DE19912966A1 - Actuator for vol. control valve for direct injection IC engine, with valve controlling pressure build-up is pressure storage - Google Patents

Abstract

The vol. control valve is earthed via a switch and a valve terminal is connectable to an energy storage, such as a booster capacitor or a capacitor of a DC/DC converter. On the switch opening, the released energy in the energy storage is recharged. The vol. control valve is connectable to supply voltage via a second switch, while a third switch provides the connection of the vol. control valve to the booster capacitor. The DC/DC converter and/or the booster capacitor may be used for voltage supply of further consumer appliances.

Description

State of the art

The invention relates to a device for controlling a Volume control valve, especially with a direct injecting internal combustion engine.

Such a volume control valve is from DE 198 34 120 known. There, a volume control valve is described that controls the pressure build-up in a pressure accumulator. Such Volume control valves are used in particular direct-injection internal combustion engines used.

Object of the invention

The invention has for its object in a Device for controlling a quantity control valve actuate the volume control valve as precisely as possible enable.  

Advantages of the invention

With the procedure according to the invention, an exact Control of the volume control valve and thus an exact Control of the pressure build-up in a pressure accumulator enables become.

It is particularly advantageous that a switching means Quantity control valve connects to ground that a connection of the Quantity control valve can be connected to an energy store and that when the switching means is released Energy is transferred to the energy storage.

It is advantageous that the energy storage device is concerned a booster capacitor or a capacitor DC / DC converter.

Because the volume control valve has a third Switching means can be connected to the booster capacitor a rapid increase in electricity and therefore a quick one Actuation of the volume control valve can be achieved.

It is particularly advantageous that the DC / DC converter and / or the booster capacitor for the power supply of others Is used by consumers. This can be significant Costs can be saved.

drawing

The invention is described below with reference to the drawing illustrated embodiments explained. Show it

Fig. 1 is a block diagram of the essential elements of the device according to the invention and

Fig. 2 shows more detailed embodiments of the circuit arrangement according to the invention.

Description of the embodiments

The procedure according to the invention is preferred for direct-injection internal combustion engines are used.

The most important elements of the device are shown in Fig. 1. 100 denotes injectors, via which the fuel is metered to the individual combustion chambers of the internal combustion engine. In Fig. 1, only three injectors are shown as an example.

The injectors are supplied with fuel by a pressure accumulator 200 . The pressure accumulator 200 , which is also referred to as a rail, is connected to a high-pressure pump 220 via a line 210 . The high-pressure pump 220 is connected via a line 240 to a low-pressure pump 250 , which is also referred to as an electric fuel pump. The electric fuel pump 250 is preferably arranged in a fuel reservoir 255 , which is also referred to as a tank. A pressure sensor 205 is arranged on the pressure accumulator 200 .

A quantity control valve 230 is arranged on the high-pressure fuel pump or in the region of the line 240 between the high-pressure fuel pump 220 and the electric fuel pump 250 .

The quantity control valve 230 , the injectors 100 and against the pressure control valve 205 are supplied with voltage by an output stage 160 . The output stage 160 is preferably integrated in a controller 260 , which processes the output signals of various sensors 270 .

This facility now works as follows. The electric fuel pump 250 pumps the fuel that is in the tank 255 via the line 240 to the high-pressure pump 220 . This compresses the fuel and delivers it via line 210 into the pressure accumulator 200 . By driving the injectors 100 , the start and end of the injection of fuel into a particular cylinder can be controlled. This control takes place as a function of the operating parameters recorded with the sensors 270 .

The fuel pressure P prevailing in the pressure accumulator 200 is detected by means of the pressure sensor 205 and is preferably evaluated in the control 260 in the sense of a pressure regulation. Depending on the comparison of the measured pressure value P with a target value, a control signal is generated to act on a pressure actuator.

In the exemplary embodiment shown, the quantity control valve 230 is used as the pressure regulator. The quantity of fuel valve delivered by the high-pressure pump can be controlled by means of the quantity control valve 230 and thus the pressure build-up in the pressure accumulator can be controlled. For this purpose, it is necessary for the quantity control valve 230 to be actuated at a specific first time and for the actuation to be withdrawn at a second time. In order to achieve precise pressure control, it is necessary for the quantity control valve 230 to open and / or close at the precisely pre-calculated time. In particular, the delay time between the activation and the actual reaction, ie the opening and / or closing of the quantity control valve, should be as short as possible.

In the case of pressure control according to need, the high-pressure pump 220 delivers only the fuel mass which is necessary for maintaining the pressure in the pressure accumulator 200 . It is necessary for the quantity control valve to be closed or opened for a specific piston position of the high-pressure pump, and for this to compress the necessary fuel mass which is necessary for maintaining the pressure or building up pressure. Exact switching times of the volume control valve 230 are the prerequisite for precise pressure control.

The output stage 160 is shown in more detail in FIG. 2. The embodiment shown is a three-cylinder internal combustion engine. Each consumer is assigned an injector and each injector a cylinder of the internal combustion engine. If the number of cylinders in the internal combustion engine is higher, more injectors, switching means and diodes are to be provided.

With 100 , 101 and 102 three consumers of the injectors and 230 are the volume control valve. In each case one connection of the consumers 100 , 101 , 102 and 230 are connected to a voltage supply 105 via a switching means 115 , a diode 110 and a measuring means 125 .

The diode 110 is arranged so that its anode is connected to the switching means 115 and its cathode is connected to the consumers ( 100 to 103 ). The switching means 115 is preferably a field effect transistor.

In each case the second connection of the consumers 100 , 101 , 102 and 230 is connected to a resistance means 125 via a respective second switching means 120 , 121 , 122 and 123 . The switching means 120 to 123 are also preferably field effect transistors. The switching means 120 to 123 are referred to as low-side switches and the switching means 115 as high-side switches. The second connection of the resistance means 125 is connected to the second connection of the voltage supply.

A diode 130 , 131 , 132 and 133 is assigned to each consumer 100 , 101 , 102 and 230 . The anode connection of the diodes is in contact with the connection point between the consumer and the low-side switch. The cathode connection is connected to a capacitor 145 and a further switching means 140 . The second connection of the switching means 140 is in contact with the first connections of the consumers 100 to 103 via a diode 142 . Switching means 140 is also preferably a field effect transistor. This switching means 140 is also referred to as a booster switch. The second connection of the capacitor 145 is also connected to the second connection of the supply voltage 105 .

The high-side switch 115 is acted upon by the control unit 160 with a control signal AH. The switching means 120 is acted upon by the control unit 260 with a control signal AL1, the switching means 121 with a control signal AL2, the switching means 122 with a control signal AL3, the switching means 123 with a control signal AL4 and the switching means 140 with a control signal AC.

A diode 150 is connected between the second connection of the voltage supply 105 and the connection point between the diode 110 and the first connections of the consumers 100 , 101 , 102 and 230 . Here, the anode of the diode is connected to the second connection of the voltage supply 105 .

The current flowing through the consumer can be determined by means of the resistor 125 .

With the arrangement shown, a current measurement via the current measuring resistor 125 is only possible if one of the switching means 120 to 123 and one of the high-side switches ( 115 , 140 ) is closed. In order to be able to detect the current even when the low-side switches are open, the current measuring resistor can also be arranged elsewhere. For example, the second connection of the capacitor 145 can be connected to the connection point between the current measuring means 125 and the switching means 120 to 123 . In this case, current measurement is also possible with the low-side switch locked. Furthermore, the current measuring means can be arranged between the voltage supply and the high-side switch or in the first or second connection of the consumers.

Instead of the resistor 125 or in addition to the resistor 125 , a further resistor 126 can be arranged between the first connection of the voltage supply 105 and the high-side switch 115 . A current measurement can also be carried out with this resistor 126 .

The connection point between the switching means 140 and the capacitor 145 is in contact with the cathode of a further diode 180 . The anode of the diode 180 is connected to the connection point between an inductance 170 and a further switching means 175 . The switching means 175 is also referred to as a charging switch. A second connection of the further switching means is connected to the second connection of the capacitor 145 or to the second connection of the supply voltage 105 . Inductance 170 is also connected to the first connection of the supply voltage.

The inductor 170 , the charge switch 175 , the diode 180 and the capacitor 145 form a voltage converter.

Instead of these elements, another configuration of a voltage converter, in particular a DC / DC direct voltage converter, can also be used. The control unit 160 likewise applies a control signal AS to the charging switch.

Different phases are distinguished in each metering cycle. The power stage is switched off before the consumer is activated. The control signals AC, AH and AL are at low potential. No electricity flows through the consumers. The capacitor 145 is charged to its maximum voltage UC, which is preferably higher than the supply voltage Ubat. This assumes a value of approx. 80 volts, for example, whereas the voltage of the power supply assumes a value of approx. 12 V.

In a first phase at the beginning of the activation, the low-side switch is activated, which is assigned to the consumer who is to meter the fuel. The booster switch 140 is in its conductive state. The position of the high-side switch is irrelevant. As a rule, the high-side switch 115 is not activated, it blocks in the first phase.

This actuation of the switching means causes a current to flow from the capacitor 145 via the booster switch 140 , the corresponding consumer, the low-side switch assigned to the consumer and the current measuring means 125 . In this phase, the current I rises very quickly due to the high voltage at the consumer.

In a second phase, the inrush current is taken over by the high-side switch 115 and the booster is deactivated. In the third phase, the drive signal is canceled for the booster switch 140 such that the switch blocks 140th The control signals AH and AL for the high-side switch 115 and the low-side switch assigned to the consumer are set to a high level so that these switches release the current flow. A current thus flows from the voltage supply 105 via the high-side switch 115 , the diode 110 , the consumer, the corresponding low-side switch, the current measuring resistor 125 back to the voltage source 105 . By contacting the high-side switch, the current, which is detected by means of the current measuring resistor 125 , can be regulated to a predeterminable value for the starting current IA. This means that when the target current IA for the starting current is reached, the high-side switch 115 is activated in such a way that it blocks. If a further threshold is undershot, it is released again.

When the high-side switch 115 is blocked, a freewheeling circuit acts. The current flows from the consumer through the low-side switch, the resistor 125 and the free-wheeling diode 150 .

A third phase follows the second phase and is also referred to as holding current control. As in the second phase, the low-side switch assigned to the consumer remains closed. By opening and closing the high-side switch 115 , the current flowing through the consumer is adjusted to the setpoint IH for the holding current. When the high-side switch 115 is blocked, a freewheeling circuit acts. The current flows from the consumer through the low-side switch, the resistor 125 and the free-wheeling diode 150 . The phase ends when the injection process is completed. The setpoint IH for the holding current is selected so that it is as small as possible but sufficient to hold the consumer in its position.

In particular, when the consumer is switched off at the time, there is a quick delete. A quick extinction can also take place at the transition between the starting current in phase 3 and the holding current in phase 4. In the case of rapid extinction, the corresponding low-side switch is switched off and the high-side switch 115 remains on. As a result, the current that flows through the consumer quickly drops to zero. At the same time, the voltage U that is present at the capacitor 145 rises. The energy released when switching off is then transferred to the capacitor 145 , 146 .

In another embodiment, the quick delete the high-side switch and the low-side switch are locked.

In a further phase after the control, which is also referred to as the charging phase, the charging switch 175 is brought into its conductive state by the control signal AS. This initiates a current flow in inductor 170 . The current flows from voltage source 105 via switch 175 and inductance 170 into voltage source 105 . After a predetermined time, which is chosen so that sufficient energy is stored in the inductor, the charge switch is activated so that it opens. This in turn causes the inductance 170 to be quickly extinguished via the diode 180 in the capacitor 145 . As a result, the voltage across capacitor 145 rises. This process is repeated until the voltage across capacitor 145 reaches a predetermined value U1. Alternatively, it can also be provided that a predetermined number of actuations takes place or that the charging switch 175 is actuated for a predetermined period of time with a clocked signal with a predetermined frequency and duty cycle.

The DC / DC converter 195 , since it does not use any consumers for recharging, can recharge the capacitor 145 at any time. However, it is preferably provided that it is not charged in the booster phase and the pull-in phase, since otherwise very high current values can occur.

In one embodiment of the invention, it can also be provided that the energy released when switching off is not transferred to the capacitor 145 , which is then only charged via the inductor 170 .

Different embodiments are shown by dashed lines. In a first embodiment, the elements 126 , the switching means 115 and the diode 110 are present. Furthermore there is the quantity control valve 230 via the diode 110 to the switching means 115 in contact. The connection between the quantity control valve 230 and the positive connection of the voltage supply 105 does not exist.

In this embodiment, it is provided that the quantity control valve 230 is controlled accordingly, like the injectors 100 . The control takes place via the high-side switch 115 and the low-side switch 123 assigned to the quantity control valve 230 . This offers the advantage that the same output stage can be used for the control of the injectors and the quantity control valve 230 .

A second embodiment differs from this first embodiment in that the connection between the quantity control valve 230 and the diode 110 is interrupted. The elements 126 , the switching means 115 and the diode 110 are present. The quantity control valve 230 is in direct contact with the positive connection of the supply voltage. In this embodiment, the quantity control valve 230 is only activated by means of the low-side switch 123 .

It is advantageous in these two embodiments that when the low-side switch 123 is opened, the voltage induced in the quantity control valve 230 is transferred to the capacitor 145 via the diode 133 .

In order to minimize the power loss in the control unit and to quickly switch off the quantity control valve, the booster capacitor 145 is extinguished. At the same time, this offers the advantage that the booster capacitor is supplied with energy again by the quenching. On the one hand, this results in fast and precise switching times of the quantity control valve 230 . Furthermore, energy recovery can be achieved by means of the booster capacitor 145 with simultaneous rapid quenching of the magnetic circuit of the quantity control valve. By deleting the quantity control valve in the booster capacitor, which is used to control the injectors, the booster capacitor can also be charged faster or to a higher voltage.

In a third embodiment, instead of the supply voltage 105 , the voltage applied to the capacitor 145 of the DC / DC converter 195 is used to control the injectors and the quantity control valve. In this case, components 126 , 115 and 110 are omitted. The switching means 140 then takes over the function of the high-side switch 115 . In this case, the energy of the quantity control valve 230 released when the switching means 123 is opened is deleted into the capacitor of the DC / DC converter 195 .

It is advantageous here that the recharge circuit of the output stage, which usually charges the capacitor 145 , is relieved by the energy recovery. This recharging circuit is designated 195 in FIG. 2 and comprises inductance 170 , switching means 175 and diode 180 . These elements form a DC / DC converter.

If the energy stored in the quantity control valve is sufficient to charge the capacitor, the inductance 170 and the charging switch 175 and the diode 180 can be omitted in a particularly advantageous embodiment. This means that the quantity control valve 230 and the low-side switch 132 take on the function of the inductance 170 and the charging switch 175 . This results in a considerable saving in costs.

Claims (5)

1. Device for controlling a quantity control valve, in particular in a direct-injection internal combustion engine, the quantity control valve controlling the pressure build-up in a pressure accumulator, characterized in that a switching means connects the quantity control valve to ground, that a connection of the quantity control valve can be connected to an energy store that the at Opening the switching means released energy is transferred to the energy storage. 2. Device according to claim 1, characterized in that the energy storage device is a booster capacitor or is a capacitor of a DC / DC converter. 3. Device according to claim 1 or 2, characterized characterized in that the volume control valve via a second Switching means can be connected to a supply voltage. 4. Device according to one of the preceding claims, characterized characterized in that the volume control valve via a third Switching means can be connected to the booster capacitor. 5. Device according to one of the preceding claims, characterized characterized in that the DC / DC converter and / or the Booster capacitor for supplying power to others Is used by consumers.