EP2758972A1

EP2758972A1 - Method and drive apparatus for driving an electromagnetic actuator

Info

Publication number: EP2758972A1
Application number: EP12745674.7A
Authority: EP
Inventors: Florian WEINL; Michael Pantke
Original assignee: ZF Friedrichshafen AG
Current assignee: ZF Friedrichshafen AG
Priority date: 2011-09-20
Filing date: 2012-08-02
Publication date: 2014-07-30
Also published as: DE102011083007B4; WO2013041283A1; US9337766B2; CN103814418A; DE102011083007A1; US20140203753A1; JP2014526876A

Abstract

What is proposed is: A method (700) for driving an electromagnetic actuator. The electromagnetic actuator has at least one coil and a movable armature. The method (700) has a step involving demagnetization (710) of the electromagnetic actuator by conducting a sequence of electrical current pulses (621, 622, 623), with a direction of flow which alternates from current pulse to current pulse and a current intensity which decreases from current pulse to current pulse, through the at least one coil, in order to reduce or eliminate a remanent flux density in the electromagnetic actuator. The method (700) also has a step involving determination (720) of a position of the movable armature by conducting a measurement current pulse (630) through the at least one coil subsequently to the demagnetization step (710).

Description

Method and drive device for driving an electromagnetic

actuator

The present invention relates to a method for driving an electromagnetic actuator and to a drive device for driving an electromagnetic actuator.

An electromagnetic actuator has at least one anchor and z. B. on two coils. The actuator may further comprise two permanent magnets. The position of the armature forms different inductances in the coils. In a method for activating the actuator, for example, the voltage profile across the two coils can be measured during an abruptly rising energization. From these measured data, for example, in a subtractor, a third voltage curve or a sensor signal can be calculated from which a logic unit can determine the position of the armature. Thus, a position determination can take place by evaluating the inductances prevailing on the coils.

For ferromagnetic materials, the relationship between magnetic field strength H and flux density B is nonlinear and depends on the history. Responsible for this are magnetic flux densities, which influence the inductance and thus the sensor signal. The magnetic flux density in ferromagnetic components depends on the strength of the prevailing magnetic field. If the prevailing magnetic field disappears, residual magnetism remains in ferromagnetic components. Depending on the direction and strength of the previously set magnetic field, the flux density of the remaining ferromagnet may vary. Since the magnetic flux density is to be evaluated, a position signal which is subject to errors due to different history can consequently result. For measuring devices and sensors, this effect is undesirable, but is often the case, especially when magnetic systems are part of the sensor. In addition, temperature fluctuations influence the remaining residual magnetism and thus in turn the position detection. WO 2010/049200 A1 relates to a method for detecting the position of a magnet armature of an electromagnetic actuator displaceably arranged between two coils.

Against this background, the present invention provides an improved method for driving an electromagnetic actuator and an improved drive device for driving an electromagnetic actuator, according to the main claims. Advantageous embodiments will become apparent from the dependent claims and the description below.

The present invention provides a method for driving an electromagnetic actuator having at least one coil and a movable armature, the method comprising the steps of:

Demagnetizing the electromagnetic actuator by passing a train of electrical current pulses having current direction alternating current pulse to current pulse and current intensity decreasing from current pulse to current pulse through the at least one coil to reduce or eliminate a remanent flux density in the electromagnetic actuator; and

- Determining a position of the movable armature by passing a measuring current pulse through the at least one coil subsequent to the step of demagnetizing.

The electromagnetic actuator can be understood to mean an actuator or converter which can convert electronic signals or electrical current into mechanical movement by means of electromagnetism, for example. This conversion can be achieved by means of the at least one coil. Windings of the at least one coil can at least partially surround a movement space of the movable armature. The movable armature may be a magnet armature or the like. The movable armature may be mechanically connected to an element to be moved. Also, the movable armature can be moved by a movement of the element with which it is mechanically connected. The movable armature may be made of a ferromagnetic material. Other components of the electromagnetic actuator can also be made from a ferromagnetic be made of material. The movable armature can be electromagnetically moved when an electric current is applied to the at least one coil. Also, a plurality of movable armatures may be provided in the electromagnetic actuator. Degaussing causes a reduction or elimination of the remanent flux density. The remanent flux density can also be referred to as magnetic remanence or remanent or residual magnetism, residual magnetism, residual magnetization or magnetic hysteresis. The remanence flux density is the magnetic flux density, which in a previously by a z. B. by means of at least one coil generated magnetic field remains magnetized particles of a ferromagnetic material after removal of the magnetic field. During demagnetization, an alternating magnetic field is applied, which initially has the coercive force and whose field strength then gradually decays. The demagnetization can cause a permanently magnetic ferromagnetic material to lose its magnetic polarization. Such an alternating magnetic field can be generated by the sequence of electrical current pulses. In this case, the at least one coil of the electromagnetic actuator is energized with alternating current direction. The electrical current pulses in the sequence of electrical current pulses have a decreasing current intensity or amplitude. An electrical current pulse thus has an opposite current direction and a greater current intensity with respect to an immediately following electric current pulse. Thus, an electrical current pulse has an opposite current direction and a lower current intensity with respect to an immediately preceding electric current pulse. In the demagnetization, a series of hysteresis loops are thus passed through the sequence of electrical current pulses until the remanent flux density becomes zero or almost zero. A position of the movable armature with respect to the coil can be determined by means of the measuring current pulse. To determine the position, several measuring current pulses can also be conducted through the at least one coil.

The present invention further provides a driving device for driving an electromagnetic actuator having at least one coil and a movable armature, characterized in that the driving device comprises means adapted to carry out the steps of the above-mentioned method. The Ansteuervornchtung may be connected to the electromagnetic actuator by means of a communication interface. The Ansteuervornchtung may be attached to the electromagnetic actuator or disposed separately therefrom. In connection with the above driving means, an above-mentioned method according to embodiments of the present invention can be advantageously carried out.

The present invention is based on the finding that prior to a position determination by means of an electromagnetic actuator, a demagnetization of the ferromagnetic components of the electromagnetic actuator is performed in order to eliminate as far as possible a remanent flux density in the ferromagnetic components of the electromagnetic actuator, so that a position determination is advantageously possible. An ideal operating point for determining the position and thus the smallest deviation of temperature and prehistory arises at a low flux density. In order to minimize the flux density, demagnetization in the actuator should be strived for. For demagnetization, for example, a saturation field strength with gradually decreasing field strength values is re-magnetized.

An advantage of the present invention is that remanence or hysteresis cancellation is performed to increase accuracy in position sensing in an electromagnetic actuator. Thus, a defined at the beginning of the position determination or position measurement and constant magnetic output state can be achieved within the actuator. In addition, a magnetic output state or operating point which is almost independent of the temperature is thus possible. Therefore, a position measurement in an external armature movement - ie an armature movement without energization - significantly less or almost no longer error-prone. By the present invention, the z. B. provides a drive algorithm for remanence cancellation, this advantageous effect can be achieved. Due to the low flux density due to the demagnetization and the associated lower permeability within the component, the magnetic field remains constant for a relatively long time or leads to a lower disintegration. Also, the influence of aging is lower due to the lower flux density in the component. Ferromagnetic materials have different magnetic field strength-flux density curves or BH curves. The present invention can be applied to all ferromagnetic components. In this case, the demagnetization process can be optimized, for example, by selective selection of the number of cycles and energizing length for different actuators. This can also be used if an actuator combines a large number of different ferromagnetic components in one component. Another advantage of the present invention is obtaining location information without the use of an additional position sensor, which saves space, cost and weight.

In this case, in the demagnetizing step, a first electric current pulse having a first current direction and a first current intensity and a subsequent second electric current pulse having a second current direction different from the first current direction and a second current intensity which is smaller than the first Amperage is passed through the at least one coil. Such an embodiment of the present invention offers the advantage that in this way the demagnetization can be carried out particularly effectively.

Also, in the step of demagnetizing, at least one further electrical current pulse, which has an opposite current direction and a lower current intensity with respect to an immediately preceding current pulse, is passed through the at least one coil. Such an embodiment of the present invention offers the advantage that in this way the demagnetization can be carried out particularly effectively.

Thus, in the step of demagnetizing, the sequence of electrical current pulses may have a duration of current flow through the coil which decreases from current pulse to current pulse. The duration of the current flow through the coil or the energization time influences the current intensity or amplitude of the electric current pulse. The longer the duration of the current flow through the coil, the greater the amplitude. The shorter the duration of current flow through the coil, the lower the amplitude. Such an embodiment of the present invention has the advantage that the decreasing current in this way can be realized simply and effectively by decreasing the duration of the current flow through the coil that is decreasing from pulse to pulse. Furthermore, in the step of determining, a current intensity of the measuring current pulse may be lower than a lowest of the current strengths of the current pulses from the step of demagnetizing. In contrast to the hysteresis loops of the demagnetization, the magnetic field strength introduced by a sensing cycle for determining the position of the armature does not allow a change in flux density in the ferromagnet. The reason for this lies in the only small application of magnetic field strengths by means of the measuring current pulse. For example, only isolated Weiß'sche districts are overturned. The operating point is therefore essentially always in the same range due to the reversible magnetic field.

In addition, a step of directing a movement current pulse through the at least one coil may be provided to effect movement of the armature. In this case, a current strength of the movement current pulse can be greater than a maximum of the current intensities of the current pulses from the step of demagnetizing. The movement current pulse, which must have a certain size due to the movement of the armature to be effected, can cause a magnetic field with the saturation field strength. Such an embodiment of the present invention offers the advantage that an actuatoric function of the electromagnetic actuator can be effectively performed.

At this time, the step of demagnetizing may be performed after the step of conducting and before the step of determining. Such an embodiment of the present invention offers the advantage that even after a current supply to the movement of the movable armature due to the demagnetization a largely protected position against falsification by magnetic remanence is possible.

In the step of determining, a reaction of the at least one coil to the movable armature in the measuring current pulse can be evaluated. The position of the movable armature affects a magnetic field generated by the current pulse of the at least one coil to determine the position of the movable armature. This influence on the magnetic field can be evaluated as a reaction, for example, in a voltage that can be tapped on the coil. Thus, the position of the movable Ankers be determined with respect to the coil. Such an embodiment of the present invention offers the advantage that in this way the position of the movable armature can be determined simply and accurately. In addition, the position can be determined by means of the at least one coil, which is already present in the electromagnetic actuator, so that costs, space and components can be saved. The electromagnetic actuator can thus provide the functions of the actuator as well as the position detection of its armature.

According to an embodiment, wherein the electromagnetic actuator comprises a first coil and a second coil, in the step of demagnetizing the sequence of electrical current pulses can be passed through the series connection of the first coil and the second coil. Also, in the step of determining the measuring current pulse can be passed through the series circuit of the first coil and the second coil. The first coil and the second coil can be connected in series. Such an embodiment of the present invention has the advantage that a movement of the movable armature can be carried out more effectively and a determination of the position of the movable armature can be made even more accurate.

According to a preferred embodiment of the invention, the electromagnetic actuator is a vehicle actuator, in particular a land-bound vehicle. Of course, however, the method according to the invention can also be used with other suitable electromagnetic actuators, for example in the case of an actuator of an aircraft, a vessel or a stationary device. Furthermore, the electromagnetic actuator may be a transmission actuator, i. an actuator that causes the execution of functions of a transmission, such as the coupling or decoupling of transmission shafts and / or gears causes. Here, the execution of the function of the transmission, which causes the actuator is monitored simply and reliably based on the determined in the context of the method according to the invention position of the movable armature.

In a particularly preferred embodiment of the invention, the actuator is a transmission actuator of a multiple-speed automated gearbox. Bes. By means of the actuator is in particular a selection of a shift gate of the automated transmission and / or an insert or lay out of the gear in the selected shift gate. In this case, the currently engaged gear or the currently selected shift gate of the automated gearbox is detected simply and reliably on the basis of the determined in the inventive method position of the movable armature.

The invention will be explained in more detail below with reference to the accompanying drawings by way of example. Show it:

Figures 1 to 3 are schematic representations of electromagnetic actuators;

Fig. 4 is a schematic hysteresis diagram;

Fig. 5 is a schematic hysteresis diagram associated with an embodiment of the present invention;

Fig. 6 is a Bestromungsdiagramm in connection with an embodiment of the present invention; and

7 is a flow chart of a method according to an embodiment of the present invention.

In the following description of preferred embodiments of the present invention, the same or similar reference numerals are used for the elements shown in the various figures and similarly acting, wherein a repeated description of these elements is omitted.

FIG. 1 shows a schematic representation of an electromagnetic actuator 100. The electromagnetic actuator 100 has a first coil 110, a second coil 120, a movable armature 130 and a connecting rod 135. The structure of such an electromagnetic actuator 100 is well known to a person skilled in the art and is therefore only briefly explained here. The first coil 110 and the second coil 120 surround a movement space of the movable armature 130. The movable armature 130 is formed to move in the movement space. The movement space is designed to allow a defined movement of the movable armature 130. Thus, windings of the first coil 110 and windings of the second coil 120 surround the movement space of the movable armature 130. The movement space can have a main axis extending through the first coil 110 and the second coil 120. In the illustration of FIG. 1, the movable armature 130 is partially surrounded by the first coil 110 and partially surrounded by the second coil 120. The first coil 110 is laterally spaced from the second coil 120. The connecting rod 135 is connected to the movable armature 130. The connecting rod 135 extends out of a housing of the electromagnetic actuator 100 out. The connecting rod 135 may be connected to a movable member outside the electromagnetic actuator 100.

FIG. 2 shows a schematic representation of a further electromagnetic actuator 200. The electromagnetic actuator 200 corresponds to the electromagnetic actuator of FIG. 1, with the exception that the electromagnetic actuator 200 shown in FIG. 2 additionally has a first permanent magnet 240 and a second permanent magnet 250 and that the connecting rod 135 is connected to two sides of the movable armature 130. In addition, in Fig. 2, a housing of the electromagnetic actuator 200 is shown in more detail. Thus, for example, in FIG. 2, the movement space of the movable armature 130 is shown explicitly. The movable armature 130 is received in the movement space. The movable armature 130 can move in the movement space between a first end and a second end of the movement space. The first permanent magnet 240 and the second permanent magnet 250 are disposed between the first coil 110 and the second coil 120. The movement space is arranged between the first permanent magnet 240 and the second permanent magnet 250. Thus, the first permanent magnet 240 and the second permanent magnet 250 are arranged opposite each other across the movement space. The connecting rod 135 extends out of the electromagnetic actuator 200 at the first end of the moving space and extends out of the electromagnetic actuator 200 at the second end of the movement space. The connecting rod 135 is received and guided at both ends of the moving space in the housing of the electromagnetic actuator 200.

Fig. 3 shows a schematic representation of an electromagnetic actuator. Specifically, Fig. 3 is a schematic circuit diagram of an electromagnetic actuator. Of the electromagnetic actuator in Fig. 3, only the first coil 1 10 and the second coil 120 are shown as a block diagram and four switching devices. The electromagnetic actuator may be one of the electromagnetic actuators of FIG. 1 or FIG. 2. The coils 1 10, 120 are, as shown in Fig. 3, connected in series. The series connection is integrated in an H-bridge. For example, a single one of the switching devices shown in FIG. 3 may include a metal oxide semiconductor field effect transistor (MOSFET) or the like. The switching devices comprise a first high-side switching device Hss1, a second high-side switching device Hss2, a first low-side switching device Lssl and a second low-side switching device Lss2. The first high-side switching device Hss1 and the second high-side switching device Hss2 are connected in the current flow direction of the series connection of the coils 1 10, 120. The first low-side switching device Lssl and the second low-side switching device Lss2 are connected in the current flow direction of the series connection of the coils 1 10, 120 downstream. By selectively closing and opening the MOSFETs or switching devices, the direction of a current flow through the coils 1 10, 120 can be adjusted. The electric current builds up a magnetic field which causes positioning of the armature (not shown in FIG. 3). The operation of such an H-bridge is well known in the art and will therefore not be discussed further here.

Fig. 4 shows a schematic hysteresis diagram. In the case of ferromagnetic materials, there is a relationship between magnetic field strength H and flux density B. This relationship is described by the hysteresis diagram in FIG. The magnetic field strength H is in this case plotted on the abscissa axis and the flux density B is plotted on the ordinate axis. The connection between magnetic field strength H and flux density B is nonlinear. In Fig. 4, a plurality of hysteresis loops are shown. Magnetic hysteresis and associated hysteresis diagrams are known to one skilled in the art and therefore will not be described again here.

Fig. 5 shows a schematic hysteresis diagram in connection with an embodiment of the present invention. Similar to FIG. 4, FIG. 5 also shows the relationship between magnetic field strength H and flux density B. In this case, the magnetic field strength H is plotted on the abscissa axis and the flux density B is plotted on the ordinate axis. Shown are a first operating point 51 1 without passing through hysteresis loops, a second operating point 512 without passing through hysteresis loops, an operating point 513 after passing through hysteresis loops, a first hysteresis loop 521, a second hysteresis loop 522 and a third hysteresis loop 523.

The relationship between magnetic field strength H and flux density B is nonlinear. Without the hysteresis loops, the hysteresis curve, starting from a maximum of positive magnetic field strength H and positive flux density B in the first quadrant of the Cartesian coordinate system, runs non-linearly in a first curve section to a maximum of negative magnetic field strength H and negative flux density B in the third quadrant of the Cartesian coordinate system. The hysteresis curve cuts the ordinate axis at the first operating point 51 1 without hysteresis loops in the positive intercept. From the maximum of negative magnetic field strength H and negative flux density B, the hysteresis curve runs nonlinearly in a second curve section different from the first curve section back to the maximum of positive magnetic field strength H and positive flux density B. However, the hysteresis curve cuts the ordinate axis at second operating point 512 without Hysteresis loops in the negative intercept.

The first hysteresis loop 521 begins at the first curve portion in the third quadrant and is nonlinear and closer to the origin of the coordinate system than the first curve portion to a first remagnetization point in the first quadrant. The second hysteresis loop 422 extends from the first Ummag- netting point in the first quadrant non-linear up to a second remagnetization point in the third quadrant. The third hysteresis loop 523 extends non-linearly from the second remagnetization point to the origin of the coordinate system. Thus, at the origin of the coordinate system is the operating point 513, which results when using the hysteresis loops. In practice, the number of hysteresis loops may differ from that shown in FIG.

An ideal operating point 513, which has as little or no dependency on the history and temperature, adjusts itself with the lowest possible flux density B and is realized in FIG. 5 at the origin of the diagram. To minimize the flux density B to this operating point 513, demagnetization is used. For demagnetization, a drive algorithm or drive method is realized which will be explained in more detail with reference to FIG. This drive algorithm is used in an embodiment of a method according to the present invention described in FIG. 7. The drive pursues the goal of gradually lowering the magnetic flux density B of a ferromagnetic material of the electromagnetic actuator to the origin through a plurality of hysteresis loops 521, 522, 523. In FIG. 5, by way of example, three such hysteresis loops 521, 522, 523 are represented symbolically.

Fig. 6 shows a Bestromungsdiagramm in connection with an embodiment of the present invention. Shown are an electric current I on the ordinate axis over the time t of the abscissa axis. Shown are an energization phase 610 for movement, a first hysteresis loop 621, a second hysteresis loop 622, a third hysteresis loop 623, and a first sensing cycle 630. The energization diagram in FIG. 6 results from an activation of an electromagnetic actuator, such as one of in FIG Figures 1 to 3 shown. In this case, the electric current I is applied to the at least one coil of the electromagnetic actuator. For demagnetization, a drive algorithm or drive method is implemented using the hysteresis loops 621 to 623, which will be explained in more detail with reference to FIG. 7. This drive algorithm is used in an embodiment of a method according to the present invention described in FIG. 7. In the energization phase 610 for movement, a high positive electric current is applied to move a movable armature of the electromagnetic actuator. The electric current I has in the energization phase 610 an increase to a saturation value which is maintained for a certain period of time. In doing so, the electric current I can oscillate around the saturation value. At the end of the energization phase 610, the electric current I is lowered to zero. During the first hysteresis loop 621, a negative electrical current pulse is applied. An amplitude in the first hysteresis loop is less in magnitude than the saturation value during the energization phase 610. In the second hysteresis loop 623, a positive electrical current pulse is applied with an amplitude that is lower in magnitude than during the first hysteresis loop 621. In the third hysteresis loop 623, a negative electric current pulse having a magnitude smaller amplitude is applied than during the second hysteresis loop 622. Subsequent to the third hysteresis loop 623, in a first sensing cycle 630, a positive measuring current pulse is applied having an amplitude that is smaller in magnitude than the amplitude during the third hysteresis loop 621. After the first sensing cycle 630, further sensing cycles may be followed by further positive measuring current pulses, for example of the same amplitude.

FIG. 7 shows a flowchart of a method 700 according to an embodiment of the present invention. The method 700 is a method 700 for driving an electromagnetic actuator having at least one coil and a movable armature. The method 700 includes a step of demagnetizing 710 the electromagnetic actuator by directing a train of current pulses from current pulse to current pulse alternating current direction and from current pulse to current pulse decreasing current through the at least one coil to reduce a remanent flux density in the electromagnetic actuator or to eliminate. The method 700 also includes a step of determining 720 a position of the movable armature by passing a measuring current pulse through the at least one coil subsequent to the step of demagnetizing 710. The method 700 can be advantageously carried out in conjunction with one of the electromagnetic actuators of one of FIGS. 1 to 3. There- an implementation of method 700 may result in a hysteresis diagram such as that illustrated in FIG. In the method, a current supply similar to that shown in Fig. 6 can be used.

With reference to FIGS. 1 to 7, an activation of an electromagnetic actuator with demagnetization before the position determination according to the exemplary embodiment in the present invention will be explained in the following in summary form. The control algorithm 710 for the hysteresis loops 51 1 to 513 and 61 1 to 613 should always be used before a position measurement 720 or the first sensing cycle 630. The timing is therefore such as shown schematically in FIG. For demagnetization 710, the same hardware is used, which also serves to drive 610 when moving. In this case, it is waited for energization 610 until the current is extinguished, and then the current through the first coil 1 10 and the second coil 120 is sent alternately and with a smaller and smaller amplitude. It will thus go through several hysteresis loops. A hysteresis loop (s) shown in FIG. 6 is / are based on a lighting cycle. By a selective selection of amplitude and number of cycles, the method 700 can be optimized for any actuator. In addition to the energizing lengths, which influence the current amplitude, the waiting time or extinguishing time, until the current is at zero, can also be adapted. After passing through the last hysteresis loop 513 or 613 and thus the demagnetization, the first position determination can begin by the first sensing cycle 630.

The embodiments described and shown in the figures are chosen only by way of example. Different embodiments may be combined together or in relation to individual features. Also, an embodiment can be supplemented by features of another embodiment. REFERENCE CHARACTERS

100 electromagnetic actuator

1 10 first coil

120 second coil

130 movable anchor

135 connecting rod

200 electromagnetic actuator

240 first permanent magnet

250 second permanent magnet

Hss1 first high-side switching device

Hss2 second high-side switching device

Lss1 first low-side switching device

Lss2 second low-side switching device

51 1 first operating point without hysteresis loops

512 second operating point without hysteresis loops

513 operating point with hysteresis loops

521 first hysteresis loop

522 second hysteresis loop

523 third hysteresis loop

610 energizing phase for movement

621 first hysteresis loop

622 second hysteresis loop

623 third hysteresis loop

630 first sensing cycle

700 method for driving

710 Demagnetizing step

720 step of determining

Claims

claims

1 . A method (700) for driving an electromagnetic actuator (100; 200) comprising at least one coil (110, 120) and a movable armature (130), the method (700) comprising the steps of:

Demagnetising (710) the electromagnetic actuator (100; 200) by passing a sequence of electric current pulses (521, 522, 523; 621, 622, 623) with current direction alternating current pulse to current pulse and current decreasing from current pulse to current pulse through the at least one a coil (110, 120) for reducing or eliminating a remanent flux density in the electromagnetic actuator (100; 200); and

- determining (720) a position of the movable armature (130) by passing a measuring current pulse (630) through the at least one coil (1 10, 120) following the step of demagnetizing (710).

2. Method (700) according to claim 1, characterized in that in the step of demagnetizing (710) a first electric current pulse (521; 621) having a first current direction and a first current strength, and a subsequent second electric current pulse (522 622) having a second current direction different from the first current direction and a second current intensity lower than the first current through which at least one coil (110, 120) is passed.

3. Method (700) according to claim 2, characterized in that in the step of demagnetizing (710) at least one further electrical current pulse (523; 623), which has an opposite current direction and a lower current strength with respect to an immediately preceding current pulse, through which at least a coil (1 10, 120) is passed.

4. Method (700) according to one of the preceding claims, characterized in that in the demagnetizing step (710) the sequence of electric current pulses (521, 522, 523; 621, 622, 623) reduces a current flow duration decreasing from current pulse to current pulse through the coil.

A method (700) according to any one of the preceding claims, characterized in that in the step of determining (720) a current strength of the measuring current pulse (630) is less than a lowest one of the current pulses of the current pulses (521, 522, 523; 621, 622, 623) from the demagnetizing step (710).

A method (700) according to any one of the preceding claims, characterized by a step of directing a moving current pulse (610) through the at least one coil (110, 120) to effect movement of the armature (130), wherein a current of the Moving current pulse (610) is greater than a maximum of the current intensities of the current pulses (521, 522, 523, 621, 622, 623) from the demagnetizing step (710).

The method (700) according to claim 6, characterized in that the step of demagnetizing (710) is performed after the step of conducting and before the step of determining (720).

8. Method (700) according to one of the preceding claims, characterized in that, in the step of determining (720), a reaction of the at least one coil (110, 120) on the movable armature (130) in the measuring current pulse (630) is evaluated to determine the position of the movable armature (130).

9. Method (700) according to one of the preceding claims, wherein the electromagnetic actuator (200) has a first coil (1 10) and a second coil (120), characterized in that in the demagnetizing step (710) the sequence of electrical Current pulses (521, 522, 523, 621, 622, 623) are passed through a series connection of the first coil (110) and the second coil (120), and in the step of determining (720) the measuring current pulse (630) through the series circuit from the first coil (1 10) and the second coil (120) is passed.

10. A driving device for driving an electromagnetic actuator (100; 200), the at least one coil (1 10, 120) and a movable armature (130), characterized in that the drive device comprises means which are adapted to the Steps of the method (700) according to one of the preceding claims.