EP2083407A1 - Device and method for contact-free energy and data transfer - Google Patents

Abstract

The device (1) has a primary unit (2) with a control device (10) and a decay accelerator (14) for interrupting an energy transmission over a transformer coupling distance in energy transmission intervals. A secondary unit (3) has an interval detector (17) for detecting the intervals. The primary unit transmits data to the secondary unit by varying length of the intervals and/or length of energy transmission phase. The secondary unit has a central processing device (21) e.g. microcontroller, for transmitting the data to the primary unit over the coupling distance in the intervals. An independent claim is also included for a method for contactless transmission of energy and data between a primary unit and a secondary unit.

Description

The present invention relates in a first aspect to a device for contactless energy and data transmission according to the preamble of claim 1.

In a second aspect, the invention relates to a method of contactless power and data transmission between the primary and secondary units.

Generic devices have a primary unit with a primary inductance and a secondary unit with a secondary inductance. The secondary unit is set up for connecting, for supplying and / or for controlling at least one terminal. Furthermore, the primary unit and the secondary unit are at least temporarily positioned relative to one another such that a transformer coupling path is formed between the primary inductance and the secondary inductance. In this case, the primary unit for contactless transmission of energy to the secondary unit is set up via the transformer coupling path and the secondary unit is provided for supplying the terminals by means of the energy received via the transformer coupling path.

Such devices are used when sensors are to be supplied and controlled, which are located on movable, such as rotatable objects and therefore can not be supplied and queried by means of a cable connection. Examples of this are sensors on pressure rollers or on moving elements in a high-bay warehouse.

Conventionally, such sensors are supplied, for example via a radio link with information. Also for the transmission of energy similar inductive couplings are used. Here, the primary unit and the secondary unit can be considered as parts of the sensor, but also as a separate device, which is responsible for the contactless transmission of energy and data. In the simplest In this case, two separate channels are provided for the transmission of energy and the transmission of data. Such devices are made, for example DE 100 12 981 A1 or DE 102 00 488 B4 known.

From other embodiments, it is known to provide only one interface, which is used both for energy and for data transmission.

In this case, for example, the data is modulated onto the energy transfer and subsequently evaluated in the sensor or the secondary unit. The problem here is to send information from the sensor back to the power supply or the primary unit, so that they can forward the data to a process control. A sensor with such a frequency modulation of the energy transfer is, for example, in DE 10 2004 015 771 B4 described. Similar energy and data transmissions are also in other non-contact systems such as access control from the DE 44 21 526 C1 known.

To send information from the sensor back to the power supply, for example, in the DE 41 30 903 A1 a device with load modulation described. In this case, the load in the sensor is changed. This is detected by the power supply. By varying the load, information can be transferred back from the sensor to the primary unit. However, a disadvantage of such devices is that more energy has to be transmitted to the secondary unit than is really needed there to carry out a load modulation. Furthermore, it is often necessary to provide cooling to dissipate heat generated by the additional consumption of energy.

An object of the invention is to provide a non-contact power and data transmission apparatus which enables efficient power transmission while still allowing easy execution of the secondary unit. In addition, a method is to be provided, with which energy and data can be transmitted without contact.

This object is achieved in a first aspect of the invention by a device for contactless energy and data transmission with the features of claim 1.

In a further aspect of the invention, the object is achieved by a method for contactless energy and data transmission according to claim 8.

Further advantageous embodiments are specified in the dependent claims, the description and the figures and their explanations.

The generic device according to the invention further developed by the fact that the primary unit has means for interrupting the transmission of energy through the transformer coupling path in energy end pauses and that the secondary unit has means for detecting the energy end pauses. It is further provided that the secondary unit have means for transmitting data to the primary unit via the transformer coupling path in the energy-saving break.

A basic idea of the invention can be seen to provide a transformer coupling between the primary inductance and the secondary inductance instead of a radio link between the primary unit and the secondary unit. The device according to the invention is used for example in large production halls or production lines. Here, many devices are already being used which communicate with each other by radio, whereby the radio bands are largely occupied and there are problems with the signal quality in the multiple use of these bands. Furthermore, radio transmissions are relatively susceptible to interference, as compared to a transformatory transmission, for example by other electromagnetic fields generated by electrical devices.

Under transformer coupling in the context of the invention, in particular, the direct coupling of two inductors, such as coils to understand. In this case, an air gap of a few centimeters or less is bridged between the two coils. Preferably, the two coils are aligned coaxially with each other. The aim of positioning the coils relative to one another is to achieve a particularly high coupling factor between the primary inductance and the secondary inductance. Ideally, a coupling factor is close to or equal to 1. This can be achieved for example by the frontal positioning of the two coils to each other. In order to enable a good coupling, as many field lines as possible of the magnetic field of the primary coil should pass through the secondary coil. The magnetic field can be additionally amplified or influenced by ferromagnetic cores in the coils.

As a further aspect of the invention, it can be considered that the transmission of data from the secondary unit to the primary unit is performed in energy transfer pauses. By doing so, at the time the data is transferred from the secondary unit to the primary unit, no other information or energy is sent via the transformer link. As a result, the data transmission, that is, for example, the pulse shape or the coding of the data, are designed to be simpler, since no other interfering signals are transmitted at the same time. It also follows that the corresponding electronics for sending the signals in the secondary unit can be easily designed. This is of particular interest because the secondary unit should only be supplied with energy via the transformer coupling path and thus should be designed to save energy.

Another basic idea of the invention is realized in that the secondary unit detects the energy-saving pauses and, as a result of the detection of an energy-saving pause, first transfers data to the primary unit. This means that data will only be transmitted to the primary unit if no energy is sent to it from the secondary unit, ie no further signals are transmitted on the transformer coupling path. The detection of the energy-saving pause ensures that data is not transmitted by mistake even when energy is sent via the transformer coupling link, which, in principle, can take place, for example, in a transmission sequence or transmission rights determined only by timing. Moreover, this does not require synchronization of two timers on the primary unit and the secondary unit.

To transmit the energy from the primary unit via the primary inductance to the secondary inductance via the transformer coupling path, the primary inductance is excited by a resonant circuit or forms itself a part of this resonant circuit. In this case, it is preferable if it forms a part of the resonant circuit itself, since in this way no further components have to be provided on the primary unit. As a resonant circuit, e.g. a parallel or a serial resonant circuit can be used.

In another variant of the device according to the invention are alternative or complementary to the means provided in the secondary unit for transmitting data to the primary unit in the primary unit means for transmitting information to the secondary unit provided. This transmission can take place, for example, by varying the length of the energy-pauses and / or the length of energy transmission phases.

If the means for transmitting are provided both in the primary unit and in the secondary unit, bidirectional communication can take place via the same channel over which energy is transmitted. Data transmitted from the primary unit to the secondary unit may be, for example, instructions for switching operations for actuators connected to the secondary unit, initialization instructions, or configuration data for the secondary unit or devices connected to it, such as sensors or actuators. Data sent from the secondary unit to the primary unit may relate to switching states or other state variables of the connected terminals.

In principle, however, it is also possible to transmit data from the primary unit to the secondary unit in the energy-saving pauses. For this purpose, a corresponding transmission control can be present, so that the data from the primary unit is not superimposed with the data of the secondary unit or vice versa.

To initiate the energy-saving break, it is basically sufficient if the resonant circuit is no longer supplied with energy, so that it decays slowly. To speed up this decay, it has proven to be advantageous to provide appropriate facilities. Normally, during the decay, the transmitted energy slowly decreases continuously. In order to be able to transmit as much energy as possible via the transformer coupling path, it is therefore preferred if no energy is transmitted as quickly as possible when initiating an energy-saving break over the transformer coupling path, that is, can be started as quickly as possible with the actual energy-saving break to accordingly quickly start again with the retransmission of energy. This is achieved by the accelerated degradation of the residual energy in the primary inductance. This degradation can be achieved for example by a transistor path, which is in series with the primary inductance. The additional use of a resistor, which absorbs energy, also has an accelerating effect.

For detecting the transmitted data in the primary unit, it is advantageous if a voltage is monitored via the primary inductance. If this voltage rises above a previously determined threshold in an energy-saving pause, this is interpreted as a data signal and corresponding information forwarded to downstream processing.

In a preferred embodiment, a current through the primary inductance is measured. This can be done for example by a transformer, which can be designed as a printed circuit transformer. The measurement signal supplied by the transformer is proportional to the current in the primary inductance. By means of the current flow through the primary inductance, for example, the load can be determined, which is represented by the secondary unit and the connected terminals. By determining the load, it is possible to regulate the resonant circuit current so that it does not become unduly high at low loads. In this case, the excitation of the resonant circuit can be interrupted, for example, until the current flow is again in a desired range.

In principle, the energy-saving pauses at the secondary unit can be arbitrarily determined. However, it is advantageous if the secondary unit has means for measuring a voltage across the secondary inductance. If this voltage drops, it is concluded that there is a start of an energy-saving break, whereby the transmission of the data from the secondary unit in the direction of the primary unit is initiated via the transformer coupling path.

Since the energy transfer is interrupted in energy-saving pauses, it is advantageous if the secondary unit has a storage capacity for buffering the energy. As a result, the supply of the secondary unit as well as the connected terminals can be ensured during an energy-saving break. In this context, it is preferred if more energy is transmitted via the transformer coupling path during the time in which energy is transmitted than is consumed at the time of energy transfer from the secondary unit and the connected terminals. The energy storage can be realized by a capacitor, which is preceded by a rectifier.

As terminals, for example, sensors or actuators can be connected. Likewise, the connection of other consumers, such as incandescent lamps, possible. Examples of actuators are electrical valves.

In principle, the sensors can be any type of sensor for detecting a measured variable or for detecting objects or objects. Particularly advantageously, the present invention for sensors in the industrial sector, for example, inductive, capacitive or optical sensors, temperature or pressure sensors, are used, each having a corresponding sensor element.

A sensor element may in principle be any element which is suitable for detecting a physical quantity. For example, the sensor element may be a coil or a resonant circuit of an inductive proximity switch, a photodetector of an optical sensor, a capacitive probe or a thermocouple.

An inventive method for contactless energy and data transmission can be performed with a primary unit and a secondary unit, each having an inductance. Here, the primary unit and the secondary unit are at least temporarily positioned so that between the primary inductance and the secondary inductance, a transformer coupling path is formed. Furthermore, at least temporarily energy for supplying the secondary unit and connectable terminals via the transformer coupling path from the primary unit to the secondary unit is transmitted contactless. It is provided that the energy transfer from the primary unit to the secondary unit is at least temporarily interrupted. This interruption of energy transfer is referred to as an energy-saving break. The secondary unit in turn detects such an energy-saving pause and, in the energy-saving pause, transmits data via the transformer coupling path to the primary unit.

In a modified version of the method according to the invention, no signals are transmitted from the secondary unit to the primary unit in the energy-saving pauses. However, data is transferred from the primary unit to the secondary unit. In this case, the data can be mapped, for example, by varying the length of the energy-saving pause. Another possibility is to use different data Expressing intervals of multiple energy silence intervals to each other or to use both types of data encoding.

In a preferred embodiment of the two methods according to the invention, both a transmission of signals in the energy-saving pauses from the secondary unit to the primary unit takes place, as well as a transmission of data from the primary unit to the secondary unit. In this variant, therefore, a single bidirectional channel is used for both the data and the energy transfer.

Data transmitted from the primary unit to the secondary unit may be, for example, instructions for switching actuators connected to the secondary unit, initialization instructions or configuration data for the secondary unit or for connected devices such as sensors or actuators. Data sent from the secondary unit to the primary unit may be, for example, switching states or other state variables of the connected terminals.

However, it is also possible to send data from the primary unit to the secondary unit in the energy-saving pauses. For this, however, a corresponding regulation may be present so that the data from the primary unit does not overlap with the data from the secondary unit.

An inventive method can be carried out for power and data transmission between a fixed primary unit and a movable secondary unit. This may be the case, for example, with pressure rollers in which the secondary unit is positioned in or near the axis. Another example is a high-bay warehouse in which the goods in the warehouse are automatically moved out of the shelves and into the shelves by means of loading and unloading equipment. The secondary unit can then be provided, for example, on a loading and unloading device and the primary unit fixed to a previously defined point to which the loading and unloading returns to the idle state.

In order to transfer energy from the primary unit to the secondary unit, it is preferable if the primary inductance for energy transfer is excited with an alternating current. In this case, the primary inductance itself can represent a part of a resonant or resonant circuit or be excited by it. The control of the resonant circuit is preferably by means of a current intensity measurement, a control and a transistor bridge regulated. The current intensity measurement can be carried out, for example, via a transformer whose measuring signal is proportional to the current intensity. In order to maintain the oscillations in the coil, the measuring signals from the transformer are amplified with a phase correction and passed on to the drive. The control controls the transistor bridge or its driver circuit such that the transistor bridge always switches in the vicinity of the zero crossing of the resonant circuit current and thus the resonant circuit is additionally excited. As a result, switching losses are avoided, and it is, so to speak, a square wave voltage on the resonant circuit. In the control, a review of the current resonant circuit current can be made to suspend the excitation at possibly too high currents.

In order to send as soon as possible no energy over the transformer coupling path at the interruption of the energy transfer, it is preferred if the residual energy is dissipated accelerated in the primary inductance. This can be done for example via the control, which then phase-inverted supplies the primary inductance or the resonant circuit with power, so that the vibration is damped. Alternatively, this can also be done by a series transistor path, e.g. made of FETs and / or resistors.

In conventional inductive coupling paths, the secondary inductance is tuned to the primary inductance or its oscillation frequency. However, this requires appropriate tuning between the two inductors. Also problematic here are drifts of the natural frequencies, e.g. due to aging or temperature changes. Therefore, it is preferred that when using the transformer coupling path according to the invention, the secondary inductance is operated uncoordinated. This means that no effort is made to match them to the resonant frequency of the primary inductor or resonant circuit in the primary unit.

One way to detect the energy end pauses by the secondary unit is to monitor the voltage across the secondary inductance. If this voltage drops, then the beginning of an energy-saving break is concluded.

The data transmission from the secondary unit to the primary unit in an energy-saving break can basically be arbitrary. But it is especially easy when the secondary inductance is supplied with current for transmitting the data, and then this current flow through the secondary inductance is aborted, in particular abruptly. As a result, a pulse is triggered, which is transmitted to the primary inductance via the transformer coupling path and can be detected in the primary unit as a voltage pulse.

So it is possible, for example, to transmit a voltage or current pulse to the primary unit or to stimulate there to transmit a date with the value "1" in the energy-saving break and to transmit a date with the value "0" in the energy-saving break no voltage or Generate current pulse. Likewise, other coding options are conceivable. Thus, information technology symbols can also be transmitted with one pulse, whereby the transmission of several bits with one pulse is possible. This requires appropriate modulation and demodulation and evaluation facilities on both the primary and secondary units.

The data that are transmitted from the secondary unit to the primary unit can be, for example, information about measuring signals of the connected sensors. It is also possible to transmit information about the current switching states of connected actuators. In doing so, it has proven to be advantageous if these data are subjected to a source or channel coding before or during the transmission, in order to reduce the susceptibility to transmission errors. Similarly, the provision of a checksum is possible to detect transmission errors.

Fig. 1

ein schematisches Diagramm des Stromflusses durch die Primärinduktivität;

Fig. 2

ein schematisches Diagramm einer Ausführungsform der erfindungsgemäßen Vorrichtung; und

Fig. 3

eine schematische Darstellung einer möglichen Anordnung der Primär- und Sekundärinduktivitäten.

The invention will be explained in more detail with reference to embodiments and schematic drawings. In these drawings show:

Fig. 1

a schematic diagram of the current flow through the primary inductance;

Fig. 2

a schematic diagram of an embodiment of the device according to the invention; and

Fig. 3

a schematic representation of a possible arrangement of the primary and secondary inductances.

In Fig. 1 the current over the time in the primary inductance 4 of the primary unit 2 is shown.

Until the time t ₁ , the primary inductance 4 or the resonant circuit is excited by the control of the primary unit 2 with current, so that it is set in oscillation. That is, from the time t ₀ and before it to the time t ₁ 41 energy is transmitted to the secondary inductance 3 in a first energy transfer interval. The residual ripple of the current is due to the regulation in the primary inductance 4. At time t ₁ , the excitation of the resonant circuit or the primary inductance 4 is terminated. Subsequently, between the time t ₁ to t _2, the energy accelerated from the primary inductance 4 or the resonant circuit degraded. This period is also referred to as cooldown 42. Basically, if no possibility of data transmission from the primary unit 2 to the secondary unit 3 is necessary, the energy-end pauses 43 are inserted at periodic intervals.

The beginning of the energy-saving break 43, which extends from the time t ₂ to t ₄ , is detected by the secondary unit 3. Subsequently, the secondary unit 3 sends a pulse 50 by means of its secondary inductance 5 via the transformer coupling path to the primary inductance 4 and thus the primary unit 2.

At the time t ₄ , the excitation of the oscillation in the primary inductance 4 is resumed by the primary unit 2 and reaches the optimum operating value again at the instant t ₅ . The interval between t ₄ and t ₅ is also referred to as turn-on delay 44. Subsequent to the turn-on delay 44, there is a new, second energy transmission interval 45. In order to also transmit data from the primary unit 2 to the secondary unit 3, the length of the energy transmission break 43 can be used for data transmission or coding. Another or additional possibility is to use the length of a power transmission interval 41, 45 for transmitting this data. For example, an energy transfer interval 41, 45 may be 4 ms and the decay time 20-30 μs. In order not to interrupt the energy transfer too long, then takes an energy-saving break 34, for example, about 100-150 microseconds.

The following is with reference to Fig. 2 describes the basic functionality and operation of a device 1 according to the invention.

The device 1 according to the invention is divided into a primary unit 2 and a secondary unit 3. These can also be regarded as primary and secondary sides of the device 1. The central elements for carrying out the method according to the invention are the primary inductance 4, which is formed by a first coil and the secondary inductance 5, which is formed by a second coil. The two coils 4 and 5 are preferably coaxially positioned. The distance 15 between the two coils 4, 5 is of the order of 2.5 mm and should not exceed 5 mm. This distance between the two coils 4, 5 is referred to as a transformer coupling path.

The following describes the control and operation of the coil 4 for transmitting the power to the secondary unit 3. The primary unit 2 is powered by an energy source 6 with energy. This is connected both to the general supply for the devices of the primary unit 2 as well as to a transistor bridge 9. This transistor bridge 9 is preferably constructed of FETs. In the embodiment shown here, a parallel resonant circuit is formed by the coil 4 and a capacitor 34 connected in parallel thereto. However, it is also possible to use another resonant circuit, for example a serial resonant circuit, for carrying out the method according to the invention.

Via the transistor bridge 9, the resonant circuit with the coil 4 and the capacitor 34, a current and voltage sensor 16, a control device 10 and a bridge driver 9, a control loop for controlling the oscillation of the resonant circuit is constructed. The current and voltage sensor 16 measures the current flowing through the coil 4 and forwards a measurement signal to the control device 10. This signal can be amplified with a phase correction. For example, the current measurement in the current and voltage sensor 16 may be performed by a transformer whose measurement signal is proportional to the current.

The control device 10, which can also be referred to as control logic for the bridge driver 8, switches the transistor bridge 9 via its driver 8 in such a way that the resonant circuit is set in oscillation. This is done, for example, by switching at the time of zero passage of the resonant circuit current. Furthermore, the current measured by the current and voltage sensor 16 is used to control the current in the coil 4 to ensure that the resonant circuit current is not inadmissible gets high. The control is carried out by the control device 10 such that when the current through the coil 4 is too high, the resonant circuit is no longer excited.

Furthermore, an energy-saving break 43 is initiated by the controller 10. To do this, it signals the driver 8 not to continue or support the oscillation. In addition, it activates a decay accelerator 14. This can be carried out for example by transistors and resistors and ensures that the residual energy, which is located in the coil 4, is degraded as quickly as possible.

In an energy-saving pause 43, the coil 5 receives a data pulse 50 in the coil 4, as previously described with reference to FIG Fig. 1 shown, excited. The results of a continuous voltage monitoring of the coil 4 are forwarded to a pulse conditioning 13. Here is decoded based on the received voltage levels, which data and information was transmitted from the secondary unit 3. These data are forwarded to a central evaluation unit 12 for further processing. The evaluation unit 12 can be realized for example by a microprocessor or by a programmable logic, such as an FPGA. The evaluation 12 prepares the results and outputs them via corresponding outputs 11, for example to a programmable logic controller, a relay or a data bus. The evaluation 12 can also control the control device 10 with instructions. It is thus possible, for example, to explicitly request data from the secondary unit 3, in which the controller 10 is instructed by the evaluation 12 to insert an energy-saving pause 43 in order to transmit data from the secondary unit 3.

In the secondary unit 3, an alternating voltage is excited via the inductive coupling path through the coil 4 in the coil 5. The coil 5 is connected to a general supply device 18. This has, for example, a capacitor for energy storage of the transmitted energy, which is charged via a rectifier. The rectified voltage is highly dependent on distance and can be at very low distance or direct contact of the coils 4, 5 over 100 volts. Therefore, a switching regulator is provided for loss of power reduction. The energy stored and processed in the general supply device 18 becomes via a switching power supply 19 the connected terminals, such as actuators or sensors, provided.

Typically, a few watts can be transmitted via the transformer coupling path. For example, the switched-mode power supply 19 supplies a voltage of approximately 12 V to the terminals, which consume approximately 160-170 mA.

In addition, a pause detection 17 is located directly on the coil 5. This pause detection measures the voltage which is transmitted to the coil 5 and signals a central processing device 21 as soon as the voltage falls below a threshold value. The central processing device 21 can be embodied, for example, in the form of a microcontroller or a programmable logic, such as an FPGA. If the central processing device 21 receives the information from the pause detection 17 that the voltage is currently below a threshold, it interprets this as an energy-saving pause 43. The central processing device 21 transmits instructions corresponding to an impulse generator 22, specific impulse forms via the coil 5 by means of the inductive Coupling path to the coil 4 of the primary unit 2 to transmit. The energy for transmit pulse generation also comes from the general power supply 18.

The central processing device 21 also receives information about inputs 23. These are connected to sensors or actuators. Similarly, the central processing device 21 via outputs, which are not shown, send instructions to actuators or sensors.

Finally, an undervoltage detection 20 is provided, which monitors the voltage at the switching power supply 19. If this voltage falls below a certain value, for example below 12 V, the data which the sensors supply via the inputs 23 are no longer reliable. This signals the undervoltage detection 20 to the central processing device 21 so that these unreliable data are not sent to the primary unit 2.

The voltage at the primary coil 4 during the energy transfer can be about 100-200 V and a data pulse has about 100-200 mV, for example.

In Fig. 3 a possibility of positioning the primary coil 4 and the secondary coil 5 is shown. The primary coil 4 far a U-shaped core 56. The secondary coil 5 is located on a rotatably mounted about its central axis 57 pulley 58 at its outer peripheral portion. The disk 58 may be, for example, a turntable of a bottling plant. Rotates now the disc 58, so is always at least a portion of the secondary coil 5 in transformer coupling with the primary coil 4. Basically, in the positioning of the two coils 4, 5 preferred when most field lines of the primary coil 4 through at least portions of the secondary coil. 5 pass.

The device according to the invention and the method according to the invention thus offer a contactless, effective and trouble-free energy and data transmission via only one interface.

Claims (15)

Device (1) for contactless energy and data transmission,
with a primary unit (2) having a primary inductance (4),
with a secondary unit (3) which has a secondary inductance (5) and which is set up for connecting, for supplying and / or for controlling at least one terminal,
wherein the primary unit (2) and the secondary unit (3) are at least temporarily positioned relative to one another such that a transformer coupling path is formed between the primary inductance (4) and the secondary inductance (5),
wherein the primary unit (2) is arranged for contactless transmission of energy to the secondary unit (3) via the transformer coupling path, and
wherein the secondary unit (3) is arranged to supply the terminals by means of the energy received via the transformer coupling path,
characterized,
that the primary unit (2) comprises means (10, 14) for interrupting the power transmission via the transformer coupling distance in energy transmission pauses (43),
that the secondary unit (3) means (17) for detecting the power transmission pauses (43),
in that the primary unit (2) has means for transmitting data by varying the length of the energy end pauses (43) and / or the length of energy transmission phases to the secondary unit (3) and / or
in that the secondary unit (3) has means (21) for transmitting data to the primary unit (2) via the transformer coupling path in the energy-saving pauses (43). Device according to claim 1,
characterized,
in that the primary unit (2) has a transistor path for accelerated decay of a residual energy in the primary inductance (4) upon interruption of the energy transfer. Device according to one of claims 1 or 2,
characterized,
in that the primary unit (2) has means (16) for monitoring a voltage across the primary inductance (4). Device according to one of claims 1 to 3,
characterized,
in that the primary unit (2) has means (16) for measuring a current in the primary inductance (4). Device according to one of claims 1 to 4,
characterized,
in that the secondary unit (3) has means (17) for measuring a voltage across the secondary inductance (5). Device according to one of claims 1 to 5,
characterized,
that the secondary unit (3) has a storage capacity for buffering a supply of the terminals. Device according to one of claims 1 to 6,
characterized,
in that the primary inductance (4) is designed as part of a resonant circuit. Method for contactless energy and data transmission
between a primary unit (2) and a secondary unit (3), which is set up for connecting, for supplying and / or for controlling at least one terminal,
wherein the primary unit (2) has a primary inductance (4), and
wherein the secondary unit (3) has a secondary inductance (5),
in which the primary unit (2) is at least temporarily positioned relative to the secondary unit (3) such that a transformer coupling path is formed between the primary inductance (4) and the secondary inductance (5),
in which at least temporarily energy for supplying the secondary unit (3) and the connected terminals via the transformer coupling path from the primary unit (2) to the secondary unit (3) is transmitted without contact,
in which the transfer of energy from the primary unit (2) to the secondary unit (3) is interrupted in energy-saving pauses (43),
in which the energy end pauses (43) are detected by the secondary unit (3),
in which the secondary unit (3) transmits data via the transformer coupling path to the primary unit (2) during the energy end pauses (43) and / or
in which information is transmitted from the primary unit (2) to the secondary unit (3) by means of the length of the energy-end pauses (43) and / or the interval between two energy-saving pauses (43). Method according to claim 8,
characterized,
that the transformer coupling path is operated outside of resonances of the secondary inductance (5). Method according to one of claims 8 or 9,
characterized,
that when interrupting the energy transfer, a residual energy in the primary inductance (4) is accelerated reduced. Method according to one of claims 8 to 10,
characterized,
that the primary inductance (4) is energized by an alternating current for energy transfer, and
in that the alternating current is regulated by means of a current intensity measurement (16), a drive (10) and a transistor bridge (9). Method according to one of claims 8 to 11,
characterized,
in that a voltage is evaluated via the secondary inductance (5) for detecting the energy end pauses (43) by the secondary unit (3). Method according to one of claims 8 to 12,
characterized,
in that for transmitting data the secondary inductance (5) is supplied with current and the current flow through the secondary inductance (5) is then aborted, in particular abruptly. Method according to one of claims 8 to 13,
characterized,
that a voltage and / or current pulse is transmitted for transmitting a data with the value "1" in an energy-saving pause (43), and
in that no voltage and / or current pulse is transmitted for transmitting a data with the value "0" in an energy-saving pause (43). Method according to one of claims 8 to 14,
characterized,
that by means of the data, in particular encoded, information is transmitted via terminals.

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