DE3817770A1 - Device for the timed operation of an electromagnetic valve - Google Patents

Abstract

A device for the timed operation of an electromagnetic valve is described which allows particularly fast reaction thereof with high efficiency. The device according to the invention provides, for this purpose, the inductive detection of two end positions of the moving valve element by detecting the collapse of the excitation current caused by its change in position, as well as the immediately subsequent asynchronous self-timing of the excitation current.

Description

The invention relates to a device for getak tied control of an electromagnetic valve the genus of the main claim.

From the publication "Low Loss Control of Actuators", published on November 13, 1987 in the trade journal "ELEKTRONIK", various possibilities are known to control electromagnetic actuators in a clocked manner to increase the efficiency. There will propose to strike the magnetic winding of such an actuator in the working position with a pulsed direct current, with a corresponding voltage drop across a resistor (Rs) flowing through the actuator current serving as a measure for an average current which is established. It is also provided there that a clocked constant control of the actuator current to a pick-up value and subsequently a clocked constant control of said current to a hold value is carried out in accordance with a control voltage during a first, predetermined time interval. In a special case, the constant control during said time interval is replaced by an immediate transition to a control of the actuator current to a steady hold value as soon as it has exceeded an initial, predetermined peak value which is above the maximum value required for triggering the actuator.

However, this facility does not allow the most varied Actuators, especially electromagnetic ones Valves, without changes to their external wiring or of individual components within such an optimal to operate. A maximum becomes optimal Efficiency with the best possible use of a be matched copper volume of the electromagnetic winding Roger that. A particularly high degree of efficiency plays e.g. with extremely small and quickly reacting solenoid valves a role in which the specific power loss for example, an undesirable heating of the controlling medium, and therefore not can be further increased. A correspondingly optimal one Operation is in the known device restricted that corresponding time constants by festge external components of an integrated circuit lays, i.e. current border requirements only approximate are adapted to be interpreted.

It is therefore an object of the invention to provide a device create that in particular a very effective operation electromagnetic valves, and smallest possible designs of the same and the highest possible specific utilization of used conductor material for the inductive element allows. In addition, a special quick response at low average operation achievable achievements and still a certain tolerance of the required response energy permitted without adjustment be.

This task is performed by a generic device with the characteristic features of the main claim solved. Advantageous further developments of the invention The facility is designed according to the teaching of Subclaims given. The device according to the invention offers the advantage of minimizing of the supply to an electromagnetic valve speech energy enables, on the other hand, to a special quick and stable response behavior. A The mean excitation current is already reduced then when there is a change in position of the movable element of an electromagnetic valve has been recognized. The Position detection is purely inductive, i.e. contact and contactless without the use of position indicators. The reduced current supply is achieved by automatic clocking in reached a closed control loop. Overall allowed this advantageously minimizes the coils resistance of an electromagnetic valve, whereby  released power loss can also be reduced can. This not only makes a small design one enables such. There will also be a power loss Control circuit significantly reduced, so that there result in significant cost advantages. While conventional If necessary, establish a test statement about the contra stand the excitation coil of a solenoid valve, opens the device according to the invention by recognition the movement or end positions of the movable valve element more extensive functional diagnoses. So through Limit evaluation of the flight times of the movable valve elements safety functions triggered in the event of an error will.

The device can be used with an analog as well realized with a fully digital arrangement e.g. as part of a computer-based Control device in a motor vehicle.

An embodiment of the device according to the invention is shown in the drawing and in the following Description explained in more detail. Show it:

FIG. 1a shows the basic circuit diagram of a simple direct current drive of an electromagnetic valve;

Fig. 1b is a schematic view of the excitation current over time in the control of Fig. 1a;

Fig. 2 shows the functional diagram of a device according to the invention;

Fig. 3 and Fig. 4 are timing diagrams of various signals of the A direction of FIG. 2.

In a simple arrangement for DC driving an electromagnetic valve 1a is shown in FIG excitation coil 1 of the valve 2 connected with in series-appearing coil resistor 5 between a Massepoten TiAl 4 and -., Via a switch 7 - a supply voltage terminal 8 switchable. The movable element 3 of the valve 2 influences, for example, the flow of a working medium. 9 symbolizes a semiconductor valve connected in parallel in the blocking direction at the switching node 6 of the excitation coil 1 , 5 with respect to the operating voltage.

FIG. 1b shows a typical current waveform in the exciting coil of such a valve at the switching on and off of the operating voltage U _Batt. This current curve applies in principle to all electromagnetic actuators, the moving elements of which take a non-negligible time to move from one end position to another, and whose resistance changes in the magnetic circuit. After actuation of the switch 7 , the current initially ramps up during a switch-on time T _E to a bump 10 with switch-on value I _E , at which the movable valve element begins to change its position from a rest position. During the switch-on flight time T _{FE of} the movable valve element, there is a current dip 11 , that is to say a temporary decrease in the current, that is to say its rise with a negative slope, due to mutual induction or change in the resistance in the magnetic circuit. The current drop 11 characterizes the reaching of the working position of the movable part at the time T _E + T _FE . From this point in time, the current continues to increase monotonously up to a stationary end value I _max predetermined by the resistor 5 and the operating voltage U _Batt . If the switch 7 is opened, the current does not suddenly drop from the maximum value I _max , but instead gradually drops by means of the semiconductor valve 9 which is now switched through as a freewheeling path, until a low point 13 is reached at the time of separation T _A , at which the movable valve element lifts off from the working position Position begins to change. During the "switch-off flight time" T _{FA of} the movable valve element, there is a temporary current increase as a result of corresponding mutual induction or change in the magnetic circuit, up to a switch-off bump 14 , from which the current then drops monotonically towards zero. At the time T _A + T _FA , the movable valve element has reached the previous rest position.

The invention now provides to use the current drop caused by changes in the magnetic circuit 10 , 11 so that this triggers or controls an asynchronously self-clocking current limitation and the quantitative analysis of the times T _FA and T _FE a diagnosis of the mechanical function of the valve allowed.

FIG. 2 shows the device proposed according to the invention, which is divided into the actual control part I and a monitoring part II. An excitation coil 16 with inherent resistance, which acts as a control element of an electromagnetic circuit on a movable valve element 17 , is supplied in series with a controllable electronic switch 18 and a current sensing resistor 19 with an operating voltage U _Batt , for example between the ground potential 21 of a vehicle chassis and a supply terminal 20 . The series circuit of excitation coil 16 and Stromfühlwi resistance 19 is bridged in the simplest case by a freewheeling diode 23 , so that this is applied over the working distance of the controllable electronic switch 18 in the blocking direction with the operating voltage U _Batt . Instead of this freewheeling diode, a more complex freewheeling circuit can also be provided at the connection 22 of the excitation coil 16 , in order to achieve, for example in a known manner, an accelerated reduction or a switch-off power loss reducing current in the excitation coil 16 . Through the scan line 25 of the current sensing resistor 19 is transmitted a current proportional clamping voltage drop to a current sensing stage 26 from the sampling point 24, which amplifies this relatively small signal or normalized to a processable current signal. A first output of this stage feeds a differentiator 27 , the output of which outputs a derived current signal to the non-inverting signal input of a comparator 28 ; the inverting reference input of this comparator is connected to a fixed reference potential U ₅ , for example the ground potential of the electronic control unit containing the device in a motor vehicle, to which the current detection stage 26 is also connected. The output of the comparator 28 drives the first input of an exclusive OR gate 29 , the second input of which can be acted upon by a control terminal 30 with a valve control signal. This valve control signal is also fed to the set input of a turn-on flip-flop 31 , the reset input of which is connected to the output of the aforementioned exclusive-OR gate 29 . An output of the switch-on flip-flop 31 controls an OR gate 35 , which draws its second input variable from the output of a hysteresis stage 32 . This is connected to a second output of the current detection stage 26 and can be acted upon at inputs 33 and 34 with two separate setting variables, which preferably determine a holding current value and the distance between the hysteresis switching points. The output of the OR gate 35 is guided to an AND gate 36 , the second input of which can be acted upon by the valve control signal from the control terminal 30 . This AND gate controls the driver stage 37 , which in turn controls the electronic switch 18 via the driver line 38 , which can be implemented, for example, as a power field effect transistor.

The monitoring part II comprises a turn-off flip-flop 39 and a status flip-flop 40 , which emits a logic output signal which is temporally dependent on the working position of the movable valve element. The set input of the switch-off flip-flop 39 is connected to the control terminal 30 and its reset input is connected to the output of the comparator 28 . Its output controls the reset input of the state flip-flop 40 , the set input of which is connected to the output of the above-mentioned switch-on flip-flop 31 . The output of the state flip-flop 40 is connected to an output terminal 49 and to a monitoring logic 41 with diagnostic output 42 , the second input of which is fed by a logic gate 47 , preferably an OR gate. Limit value signals are supplied to this, specifically from the output of a first limit value comparator 43 , from the output of a second limit value comparator 45 , and from a limit value terminal 48 . The non-inverting inputs of these comparators are connected to the current detection stage 26 ; the inverting input of the comparator 43 is led to a limit value terminal 44 , the non-inverting input of the comparator 45 is led to a limit value terminal 46 . The limit terminal 44 is connected to a threshold potential which corresponds to the maximum permissible excitation current of the electromagnetic valve. The limit terminal 46 is connected to a threshold potential, which corresponds to the corresponding no-load current. A temperature sensor (not shown here) can be connected to the limit value terminal 48 , which, for example, monitors the operating temperature of the entire control arrangement, preferably if it is designed as an integrated circuit on a semiconductor chip.

The function of the device is explained with reference to FIGS. 3 and 4. Figure 3 illustrates some static and Figure 4 some dynamic waveforms within the device; The assignment of individual signals is given by the entered signal identifier.

part One

Under an exemplary excitation current proportional voltage curve U _A (as can be picked up when the static current supply to the excitation winding 16 is sensed at the current resistance 19 ), U _{B represents} the output voltage of the differentiator 27 . The valve control signal at terminal 30 is marked with U _C ; it sets the outputs of flip-flops 31 and 39 to log with its rising edge. "L". Due to the change in sign of the differentiated current signal, the signal curve U _D arises at the output of the comparator 28 . The OR pulse with the valve control signal U _C results in the double pulse U _E ; the duration of the two individual pulses corresponds to the duration T _FE and T _{FA of the} transient position of the movable valve element. The output of the flip-flop 31 is reset to "0" by the falling edge of the signal U _E. The signal curve U _A according to FIG. 4 symbolizes a voltage curve U _{A which is} analogous to U _A 'with self-clocking of the energization of the excitation winding 16 according to the invention; the corresponding time profile of the valve control voltage U _C is indicated below. For the self-clocking mentioned, the elements 16 , 19 , 26 , 32 , 35 , 36 , 37 and 18 form a closed two-point hysteresis circuit, which is overlaid by the elements 29 and 31 at the start of activation of the initialization pulse U _F. By specifying fixed voltage values U ₁ and U ₂ , which determine, for example, the average excitation current 56 and the current swing 57 , the hysteresis stage 32 triggers the signal curve U _G with Um when the upper and lower switching thresholds 54 and 55 of the excitation current signal U _{A are} reached or exceeded switching edges 58 to 63 at corresponding times T ₁ to T ₆ . The OR pulse 35 adds the initialization pulse U _{F to} this signal, which produces the signal U _H. The AND operation 36 causes the signal U _H to the valve control signal U _C clipping of signal parts after the disappearance of the valve control signal U _C. As a result, a current curve corresponding to the voltage U _{A shown appears} in periodic sequence from time T ₂ , as long as the valve control voltage U _{C is} effective. It can be seen that a minimal response energy can be supplied to the excitation winding because, immediately after detection of the reaching of the working position of the movable valve element, a limitation of the excitation current to a holding value below the value which causes the moving valve element to leave the rest position, or when it reaches its working position.

Part II

The set by the rising edge of the valve control signal to "L" output of the flip-flop 39 is reset by the falling edge 52 of the output signal U _{D of} the comparator 28 ; alternatively, the same also caused a falling edge of the signal U _E. The falling edge 53 of the signal U _F sets the output of the flip-flop 40 to "L", cf. U _L. The falling edge 63 of the signal U _K resets the output of the flip-flop 40 or U _L to "0" again. Thus, a pulse is available at terminal 49 , which corresponds to the time from reaching the working position to reaching the original rest position of the movable valve element, and can be used for testing purposes or to check the proper functioning of the valve (confirmation of receipt). The logic 41 links the corresponding time window with the output signal of the link gate 47 (as a logic limit value exceeding signal) and forms a status signal on its diagnostic output 42 about the correct or non-correct operating state of the device or the valve. The inputs 44 and 46 are connected to reference potentials U ₃ and U ₄ , which define corresponding thresholds for switching the comparators 43 and 45 .

When the device according to the invention is implemented by means of a software-driven computer circuit, the reference potentials U ₁ to U _{5 are} replaced by stored fixed values.

Claims (8)

1. Device for the timed control of an electromagnetic valve with a movable element that can be deflected in two end positions, with a magnetic circuit that can be changed as a function of the position of the movable element, with a winding that excites the magnetic circuit, with an electronic that is controlled by a driver stage Switch via which this winding can be connected to an operating voltage, with a current sensing resistor connected in series to the winding, at which a sensing voltage proportional to the current applied to the winding can be tapped, with an AND logic function, which can be supplied with a valve control signal and clock pulses on the one hand and from whose output said driver stage can be controlled, characterized in that

• - That the above-mentioned sensing voltage of a differentiating function ( 27 ) with connected comparison function ( 28 ) can be supplied, which allows the rising and falling edges of the above-mentioned sensing voltage to be distinguished by comparing the result of differentiation with a reference value ( U 5 ) ( U _D );
• - That a (first) memory cell ( 31 ) is present, which can be set by the valve control signal ( U _C );
• - That with the result of an exclusive OR operation of the corresponding differentiation result ( U _D ) with the valve control signal ( U _C ), the (first) memory cell ( 31 ) can be reset;
• - That the state of the (first) memory cell ( 31 ) can be fed at least via a further logic function ( 35 ) as an input condition of said AND logic operation;
• - That after resetting the (first) memory cell ( 31 ) said AND logic function periodically ge clocked can be controlled.

2. Device according to claim 1, characterized in

• - That the aforementioned sensing voltage of a hysteresis function ( 32 ) can be supplied;
• - That the hysteresis function ( 32 ) changes its initial state as a function of the sensing voltage and two predeterminable fixed values;
• - That the initial state of the hysteresis function ( 32 ) with the state of the (first) memory cell ( 31 ) OR can be linked ( 35 ) and
• - That the link result as input condition be said AND link ( 36 ) can be fed.

3. Device according to claim 2, characterized, that the ripple of the clocked excitation current (Holding current) at least through one of the hysteresis function definable fixed values. 4. Device according to one of the preceding claims, characterized in that after reaching the working position of the movable element or after resetting the memory cell ( 31 ) setting excitation current (holding current) is less than the response current achieved for leaving the rest position of the movable element. 5. Device according to one of the preceding claims, characterized in that the excitation current triggered as a result of the valve control signal and fed both into the winding ( 16 ) and into a freewheeling path ( 23 ) consists of a longer initial pulse and a subsequent pulse which consists of shorter, essentially periodically consecutive individual pulses is formed. 6. Device according to claim 1, characterized in

• - That a (second) memory cell ( 39 ) is present, which can be set by the valve control signal ( U _C );
• - That the (second) memory cell ( 39 ) from the result ( U _D ) of the comparison function ( 28 ) can be reset;
• - That a (third) memory cell ( 40 ) is present, which can be set by a change of state of the (first) memory cell ( 31 ) and can be reset by a change of state of the (second) memory cell ( 39 ), and
• - That the (third) memory cell ( 40 ) after its setting can be queried ( U _L ; 49 ).

7. Device according to claim 6, characterized in

• - That a (second) comparison function ( 43 ) is provided, both a maximum permissible He excitation current corresponding limit value ( U ₃ ; 44 ) and at least a first sample of the sensing voltage can be supplied;
• - That a (third) comparison function ( 45 ) is provided, which is both a limit value corresponding to an open circuit current ( U ₄ ; 46 ) and at least a second sample value of the sensing voltage can be supplied;
• - That at least the results of the aforementioned comparison functions ( 43 , 45 ) can be linked ( 47 ) and that both the resulting linkage and the state of the (third) memory cell ( 40 ) can be supplied as an input variable to a logic monitoring function ( 41 ), and
• - That a diagnostic output ( 42 ) can be controlled by the monitoring function ( 41 ).

8. Device according to claim 7, characterized in that with the results of the aforementioned comparison functions ( 43 , 45 ) at least one further monitoring variable ( 48 ) can be linked in an equivalent manner ( 47 ).