DE10348569A1 - Device for triggering actuator, e.g. for electronic lock cylinder, has receiver unit via which energy for charging energy storage device can be delivered; energy fed to receiver unit is converted into voltage - Google Patents

Abstract

The device has an energy storage device (7) for supplying the actuator (3), a receiver unit (2) for contactless reception of a control signal and a control unit (8) for feeding energy to the actuator depending on the control signal. Energy for charging the energy storage device can be delivered via the receiver unit. The energy fed to the receiver unit is converted into a voltage. Independent claims are also included for (A) a system with a transmitter, a controller and an actuator (B) and a method of triggering an actuator.

Description

The The invention relates to a device for driving an actuator. Furthermore, the invention relates to a system of such Device, an actuator and a transmitter and a method for driving an actuator.

It is already known, the activation of actuators on contactless Way to trigger. Such actuators, for example, in electronic lock cylinders used. In this application, the actuator is designed as a closing magnet, which is controlled by an electronic circuit. The electronic Circuit receives their control commands over an antenna. As an energy source for the operation of electronic Circuit and the closing magnet serves a built-in electronic lock cylinder battery. To This principle can be very high quality electronic lock cylinder realize. However, there is a risk that an electronic lock cylinder its services fail because the battery is not adequately charged has more. This can also occur in applications where the closing magnet is relatively rarely activated, since the electronic circuit incessantly Consumes energy and thereby gradually discharges the battery.

Farther is it from Klaus Finkenzeller, RFID manual, 3rd edition (2002) Pages 81-85 known, the supply voltage of a transponder to a constant To regulate value. The transponder is an electronic circuit arrangement, which exchanges data with a communication partner in a contactless way. Of the Transponder can be designed so that it can be used for his Operation required supply voltage by means of a coil, the also for the data transmission is used from the for the data transmission relates generated field. To control the supply voltage can the transponder have a shunt regulator with which by switching a variable resistor in parallel to the coil of the transponder the goodness the resonant circuit and thus set the supply voltage of the transponder can be.

Finally is it known, electrical appliances, for example, an electric toothbrush, by a contactless Charge coupling with a charger. For the business becomes such a device removed from the charging device and arranged by means of a device Switched on manually.

Of the Invention is based on the object, a contactless release of Activation of an actuator in the simplest and most reliable way to enable.

These Task is solved by the combination of features of claim 1.

The inventive device for driving an actuator has an energy storage for feeding the actuator, a receiving unit for contactless receiving a Control signal and a control unit for controlling the power supply depending on the actuator from the control signal. The peculiarity of the device according to the invention is that over the receiving unit can be supplied with energy for charging the energy store.

The Invention has the advantage that only an energy storage with a relatively small capacity is necessary for a single activation of the actuator is sufficient. Another Advantage is the high reliability of the device according to the invention, resulting from the fact that the energy storage are charged via the receiving unit can, so easily always a sufficient amount of energy for the Activation of the actuator can be provided and the risk of a inoperability does not exist because of an insufficiently charged energy storage. moreover deleted the required battery change in known devices. Finally is It is still beneficial that even actuators with high power consumption can be operated for a short time.

The energy supplied to the receiving unit can be converted into a voltage. It is advantageous if a first current path for a first partial current for at least temporary control of the voltage to a default value is formed. This makes it possible, for example, to supply the control unit with this regulated voltage. In a preferred embodiment of the device according to the invention, a second current path for a second partial current for charging the energy store is formed. The first current path and / or the second current path can run parallel to the control unit. Furthermore, a control circuit may be provided, which regulates the voltage to the default value by a coordinated influencing of the first current path and the second current path. In particular, the two current paths are each influenced in such a way that a second partial current flowing through the second current path assumes a maximum possible value under the respective operating conditions. This has the advantage that optimal charging of the energy storage possible is, without departing from the standard value at the regulated voltage. A further advantage is that the excess energy to be dissipated for the regulation of the voltage to the default value is at least temporarily supplied wholly or partly to the energy store and thus is not released in the form of heat. The first current path and / or the second current path can each be influenced by means of a controllable resistor, in particular a transistor.

at a particularly cost-effective embodiment the device according to the invention are a variety of components as an integrated circuit realized, an interface for contactless data transmission having. Such a circuit has particularly small dimensions and can therefore be used in many ways.

Around one possible good availability of energy storage for To achieve the activation of the actuator, it is advantageous if the energy store exclusively Supply of the actuator and not supply of the management unit serves.

at an advantageous embodiment of the device according to the invention the energy storage is at a higher voltage than the supply voltage the control unit charged. This will make the uses the device according to the invention considerably expanded. To the control unit despite the increased voltage operate properly to be able to For example, a voltage converter can be used to increase the voltage to that for the energy store required Value or to reduce the voltage to that of the control unit required Be provided value.

at a development of the device according to the invention is the receiving unit a component of the actuator. This has the advantage that the number reduces the individual components and thus the cost of production the device according to the invention is reduced accordingly.

The Actuation of the actuator can via a Connection device for establishing a temporary connection take place between the energy store and the actuator.

The inventive system has in addition to the control device according to the invention a transmitting device and an actuator, wherein the actuator dependent on the control device from a contactless transmitted Control signal of the transmitting device can be controlled.

At the inventive system may be a tuned to the controller programming device be provided for programming the transmitting device. In one advantageous embodiment the transmitting device is part of a mobile terminal. Of the Actuator may for example be part of a locking device.

At the inventive method for driving an actuator with a control device is a Control signal contactlessly transmitted to the control device and the actuator depends on Control signal connected to an energy store of the control device. The peculiarity of the method according to the invention is that the control device in a contactless way energy for charging supplied to the energy storage becomes.

The Invention will be described below with reference to the drawing Embodiments explained.

It demonstrate:

1 a schematic diagram of the device according to the invention,

2 a circuit diagram for a first embodiment of the device according to the invention,

3 a circuit diagram for a second embodiment of the device according to the invention,

4 a circuit diagram for a third embodiment of the device according to the invention,

5 a schematic diagram of a development of the device according to the invention and

6 a simplified block diagram of an embodiment of the system according to the invention.

1 shows a schematic diagram of the device according to the invention. The device has a circuit arrangement 1 on, to the one antenna coil 2 connected. Instead of an antenna coil 2 can any other suitable receiving unit 2 , such as a printed antenna. With the device according to the invention is an actuator 3 controlled, the purpose of this with the circuitry 1 connected is. At the actuator 3 it may, for example, be a closing magnet or any other optical, acoustic, electrothermal, electrochemical, thermomechanical, electromechanical, electromagnetic, etc. device which, due to its high energy consumption or because of its high inrush current, is not directly from the antenna coil 2 can be fed.

The circuit arrangement 1 has a rectifier 4 on, on its AC side with the antenna coil 2 connected is. The rectifier 4 is a charging circuit on its DC side 5 downstream, the output side via a switch 6 with a capacitor 7 can be connected. Alternative to the charging circuit 5 can the capacitor 7 over the switch 6 with the actuator 3 get connected. The switching state of the switch 6 is from a transponder circuit 8th controlled by the charging circuit 5 is connected in parallel.

The charging circuit 5 has a control circuit 9 on, connected to the DC side of the rectifier 4 is connected and a first variable resistor 10 and a second variable resistor 11 controls. The first variable resistor 10 is the DC side of the rectifier 4 connected in parallel. The second controllable resistor 11 connects one of the terminals of the DC side of the rectifier 4 over a diode 12 with the switch 6 ,

The inventive device is based on the following operation: The antenna coil 2 is exposed to an alternating magnetic field that is caused by an in 1 not shown transmitter is generated. This will be in the antenna coil 2 a voltage induced by the rectifier 4 is rectified. The magnetic alternating field can be formed, for example, in the frequency range at 13.56 MHz. The field strength of the alternating magnetic field varies depending on the distance of the transmitter from the antenna coil 2 , In a corresponding manner, the induced voltage and the rectified voltage produced therefrom also vary, among other things, the supply of the transponder circuit 8th serves. In order to obtain a constant supply voltage, the rectified voltage from the control circuit 9 regulated to a constant default value. The control circuit controls this 9 the two variable resistors 10 and 11 such that the rectified voltage assumes the desired default value. It flows through the two variable resistors 10 and 11 altogether a current Is, which at the in 1 shown first switching state in which the switch 6 the diode 12 with the capacitor 7 connects, from a first partial current I1 through the first variable resistor 10 and a second partial current I2 through the second variable resistor 11 composed. The current Is is from the control circuit 9 each regulated to a value which is required for setting the rectified voltage to the desired default value. Consequently, the current Is is forcibly determined and can not be freely selected. However, the division of the current Is into the partial currents I1 and I2 can be chosen freely.

In the context of the invention, the distribution of the current Is in the partial currents I1 and I2 is made so that the second partial current I2 is as large as possible to the capacitor 7 charge as fast as possible. For this purpose, the first controllable resistance 10 initially set to an infinite value and the second variable resistor 11 be controlled so that the second partial current I2 corresponds to the required for the regulation of the default value for the rectified voltage current Is. With increasing charging of the capacitor 7 becomes the second variable resistor 11 set to a smaller and smaller value. As soon as the second adjustable resistor 11 has reached its minimum value, it is also necessary to know the value of the first variable resistor 10 to keep the rectified voltage still constant at the default value. Accordingly, the second partial current I2 decreases and the first part of the current I1. In this way you can charge the capacitor 7 each time to be reduced to a minimum possible under the given conditions. How long this time really is, depends crucially on the field strength of the alternating magnetic field in the area of the antenna coil 2 since this determines the induced voltage and thus also the current Is needed to adjust the standard value for the rectified voltage. The current Is in turn is a maximum as a second partial current I2 for charging the capacitor 7 to disposal. At a high field strength, only a short charging time is needed. With a low field strength, the charging process takes longer.

When the capacitor 7 has a sufficient state of charge, the switch 6 from the transponder circuit 8th be switched to a second switching state and thereby the capacitor 7 over the actuator 3 be discharged. It can be a significant part of the capacitor 7 slowly supplied charge can be released in a relatively short time and through this energy supply the actuator 3 to be activated. As a result, for example, in an embodiment of the actuator 3 as a closing magnet, the opening of a door can be effected. The command to activate the actuator 3 the device according to the invention is transmitted via the alternating magnetic field from which the device also receives its supply voltage. For this purpose, the alternating magnetic field is modulated accordingly, for example by means of an ASK modulation. ASK stands for "amplitude shift keying" and means that the amplitude of the alternating magnetic field is transposed between two values in time with the data to be transmitted, and that in the antenna coil varies accordingly 2 induced voltage. To prevent the capacitor 7 a voltage in the Transponderschal device 8th feeds and thereby that of the transponder circuit 8th received modulated signal falsified, is the diode 12 intended.

The transponder circuit 8th may be configured as a hard-coded state machine or as a microprocessor with appropriate software. Depending on the security requirement, the evaluation of the activation command by the transponder circuit 8th be very simple or include, for example, an authentication. In any case, the activation of the actuator 3 at a well-defined time. The operation of the transponder circuit 8th is due to the inventive use of excess energy removed from the alternating magnetic field for charging the capacitor 7 not impaired, so that, for example, at any time an unrestricted communication with the transponder circuit 8th is possible.

2 shows a circuit diagram for a first embodiment of the device according to the invention. In this embodiment, the transponder circuit is 8th is designed as a dual-interface chip which is used in chip cards and has a contactless interface and a contact interface. At the contactless interface of the transponder circuit 8th is the antenna coil 2 connected. With the contact interface, a self-locking transistor 13 be driven, the capacitor in the driven state 7 with the actuator 3 connects, so that the capacitor 7 over the actuator 3 can discharge. Without drive signal is the transistor 13 blocked. Furthermore, in the first embodiment, a rectifier diode 14 provided between the capacitor 7 and the contactless interface of the transponder circuit 8th is arranged and thereby in addition to their rectification function, a reaction of the capacitor 7 on the transponder circuit 8th prevented.

The first embodiment of the device according to the invention is very simple and has no way, the second partial stream I2, with which the capacitor 7 is charged to settle. This results in the supply voltage assuming very small values at the beginning of the charging process due to the very large second partial current I2, and thus initially insufficient, the transponder circuit 8th to operate. The transponder circuit 8th is thus at largely discharged capacitor 7 not immediately from the time when the antenna coil 2 an alternating magnetic field is exposed, ready for use. Only when a certain state of charge of the capacitor 7 is reached and the second partial current I2 has decreased accordingly, is a sufficient supply voltage for the operation of the transponder circuit 8th ready. However, this time delay is not very serious in practice, as activation of the actuator 3 anyway only possible when the capacitor 7 has a sufficient state of charge. Once the transponder circuit 8th is ready, it evaluates those of the antenna coil 2 received signals and controls the transistor 13 through to the actuator 3 with the help of the capacitor 7 to activate if there is an activation command.

3 shows a circuit diagram for a second embodiment of the device according to the invention. This embodiment provides a 1: 1 conversion of the in 1 All presented in 1 shown circuit components are also present in the second embodiment and interconnected in a corresponding manner. Here are the first controllable resistance 10 and the second adjustable resistor 11 as transistors formed by the control circuit 9 be controlled. The desk 6 is by two alternately conducting transistors 15 and 16 realized, both from the transponder circuit 8th be controlled. Here is the transistor 15 designed to be self-conducting and connects in the non-activated state, the capacitor 7 with the diode 12 , The transistor 16 is self-locking and connects in the driven state, the capacitor 7 with the actuator 3 , As an additional element, the principle of the 1 is not present, in the second embodiment, a connection 27 between the connection side of the capacitor 7 at the two transistors 15 and 16 are connected, and the transponder circuit 8th provided via which the transponder circuit 8th the state of charge of the capacitor 7 can query. It is also possible by means of a query command the state of charge of the capacitor 7 via the reader to query.

By appropriate control of the transistors 15 and 16 by means of the transponder circuit 8th can the capacitor 7 either for charging with the diode 12 or for unloading with the actuator 3 get connected. Specifically, the control is such that for charging the capacitor 7 the transistor 16 locked and the transistor 15 is switched through. To activate the actuator 3 by discharging the capacitor 7 first becomes the transistor 15 locked and then the transistor 16 connected through. Is the activation of the actuator 3 when the charging of the capacitor is not completed yet 7 , then the transistors 15 and 16 switched to a time at which the partial current I2 is greater than zero. This can cause voltage spikes and unwanted fluctuations in the supply voltage of the transponder circuit 8th have as a consequence. To avoid this, can be the abrupt switching of the transistor 15 be replaced by a soft transition, in which the transistor 15 is so controlled that its resistance slowly increases to the locked state. The time scheduled for the transition is chosen so that the control circuit 9 is capable of correcting the partial current I1 accordingly, thereby largely preventing voltage spikes and overshoots.

4 shows a circuit diagram for a third embodiment of the device according to the invention. This embodiment is characterized in that the actuator 3 is operated at a higher voltage than the supply voltage of the transponder circuit 8th equivalent. For this purpose, in addition to the second embodiment, a voltage multiplier 17 provided between the rectifier 4 and the transistor 11 the charging circuit 5 is switched and the voltage multiplied by a factor of n. Accordingly, the second partial current I2 is reduced to a fraction 1 / n. The transistor 11 is directly with the transistor 15 connected. For the supply of the other components of the charging circuit 5 and for the supply of the transponder circuit 8th is a rectifier 18 provided on its AC side as well as the rectifier 4 with the antenna coil 2 connected is. Otherwise corresponds to the circuit structure in 3 illustrated second embodiment.

The third embodiment thus has a first circuit part, which consists of the rectifier 4 is fed and with a through the voltage multiplier 17 n-fold increased voltage is operated. The increased voltage will charge the capacitor 7 used, wherein the charging current is reduced because of the voltage increase to the fraction 1 / n of the second partial stream I2. The charging current is connected to the transistor 11 regulated and with the transistor 15 to the condenser 7 connected through. The connection of the capacitor 7 to the actuator 3 takes place according to the second embodiment with the transistor 16 , being attached to the actuator 3 However, a higher voltage is applied because of the capacitor 7 was charged with the increased voltage. Furthermore, the third embodiment has a second circuit part, which consists of the rectifier 18 is fed and with the of the transponder circuit 8th required supply voltage is operated. In addition to the transponder circuit 8th belong to the control circuit 9 and the transistor driven thereby 10 , with which the first partial current I1 is regulated, to the second circuit part. The control circuit 9 controls the voltage applied to the second circuit part supply voltage of the transponder circuit 8th to the default value, wherein in each case the voltage actually applied to the second circuit part is used as the actual value for the control.

For the functionality of the third embodiment, it is immaterial whether the partial currents I1 and I2 occur in the first or in the second circuit part. Decisive for the quality of the antenna coil 2 formed resonant circuit and thus for in the antenna coil 2 induced voltage is the sum of the partial currents I1 and I2 in the overall circuit.

In a modification of the third embodiment is with the control circuit 9 through the voltage multiplier 17 increased supply voltage regulated and the increased supply voltage in turn to charge the capacitor 7 used. The transponder circuit 8th Then a voltage reduction circuit is connected in order to operate properly. As Spannungsreduzierungsschaldung a clocked capacitor circuit is preferably used for lossless voltage reduction. Likewise, it is also possible to use a lossy series control in the form of a controllable series resistance.

5 shows a schematic diagram of a development of the device according to the invention. The peculiarity of this development is compared with 1 in that the antenna coil 2 also as an actuator 3 is used. This will be a few hundred turns of wire 19 on a ferrite rod 20 wound. Near the ferrite bar 20 becomes a ferromagnetic body 21 arranged at a sufficiently high current flow through the wire turns 19 from the ferrite rod 20 magnetically attracted. This current flow is using the capacitor 7 generated. The wire turns 19 and the ferrite rod 20 thus serve on the one hand in combination with the ferromagnetic body 21 as an actuator 3 , On the other hand serve the wire turns 19 and the ferrite rod 20 as an antenna coil 2 , The thus formed antenna coil 2 is typically operated in the frequency range around 125 kHz. Here is the antenna coil 2 as another resonant circuit element, an additional capacitor 22 connected in parallel. From the in 1 illustrated device differs according to the training 5 still in that in addition to the switch 6 another switch 23 is provided in common with the switch 6 from the transponder circuit 8th is controlled. The desk 6 and the switch 23 are each a connection side of the capacitor 7 connected and connect the capacitor 7 in a first switching state for charging with the charging circuit 5 and in a second switching state for activating the actuator 3 with the wire turns 19 , The other wiring and operation of the training according to 5 correspond to the in 1 illustrated device.

6 shows a simplified block diagram ment of an embodiment of the system according to the invention. A component of the system according to the invention is the actuator 3 that with the circuitry 1 connected is. To the circuit arrangement 1 which, according to one of the 1 to 5 may be formed, is still the antenna coil 2 connected. In addition, the system according to the invention has a transmitter 24 on, to the one antenna coil 25 is connected and that of a battery 26 or a different type of energy source. The transmitter 24 not only can send data but also receive data and is inclusive of the antenna coil 25 For example, in a mobile terminal, such as a mobile phone, a laptop, a PDA, etc. installed. In this case the transmitter does not need its own battery 26 but can be powered by the battery of the mobile terminal. Alternatively, the transmitter 24 be arranged in other devices or be designed as a standalone device.

The system according to the invention is based on the following functional principle:
The antenna coil 25 the transmitter 24 Will the with the circuitry 1 connected antenna coil 2 approximated. Before, during or after the approach becomes the transmitter 24 activated. With the help of the antenna coil 25 the transmitter 24 on the antenna coil 2 the circuit arrangement 1 transmitted energy becomes the capacitor 7 the circuit arrangement 1 charged. Optionally, the triggering of the actuator 3 an authentication between the sender 24 and the transponder circuit 8th the circuit arrangement 1 precede. With the aid of the data also transmitted during the energy transmission, the transponder circuit 8th the capacitor 7 to the actuator 3 by turn. Already before the transmission of the data or before the authentication of the circuit arrangement 1 Identification data to the sender 24 transmitted by an associated application in the transmitter 24 automatically starts to the user of the transmitter 24 to facilitate the operation. If the actuator 3 For example, is designed as a closing magnet of a batteryless door opener, the door opener can be operated in this way. The actuator 3 can also be integrated into a bicycle lock, a padlock or other mechanical locking device, etc. In all cases, high availability is given in the system according to the invention, since the capacitor 7 each immediately before activation of the actuator 3 is charged.

As in the activation of the actuator 3 Safety aspects may play a role, for example in connection with an electric door opener, are the transmitter 24 and the circuit arrangement 1 so that the activation of the with the circuit arrangement 1 controlled actuator 3 exclusively with the dedicated transmitter 24 is possible. For this purpose, the circuit arrangement 1 be initialized accordingly, wherein the same initialization is transferred to a programming card, which together with the circuitry 1 is delivered. With the help of the programming card, one can cause activation of the actuator 3 required application and a secret to perform the authentication and activation of the actuator 3 is needed on the transmitter 24 be transmitted.

In a modification of the device according to the invention, instead of the capacitor 7 a battery or other device used to store electrical charge.

In addition to the already mentioned door opener application, the device according to the invention can also be used, for example, as an implantable transponder, in particular in a sterile envelope for medical purposes. In this case, the actuator 3 as a miniature pump, dosing device or membrane z. B. for the dosage of drugs. If necessary, the actuator 3 be put into operation from the outside. In this case, abuse by unauthorized persons can be prevented by authentication.

Claims (24)

Device for driving an actuator ( 3 ), with an energy store ( 7 ) for feeding the actuator ( 3 ), a receiving unit ( 2 ) for contactless receiving a control signal and a control unit ( 8th ) for controlling the power supply to the actuator ( 3 ) depending on the control signal, characterized in that via the receiving unit ( 2 ) Energy for charging the energy store ( 7 ) can be fed. Apparatus according to claim 1, characterized in that the receiving unit ( 2 ) supplied energy is converted into a voltage. Device according to claim 2, characterized in that that a first current path for a first partial flow (I1) for at least temporary control of Voltage is formed to a default value. Device according to one of the preceding claims, characterized in that a second current path for a second partial current (I2) for charging the energy store ( 7 ) is trained. Device according to one of claims 3 or 4, characterized in that the first current path and / or the second current path parallel to the STEU unit ( 8th ). Device according to one of claims 3 to 5, characterized in that a control circuit ( 9 ) is provided, which regulates the voltage to the default value by a coordinated influencing of the first current path and the second current path. Device according to claim 6, characterized in that that the two current paths are each influenced so that the second partial flow (I2) flowing through the second current path a maximum possible under the respective operating conditions Takes value. Device according to one of claims 3 to 7, characterized in that the first current path and / or the second current path in each case by means of a variable resistor ( 10 . 11 ), in particular of a transistor. Device according to one of the preceding claims, characterized characterized in that a plurality of components as an integrated Circuit are realized and the integrated circuit an interface for contactless data transmission having. Device according to one of the preceding claims, characterized in that the energy store ( 7 ) excluding the supply of the actuator ( 3 ) and not the supply of the control unit ( 8th ) serves. Device according to one of the preceding claims, characterized in that the energy store ( 7 ) to a higher voltage than the supply voltage of the control unit ( 8th ) is charged. Device according to claim 11, characterized in that a voltage transformer ( 17 ) is provided for increasing the voltage to that for the energy storage ( 7 ) value or to reduce the voltage to that of the control unit ( 8th ) required value. Device according to one of the preceding claims, characterized in that the receiving unit ( 2 ) a component of the actuator ( 3 ). Device according to one of the preceding claims, characterized in that a connecting device ( 6 . 13 . 15 . 16 . 23 ) for establishing a temporary connection between the energy store ( 7 ) and the actuator ( 3 ) is provided. Device according to one of the preceding claims, characterized in that the actuator ( 3 ) is designed as an optical signal generator. Device according to one of the preceding claims; characterized in that the actuator ( 3 ) is designed as an acoustic signal generator. Device according to one of the preceding claims, characterized in that the actuator ( 3 ) is designed as an electromechanical device. Device according to one of the preceding claims, characterized in that the actuator ( 3 ) is designed as a device for dosing of drugs. System consisting of a transmitting device ( 24 . 25 ), a control device ( 1 . 2 ) and an actuator ( 3 ), wherein the actuator ( 3 ) from the control device ( 1 . 2 ) depending on a contactless transmitted control signal of the transmitting device ( 24 . 25 ), characterized in that the control device ( 1 . 2 ) is formed according to one of the preceding claims. System according to claim 19 , characterized in that a control device ( 1 . 2 ) tuned programming device for programming the transmitting device ( 24 . 25 ) is provided. System according to one of the claims 19 or 20 , characterized in that the transmitting device ( 24 . 25 ) Is part of a mobile terminal. System according to one of the claims 19 to 21 , characterized in that the actuator ( 3 ) Is part of a locking device. System according to one of the claims 19 to 22 , characterized in that activation of the actuator ( 3 ) after a successful authentication between the transponder ( 1 ) and the transmitting device ( 24 ) he follows. Method for actuating an actuator ( 3 ) with a control device ( 1 . 2 ), wherein a control signal contactlessly to the control device ( 1 . 2 ) and the actuator ( 3 ) depending on the control signal with an energy storage ( 7 ) of the control device ( 1 . 2 ), characterized in that the control device ( 1 . 2 ) in a contactless way energy for charging the energy storage ( 7 ) is supplied.