DE202015101334U1 - Device for transmitting data and energy between two relatively moving objects - Google Patents

Abstract

Apparatus for contactless transmission of data and energy between two objects moving relative to one another about a common axis of rotation (A), wherein - a first coil (14) is provided on the first object, - a second coil (114) is provided on the second object is that of the first coil axially spaced with respect to the axis of rotation (A) that energy transfer by inductive coupling between the two coils (14, 114) is possible, - coaxial and rotationally fixed to the first coil (14) a first disc or annular disk-shaped An electrode carrier is provided with a first electrical conductor (12), coaxially and non-rotatably with respect to the second coil (114) a second disk-shaped or annular disk-shaped electrode carrier facing the first electrode carrier is provided with a second electrical conductor (112), wherein the first and the second electrode carrier in such a way with respect to the axis of rotation (A) axially spaced and the first and second electrical conductors (12, 112) are arranged so as to permit data transmission by electrical coupling between the first and second conductors (12, 112), and - in the radial region between the first coil (14) and the first electrical conductor (12) and / or in the radial region between the second coil (114) and the second electrical conductor (112) each coaxially between coil and conductor an arrangement of conductive material (18, 20 ; 118, 120) is provided for electrical shielding.

Description

The invention relates to a device for the contactless transmission of data and energy between two relatively moving objects about a common axis of rotation, wherein the first article comprises a first coil and the second article comprises a second coil, wherein the coils are so axially with respect to the axis of rotation spaced apart that energy transfer by inductive coupling between the two coils is possible. The invention further relates to a laser scanner with such a device.

With relatively rotating objects, it is often necessary for energy and data to be transferred between the two relatively moving objects. For example, in today's applications, it is often necessary for power and data signals to be transferred between a steering column fixed in a motor vehicle and the steering wheel. So it is e.g. necessary to transfer energy to the steering wheel in order to trigger the ignition of an airbag mounted therein. On the other hand, data signals, e.g. after pressing the horn to be transmitted so that the corresponding requested action is performed in the motor vehicle.

Another application is found e.g. in corresponding embodiments of laser scanners for monitoring an environment. Energy and data signals are described here, e.g. exchanged between a rotating sensor head and a fixed evaluation and supply unit.

DE 195 32 043 A1 describes a steering wheel for a vehicle, in which between the steering column and the relatively rotating steering wheel energy is ensured via an inductive coupling of corresponding coil systems. For signal transmission sees the DE 195 32 043 A1 the transmission on an inductive basis or on an opto-electrical basis.

The opto-electrical transmission according to DE 195 32 043 A1 requires additional optical elements. On the other hand, the possible data rates for inductive transmission of data are very limited in their height. So usually a maximum of several 10 kbit are possible, which is not sufficient for many applications.

DE 44 07 277 A1 describes a transformer for energy between two relatively rotating elements. Provided for this purpose are two coil carriers in the form of printed circuit boards, on each of which coil windings are provided which are essentially concentric with the axis of rotation of the relative movement and which serve to transmit energy via an inductive coupling between the two relatively moving objects. The coils are penetrated by ferrite cores, which cause or promote the magnetic coupling. This arrangement is according to DE 44 07 277 A1 also used for information transmission.

DE 41 20 650 A1 describes the energy and data transmission between steering column and steering wheel of a motor vehicle. An inductive coupling is effected via two opposing coils, with which the energy between the two relatively moving objects can be transmitted. The coil windings have approximately the same extent in the axial direction as in the radial direction. Radially or axially away from the coils, condenser electrodes used to transfer data are located on the relatively rotating objects.

It is the object of the present invention to provide a device with which both the energy and the data transmission between two relatively moving around a rotation axis objects can be effected without contact in a simple, effective, compact and störunanfällige manner, so that The device can also be used when only little space is available.

This object is achieved with a device for contactless transmission of data and energy with the features of claim 1. Subclaims are directed to preferred embodiments. A laser scanner with a device according to the invention for the transmission of data and energy is the subject of claim 16.

The device according to the invention for the transmission of data and energy between two objects which move relative to one another about a common axis of rotation has a first coil on the first article and a second coil on the second article. The second coil is the first coil axially spaced relative to the axis of rotation with respect to that a contactless energy transfer by inductive coupling between the two coils is possible.

Coaxially with and rotatably with the first coil, a first disk or disc-shaped electrode carrier is provided with a first electrical conductor. Coaxial with and non-rotatable with the second coil, a second disc or disc-shaped electrode carrier opposite the first electrode carrier is provided with a second electrical conductor. The electrode carrier are axially spaced from each other and the first and second electrical conductors are arranged such that data transmission by contactless electrical coupling between the first and the second electrical conductor is possible.

The term "electrical coupling" between the first and the second electrical conductor is thus to be understood here as a contactless capacitive coupling.

In the device according to the invention, between the first coil and the first electrical conductor and / or between the second coil and the second electrical conductor is also provided coaxially between coil and conductor, an arrangement of conductive material for electrical shielding. It is thus possible in an effective manner, in spite of the compact arrangement of the device, to effectively limit disturbances in the data transmission via the electrical conductors through the adjacently arranged inductive energy transmission via the coils. Nevertheless, a small design is possible because the inductive energy transfer and the electrical data transmission need not be physically far apart to prevent the otherwise occurring electromagnetic interference.

A simple and easy to handle embodiment provides that the coil or the coils are concentric with the axis of rotation of the relative movement of the objects. Advantageously, the electrical conductors for data transmission can be configured circular or part-circular, wherein the circles or pitch circles are concentric with the axis of rotation of the relative movement.

In principle, it is possible that the coils are self-supporting structures. It is particularly advantageous, however, if the first article comprises a first disk-shaped or annular disk-shaped coil carrier which carries the first coil, and the second article comprises a second disk-shaped or annular disk-shaped coil carrier which carries the second coil. Such disc or annular disc-shaped coil carriers are easy to manufacture and can be used e.g. be processed by lithographic processes to apply the coils on it.

In addition, in such an embodiment, not only the electrode carrier disc or annular disc-shaped and are axially spaced data transmission, but also the coils on the disc or annular disc-shaped coil carrier are axially spaced opposite to allow the inductive coupling for energy transfer , In this way, a very compact and simple construction is guaranteed. It is particularly simple and advantageous in this case if the coil carriers are designed directly as printed circuit boards on which the respective coil windings are applied for energy transfer. Likewise, the electrode carrier may comprise printed circuit boards to which the electrical conductors for data transmission are applied. The metal coil windings for energy transmission and the electrical conductors for data transmission can be produced on printed circuit boards very simply by lithographic processes known per se (for example vapor deposition or etching).

In this way, the geometry of the coil turns or the electrical conductor can be fixed in a simple manner and the circuit boards can themselves serve as a carrier for the coil windings and the electrical conductors. Particularly cost-effective and cost-effective to produce is when the first object of the first coil carrier and the first electrode carrier are integrally provided (that can be formed by a part) and / or on the second object, the second coil carrier and the second electrode carrier are in one piece. In this way, only one support structure, e.g. a printed circuit board per object, be provided. In each case, the coil for energy transmission and the electrical conductor for data transmission can be provided on this circuit board and processed simultaneously during manufacture.

In embodiments in which the coil carrier or the electrode carrier are provided as printed circuit boards, it is also of particular advantage that it is possible in a space-saving manner to provide further - in particular electronic - components and connecting lines.

In embodiments according to the invention, in which the first article comprises a first disk-shaped or annular disk-shaped coil carrier which carries the first coil, and the second article comprises a second disk-shaped or annular disk-shaped coil carrier which carries the second coil, the coils are advantageously designed flat. That is, they include coil turns which are juxtaposed on a surface of the respective disc or annular disc-shaped bobbin. In principle, it is possible that on the second surface of the respective bobbin in each case a further planar coil is provided which the inductive coupling, for. reinforced by a ferrite structure.

However, it is preferable if the coil turns of the first coil (on the first object) and the coil turns of the second coil (on the second object) are opposite on the opposite sides of the two coil support, as also below with reference to the in the figures embodiment shown is described.

A simple realization of the shielding between the energy-transmitting coils and the data-transmitting electrodes in an embodiment with printed circuit boards as support structures provides that holes are provided in the respective printed circuit board between the coil turns and the electrical conductor, in which conductive material is located. For this purpose, it can be provided, in particular, that the inner peripheries of the holes in the printed circuit boards are coated with metallic material in order to produce a shield which can be realized in a simple manner without weakening the support structure too much.

It is particularly advantageous if the device has a first housing shell of conductive material and / or a second housing shell of conductive material, wherein the first housing shell is non-rotatable with the first article and the second housing shell is non-rotatable with the second article. The housing shells of conductive material serve to electrically shield the system from the outside and effectively prevent interference from external influences.

In addition, such arranged and configured housing shells provide a connection to the virtual ground by causing a capacitive coupling between the real ground and the virtual ground.

It is particularly advantageous if the first housing shell is electrically connected to the electrical arrangement between the coil turns of the first coil and the first electrical conductor and the second housing shell electrically connected to the electrical arrangement of conductive material for electrical shielding between the coil turns of the second coil and is connected to the second electrical conductor.

In this way, the shielding arrangements between the respective coil turns and electrodes are electrically connected to a respective housing shell, so that an effective shielding of the data transmission against any external influences and in particular against the influences of the coils used for energy transmission is provided. Only that side of the electrode carrier that directly faces the electrode carrier on the other relatively rotating object is not surrounded by the shield.

The connection may be made, for example, by a conductive annular structure, e.g. be formed conductive foam, which is arranged coaxially to the axis of rotation between the coil and the electrode.

Particularly effective is the shielding by the housing shells, when the two housing shells at their radially outer region each comprise an angled region, wherein the angled portions of the two housing shells radially spaced from each other are adjacent. The larger the overlapping area of the shield (in particular the housing shells) and the smaller the spacing of the overlapping areas, the better the shielding effect.

Advantageously, that region of the respective coil carrier on which the respective coil is located surrounds at least on its radially outer circumference an arrangement of magnetic material and / or is arranged in its radially interior. If the coil carriers of each of the objects moving relative to one another have a corresponding arrangement of magnetic material, the inductive coupling for energy transmission is effectively amplified by the transforming effect.

In addition, a corresponding arrangement of magnetic material, which surrounds the region of the coil carrier, have a further shielding effect, which prevents the inductive energy transmission from adversely affecting the electrical data transmission.

In a particularly advantageous manner, this magnetic arrangement is made of soft magnetic materials, in particular "ferrite".

The arrangement of magnetic material on the respective object has a particularly effective and effective effect if it has a circular or part-circular section concentric with the axis of rotation of the relative movement of the articles, which passes through the printed circuit board, and / or a second circle concentric with the axis of rotation of the relative movement of the objects - or part-circular portion which passes through the circuit board and has a larger radius than the first section.

It is thus possible to surround a concentric with the axis of rotation of the relative movement of the objects arranged coil on the circuit board in the circumferential direction with the magnetic arrangement. In this way, the inductive coupling is intensified by the coil and on the other hand improves the shield.

In particular, in the embodiment in which the elements are in the manner described on a respective printed circuit board, it can be provided that a drive motor for generating the relative movement of the two objects or the Drive shaft of a corresponding drive motor passes through the printed circuit boards to ensure the most compact possible construction.

A substantially rotationally symmetrical about the axis of rotation of the relative movement arrangement and configuration of the individual elements of the device according to the invention and its preferred embodiments is advantageous because of the ease of manufacture, ease of use and ease of operation.

In addition, the device according to the invention and its particularly preferred embodiments, due to the good shielding, in particular between the data-transmitting electrodes and the energy-transmitting coils, enables data transmission in the single-digit 100 MHz range at data rates of about 30 Mbit, whereby a more cost-effective and energy-saving operation is possible than when a data transmission in the GHz range is provided.

The device according to the invention can be used particularly advantageously for the transmission of energy and data in laser scanners in which a sensor head rotates relative to a supply unit. Here in particular the compact design and yet precise data transmission is advantageous, which can be achieved by the inventive device for the transmission of energy and data and their advantageous embodiments.

Preferred embodiments will become apparent from the dependent claims, the accompanying drawings and / or the embodiments described below.

The invention will be described in detail with reference to the accompanying figures, which show an embodiment. Showing:

1 an embodiment of a device according to the invention in a schematic representation in the lateral section,

2 a slightly perspective top view of a printed circuit board for use in an embodiment of the device according to the invention,

3 a ferrite assembly for use in an inventive arrangement of 1 or 2 , and

4 a representation in which the ferrite of the 3 and the circuit board of the 2 assembled.

1 shows an embodiment of a device according to the invention in a lateral section in a schematic representation. In the lateral section you can see two opposing circuit boards 10 . 110 , which are mutually movable about the axis A relative to each other.

2 shows in particular the printed circuit board 10 in a line of sight that in 1 from below would be. You can see here that side of the circuit board 10 , the leaderboards 110 faces.

On the radially inner area 10 ' the circuit board 10 is on the side of the circuit board 110 facing, a coil 14 with coil windings which are substantially concentric with the axis of rotation A of the relative movement. These coil turns are on average the 1 schematically as just a black bar at the bottom of the printed circuit board section 10 ' shown. In 2 is the coil on the circuit board in its area 10 ' not shown. The coil turns are formed on the respective printed circuit board by vapor-deposited or etched tracks. For the coil 14 on the circuit board 10 and the coil turns forming it become the same reference numeral in the present text for the sake of brevity 14 used.

In the outer area of the printed circuit board 10 is on the side of the circuit board 110 facing, an electrode 12 , which is arranged concentrically to the rotation axis A as a conductor ring annular. One recognizes this electrode 12 in 1 on average and in 2 in the plan view.

In 1 not recognizable, however in 2 It is clearly visible that the printed circuit board area of the printed circuit board 10 on which the electrode 12 is applied, and the printed circuit board area 10 ' on which the coil 14 is applied, by corresponding radial webs 11 connected to each other. In the described embodiment, therefore, form the coil carrier area 10 ' and the electrode carrier with the electrode 12 a one-piece circuit board 10 ,

The circuit board 10 is about one or more insulating spacers 16 ( 1 ) with a metallic housing shell 22 connected, which may include, for example, a thermoforming sheet. In the described embodiment, this housing shell 22 with the drive shaft 52 a drive motor 50 rotatably connected, so that the housing shell 22 along with the circuit board 10 and the structures applied to it.

In or on the circuit board 10 is - with respect to the electrode 12 offset radially inward - a shielding structure 18 . 20 provided, which is configured in the described embodiment as follows:
In the circuit board 10 are located radially opposite the electrode 12 inside offset on a ring arranged holes 20 whose interior is metallically lined, eg by a corresponding evaporation process. These metal-lined holes 20 stand over a metallic material 18 with the housing shell 22 in electrical connection. In the metallic material 18 it may be, for example, conductive foam.

As it is in 1 is visible, the housing shell points 22 on the radially outer side of the printed circuit board 10 an angled area 26 on. Overall, this results in a shield structure consisting of the metal-lined holes 20 , the ring-shaped material structure 18 , the planar surface of the housing shell 22 and the angled area 26 the housing shell 22 is formed.

On the drive motor 50 is a housing shell in the described embodiment 122 firmly mounted. This housing shell 122 carries a structure that is the structure described in the housing shell 22 is intended, corresponds and meets her. So here is an electrode 112 on a printed circuit board area of a printed circuit board 110 provided by one or more insulating spacers 116 with the housing shell 122 connected is. An annular structure of metallic foam 118 connects the housing shell 122 with holes 120 in the circuit board 110 are arranged annularly and are lined with metal. At the radially outermost region of the housing shell 122 this has an angled area 126 on.

It can be seen that the opposing electrodes 12 respectively. 112 on the opposing circuit boards 10 respectively. 110 are effectively shielded by the shielding structure passing through the housing shells 22 . 122 whose angled areas 26 . 126 , the structures of metallic foam 18 . 118 and the metal-lined annularly arranged holes 20 . 120 is formed. Particularly effective is the shield to the outside, as in the embodiment shown, the angled areas 26 . 126 the two housing shells 22 . 122 overlap.

The housing shells 22 . 122 and in particular the angled areas 26 . 126 also form an effective capacitive coupling of the mass between the relatively rotating elements.

Radial inside the structure with the electrodes 12 are the already described lithographically produced coil turns 14 on the circuit board area 10 ' intended. These coil turns 14 stand on the in 1 lower printed circuit board 110 in their area 110 ' coil windings 114 opposite, the same as the coil turns 14 are produced lithographically on the respective circuit board. For the coil on the circuit board 110 and the coil turns forming it become the same reference numeral in the present text for the sake of brevity 114 used.

The circuit board area 10 ' is made of a ferrite structure 24 surrounded in 3 is shown isolated. One sees that this structure is angled areas 30 . 32 that has the circuit board 10 ' push through ( 1 ). In this case, the outer angled section 32 only at the areas cutouts, through which the web areas of the circuit board 10 reach through the circuit board area 10 ' connect to the rest of the circuit board.

The ferrite structure 24 acts in this way particularly effective with a ferrite structure 124 on the other circuit board 110 together. The second ferrite structure 124 encloses the printed circuit board area 110 ' the second circuit board 110 in the same way as the ferrite structure 24 the circuit board area 10 ' the circuit board 10 , In this way, the inductive coupling between the opposing coils 14 . 114 through the ferrite structures 24 . 124 strengthened effectively transformatory. In addition, the ferrite structures act 24 . 124 additionally shielding in such a way that the electrical coupling of the electrodes 12 . 112 for data transmission is not or less by the inductive coupling between the coils 14 and 114 is disturbed.

In 4 you can see the printed circuit board of the 2 together with the ferrite structure of 3 , You can see here in the same perspective on the circuit board 10 as in 2 , Through the corresponding recesses in the circuit board 10 between the inner area 10 ' and the outer area of the circuit board protrudes the angled area 32 the ferrite structure in 3 is shown. Radial inside the circuit board area 10 ' is the angled area 30 the ferrite structure 24 , In the 2 to 4 In each case the side is shown, that of the second printed circuit board 110 facing, which has the same structures in the same arrangement.

The relatively rotating structures thus include corresponding opposing elements, wherein in 1 the elements of the second structure repeat the reference signs of the first structure ("xx") with an imaginary one ("1xx").

During operation, the drive shaft moves 52 relative to the engine 50 , In this respect, the housing shell moves 22 , the circuit board 10 , the electrode 12 and the coil turns 14 together with the ferrite core 24 around the axis of rotation A. These elements thus form the "rotor", while the stationary elements form the "stator" of the arrangement. Stationary is the housing shell in the described embodiment 122 with the engine 50 connected. In this respect, also move the circuit board 110 with the electrode 112 and the coil turns 114 Not. So it finds a relative rotational movement between the coil turns 14 and 114 instead, which provide an inductive coupling for energy transfer. The opposing electrodes 12 and 112 are used for data transmission between the elements rotating relative to the axis A.

For example, the drive motor 50 with the stationary housing shell 122 be provided on the stationary part of a laser scanner, while the housing shell 22 with the associated elements together with the drive shaft 52 turns relative to it.

With the drive shaft 52 can then be connected, for example, the sensor head of the laser scanner. The device according to the invention then effectively enables the transmission of energy via the inductive coupling between the coils 14 and 114 and the data transfer from the sensor head to the stationary elements of the laser scanner via the electrodes 12 and 112 ,

During the relative rotation of the elements about the axis of rotation A, despite the rotational movement, it is ensured that the electrodes 12 . 112 and the overlying data transmission is effectively shielded from the environment as the electrodes 12 . 112 enclosed on all sides by metallic material, with the exception of the side facing the other circuit board.

In the described embodiment, the data transmission is via the electrodes 12 . 112 radially outside the energy transfer via the coil turns 14 . 114 described. Not shown, but equally possible, is an arrangement in which the inductive energy transfer across the coil turns 14 . 114 radially outside the electrodes 12 . 112 on the circuit board 10 . 110 is provided. Otherwise, and in particular with regard to the shielding between the data transmission electrodes and the energy transmission coils, such an arrangement is analogous to the one described above.

LIST OF REFERENCE NUMBERS

10, 110

 circuit board

10 ', 110'

 radially inner region of the printed circuit board

11

 radial web

12, 112

 annular electrode

14, 114

 Coil, coil turns

16, 116

insulating spacer

18, 118

 annular metallic foam structure

20, 120

 annularly arranged metal-lined holes

22, 122

 shell

24, 124

 ferrite

26, 126

 angled portion of the housing shell

30, 130

 radially inner angled region of the ferrite structure

32, 132

 radially outer angled portion of the ferrite structure

50

 drive motor

52

 drive shaft

A

 Axis of relative rotational movement

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 19532043 A1 [0004, 0004, 0005]
• DE 4407277 A1 [0006, 0006]
• DE 4120650 A1 [0007]

Claims (16)

Device for contactless transmission of data and energy between two objects moving about a common axis of rotation (A) relative to one another, wherein - on the first object a first coil ( 14 ) is provided, - on the second object, a second coil ( 114 is provided, which is axially spaced from the first coil in such a way with respect to the axis of rotation (A), that an energy transmission by inductive coupling between the two coils ( 14 . 114 ) is possible, - coaxial and rotationally fixed to the first coil ( 14 ) a first disc or disc-shaped electrode carrier with a first electrical conductor ( 12 ) is provided, - coaxial and rotationally fixed to the second coil ( 114 ) a first disc or disc-shaped electrode carrier opposite the first electrode carrier with a second electrical conductor ( 112 ), wherein the first and the second electrode carrier are so axially spaced with respect to the axis of rotation (A) and the first and the second electrical conductor ( 12 . 112 ) are arranged such that a data transmission by electrical coupling between the first and the second conductor ( 12 . 112 ) is possible, and - in the radial region between the first coil ( 14 ) and the first electrical conductor ( 12 ) and / or in the radial region between the second coil ( 114 ) and the second electrical conductor ( 112 ) coaxial between coil and conductor an arrangement of conductive material ( 18 . 20 ; 118 . 120 ) is provided for electrical shielding. Device according to claim 1, characterized in that the electrical conductors ( 12 . 112 ) are circular or part-circular, wherein the circles or pitch circles are concentric with the axis of rotation (A) of the relative movement of the objects. Device according to claim 2, characterized in that the coil turns of the first coil ( 14 ) and the first electrical conductor ( 12 ) are arranged concentrically to each other and the coil turns of the second coil ( 114 ) and the second electrical conductor ( 112 ) are arranged concentrically with each other. Apparatus according to claim 3, characterized in that the first article comprises a first disc or annular disc-shaped coil carrier which carries the first coil, and the second article comprises a second disc or annular disc-shaped coil carrier which carries the second coil. Apparatus according to claim 4, characterized in that the first coil carrier and the first electrode carrier are in one piece and from a first printed circuit board ( 10 ) are formed and that the second coil carrier and the second electrode carrier are in one piece and from a second printed circuit board ( 110 ) are formed. Device according to claim 5, characterized in that the coil turns of the first coil ( 14 ) flat on the first printed circuit board ( 10 ) are applied and the coil turns of the second coil ( 114 ) flat on the second printed circuit board ( 110 ) are applied. Device according to one of claims 5 or 6, characterized in that the arrangement for electrical shielding holes ( 20 ; 120 ) in the respective printed circuit board ( 10 ; 110 ) in the radial region between the coil ( 14 ; 114 ) and the electrical conductor ( 12 ; 112 ), in which conductive material is located. Device according to one of the preceding claims, characterized by a first housing shell ( 22 ) made of conductive material which is non-rotatable with the first article, and / or a second housing shell ( 122 ) of conductive material which is non-rotatable with the second article. Apparatus according to claim 8, characterized in that the first housing shell ( 22 ) electrically with the arrangement ( 18 . 20 ) of conductive material for electrical shielding between the first coil ( 14 ) and the first electrical conductor ( 12 ) and the second housing shell ( 122 ) electrically with the arrangement ( 118 . 120 ) of conductive material for electrical shielding between the second coil ( 114 ) and the second electrical conductor ( 112 ) connected is. Device according to claim 9, characterized in that the arrangement of conductive material in the radial region between the respective coil and the respective electrode (an annular structure 18 ; 118 ) coaxial to the axis of rotation (A) between the respective coil ( 14 ; 114 ) and the respective electrode ( 12 ; 112 ) is arranged and with the respective housing shell ( 22 ; 122 ) is electrically connected. Device according to one of claims 8 to 10, characterized in that the two housing shells ( 22 ; 122 ) each have at least one disc-shaped, aligned perpendicular to the axis of rotation region and a radially outwardly located therefrom angled region ( 26 ; 126 ), wherein the angled regions ( 26 ; 126 ) of the two housing shells ( 22 ; 122 ) are radially spaced from each other next to each other. Device according to one of the preceding claims, characterized by a first arrangement ( 24 ) of magnetic material, in particular of ferrite, which is the first coil ( 14 ) surrounds at its radially outer periphery and / or is arranged in its radially inner. Apparatus according to claim 12, characterized by a second arrangement ( 124 ) of magnetic material, in particular of ferrite, the second coil ( 114 ) surrounds at least at its radially outer circumference and / or is arranged in its radially inner and in transformer action with the first arrangement ( 24 ) cooperates of magnetic material. Device according to at least one of claims 12 or 13, insofar as it depends directly or indirectly on claim 4, characterized in that the arrangement of magnetic material comprises at least one section ( 30 . 32 ; 130 . 132 ), which passes through the coil carrier. Device according to at least one of the preceding claims, insofar as it depends directly or indirectly on claim 4, characterized in that a drive motor ( 50 ) or a drive element ( 52 ) of a drive motor for generating the relative movement of the two objects passes through the coil carrier.  Laser scanner with a device according to one of the preceding claims for transmitting energy and data between a supply unit forming the first object and a sensor head which rotates about a rotation axis (A) and forms the second object.

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