EP0980575A1

EP0980575A1 - Electronic control circuit

Info

Publication number: EP0980575A1
Application number: EP98924050A
Authority: EP
Inventors: Wolfram Breitling; Horst Singer; Reinhold Weible; Rolf Falliano; Florian Richter
Original assignee: GKR Gesellschaft fuer Fahrzeugklimaregelung mbH
Current assignee: GKR Gesellschaft fuer Fahrzeugklimaregelung mbH
Priority date: 1997-05-09
Filing date: 1998-05-07
Publication date: 2000-02-23
Also published as: WO1998052201A1; DE19719602A1; US6394414B1; JP2001525125A

Abstract

The invention relates to an electronic control unit for controlling an electromagnetic valve having an armature, in particular for a heating and/or air conditioning installation in a motor vehicle. The circuit has an electronic switch element (8) which is mounted in a row with the valve coil. Said switch element (8) is characterized in that it controls the valve voltage (29) (or valve current (44)) at the coil (12) in such a way that, when the valve is switched in, the valve voltage (29) reaches a first value (U1). The valve voltage (29) is then brought back to a second value (U2) which is less than the first value (U1). The valve voltage (29) then takes on a third value (N) which is greater than the second value (U2) and represents a withstand voltage for maintaining the armature (13) in its switch-on position.

Description

Electronic control circuit

The invention relates to an electronic control circuit for controlling an electromagnetic valve having an armature, in particular for a heating and / or air conditioning system of a motor vehicle, with an electronic switching element lying in series with the coil of the valve.

State of the art

A control circuit for a solenoid valve is known from the publication WO 94/19810, which changes the drive current of the solenoid valve as a function of time when the solenoid valve is to be brought from a passage position into a closed position. This is done by reducing the drive current of the valve in such a way - but not to zero that the solenoid valve drops. Immediately afterwards, the control current is increased again, but the current value remains below a value at which the solenoid valve is moved into its closed position. The control circuit consequently controls the drive current during a switch-off phase. It is also known in the prior art to operate solenoid valves with a rectangular pulse-shaped drive current. This means that the excitation of the magnetic coil is either switched off or switched on, and it is maximum when switched on.

Furthermore, it is known to first control the control current for the coil excitation at the beginning of the pulse to an increased value, the coil excitation - after a spring-loaded armature has overcome the first spring forces and the static friction - being reduced to a nominal value at which the armature remains in a stop position .

A disadvantage of the solenoid valves known in the prior art is that they produce relatively loud switching noises when closing, when the armature and / or the valve hit a stop when closing. If the valve is used, for example, in a motor vehicle to control the air conditioning system, the switching noise disturbs in particular when driving slowly and when the vehicle is stationary, since the engine and driving noise are then low.

Advantages of the invention

The electronic control circuit according to the invention for controlling an electromagnetic valve having an armature, in particular for a heating and / or air conditioning system of a motor vehicle, with an electronic switching element lying in series with the coil of the valve, therefore offers compared to the advantage that the switching element controls the valve voltage (or the valve current) on the coil such that the valve voltage reaches a first value when the valve is switched on, that the valve voltage is subsequently reduced to a second value that is less than the first value and that subsequently the valve voltage assumes a third value which is greater than the second value and which represents a holding voltage for holding the armature in its switched-on position. Because the electromagnetic valve is first operated with a first value of the valve voltage, the armature is initially accelerated to such an extent that the initial spring forces and static friction are overcome. The armature thus set in motion subsequently experiences a reduced acceleration due to a reduced electromagnetic energy, since the second value of the valve voltage is lower than the first value, the second, however, preferably being chosen so that the armature essentially maintains its speed. In the course of the further switch-on process, the valve voltage assumes the third value, which is greater than the second value, so that the armature of the valve reaches the end position in a very short time in spite of the voltage drop from the first to the second value which occurred previously. Furthermore, there is the advantage that the impact of the armature on the end stop is not associated with the loud impact noise mentioned in the prior art, since the voltage or current control according to the invention enables rapid switching, but nevertheless excessive impact on the end stop prevented.

According to the invention it is provided that the first value of the valve voltage or the valve current is in the form of a switch-on pulse. The amplitude of the switch-on pulse is greater than half of the nominal value. The duration of the switch-on pulse is approximately 0.1 to 0.6 times the valve switching time when the valve is suddenly energized with a voltage above the holding voltage. Alternatively, it can be provided that the switch-on pulse is composed of several successive pulses.

It is further provided that the second value of the valve voltage or the valve current forms an initial value for a switch-on ramp. The maximum value of the second value is 0.8 times the nominal value of the valve voltage or the valve current. After the valve voltage or the valve current is reduced from the first to the second value, the switch-on pulse is followed by a voltage or current curve which increases linearly. Alternatively, it can be provided that the rise of the switch-on ramp is non-linear, preferably progressive or degressive. It can be deduced from this that the electromagnetic valve is operated during the switch-on ramp with reduced, but specifically controlled, increasing magnetic energy, so that the acceleration of the armature is reduced. Furthermore, it is provided in a preferred embodiment that the switch-on pulse is followed by a "dead time" during which the valve voltage or the valve current is kept constant at the second value, so that the startup of the switch-on ramp is delayed.

The end value of the switch-on ramp preferably forms the third value, the third value in particular corresponding to the nominal value of the valve voltage or the valve current. The third value has at least a height which corresponds to the holding voltage of the armature in its switch-on position. The valve voltage or the valve current is kept constant over a period of time during which the valve is in the closed position. This period can be varied depending on the requirement.

To switch off the valve, the valve voltage or the valve current is suddenly reduced, to a value that lies between the third value and the voltage-free state. In a further development of the invention, this value simultaneously forms an initial value for a switch-off ramp. During the switch-off ramp, the valve voltage or the valve current will drop linearly to zero. Alternatively, the course of the switch-off ramp can be non-linear, in particular progressively or degressively decreasing. The duration of the switch-off ramp is determined by a coil freewheel, which is formed, for example, by a freewheeling diode connected in parallel to the coil. In a particularly preferred embodiment, it is provided that the individual control sections (switch-on pulse, dead time, switch-on ramp, switch-on position and switch-off ramp) are not determined by predefined conditions, but that current status parameters determine the amplitude and / or the duration of at least one control section. In a motor vehicle, such state parameters are, for example, the battery voltage, the speed of a water pump of an internal combustion engine, the fluid pressure of a water circuit in an air conditioning system and the coil temperature. To do this, it is necessary to record the state parameters using suitable sensors. For example, a thermocouple can be provided for detecting the coil temperature.

Furthermore, it is preferably provided to set the level of the switch-on pulse, that is the level of the first value, by means of the electronic switching element independently of the supply voltage — for example, the on-board electrical system voltage of a motor vehicle, that is, the battery voltage — of the electronic control circuit to a desired level. This is particularly important if the battery voltage is not constant due to external influences, for example outside temperature, since then reproducible switch-on processes are still always implemented.

Furthermore, it is particularly provided that the duration of the switch-on pulse can be set automatically. The duration of the switch-on pulse depends on the position of the armature. The position of the anchor is derived from the course of the valve voltage and / or the valve current by means of a suitable electronic circuit which can be assigned to the electronic control circuit.

In a particularly preferred embodiment it is provided that an evaluation device is assigned to the electronic control circuit. The assignment not only includes the provision of information to one another, but also the spatial assignment to one another. In particular, the evaluation device is part of the electronic control circuit.

It is provided that when the valve is switched on, the evaluation device determines from the slope of the valve current and / or the valve voltage a point in time at which the valve current will assume a plateau value which is below the holding current of the armature and at which the slope of the valve current Is zero or approximately zero. The increase in the valve current in this time range corresponds to the switch-on pulse mentioned at the beginning, but the valve current increase — depending on the inductance of the coil — is preferably non-linear. For this purpose, the course of the valve current or the valve voltage during a switch-on process is first detected when no or only known magnitudes affect the valve. This curve corresponds to a set curve curve from which the gradient is determined at any desired point in time, so that if the curve deviates therefrom, this also results in a deviating gradient of the valve. current or the valve voltage, conclusions can be drawn as to the conditions under which the valve operates. If disturbance variables act on the valve or if the valve itself causes disturbance variables, the course and the gradient of the valve current or the valve voltage change. It is therefore possible to make a statement about the magnitude of the disturbance variable (s) acting on the basis of a comparison between the desired curve shape and the course of the valve current or the valve voltage, so that the course of the valve current or the valve voltage can be adapted to the desired curve shape by means of the electronic circuit is. Alternatively, it can be provided that individual values of the target curve are determined at definable times. Values of the valve current or of the valve voltage which are detected in an operational switch-on process and which deviate due to disturbance variables result in direct comparison with the determined values of the target curve to provide information about the magnitude of the disturbance variable (s). Consequently, an adaptation of the course of the valve current or of the valve voltage to the desired curve course is also possible here in an advantageous manner. Both of the variants described above enable the valve to be securely closed in a sufficiently short time for various operating conditions, with optimum noise reduction being achieved.

At least one disturbance variable occurs with every control or regulation process. In the present case, several disturbance variables occur, after which is discussed in more detail below. If the coil is actuated for a switch-on process, an electromagnetic field is formed which acts on the armature, causing the armature to set in motion. At the same time, the movement of the armature acts on a valve unit that is to close the circuit of the heating or cooling water circuit. The water pressure in the medium circuit counteracts the valve unit and thus the armature, which in turn counteracts the electromagnetic force generated by the coil. A disturbance variable therefore occurs on the valve unit, which also acts indirectly on the coil via the armature. Furthermore, a further disturbance variable produces the armature itself, namely by friction in its mechanical guidance and / or by the fact that the movement of the armature is damped, for example by a spring. Another disturbance variable acts on the coil, which results from an electrical coil resistance that can be changed depending on the coil temperature, the change in the magnetic circuit caused by the armature movement (the armature is moved out of the coil) and the resulting change in the valve current put together. Finally, a voltage is induced by the movement of the armature in the coil, which causes a current against the valve current. Due to these internal and external influences, when the valve is switched on, the valve current or the valve voltage does not increase in accordance with the desired curve profile, but rather deviates from it. This deviation can preferably be detected by means of the evaluation device, so that it provides information about the electronic control circuit the disturbance variables acting on the valve are transmitted, as a result of which the course of the valve current or the valve voltage can be adapted to the desired curve course. This advantageously enables a noise-reduced closing operation of the valve in a sufficiently short time.

In deviation from what has been described above, the target curve profile of the valve current or the valve voltage is not determined by means of a switch-on operation of the valve, in which no or only known magnitudes are involved, but it is of course also possible - in one embodiment variant - to use a simulation and the target curve profile / or to determine a (laboratory) experiment. The values determined in this way serve as standard values and can in particular be stored in the evaluation device.

Finally, it is preferably provided that the evaluation device uses the slope and / or individual values of the valve current and / or the valve voltage from the time the valve is switched on until the plateau value is reached, depending on the disturbance variables acting on the valve, control parameters for influencing the course of the valve current and / or the valve voltage of a later time range. Furthermore, a prediction of the expected total closing time of the valve is possible from the initial course of the control signal of the valve. For example, if the predicted total closing time is too long due to high water pressure, the electronic control circuit can Increase the valve current or the valve voltage so that the armature is accelerated more, which results in a shorter closing time compared to the expected total closing time. On the other hand, however, it is also possible to switch off the valve current or the valve voltage for a short time if the overall closing time is too short, resulting from a high speed of the armature, so that the speed of the armature is reduced, as a result of which an optimal, noise-reduced closing process is also achieved here .

drawings

The invention is explained in more detail using exemplary embodiments with reference to the drawings. Show it:

FIG. 1 shows a first exemplary embodiment of the electronic control circuit with an electromagnetic valve to be controlled,

FIG. 2 shows a time-dependent course of the valve voltage applied to the coil,

FIG. 3 shows a block diagram of a second exemplary embodiment of the electronic control circuit,

FIG. 4 shows a block diagram of a third exemplary embodiment of the electronic control circuit and 5 shows a time-dependent course of a valve current when the valve is actuated with the electronic circuit according to FIG. 4.

Description of the embodiments

FIG. 1 shows an electronic control circuit 1, hereinafter referred to as control unit 2, which is supplied with voltage via connections 3. A connection 3 'represents a connection to a positive pole of an on-board electrical system of a motor vehicle, not shown here. Furthermore, FIG. 1 shows an electromagnetic valve 4 with a coil freewheel 5. The electromagnetic valve 4 is assigned to a medium circuit, not shown here, in such a way that it regulates a heating and / or cooling water supply for a heat exchanger of a heating and / or air conditioning system. The control unit 2 includes a control device 6, a control circuit 7, an electronic switching element 8 and a shunt resistor 10. The switching element 8 is designed as a field effect transistor, hereinafter referred to as FET 9 for short.

The electromagnetic valve 4 has a coil 12, an armature 13 movably mounted within the coil 12 and a valve unit 14, the movable part of the valve unit 14, not shown here, being actuated by means of the armature 13. A connection 15 of the coil 12 of the electromagnetic valve 4 is connected to a positive pole of the vehicle electrical system, not shown here, this is the positive pole of the motor vehicle battery. With their other connection 16 the coil 12 is connected to the control unit 2. The coil freewheel 5 is connected parallel to the coil 12, that is to say a connection 17 of the coil freewheel is connected to the connection 15 of the coil and a further connection 18 of the coil freewheel 5 to the other connection 16 of the coil 12. Alternatively, the coil freewheel 5 can also be used be integrated in the control unit 2 (not shown). The coil freewheel 5 then acts either between the connections 3 'and 16 or it is connected in parallel to the switching element 8 and acts between the connection 16 and the ground (negative pole of the on-board battery) of the on-board electrical system.

The control device 6 of the control device 2 transmits information via a connection 19 to the control circuit 7 and receives information from the control circuit 7 via a connection 20. The control circuit 7 controls the gate 22 of the FET 9 with its output 21, so that the through-wi - The state between a source connection, hereinafter referred to only as source 23 and a drain connection, hereinafter referred to only as drain 24, can be changed as a function of a drive signal present at gate 22. Furthermore, the control circuit 7 has connections 25 and 26, the connection 25 being connected to the source 23 and the connection 26 being connected to the drain 24. Furthermore, the shunt resistor 10 is connected to its one terminal 27 at the drain 24. Another connection 28 of the shunt resistor 10 is connected to ground, namely the negative pole of the battery of the motor vehicle. The overall result is a current path in which the coil 12, the FET 9 and the shunt resistor 10 are connected in series, the coil 12 with its connection 15 - as already mentioned - at the positive pole of the battery and the shunt resistor 10 is connected to ground. Due to the series connection of the components, a partial voltage, namely a valve voltage 29, is applied to the coil 12.

The diagram in FIG. 2 shows a time-dependent course of the valve voltage 29 during a switching process, which consists of a switch-on phase E (0 to t ₃ ), a phase with constant valve voltage K (t ₄ -t ₃ ) and a switch-off phase A (t ₅ ~ t ₄ ) is divided. The voltage U is plotted on the ordinate axis and the time t on the abscissa axis. The course of the valve voltage 29 is composed of a switch-on pulse 30, a switch-on ramp 32, a closing time 41 and a switch-off ramp 34 when the valve 4 is switched on. The switch-on ramp 32 has a dead time 31 and a run-up 33. The magnitude of the switch-on pulse 30 represents a first value u, which can be greater or less than a nominal value N and which is applied to the coil 12 for a period of time - _{j ^} -tg. The switch-on ramp 32 begins at the time t 1 and the valve voltage 29 drops to a second value U ^″ _2. The second value U ₂ thus forms the initial value of the switch-on ramp 32, the switch-on ramp 32 having a total duration of ₃ −t ₁ Dead time 31 is the second value U _2. The start-up time 33 starting at time t ₂ has a linearly increasing valve voltage 29 up to time t ₃ to the nominal value N. The nominal value N of the valve voltage 29 is applied to the coil 12 during the closing time 41 for a period t ₄ ~ t ₃ and thus forms a holding voltage. At time t ₄ , valve voltage 29 drops to a third value U ₃ , which at the same time represents an initial value for switch-off ramp 34. During a time period t ₅ -t _{4 of} the switch-off ramp 34, the valve voltage 29 drops to a voltage-free state 35. The electromagnetic valve 4 is therefore preferably in its switch-off position at the time t ₅ .

The course of the valve voltage 29 shown in FIG. 2 is generated in that the gate 22 of the FET 9 is controlled with a signal via the output 21 of the drive circuit 7 in such a way that such a volume resistance is established between the source 23 and the drain 24, that the desired voltage drop occurs on the switching element 8, that is to say the valve voltage 29 arises after the course of FIG. 2. The voltage drop is sensed via the connections 25 and 26, taking into account the level of the battery voltage. This makes it possible to set the level of the valve voltage 29 precisely to the desired curve shape by the control device 6. For the operation of the electromagnetic valve 4, the control unit 2 generates a number of switching operations in succession with the time period t ₅ -t _Q , the period between two switching operations being determined by the power demanded by the heat exchanger of the heating and / or air conditioning system. The exemplary embodiment in FIG. 3 shows an electronic circuit 1 a, which is designed as a control unit 2 a. The connection 16 of the electromagnetic valve 4 is located at the connection 25 of the control device 2a, so that the same basic structure as shown in FIG. 1 results. In addition to the control device 2 from FIG. 1, the control device 2a has connections 36 and 37 to which sensors 38 are connected. A thermocouple 39 measures the temperature - as a disturbance variable - of the coil, so that the control unit 2a regulates the valve voltage 29 depending on the temperature of the coil 12. The sensor 38 connected to the outlet 37 is a pressure sensor 40, which senses a water pressure - as a further disturbance variable - in the heating or cooling water inlet, namely that which the electromagnetic valve 4 is to open or close. The variables ascertained by sensors 38 thus serve to determine control parameters, as a result of which the individual control sections are optimally adapted to changing operating states of a heating or air conditioning system with regard to their duration and amplitude. Of course, further sensors 38 can be assigned to control unit 2a via further connections, but this has been omitted in FIG. 3 for the sake of simplicity.

The alternative mentioned in claim 1, namely that the valve current can also be controlled instead of the valve voltage, is explained in more detail in a further exemplary embodiment, shown in FIG. 4-. Accordingly, claim 1 also applies analogously to this exemplary embodiment if in instead of the term "valve voltage", the term "valve current" is adopted.

For the exemplary embodiment according to FIG. 4, it is provided that a control device 2b is assigned a digital and / or analog evaluation device 42. It detects the signal which drives the valve 4, namely a valve flow 44 (FIG. 5). From its time profile, it determines the slope of the valve flow 44 at least at a definable point in time, as a result of which a movement profile of the armature 13 can be derived in comparison with an increase in the setpoint curve (not shown).

If the coil 12 is actuated by the control device 2b via the switching element 8 (not shown in FIG. 4) with a valve voltage 29 "having the value U (FIG. 5) that is constant over a period of time t ₃ ~ t _Q , the valve current 44 first increases as a function of the inductance and the ohmic resistance of the coil 12. In this regard, it should be noted that in the case of a valve current control, the switching element 8 is preferably connected in parallel with the coil 12. Because of the control, an electromagnetic field is formed in the coil 12 which is based on the Anchor 13 acts, which thereby sets in motion, which acts in its movement on valve unit 14, which is intended to interrupt or close the circuit of the heating or cooling water circuit (not shown) The closing of the interrupted medium circuit transmits a disturbance variable Z ₁₄ the valve unit 14. The disturbance variable Z ₁₄ is caused by the differential pressure between inlet and A outlet (not shown) set) of the valve unit 14 and caused by the amount of the flow rate to be blocked. The disturbance variable Z ₁₄ depends on the temperature and the viscosity of the medium, on the speed of the pump that pumps the medium and on the operating status of any branched media circuits that may be present. Since the disturbance variable Z ₁₄ acts on the valve unit 14, it also counteracts the armature 13. During the movement of the armature 13, this additionally experiences a disturbance variable Z ₁₃ , caused by friction in its mechanical guidance and by a damping (electrical, magnetic and / or mechanical) which acts on it. The armature 13 thus counteracts the electromagnetic force generated by the coil 12. Furthermore, a disturbance variable Z ₁₂ acts on the coil 12, which is composed of an electrical coil resistance that can be changed as a function of the coil temperature, the change in the magnetic circuit caused by the armature movement and the resulting change in the coil current (valve current 44). Furthermore, a voltage is induced in the coil 12 by the movement of the armature 13, which causes a current against the current feeding the coil 12.

Because - as already mentioned - the evaluation device 42 detects the slope of the valve flow 44, information about the disturbance variables ₁₂ , Z ₁₃ and Z ₁₄ acting on the valve 4 can be derived therefrom, so that the valve flow 44 is dependent on it Control device 2b is controllable. This makes it possible for it to optimally match the operating status of the heating or air conditioning location can be adjusted. This advantageously enables a noise-reduced closing process of the valve 4, which will be discussed in more detail below with reference to FIG. 5.

When the valve 4 is actuated with the valve voltage 29 'at the beginning of the switch-on process, the valve current 44 rises non-linearly over a time range t- ^ t _Q , as already described. The movement of the armature 13 induces a voltage in the coil 12, which causes a current direction counter to the supplying valve current 44. Due to the increasing speed of the armature 13 after overcoming the first friction and spring forces and the higher induction voltage generated therefrom, the gradient of the valve current 44 decreases with increasing time t. At the time t ^, the valve current 44 reaches a plateau value, which is preferably below a nominal value N _j , which corresponds to the holding current of the armature in its switched-on position. The slope of the valve current 44 is zero. The evaluation device 42 derives information from this, namely that the armature 13 must have moved. As the speed of the armature 13 continues to increase, the valve current 44 decreases in the further course until it assumes a relative minimum with the value I ₂ at a time t ₂ , which is below the value 1- ^. The slope of the valve current 44 is negative in the time range t ₂ -t ₁ . At time t ₂ , valve unit 14 reaches its end stop and thus valve 4 reaches its switched-on position. The movement of the armature 13 is now complete. As a result, the force generated in the coil 12 by the accelerated movement of the armature 13 is genstro, which leads to a decrease in the valve current 44 (also called total coil current) during the movement of the armature, now almost 0. The valve current 44 can thus build up unhindered in the time range t ₃ ~ t ₂ up to a nominal value N _j . This course of the valve current 44 corresponds to a digital actuation of the valve 4 by means of a valve voltage 29 ′, which is _stepped from a value equal to zero, abruptly to a nominal value U, at the time t _Q.

It is, of course, also possible for the exemplary embodiment according to FIG. 4, from time t 1, when the valve current 44 has reached the plateau value I or the slope of the valve current 44 has a predeterminable value, the valve with a valve voltage 29 (according to FIG. 2 to operate in the time range t ₅ ~ t ₂ ). Accordingly, at time t- ^ the valve voltage 29 'is reduced with the nominal value U at time t ^ - to a value U ₂ , as a result of which the electromagnetic energy in the coil 12 decreases. This leads to a reduced acceleration of the armature 13. This results in a speed which is sufficiently high to ensure a reliable closing of the valve 4, but is so low that noise development when the armature 13 strikes its end stop is essentially prevented, the influence of the disturbance variables Z ₁₂ , Z ₁₃ and Z _{14 being} taken into account until the plateau value 1 ^ of the valve current is reached.

If the state parameters change in the medium circuit, the time ranges would be t - ^ - t _g , t ₂ -t- _j _ and t ₃ -t ₂ not constant with each switching operation of the valve 4, but changeable depending on the disturbance variables ₁₂ , Z ₁₃ and Z ₁₄ acting. If, for example, there is a particularly high fluid pressure in the medium circuit, the time t 1 would be delayed when the valve 4 is actuated, since the valve unit 14 and thus the armature 13 are opposed to higher forces. The valve flow 44 rises less steeply, this is recognized by the evaluation device 42 and, in comparison with an increase in the desired curve, determines the expected time t 1,. Accordingly, if the time period t, -t ₀ were too long, so that the valve 4 would take too long to close, it causes the control unit 2b to increase the valve current 44, so that the armature 13 counteracts the increased counteracting forces, as a result of which the valve 4 can be closed quietly and yet safely in a sufficiently short time. Furthermore, the evaluation device 42 determines information on the acting disturbance variables Z ₁₂ , Z ₁₃ and Z ₁₄ from the gradient of the valve current 44 in the time range t -tg, so that, depending on their amplitude, the valve current 44 also depends on its amplitude in the subsequent time range t ₃ -t ₁ is changeable.

Furthermore, if the armature 13 moves too quickly, resulting in a very steep current rise, the valve voltage 29 'is briefly interrupted by the control unit 2b, so that a dead time, as in the exemplary embodiment according to FIG. 1-, in the valve voltage 29' can be integrated. Of course, if necessary, several brief interruptions of the valve voltage 29 'are possible in all control sections. Hence, too in this situation, an optimal closing process of the valve 4 is carried out taking into account the disturbance variables ^z 12 ′ ^z 13 ^unc ^ ^z 14.

To open the valve 4 after the closing time, it can be provided either to switch off the valve flow 44 in a controlled manner or in an uncontrolled manner. However, it must be ensured that the valve flow 44 drops to zero in the switch-off phase, corresponding to the exemplary embodiment according to FIG. 1-, so that the valve 4 can assume its switch-off position.

Claims

Expectations

1. Electronic control circuit for controlling an, an armature electromagnetic valve, in particular for a heating and / or air conditioning system of a motor vehicle, with an in-line to the coil of the valve electronic switching element, characterized in that the switching element (8) at the Coil (12) lying valve voltage (29) (or the valve current (44)) controls such that the valve voltage (29) reaches a first value (U- ^) when the valve is switched on, that the valve voltage (29) then to a second Value (U ^" ₂ ) is reduced, which is smaller than the first value (U- ^), and that subsequently the valve voltage (29) assumes a third value (N) which is greater than the second value (U ₂ ) and which represents a holding voltage for holding the armature (13) in its switched-on position.

2. Electronic control circuit according to claim 1, characterized in that the first value (U- _j in the form of a switch-on pulse (30) is formed.

3. Electronic control circuit according to one of the preceding claims, characterized in that the amplitude of the switch-on pulse (30) is greater than half the holding voltage.

4. Electronic control circuit according to one of the preceding claims, characterized in that the duration of the switch-on pulse (30) approximately between 0.1 and 0.6 times the value of the valve switching time when the valve is energized suddenly with a voltage above the holding voltage is.

5. Electronic control circuit according to one of the preceding claims, characterized in that the switch-on pulse (30) is composed of several pulses.

6. Electronic control circuit according to one of the preceding claims, characterized in that the second value (U ₂ ) forms an initial value of a switch-on ramp (32).

7. Electronic control circuit according to one of the preceding claims, characterized in that the end value of the switch-on ramp (32) forms the third value (N).

8. Electronic control circuit according to one of the preceding claims, characterized in that the switch-on ramp (32) has a dead time (31) following the switch-on pulse (30) during which the value of the valve voltage (29) does not change.

9. Electronic control circuit according to one of the preceding claims, characterized in that the valve voltage (29) when the valve is switched off to an initial value (U ₃ ) of a switch-off ramp (34) which is between the third value (N) and the voltage-free state ( 35) lies.

10. Electronic control circuit according to one of the preceding claims, characterized in that the end value of the switch-off ramp (34) is smaller than the initial value of the switch-off ramp (34).

11. Electronic control circuit according to one of the preceding claims, characterized in that the voltage profile of the switch-on ramp (32) and / or the switch-off ramp (34) is linear, progressive or degressive.

12. Electronic control circuit according to one of the preceding claims, characterized in that the duration of the switch-on pulse (30) is dependent on the respective position of the armature (13).

13. Electronic control circuit according to one of the preceding claims, characterized in that the position of the armature (13) from the course of the valve voltage (29) and / or the valve current (44) is determined by means of an electronic circuit.

14. Electronic control circuit according to one of the preceding claims, characterized in that the electronic switching element (8) the level of the switch-on pulse (30) regardless of the supply voltage of the electronic control circuit (1) to the first value (U- ^.

15. Electronic control circuit according to one of the preceding claims, characterized in that an evaluation device (42) at the start of the switching on of the valve (4) from the slope of the valve current (44) and / or the valve voltage (29) determines a time t ^, in which the valve current (44) will assume a plateau value (1- ^) which is below the holding current of the armature (13) and in which the slope of the valve current (44) is zero or approximately zero.

16. Electronic control circuit according to one of the preceding claims, characterized in that the evaluation device (42) from the slope and / or from individual values of the valve current (44) and / or the valve voltage (29) from the switch-on time of the valve (4) to Time t _χ as a function of disturbance variables (Z ₁₂ , Z ₁₃ , Z ₁₄ ) acting on the valve (4) determines control parameters for influencing the course of the valve current (44) and / or the valve voltage (29) of a later time range.

17. Electronic control circuit according to one of the preceding claims, characterized in that the disturbance variables acting on the valve (4) (Z ₁₂ , Z ₁₃ , Z ₁₄ ) from the gradient of the valve current (44) and / or the valve voltage (29) Comparison with an interference-free gradient can be determined by the evaluation device (42) to influence the course of the valve current (44) and or the valve voltage (29).

18. Electronic control circuit according to one of claims 1 to 16, characterized in that the disturbance variables (Z ₁₂ , Z ₁₃ , Z ₁₄ ) are detected by the control device (2a) by means of sensors (38).

19. Electronic control circuit according to one of claims 1 to 17, characterized in that the evaluation device (42) is assigned to the control device (2b).