signal Negative Current Control (NSC) appears, which is fed to the circuitry of the other coil.

5. Apparatus according to claim 1 or 4, characterized in that for the control of a standard fuel injection valve depending on a circuit arrangement according to claim 1 and a control device according to claim 4 is provided.

6. An apparatus for switching inductive fuel injection valves, wherein in a bistable fuel injection valve (with opening and closing coil) caused by remanence magnetic holding forces which hold the valve needle (1) in the closed position, for accelerated opening of the valve by a ne ^¬ negative flow generated in the closing coil are eliminated, and which hold the Ventilna- del (1) in the open position, are eliminated for accelerated closing of the valve by a negative current generated in the opening coil; and wherein in a standard fuel injection valve (with Öff ^¬ tion coil and closing spring), the eddy currents in Magnetma- material of the opening coil (Ll), which arise after switching off the Be ^¬ tätigungssignals (EO) and decay only slowly, by one in the opening coil generated negative current are defined, wherein as a negative current, a current through the opening or closing coil in the direction of the operating current entge ^¬ gengesetzter direction is defined, with a circuit arrangement which one of a switching signal (enable-open EO, enable-close ES) via a pulse width modulation unit (PWM) controlled coil (Ll) of a fuel injection valve, whose one terminal by means of a first switching transistor (Tl) to the positive pole (V +) a supply Spannungsquel- Ie (V) and the other terminal is connected by a second switching transistor (T2) to reference potential (GND), wherein the source terminal of the first switched ransistors (T1) with one terminal of the coil (L1), its drain Terminated with the positive pole (V +) of the supply voltage source (V), and its gate terminal connected to the output of the PWM unit (PWM), wherein the source terminal of the second switching transistor (T2) with reference potential (GND ) and its drain connection to the other terminal of the coil (Ll) is connected, wherein a freewheeling diode (Dl) of reference potential (GND) current conducting to a connection of the coil (Ll) is arranged ^{¬ way} and a Rekuperationsdiode (D2) from the other The end of the coil (L1) is arranged in an electrically conductive manner to the positive pole (V +) of the supply voltage source (V),

characterized ,

that is a third is provided in parallel with the freewheeling diode (Dl) peeled ^¬ ter transistor (T3) whose source is connecting via a seventh resistor (R7) with reference ^¬ potential (GND), and its drain terminal connected to the junction of Freewheeling diode (Dl) and the one terminal of the coil (Ll) is connected to a complementary Darlington current mirror (transistors

T4 to T6, resistors R2 to R4) is provided, wherein the source terminal of the fourth transistor (T4) is connected to the other terminal of the coil (Ll), the source terminal of the sixth transistor (T6) via the series connection of a seventh Transistors (T7) and a fifth resistor (R5) to reference potential (GND) ver ^¬ is connected, and the drain terminals of the fourth and sixth transistors (T4, T6) via a respective resistor (R2, R3) to the positive pole (V + ) of the supply voltage source (V) are connected such that the gate terminals of the third transistor (T3) and the seventh transistor (T7) are connected to each other, which the control signal negative current control (NSC) is supply ^¬ bar , and in that a signal negative current sense (NSS) can be picked up at the seventh resistor (R7).

7. The device according to claim 6, characterized in that in a bistable fuel injection valve for the generation of the control signal negative current control (NSC) a control device is provided which contains a comparator (Compl) whose noninverting input the signal-Negative current sense (NSS), and of which a reference voltage (Vref) can be fed in ^¬ vertierendem input that a flip-flop (ICLA) is provided whose set input

(CLK) is connected to the output of the comparator (Compl), at whose non-inverting output (Q) a signal

Negative current diagnosis (NSD) can be tapped that a monoflop (IC2) and a three-input AND gate (IC3A) are provided, wherein one input of the AND gate (IC3A), the trigger input (Ck) of the monoflop ( IC2) and the reset input of the

Flip-flop (IClA) closing signal (ES) or the opening ^¬ signal (EO) can be supplied, a second input of the AND gate (IC3A) with the inverting output (Q-not) of the flip-flop (IClA) and a third Input of the AND gate (IC3A) to the output (Q) of the monoflop (IC2) are connected, and at the output of the AND gate (IC3A), the signal negative current control (NSC) can be tapped.

8. Apparatus according to claim 6, characterized in that in a standard fuel injection valve for the generation of the control signal negative-current control (NSC), a control device according to claim 12 is provided, wherein additionally an inverter (IC4) is provided in in which the closing signal (ES) is inverted before it is applied to one input of the AND gate (IC3A), the trigger input (Ck) of the monoflop (IC2) and the reset input of the flip-flop (IClA) is supplied.

9. Apparatus according to claim 7 or 8, characterized in that

- The Negative Current Diagnosis (NSD) signal of the opening coil

(Ll) before switching on the opening signal (EO) or

- the Negative Current Diagnosis (NSD) signal of the closing coil before switching on the closing signal (ES)

Low level, when the current flowing through the opening or closing coil negative current

- does not reach its intended give ^¬ NEN value before the monoflop-life, or - for one of the leads to the coils, a short circuit to reference potential (GND) or a line interruption occurs.

10. Device according to one of claims 1 or 4 to 8, characterized in that in a standard fuel injection valve, the iron yoke (S5) of the coil (S4) and the armature (S6) are made of materials having different electrical conductivities.

11. Apparatus according to claim 10, characterized in that the armature (S6) consists of material having the highest possible electrical conductance ^¬ schem and the magnetic yoke (S5) consists of material having low electrical conductivity is.