KR101520096B1 - Apparatus and method for wireless energy and/or data transmission between a source device and at least one target device - Google Patents

Abstract

The present invention relates to an apparatus and method for wireless transmission of energy and / or data between a source device and a target device, wherein the voltage is applied to a first coil (18) on the source device side of at least one first circuit, At least one second coil (20) and at least one resonant circuit on the target device side of at least one second circuit, wherein the resonant circuit is electrically isolated from the first circuit and the second circuit Respectively.

Description

[0001] APPARATUS AND METHOD FOR WIRELESS ENERGY AND OR DATA TRANSMISSION BETWEEN A SOURCE DEVICE AND AT LEAST ONE TARGET DEVICE [0002]

The present invention relates to an apparatus and method for wirelessly transmitting energy and / or data between a source apparatus and at least one target apparatus, the apparatus comprising: at least one primary coil located on one side of the source apparatus, And at least one secondary circuit located on one side of the target device and having at least one secondary coil. The secondary circuit includes at least one first circuit having a first coil and a second coil. In particular, the invention relates to a method for charging at least one rechargeable battery disposed in a component of an apparatus or apparatus, for charging a rechargeable battery, for example at a remote control, And more particularly to inductive energy transmission.

In the case of medical devices, in particular, operating tables, remote controls are useful as wireless actuators, and with the aid of remote control, each device can be operated from various positions, and the device for receiving signals from remote controls And may be operated at a certain distance from the receiver unit. This remote control enables convenient use of at least some of the operating functions of the medical device or operating table. Conventionally, such an operating device has been operated by a battery or a rechargeable battery. To ensure ease of use of this remote control, it is recommended to use a rechargeable battery, and once the rechargeable battery is charged or refilled, remote control can be used as an operating unit during subsequent treatment Results.

In addition, the use of a special rechargeable battery makes it possible to supply a large amount of energy for the operation of the remote control in the case of a relatively small physical size in accordance with the design-related conditions of the remote control. In order to charge the rechargeable battery, a connection to a further energy source needs to be created, in particular a connection to a suitable switched-mode power supply or charger. For this purpose, both arrangements with a DC connection between a charger and a rechargeable battery and arrangements without a DC connection between a charger and a rechargeable battery are known in the prior art. In the case of known arrangements where there is no DC connection between the remote control and the energy source (ie in the case of DC insulation), the energy transfer is induced inductively between the charging station or the base station and the remote control (indictively). In this case, the charging station or base station is the source device and the remote control is the target device.

Figure 1 illustrates a known arrangement for inductive transmission of energy. In this case, the arrangement 10 includes the source device 12 and the target device 14. The source device 12 includes an energy source 16 and the energy source 16 is in the form of an AC source and generates an AC voltage. Additionally, the source device 12 includes a coil 18 on one side of the source-device, and the coil 18 is a first coil 18 for transferring energy or data to the target device 14 . The target device 14 includes a coil 20 on one side of the target device and the coil 20 acts as a second coil 20 and is electrically connected to the charging circuit 22, Is shown as a load resistor. The energy source 16 of the source device 12 is electrically connected to the first coil 18 on one side of the source device so that the energy source 16 is connected to the first coil 18 through the alternating current Causing an alternating current, with the result that the first coil 18 generates a magnetic field that varies with time (alternating magnetic field). The second coil 20 on one side of the target device is located in the magnetic field induced by the first coil 18 if the target device 14 is located within the charge and / or data transfer position. The voltage is induced in the second coil 20 by the alternating magnetic field and as a result of this voltage current flow is possible through the charging circuit 22 where the charging circuit 22 is connected to the load the energy transferred from the energy source 16 via the first and second coils 18 and 20 is supplied to the charging circuit 22. The charging circuit 22 is a circuit that is connected to the charging circuit 22, As an alternative to or in addition to the charging circuit 22, an evaluation circuit may be provided for determining the data transmitted via the arrangement shown in Fig.

2, there is shown an arrangement 24 for transferring energy between a source device 26 and a target device 28, similar to the arrangement 10 shown in FIG. The same component has the same reference symbol. In contrast to the arrangement 10 shown in FIG. 1, the circuit of the source device 26 and the circuit of the target device 28 each include capacitors 30 and 32. The series resonant circuit is formed by the arrangement of the capacitors 30 in the circuit of the source device 26 and the parallel resonant circuit is formed by the capacitors 32 in the second circuit. A resonant coupling occurs between the source device 26 and the target device 28 by these resonant circuits and may occur from the first circuit to the second circuit or from the source device 26 to the target device 28 Lt; RTI ID = 0.0 > energy transfer < / RTI > In the arrangement 24 shown in FIG. 2, the magnetic field is induced by the first coil 18. The first coil 18 tune the capacitor 30 from the first coil to resonance. The magnetic field induced by the first coil 18 passes through the second coil 20, which is part of the second resonant circuit. However, in reality, it is difficult to match the resonance frequencies of the primary-side resonant circuit and the secondary-side resonant circuit with respect to each other. The difficult reason is that the resonance condition changes depending on the state of charge of the rechargeable battery or depending on the resistance value of the load resistor 22. And, the resonance condition changes during the charge cycle.

In order to match the resonant frequency, various measures can be taken into account in both the first and second sides. For example, an appropriate frequency of the energy source 16 may be selected, whereby it is possible for the frequency to be preset, set, regulated or corrected within a predetermined frequency range. In addition, appropriate design measurements may be provided, particularly mechanical and electrical measurements, to maintain resonance conditions during relatively long charge cycles. In particular, maintenance of resonance conditions can be achieved or at least assisted by appropriate selection of components. In addition, it can be achieved by varying the inductance of at least one of the capacitances or coils 18, 20 of at least one of the resonance adjustment capacitors 30, . However, this is associated with a relatively high level of complexity. Overall, the maintenance of resonance conditions in the first and / or second circuit is relatively complex.

FIG. 3 shows an arrangement 24 for transferring energy between a source device 36 and a target device 38, similar to the arrangement 10 shown in FIG. 1, the first coil 18 is disposed about a first iron core segment 40 and the second coil 20 is disposed about a second iron core portion 40 second iron core segment 42, as shown in FIG. The first and second iron core portions 40 and 42 have gaps 44 on opposite end sides of the first and second iron core portions in the fill and / or data transfer locations. In particular, the gap 44 is formed by a respective closed housing of the source device 36 and the target device 38 and / or by an additional air gap. Lines of force emerging from one of the end sides of the magnet core portions 40 and 42 are arranged such that the end sides are spaced apart from each other and enter the opposite far end side surface, The magnetic circuit is closed to the magnetic gap 40, 42 and to the gap 44.

Figure 4 shows a similar arrangement 46 to the arrangement 34 shown in Figure 3 and shows the magnet core portions 52 and 54 to be inserted in both the case of the source device 48 and the case of the target device 50, Shaped and disposed at data and / or energy transfer locations. The placement of the magnetic core portions 52, 54 at the data and / or energy transfer locations is such that in each case both end faces of the magnet core portions 52, 54 are opposite to each other and are spaced apart from one another And gaps 56 and 58 similar to the gaps 44 in the arrangement 34 according to Fig. 3 in each case are provided between the end sides.

Figure 5 shows a similar arrangement 60 to the arrangement 46 shown in Figure 4 in which the capacitors 30 and 32 are in each case a resonant circuit In the circuitry of the source device 62 and in the circuitry of the target device 64 to form the source device 62 and the source device 62, respectively.

Generally, the housing of the source device and the target device is made of an electrically insulating material, and the electrically insulating material does not weaken the electromagnetic field or weakens it to only a small size. As a result of the minimum thickness required for the housing wall, in particular for mechanical strength and electrical insulation of the housing of the source device and the target device, the gap is greater than the minimum gap width ), Which affects the characteristics of the magnetic circuit. The gap width is important for the magnetic field strength in the magnetic circuit of the arrangement shown in Figs. 1 to 5, formed by the magnetic core portion.

DE 38 10 702 C2 discloses arrangements performed on frequency modification of energy sources. For this purpose, in this arrangement, the phase relationship between the current and the voltage in the first circuit is determined and adjusted to a preset value.

DE 198 37 675 A1 discloses a charging device in which a power oscillator is provided in a first part of an inductive coupler for inductive transmission of charging energy. A switching device is provided in the second part for alternating the power to charge the rechargeable battery.

DE 601 02 613 discloses the arrangement in which the transmission power of the energy output by the transponder read apparatus is set. In this case, the series resonant circuit is provided in the primary-side or transmitter-side circuit to provide transmission power. Up-to-date information on the magnetic coupling between the transponder and the reader is detected. The resonant circuit has various capacitances, and the resonant circuit can be adjusted by the capacitance.

The present invention is directed to an apparatus and method for wireless transmission of energy and / or data between a source device and at least one target device, that is, effective energy and data transfer, with a simple design, in the background of a device known in the prior art Based on the purpose of specifying the device and method in question.

This object is achieved by a method having the features of the apparatus and method independent claim having the features of claim 1. Beneficial improvements of the invention are described in detail in the dependent claims.

As a result of the apparatus according to the invention and the method according to the invention for the wireless transmission of energy and / or data between the source device and the at least one target device, the fulfillment of the resonant frequency and the resonant condition of the resonator, And the changing conditions of the second circuit. In particular, the resonator does not depend on the varying load in the second circuit. As a result of the resonator, the resonator is electrically isolated from the first circuit and the second circuit, as well as efficient energy transfer between the target first and second circuits. In the case of the arrangement of a plurality of resonators having different resonant frequencies, each of the plurality of resonators is electrically isolated from the first circuit and the second circuit. In fact, any desired signal form can be used, for example, -wave signals may comprise a plurality of harmonic oscillations. Each resonator is formed by a resonant circuit, and in particular, the resonant circuit includes at least one induction coefficient and capacitance.

Then, the energy is transferred from the first side to the second side by each resonant circuit, and the total amount of energy transferred as a result thereof is proportional to the energy component transmitted directly from the first circuit to the second circuit, Is the sum of the energy components transmitted from the circuit to the resonant circuit and transmitted from the resonant circuit to the second circuit. For example, if two resonators are provided instead of one resonator, the total amount of energy transferred can be increased by about 15%. Preferably, the second resonator has a resonant frequency twice that of the first resonator. However, for the present invention, other resonators, for example acoustic, mechanical or hydrodynamic resonators, may also be used in place of electromagnetic resonators. A resonator within the meaning of the present invention is any vibration system. The components of the oscillating system are tuned to the input frequency in such a way that the resonator decays from the input frequency to excitation.

In the development of the present invention, the resonator is in the form of a resonant circuit, or the resonators are in the form of resonant circuits. The induction coefficients of the first coil, the second coil, and the insulation resonant circuit / insulation resonant circuits are arranged in the same magnetic circuit. If the induction coefficients of the first coil, the second coil and the insulation resonant circuit are arranged around a magnetic circuit surrounded by a magnetic circuit, a magnetic circuit having a magnet core without a gap preferably is advantageous here.

In addition, it is advantageous to provide at least two resonant circuits electrically isolated from the second circuit and from each other circuit. The induction coefficients of the at least two resonant circuits are preferably each in the form of a coil, the winding of which is formed by bifilar winding, or in the case of two or more resonant circuits, (n-filar winding). As a result of the double-strand winding, or in the case of an n resonant circuit, the coil formed by such winding has the same inductance coefficient, so that the resonant frequency can be set by selecting a different capacitance have. It is advantageous if the resonant circuit has different resonant frequencies so that the energy transfer between the first and second circuits is affected by the resonant circuit or resonant circuit with the added resonant frequency of the resonator.

The winding of the second coil and the winding of the coil forming the induction coefficient of the resonance circuit and / or the winding of the first coil and the winding of the coil forming the induction coefficient of the resonance circuit are formed by bifilar winding . If a plurality of resonant circuits are provided, the winding of the coil of the resonant circuit or some of the winding of the coil of the resonant circuit and the primary winding or the second winding may be n-filar winding As shown in FIG. The preparation of the n-filar winding simplifies the manufacture of the entire device. In particular, the induction coefficient of a coil formed by an n-filar winding can be easily changed by a plurality of mutually connected coils, which can be changed in particular by a factor of two.

In addition, it is advantageous to analyze the signal to be transmitted with the aid of Fourier transformation. The resonant circuit is provided for each harmonic oscillation of the signal to be transmitted which is analyzed by Fourier transform and the resonant frequency of the resonant circuit corresponds to the frequency of the individual harmonic oscillation. As a result, virtually any desired signal form can be formed from harmonic vibrations and, as a result, for example, a substantially square-wave signal profile can be generated on the secondary side. It is noted that the independent claim of a method can be developed into the features of the dependency of the respective device or the corresponding method features.

Additional features and advantages of the invention will be set forth in the description which follows, with reference to the accompanying drawings, in which the following description describes the invention in more detail with reference to illustrative embodiments.

According to the present invention, the measure need not be performed on either the first side or the second side to satisfy the resonance condition. Instead, compensation of the currentless wattless power can occur at the first or second side, and is particularly independent of resonance conditions.

The placement of the resonator on the first side or the second side is of secondary importance for the system to function. Instead, design-related requirements can be considered, particularly the physical size of the target device and / or the source device. It is advantageous if the energy source 16 has an AC voltage with a frequency in the region of 20 kHz to 5 MHz, preferably in the region of 60 kHz to 500 kHz.

FIG. 6 shows a layout 100 for wireless transmission of energy and / or data between a source device 102 and a target device 104 in accordance with a first embodiment of the present invention. The arrangement 100 has a design similar to the known arrangement 46 shown and described previously in Fig. The same components have the same initial symbol. In addition to the first side circuitry, the first side circuitry includes an energy source 16 and a first coil 18, and the arrangement 100 includes a charging circuit 22, shown as a load resistor, And a second side circuit having a coil (20). The magnet or iron core includes a first side U-shaped magnetic core portion (52) and a second side U-shaped magnetic core portion (54), and the first side U-shaped magnetic core portion (52) (18). ≪ / RTI > The gaps 56 and 58 are provided between the magnetic core portions 51 and 54 at the charging and / or data transfer locations of the source device 102 and the target device 140. The arrangement 100 has a coil 106 and the winding of the coil 106 is disposed about the second magnetic core portion 54 and electrically connected to the capacitor 108. [ The coil 106 and the capacitor 108 from the resonant circuit depend on the inductance of the coil 106 and the capacitance of the capacitor 108 and the resonant circuit has a resonant frequency. This resonant circuit is a resonator in the sense of the present invention. In the arrangement 100 shown in FIG. 6, the resonator is disposed in the second side, i.e., the target device 104.

FIG. 7 shows a layout 110 for wireless transmission of energy and / or data between a source device 112 and a target device 114 in accordance with a second embodiment of the present invention. The arrangement 110 has a design similar to the arrangement 100 shown in FIG. In contrast to the arrangement 100 shown in FIG. 6, the resonator includes a first coil 106 and a capacitor 108 physically located in the source device 112. The winding of the coil 106 is disposed around the first magnet core portion 52 of the magnet core.

Figure 8 illustrates a deployment 120 for energy and / or data wireless transmission between a source device 122 and a target device 124 in accordance with a third embodiment of the present invention, Side resonator and the second-side resonator are provided. The first coil 126 and the capacitor 128 are electrically connected to each other to form a circuit and a first side resonator. The winding of the coil 130 and the first coil 18 on the source device side is formed by bifilar winding. In the same way, the winding of the coil 126 and the second coil 20 of the target device is also bifilar winding.

9 illustrates a deployment 140 for energy and / or data wireless transmission between a source device 142 and at least one target device 144 in accordance with a fourth embodiment of the present invention, Similar to arrangement 120. The winding of the first coil 18 on the source device side and the coil 130 of the first side resonator are formed as separate windings. In the same manner, the winding of the second coil 20 of the target circuit side and the coil 126 of the second side resonator are also formed as separate windings.

Figure 10 shows a layout 150 for energy and / or data wireless transmission between a source device 152 and a target device 154 according to a fifth embodiment of the present invention and has a resonator on the target device side. The winding of the coil 18 of the resonator on the target device side and the winding of the second coil on the target device side are formed by bifilar winding in the present embodiment. In this embodiment, the resonator of the first side is not provided.

11 shows a layout 160 for wireless transmission of energy and / or data between a source device 162 and a target device 164 in accordance with a sixth embodiment of the present invention. The arrangement has a resonator on the first side. The winding of the coil 130 of the resonator is bifilar winding with the winding of the first coil 18 on the source device side.

Embodiments of the present invention as described may be used in the case of the form of winding of the coils of resonators by bifilar winding with the first coil 18 on the source device side or by bifilar winding on the side of the second coil 20 Or a separate winding of the coils of the first coil and the resonator on the side of the source device and a separate winding of the second coil 20 on the side of the target device, And the use of a separate arrangement of the coil (s) of the resonator (s). However, in the same manner, for example, the arrangement may be such that the winding of the first side resonator and the winding of the first coil 18 on the side of the source device are formed as separated separate windings and the winding of the coil of the second side resonator And the second coil 20 on the target device side may be formed as separate windings. In the same manner, the coils of the first side resonator and the first coil 18 on the side of the source device are formed by separate winding, and the coils of the second side resonator and the second coil 20 on the target device side are wound It is possible to form a bifilar winding. For simplicity, in each case in the exemplary embodiment, only one resonator is shown on both the first side and the second side. However, in certain embodiments of the present invention, it is appropriate to provide a plurality of first sides and / or a plurality of second side resonators, and the windings of the resonators may be connected to either the first coil 18 or the second coil 20 And / or a separate winding from which the first coil 18 and the second coil 20 are separated from the windings.

In a case where a plurality of resonators are provided, it is preferable that the plurality of resonators have different resonance frequencies. In this case it is advantageous to form the coils of all the second side resonators and the windings of all the second side resonators as the n-filar winding, and as a result, Coefficient. As a result of the n-filar winding of the n-strand, it is possible that the substantially corresponding inductance of the winding coil can be produced in a simple manner in the manufacturing process.

By interconnecting a plurality of coils, the induction coefficient is exactly doubled. To fix the desired resonant frequency, capacitors with suitable capacitances are provided and each of the capacitors is electrically connected to the coil or to a plurality of interconnected coils, thereby forming a resonant circuit (resonator). A high level of efficiency for energy and data transmission is achieved by providing resonators that are not electrically connected to the second circuit and the second circuit, i.e., electrically isolated. The tolerance component of the components is included in the first and second circuits and the change in the characteristics of the load resistor formed by the charging circuit 22 is the result of the change in the characteristics of the resonator , Especially at resonant frequencies. Complex adjustment or correction of the resonant frequency is not necessary as a result of the present invention.

As shown in the exemplary embodiment, it is advantageous to place at least one resonator in the same magnetic circuit as the first and second coils 20. When a plurality of resonators are used, a non-sinusoidal signal including a resonant transmission of radiofrequency and a plurality of sinusoidal harmonic oscillations may occur. As a result, particularly square wave signals can be transmitted in a simple manner. An arrangement according to the invention is shown with two U-shaped magnetic core portions 52, 54. However, other core shapes of the present invention may also be used in the same way. In particular, it is also possible that only one first side magnet core is provided and the magnet core can be designed to be constructed in such a way that it protrudes mechanically from the source device. The cutout is preferably provided in the housing of the target device, and the projecting magnet core is protruded in a cutout at the charging position and / or the data transmission position. The second coil 20 is disposed around the cutout, so that if the source device and the target device are located at the data transfer position or the energy transfer position, the second coil is disposed around the magnet core. Alternatively or additionally, the target device has a projecting core region, and the protruding core region protrudes from the cutout of the source device if the source device and the target device are located at a data transfer position or an energy transfer position. The first coil is then placed around the cutout of the source apparatus. Preferably, the housing of the source device or the target device is formed around the protruding magnet core and along the cutout, such that at least one target device has a housing closed to surround the periphery.

The transfer of energy between the first side of the source device side and the second side of the target device side is effected by the intensity of the magnetic field induced by the first coil or the magnetic flux in the magnetic circuit and the AC generated by the energy source 16 And is substantially dependent on the frequency of the voltage. Magnification of the current and / or voltage due to resonance by the resonant circuit can occur. The stick shape of the magnet core leads to the problem of EMC due to the relative free propagation of the lines of the force of the magnetic field in the outer region, as shown in connection with Fig. In addition, the field strength or magnetic flux may increase in complexity to a relatively large degree. The amount of energy transferred to the second side depends on the magnetic field strength and frequency when the magnetic field strength is changed. The voltage is induced in the second coil 20 by varying in the field strength of the magnetic field induced by the first coil.

According to the present invention, a first side circuit having a first side coil, a second side circuit having a second side coil, and a resonator are used to enable wireless energy transfer or data transfer between the first side and the second side. do. Here, the resonator may be additionally disposed in the region of the magnetic field induced by the first coil or in the magnetic circuit.

Figure 1 is a diagram showing a known arrangement for induction transfer of energy.

FIG. 2 is a diagram showing an arrangement 24 for transferring energy between a source device 26 and a target device 28, similar to the arrangement 10 shown in FIG.

FIG. 3 is a diagram showing an arrangement 24 for transferring energy between a source device 36 and a target device 38, similar to the arrangement 10 shown in FIG.

Fig. 4 is a diagram showing another arrangement 46 similar to the arrangement 34 shown in Fig.

FIG. 5 is a diagram showing another arrangement 60 similar to the arrangement 46 shown in FIG.

6 is a diagram illustrating an arrangement for inductive transmission of energy according to a first embodiment of the present invention.

7 is a diagram illustrating an arrangement for inductive transmission of energy according to a second embodiment of the present invention.

8 is a diagram illustrating an arrangement for inductive transmission of energy according to a third embodiment of the present invention.

9 is a diagram showing an arrangement for induction transmission of energy according to a fourth embodiment of the present invention.

10 is a diagram illustrating an arrangement for inductive transmission of energy according to a fifth embodiment of the present invention.

11 is a diagram showing an arrangement for inductive transmission of energy according to a sixth embodiment of the present invention.

Claims (14)

An apparatus for wireless transmission of energy and / or data between a source apparatus and at least one target apparatus, At least one first coil (18) of at least one first circuit in the source apparatus, At least one second coil (20) of at least one second circuit in the target device, And a first resonator having a first resonant circuit coil and a first resonant circuit having a first capacitor, wherein the first resonant circuit is electrically insulated from the first circuit and the second circuit, And a second resonator having a second resonant circuit coil and a second resonant circuit having a second capacitor, wherein the second resonant circuit is electrically connected to the first circuit, the second circuit, and the first resonant circuit Isolated, Characterized in that the first coil, the second coil, the first resonant circuit coil and the second resonant circuit coil are arranged in the same magnetic circuit, characterized in that the energy and / or data wirelessly between the source device and the at least one target device A device for transmission. The method according to claim 1, Each resonator having a resonant frequency that is different from a frequency of the energy source disposed in the first circuit, wherein the resonant frequency is two or one-half times the frequency of the energy source. For energy and / or data wireless transmission. 3. The method according to claim 1 or 2, Characterized in that the first coil (18), the second coil (20) and the coil forming the induction coefficient of the resonant circuit are arranged around a magnet core forming a magnetic circuit. / RTI > for wireless transmission of energy and / or data. The method according to claim 1, Wherein the winding of the coil of the resonant circuit is formed by a bifilar winding. ≪ Desc / Clms Page number 13 > The method according to claim 1, Wherein at least two resonators have different resonant frequencies. ≪ Desc / Clms Page number 21 > The method according to claim 4 or 5, Characterized in that the at least two resonant circuits have a coil with the same induction coefficient and the winding of the coil is formed as an n-filar winding. An apparatus for wireless transmission of energy and / or data. The method according to claim 6, Wherein at least two resonant circuits have different frequencies. ≪ Desc / Clms Page number 13 > 21. An apparatus for wirelessly transmitting energy and / or data between a source device and at least one target device. The method according to claim 1, Characterized in that the winding of the second coil (20) and the winding of the coil forming the induction coefficient of the resonant circuit are formed by a bifilar winding of the source device and the at least one target device An apparatus for wireless transmission of energy and / or data. The method according to claim 1, Characterized in that the resonator is provided for each harmonic oscillation of the signal to be transmitted analyzed by Fourier transformation and the resonant frequency of the resonator corresponds to the frequency of each harmonic oscillation. An apparatus for wirelessly transmitting energy and / or data between a device and at least one target device. The method according to claim 1, Wherein the energy source disposed in the first circuit generates a square-wave output voltage. ≪ Desc / Clms Page number 21 > A method for wireless transmission of energy and / or data between a source device and at least one target device, At least one first coil (18) of at least one first circuit in the source device, at least one second coil (20) of at least one second circuit in the target device, So that the first resonator and at least the second resonator are excited, Wherein the first resonator is formed by a first resonant circuit having at least a first coil and at least a first capacitance and the first resonant circuit is arranged to be electrically isolated from the first circuit and the second circuit, Characterized in that the second resonator is formed by a second resonant circuit having at least a second coil and at least a second capacitance and the second resonant circuit is arranged to be electrically isolated from the first circuit and the second circuit Gt; and / or < / RTI > data between the source device and the at least one target device. 12. The method of claim 11, Energy is supplied to the resonator circuits by the induced voltage, the energy excites each resonant circuit, and Characterized in that the excited resonant circuit generates a magnetic field which varies with the resonant frequency of each resonant circuit so that the voltage is induced in the second coil (20) and / or the energy between the source device and the at least one target device Method for wireless data transmission. delete delete

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