EP0429573A1

EP0429573A1 - Circuit for operating electromagnetic users.

Info

Publication number: EP0429573A1
Application number: EP19900906897
Authority: EP
Inventors: Siegbert Schwab; Wolfgang Vogel
Original assignee: Robert Bosch GmbH
Current assignee: Robert Bosch GmbH
Priority date: 1989-06-20
Filing date: 1990-05-16
Publication date: 1991-06-05
Anticipated expiration: 2010-05-16
Also published as: JPH04500399A; BR9006811A; DE59002301D1; WO1990015922A1; EP0429573B1; DE3920064A1

Abstract

Des circuits servent à commander des consommateurs électromagnétiques, notamment des soupapes magnétiques de moteurs à combustion interne. Afin de réduire autant que possible la dissipation de puissance, au moins deux organes commutateurs (4, 5) susceptibles d'être commandés indépendamment l'un de l'autre appliquent des tensions (U1, U2) différentes au consommateur (1).Circuits are used to control electromagnetic consumers, including magnetic valves of internal combustion engines. In order to reduce the power dissipation as much as possible, at least two switching members (4, 5) capable of being controlled independently of one another apply different voltages (U1, U2) to the consumer (1).

Description

Schaltunqsanordnunq for the operation of electromagnetic consumers

State of the art

The invention relates to a circuit arrangement for operating electromagnetic consumers, in particular solenoid valves of internal combustion engines.

In order to bring electromagnetic consumers into their nominal excitation state as quickly as possible, it is known to apply them to a higher voltage for a short time than is necessary for the nominal excitation state when they are switched on. In internal combustion engines with a fuel supply system having solenoid valves, there is a need to switch on the solenoid valves that form electromagnetic consumers as quickly as possible and then to switch them on with as little energy as possible hold. In the pull-in phase, each solenoid valve is therefore supplied with a higher voltage than in the subsequent hold phase. For this purpose, a clocking supply (electronic switch) of the solenoid valve in connection with a freewheeling diode is known, "whereby the clocking current (or peak) and holding current is set and, if necessary, regulated. This is how it is from DE-OS 28 41 781 known to apply an electromagnetic consumer to a supply voltage via a switching element controlled by two threshold value transmitters. The two threshold value transmitters enable two-point controller operation. The consumer flow is kept between an upper and a lower current limit value depending on a specification unsatisfactory with regard to their electromagnetic compatibility (EMC property).

Furthermore, it is known to control the consumer flow according to a setpoint specification profile in such a way that a peak current flows in the pull-up phase of the solenoid valve and a holding current flows in the solenoid valve in the subsequent operating phase. The consumer current is preferably set by a transistor which, particularly in the holding current phase, develops a high, undesired power loss due to the circuit structure.

Advantages of the invention

The circuit arrangement according to the invention with the features mentioned in the main claim works in stationary, ie in non-clocked mode, so that the disadvantages associated with the clock operation do not occur. This results in a favorable energy balance and a significantly improved EMC property. The switching elements assume either their blocked or their conductive state, so that only very low power losses can occur. In order to bring the electromagnetic consumer into its nominal excitation state as quickly as possible, a higher voltage is first applied to the consumer by the corresponding switching element and then a voltage which is smaller in comparison by another switching element. With solenoid valves, a corresponding tightening energy is available in the tightening phase and subsequently the much lower holding energy required. Two circuits with different voltages are thus provided, so that "two-stage" operation is possible. If, however, a further gradation is desired, a number of switching elements exceeding the number "two" can also be provided within the scope of the invention, which accordingly apply differently large voltages to the consumer.

According to a development of the invention, it is provided that the smaller voltage has the size of the minimum excitation voltage of the consumer. As described above, it is preferably only applied to the consumer a certain time after the consumer has been switched on, so that he maintains his minimum excitation. In the case of a solenoid valve, the smaller voltage represents the holding voltage, while the larger voltage applied directly to the consumer when switched on forms the pull-in voltage of the solenoid valve. The tightening voltage can - depending on the load capacity of the switching element and consumers - make up a multiple of the nominal voltage.

According to a preferred embodiment, the larger voltage is formed by an operating voltage and the smaller voltage is generated from the operating voltage by means of a direct voltage converter (DC / DC converter). The output voltage of the DC-DC converter is selected in such a way that the solenoid valve assumes its holding state, whereby voltage drops on any other circuit components that may be present and also disturbance variables (such as tolerance, temperature, etc.) are taken into account. The DC-DC converter can be used for several circuit arrangements of an overall system which has several solenoid valves. For example, each cylinder of an internal combustion engine requires an injection valve which is formed by the solenoid valves mentioned.

In order to prevent the switching elements from influencing one another, a further development of the invention provides that the two switching elements are connected to the consumer via a decoupling circuit. This decoupling circuit is preferably formed by a diode arrangement. The arrangement is particularly designed so that two diodes are connected in the forward direction with electrodes of the same type (anodes or cathodes) to the consumer and the other electrodes (cathodes or anodes) are each connected to one of the switching elements. In this way, undesired equalizing currents between the two voltage levels are avoided. According to a preferred embodiment, at least one of the circuits operated with the differently large voltages has a current control. The circuit having the holding voltage is preferably provided with the current control. This has a sensor that detects the holding current and is connected to a current regulator. This controls the associated switching element.

The sensor is preferably designed as a shunt. Transistors can be used as switching elements.

Furthermore, a control circuit is provided which supplies the current regulator with a holding current setpoint and the control element supplied with operating voltage directly with a control value for the starting phase. The control circuit preferably works in such a way that when switching on the control value is first supplied to the base of the transistor connected to the larger voltage, so that a defined peak current is set for switching the solenoid valve on as quickly as possible. After the pull-in phase, the supply of the solenoid valve is taken over by the holding circuit operated at a lower voltage. For this purpose, the switching element assigned to the holding circuit is switched on and the switching element assigned to the pull-in circuit is switched off. However, it is also possible for both circuits to be switched on at the same time and for the pull-in circuit to be switched off after the pull-in phase, the holding circuit remaining switched on. As a result, the consumer is initially operated with the correspondingly higher voltage, since the smaller voltage no effect. The decoupling circuit prevents mutual interference between the two voltages. After switching off the larger voltage (operating voltage), further operation with the lower holding voltage takes place.

The current regulation of the holding circuit reduces the power loss and the current load of the solenoid valve to the lowest possible value. The current control also offers the possibility of tuning the holding current precisely to a predetermined value. In addition, any voltage ripple in the holding circuit that may be present is largely corrected by the current regulator. Due to the use of the DC-DC converter to generate the holding voltage, there is only a very low power loss in the associated switching element, so that, in particular, common transistors can be used.

The withstand voltage, i. H. the output voltage of the DC-DC converter is preferably set so that there is a transition from the current control to a voltage control when the ohmic resistance of the consumer increases (e.g. due to temperature influences). This additionally limits the power loss in the consumer (solenoid valve).

drawing

The invention is explained in more detail below with reference to the figures. Show it: FIG. 1 shows a block diagram of the circuit arrangement according to the invention,

FIG. 2 shows a detail of the block diagram in accordance with FIG. 1,

FIG. 3 shows a control signal for a holding circuit,

FIG. 4 shows a control signal for a pull-in circuit,

5 shows a voltage curve on a with the

Circuit arrangement operated electromagnetic consumers and

6 shows a current profile of the consumer.

1 shows as a block diagram a circuit arrangement for operating an electromagnetic consumer 1. This is designed as a solenoid valve of an internal combustion engine, not shown. The fuel injection of the internal combustion engine is controlled by means of the solenoid valve.

The circuit arrangement is connected to an operating voltage Ug, which is fed as an input voltage to a DC-DC converter 2. The DC-DC converter 2 represents a so-called DC / DC converter, which generates a holding voltage U _H from the operating voltage U _B. The operating voltage U _B and the holding voltage U _H are DC voltages. The operating voltage U _B represents a voltage U ₁ which is greater than the holding voltage U _H , and consequently the holding voltage U _{H forms} a voltage U ₂ which is smaller by comparison. The holding voltage U _H is fed to a first switching element 4 via a sensor 3. The operating voltage U _B is connected to a second switching element 5. The switching elements 4 and 5 are preferably designed as transistors. The emitter-collector paths form the switching paths of the switching elements 4 and 5. The operating voltage U _B is preferably applied to the emitter of the associated transistor and the holding voltage U _H reduced by the voltage drop at the sensor 3 is likewise applied to the emitter of the other transistor. The outputs 6 and 7 of the switching elements 4 and 5 are connected to a decoupling circuit 8. The outputs 6 and 7 are formed by the collectors of the transistors of the switching elements 4 and 5.

The decoupling circuit 8 has a diode arrangement 9 which, as shown in FIG. 2-, consists of two diodes D ₁ and D ₂ . The anodes of the diodes D ₁ and D ₂ are each connected to one of the collectors of the transistors forming the switching elements 4 and 5. The cathodes of the diodes D ₁ and D ₂ are brought together at a summation point 10, which is also connected to one terminal of the consumer 1. The other connection of the consumer 1 is grounded.

The circuit arrangement also has a control circuit 11 which provides a first control signal S ₁ at its output 12 and a second control signal S ₂ at its output 13. The control signal S ₁ is fed to a current controller 14 as a holding current setpoint. Furthermore, the sensor 3 designed as a shunt 15 is connected to the current regulator 14 via a line 16. The output 17 of the current regulator 14 leads to the first switching element 4, to the base of the transistor used there. At the output 13 of the control circuit 11, the second control signal S ₂ is available, which is given via a line 18 to the base of the transistor of the second switching element 5.

The circuit arrangement according to the invention works as follows:

To open the solenoid valve (consumer 1), the control circuit 11 provides the pulses shown in FIGS. 3 and 4 (control signals S ₁ and S ₂ ). Both control signals S ₁ and S ₂ are emitted at the same time t ₁ . At time t ₂ , control signal S ₂ , which acts on second switching element 5, goes back to zero, while control signal S ₁ continues to be delivered - up to time t ₃ . The output of the control signals S ₁ and S ₂ has the result that the current controller 14 is given a holding current setpoint, via line 16 the current controller 14 receives the actual holding current value detected by the sensor 3. The control difference resulting between the holding current setpoint and the holding current actual value leads at the output 17 of the current regulator to a corresponding output signal which drives the base of the transistor of the first switching element 4.

At time t ₁ , the two switching elements 4 and 5 are turned on based on the control signals S ₁ and S ₂ , so that the voltage profile of the consumer voltage U _L shown in FIG. 5 and the associated consumer current profile (consumer current I _L ) shown in FIG. 6 are set . As long as the control signal S _{2 is applied} to the second switching element 5, the larger voltage U ₁ (operating voltage U _B ) applied to the consumer 1 via the decoupling circuit 8. The smaller voltage U ₂ (holding voltage U _H ), which is present at the summation point 10 and accordingly also at the consumer 1, has no effect since it is less than the operating voltage U _B. In this respect, it only comes into play at time t ₂ , since then the second switching element 5 assumes its locked state and now only the lower voltage u ₂ , ie U _H, is available at the consumer 1. The consumer voltage U _L accordingly decreases to a lower value at time t ₂ . At time t ₃ , the control signal S ₁ is also switched off, so that the first switching element 4 also changes into its locked state. The consumer 1 is thus de-energized.

FIG. 6 shows the current diagram associated with the voltage profile of the consumer 1. The consumer current I _L rises rapidly due to the relatively large operating voltage U _B and very quickly reaches its maximum value I _max . This allows the solenoid valve to tighten in a very short time. If the tightening has taken place, it is sufficient for maintaining this state that the winding of the solenoid valve is flowed through by a current which is smaller than the maximum current I _max , namely the holding current I _H. This occurs at time t ₂ . It is supplied by the DC / DC converter 2, set by the switching element 4-. Since the current regulation (current regulator 14) takes place with the voltage U _{2 that} is lower than the operating voltage U _B , only a relatively low power loss occurs in the first switching element 4. The circuit arrangement according to the invention can be used in particular in the case of shock absorbers for motor vehicles which are adjustable in their damping force. The adjusting member of such a shock absorber is designed as a solenoid valve so that it forms the consumer 1.

Claims

Expectations

1. Circuit arrangement for operating electromagnetic consumers, in particular of solenoid valves of internal combustion engines, characterized by at least two independently controllable switching elements (4, 5) which apply differently large voltages (U _{1 '} U ₂ ) to the consumer (1).

2. Circuit arrangement according to claim 1, characterized in that the smaller voltage (U ₂ ) has the size of the minimum excitation voltage of the consumer (1).

3. Circuit arrangement according to one of the preceding claims, characterized in that the smaller voltage (U ₂ ) is the holding voltage (U _H ) of the consumer (1) forming the solenoid valve and the larger voltage (U ₁ ) is the pull-in voltage of the solenoid valve.

4. Circuit arrangement according to one of the preceding claims, dadurchgeken nz eichnet that the larger voltage (U ₁ ) is an operating voltage (U _B ) and that the lower voltage (U ₂ ) by means of a DC converter (2; DC / DC converter) the operating voltage (U _B ) is formed.

5. Circuit arrangement according to one of the preceding claims, that the two switching elements (4, 5) are connected to the consumer (1) via a decoupling circuit (8).

6. A circuit arrangement according to one of the preceding claims, that the decoupling circuit (8) has a diode arrangement (9).

7. Circuit arrangement according to one of the preceding claims, characterized in that the decoupling circuit (8) has two diodes (D ₁ , D ₂ ) which are connected in the forward direction with electrodes of the same type (anodes or cathodes) to the consumer (1) and whose other electrodes (cathodes or anodes) are each connected to one of the switching elements (4 or 5).

8. Circuit arrangement according to one of the preceding claims, characterized in that at least one of the voltages of different sizes (U ₁ , U ₂ ) operated circuits has a current control.

9. Circuit arrangement according to one of the preceding claims, characterized in that the circuit having the holding voltage (U _H ) is provided with the current control.

10. Circuit arrangement according to one of the preceding claims, characterized in that the current control has a holding current (I _H ) sensing sensor (3) which is connected to a current regulator (14) which controls the associated switching switching element (4).

11. Circuit arrangement according to one of the preceding claims, that the sensor (3) is designed as a shunt (15).

12. Circuit arrangement according to one of the preceding claims, that the switch elements (4, 5) are designed as transistors.

13. Circuit arrangement according to one of the preceding claims, characterized by a control circuit (11), the current controller (14) a holding current setpoint (control signal S ₁ ) for the holding phase and the switching element (5) supplied directly by the operating voltage (U _B ) Tax value (Control signal S ₂ ) for the pull-in phase of the solenoid valve.