DE10356109A1 - Computer tomograph system has rotating and stationary parts linked by an inductive coupler that meshes with a stationary conductor arrangement dependent on the position of the rotating part - Google Patents

Abstract

System has a rotating part (1) that holds at least an X-ray tube (4) and a detector arrangement (5) as well as a stationary part (2). A bearing is provided for the rotational mounting of the rotating part and at least an inverter (6) for generating an alternating current at a first frequency. The stationary part has at least a conductor arrangement (7) that is supplied with alternating current from the inverter, while the rotating part has an inductive coupler (8) which meshes with the conductor arrangement in a position dependent manner and couples electrical energy from it.

Description

Technical area

The The invention relates to a computer tomograph with non-contact Energy transfer. in this connection the transfer takes place the energy needed by the x-ray tube contactless between a stationary Power supply and the rotating X-ray tube. At the same time more can Consumers such as detectors or data acquisition systems on the turning Part to be supplied with.

State of the art

at conventional computer tomographs carry the transmission of electrical energy between the stationary arranged power supply and the rotating part by means of mechanical slip ring systems. This is a brush, preferably made of carbon material on a slideway, for example made of brass. A disadvantage of this arrangement is the short life, the regular maintenance intervals, in which the brushes need to be replaced and this pollution caused by coal erosion.

An improvement is for example in the US 4,91 2,735 disclosed. In it, the computed tomography system is trained as a rotating transmitter. On the stationary side, a primary winding, which is fed by a primary AC source is arranged. This opposite is mounted on the rotating side of a secondary winding. For better coupling between the primary winding and the secondary winding, these are surrounded by rotationally symmetrical cores of soft magnetic materials. However, this device is not suitable for transmitting high power in the range of 100 kilowatts, as they are needed to power modern x-ray tube suitable. This is because the transformer has a high stray inductance due to the unavoidable air gaps between the stationary and rotating sides. This behaves electrically like a series inductance and thus represents a high series impedance for the current to be transmitted, which limits the transmittable power.

Another improvement is in the US 5,608,771 disclosed. Here, the leakage inductance of the transmission is supplemented by means of a further inductance and a capacitance to form a resonant circuit. At the same time, the high-voltage transformer is connected directly to the secondary winding of the rotating part. With this arrangement, a certain leakage inductance can now be tolerated. However, a very high coupling factor of the rotary transformer is necessary, since otherwise too high a current component would flow as reactive current through the primary winding of the transformer. In addition, with high leakage inductance hardly a reasonable adaptation to the high-voltage transformer would be possible.

adversely on the two cited arrangements is the high material usage on expensive, high-permeability ferromagnetic materials. So would be at a typical dimensioning some 100 kilograms of iron or Ferrite material necessary. These would also be the total weight significantly increase the computer tomograph. Is particularly disturbing the size Mass on the rotating part, as well as the storage accordingly sustainable must be designed. Another disadvantage arises in the high demands on the mechanical tolerances in the rotation between the rotating and the stationary part. So should the air gap between the primary side in the stationary Part and the secondary side in the rotating part Ideally in the range of a few tenths of a millimeter be. The typical tolerances that can be achieved by computer tomographs are but by almost an order of magnitude higher. Especially Critical here is the operation at a relative to the horizontal axis inclined rotating part, since here the rotating part opposite the stationary part tilted out of his normal position.

Presentation of the invention

Of the Invention is based on the object, a device for contactless transmission electrical energy between the stationary and the rotating part of a computed tomography the state of the art cheaper to shape and continue to train in such a way that the mass of entire arrangement is reduced and continues to be larger mechanical Tolerances between the rotating part and the stationary part are allowed.

A inventive solution this Task is in the independent claims specified. Weiterbildun conditions of the invention are the subject of the dependent claims.

The device according to the invention comprises a computer tomograph with a rotating part 1 and a stationary part 2 , The stationary part comprises a warehouse 3 for rotatably supporting the rotating part 1 , Furthermore, at least one inverter (inverter) is connected to the stationary part. 6 provided for generating an alternating current. This alternating current has at least the fundamental wave of a first frequency. Furthermore, a conductor arrangement 7 present, which of the alternating current of a or more inverters 6 is fed. This conductor arrangement is arranged at least along a part of a circular path on the stationary part. A conductor arrangement according to the invention consists essentially of electrical conductors which are mounted on a support or on supports 23 are stored. Such a conductor arrangement is much easier to implement than the known from the prior art rotating transformers in which the primary side already a completely formed primary side of a transformer is necessary in place of the simple conductor arrangement. In addition to development and insulation, this also includes iron or ferrite cores, which have to be manufactured with low mechanical tolerances to form the smallest possible air gap between the primary side (stationary) and the secondary side (rotating). To decouple the electrical current from the conductor arrangement is an inductive coupler 8th attached to the rotating part. This inductive coupler 8th has a length which is short of the length of the conductor arrangement 7 is and is moved by the movement of the rotating part relative to the stationary part along the conductor arrangement. That of the inductive coupler 8th decoupled power can now be used to power consumers such as the X-ray tube 4 or also a detector arrangement 5 be used on the rotating part.

In This representation becomes the term "current" in the sense of a general concept for electrical energy used. Likewise could Instead, they also referred to the term tension or energy become.

Another device according to the invention is designed similar to the device described above. There are, however, ladder arrangement 7 and couplers 8th interchanged. Such is the coupler 8th the stationary part 2 assigned and is from the inverter 6 powered by alternating current. Opposite the coupler 8th mobile is the ladder arrangement 7 on the rotating part 1 arranged. Accordingly, the now of the conductor assembly 7 decoupled power to power consumers such as the X-ray tube 4 or also the detector arrangement 5 be used on the rotating part.

In a particularly advantageous embodiment of the invention, a conductor arrangement provides which 1, 2 or even 3 parallel electrical conductors ( 9a . 9b . 9c ). Furthermore, these conductors are flowed through by currents such that the sum of the currents through all conductors at each angular position of the conductor arrangement is equal to zero. If the conductor arrangement is cut through at any point by a radial cut at any point and measured at this point currents, the sum of the currents is zero. This can be realized, for example, in that, in the case of a two-conductor system, the current flows in a first direction through a conductor and the current of the same magnitude flows in the opposite direction through the second conductor. In a three-wire system, the currents of the three conductors could be phase shifted by 120 degrees each at the same amplitude. By such a configuration, the electromagnetic emission of the device can be substantially reduced. Since the sum of the currents at each piece of the conductor arrangement is zero, the external magnetic field is also zero. In order to achieve a good symmetrization, for example, a balancing transformer or a common mode filter can be used. To control several conductors, a phase-shift bridge in the inverter is particularly suitable.

In a further advantageous embodiment of the invention, the conductor arrangement 7 in the circumferential direction several segments ( 10a . 10b . 10c ) on. By such a segmentation different types of electrical energy, such as the high power to power the x-ray tube and the electrical auxiliary supply can be transmitted through separate segments. Likewise, by parallel connection of several segments, the total transmitted power can be increased. Of course, a plurality of conductor arrangements parallel to each other, ie, for example, in the axial direction Rich next to each other or in the radial direction can be arranged with each other with corresponding couplers.

A further advantageous embodiment of the invention provides that a plurality of couplers ( 8a . 8b . 8c ) are provided, wherein at any time at least one coupler in engagement with the conductor arrangement 7 is. The term of the time refers here to a rotational movement of the rotating part 1 opposite the stationary part 2 , Put differently, this means that at every position of the rotating part 1 at least one coupler 8th engaged with the conductor assembly 7 stands. Thus, an energy transfer is possible at any time of the movement or to any place.

In a further advantageous embodiment of the invention has at least one tap 8th soft magnetic material for concentration of magnetic flux. Thus, the tap can be provided, for example, with iron material, preferably in the form of iron sheets or else ferrite materials. Particularly advantageous here is the use of iron or ferrite especially powder, which is bound by plastic. Optionally or additionally, soft magnetic material can also be applied to the conductor arrangement 7 be provided to improve the coupling.

A further advantageous embodiment of Invention provides that multiple inverters 6 are provided, wherein in each case an inverter 6 optionally a ladder 9 and / or a segment 10 the conductor arrangement feeds.

In a further advantageous embodiment of the invention, at least one inverter for feeding a conductor 9 and / or a segment 10 the conductor arrangement 7 formed at or near the respective resonance frequency.

In another advantageous embodiment of the invention optionally the conductor arrangement 7 and / or at least one tap 8th supplemented by at least one capacitor and optionally one or more additional inductances to a resonant entity at a predetermined resonant frequency. It is particularly advantageous if the arrangement for forming a series resonance is supplemented by adding a series capacitance and an optional series inductance if the inductances of the conductor arrangement or the tap are not sufficiently large. Alternatively, the arrangement can also be used to form parallel resonances by adding at least one parallel capacitance parallel to the conductor arrangement 7 or to tap 8th be educated. The operation of the inverter 6 can now be adapted to the different resonance conditions. For example, a regulation of the output power is done by frequency variation of the inverter. Thus, when outputting an output current of the inverter at the resonant frequency, the maximum power will certainly be transmitted, while depending on the quality of the resonant circuit in case of frequency deviations a lower power is transmitted.

It is particularly advantageous at low load impedances the inverter 6 to regulate a series resonance, since this has a rising with decreasing load impedance quality. At high load impedances, however, it is advantageous to control a parallel resonances, since with parallel resonances the quality increases with the load impedance. Conveniently, a switching device is provided which initially the load impedance, for example from the ratio of output voltage to output current of the inverter 6 determined and configured accordingly the frequency control of the inverter to parallel resonance or series resonance.

Basically, a system of inverters 6 , Conductor arrangement 7 as well as tap 8th optionally used for power transmission and at the same time for controlling or regulating the transmitted power or else exclusively for pure power transmission. If the transmitted power controlled or regulated by the system, so for example, a pulse width modulation in pulse packets of the output signal or a shift in the frequency away from the resonant frequency is necessary. In principle, the frequency of the inverter reduces the efficiency of the inverter. Likewise, the emissions of high-frequency signal components also increase. Alternatively, the inverter may always be operated at an operating point of optimum efficiency at the resonant frequency. In order to control the output output now, for example, on the primary side another switching power supply or a power factor correction circuit with an adjustable range within wide limits output range necessary. If the inverter is operated at the resonant frequency, its efficiency is very high, so that the high-frequency output current does not have to be measured to measure the transmitted current. Rather, the direct current consumption of the inverter can be used for this purpose.

In a further advantageous embodiment of the invention is at least one inverter 6 designed to detect different load conditions, so that it can detect if this associated segment of the conductor arrangement 7 not engaged with at least one tap 8th stands. According to this detection is now the inverter 6 switch off its output signal or control to an idling frequency.

Furthermore, at least one inverter can be 6 designed for delivery in signals on at least a second frequency. Furthermore, on the rotating part 1 at least one frequency-selective means for selection of this second frequency is formed, so that now preferably decouples the energy transmitted at the second frequency and hereby at least one other consumer, such as a control computer or the detector array 5 fed.

In a further advantageous embodiment of the invention, the inverter 6 designed such that the duty cycle of its output current can be selectively changed by a control unit. Advantageously, the output frequency is not influenced. By changing the duty cycle, the spectral distribution of the output current changes. Thus, with a duty cycle of 50 percent, corresponding to a symmetrical output signal, the proportion of even multiples of the fundamental frequency f0, ie 2 * f0, 4 * f0, 6 * f0 etc., ideally approaches zero. If the duty cycle to unbalanced output currents, for example, even slightly changed to 49 and 48 percent, or on a larger scale to 40 or 30 percent, the amplitude of the even-numbered multiples increases. By selective filtering of ge radzahligen multiples on the rotating part can now selectively a certain proportion of the transmitted power, for example, to supply smaller consumers such as a control computer or the detector arrangement are coupled out. Advantageously, it is still necessary to provide an auxiliary supply which, in the event that the inverter configured for delivering high power is not active, because, for example, the x-ray tube does not have to be supplied, will supply the smaller consumers.

A further advantageous embodiment of the invention provides at least one inverter 6 for the delivery of a frequency modulated output current. The modulation of the output frequency widens the individual spectral lines of the output signal, while at the same time reducing their amplitude. This results in improved EMC properties of the system. The modulation frequency must be greater than or equal to 100 Hz, so that it is greater than a measurement interval of the common EMC standards. Furthermore, the modulation deviation, ie the frequency variation, should be chosen to be so small that there are no significant fluctuations in the current on the rotating side.

description the drawings

The Invention will be described below without limiting the general inventive concept of exemplary embodiments described by way of example with reference to the drawings.

1 shows an example of a device according to the invention in a perspective view.

2 shows in schematic form a device according to the invention, as in 1 shown, on average.

3 shows a section of the upper area 2 a device according to the invention.

4 shows an electrical block diagram of an exemplary device according to the invention.

In 5 an arrangement with a single conductor is shown.

6 shows an arrangement with two electrical conductors.

7 shows an arrangement with three electrical conductors.

8th shows a carrier 41 with plates of soft magnetic material attached 44 ,

9 shows an arrangement with three parallel conductors.

10 shows an arrangement with segmented conductors.

1 shows an example of a device according to the invention in a perspective view. The computed tomography (CT scanner) consists of two main mechanical components. A stationary part 2 serves as a base and carrier of the whole device, in which the rotating part 1 rotates. The patient is positioned on a couch in the opening of the rotating part. For storage of the rotating part 1 serves the camp 3 which of the hollow profile 15 of the stationary part 2 is held. This bearing is designed in the exemplary embodiment as a ball bearing. Of course, various other types of bearings can be used for this purpose. The scanning of the patient by X-rays is an X-ray tube 4 and one of these oppositely disposed detector 5 intended. X-ray tube 4 and detector 5 are on the rotating part 1 rotatably arranged. To drive the rotating part is a motor 20 intended. A slip ring 16 , which on the rotating part 1 attached, serves together with the Schleifringabgriff 21 , the stationary part 2 is attached, for the transmission of auxiliary and control signals. Thus, for example, safety signals such as for the release of the X-ray radiation can still be transmitted via mechanical sliding contacts, as currently required by the safety standards. Alternatively, the activation signal for the X-ray tube could also be transmitted without contact. To meet the safety standards, this signal would have to be repeated at regular intervals. If the signal from the rotating part is not received at these intervals, the X-ray tube is deactivated. The still required in the mechanical configuration two sliding contacts are virtually maintenance-free due to the low current load and cause a much lower abrasion and thus a lower pollution than the contacts previously used for energy transfer. In parallel with this arrangement, for example, the image data of the detector arrangement can be made in a contactless manner 5 to the stationary part 2 be transmitted. For energy transfer, ie in particular for the transmission of that high energy, which is required by the X-ray tube, is at the stationary part 2 a ladder arrangement 7 provided which of the inverter (inverter) 6 is fed. The tap of the signals from this ladder arrangement 7 done by means of a coupler 8th on the rotating part 1 , To ensure the function is at least one coupler 8th provided. Selbstver Of course, also several couplers 8th be provided. These can optionally be connected in parallel or also for the individual tap of the supply energy for the x-ray tube 4 , the detector arrangement 5 or other electronic components.

2 shows in schematic form a device according to the invention, as in 1 shown, on average.

Therein are the in 1 Parts shown marked with the same reference numerals.

3 shows a section of the upper area 2 a device according to the invention. In this illustration, most of the parts described above can be seen more clearly. Furthermore, the functional relationship of the parts is clearer. The stationary part 2 is in the illustrated area to increase the stability as a hollow profile 15 educated. At this is by means of a warehouse 3 the rotating part 1 rotatably mounted. The ball bearing 3 has an outer, fixed (stationary) bearing ring 3a on, which by means of several screws 14 at the stationary part 2 is attached. Opposite this is by means of the balls 3b the inner bearing ring 3c rotatably mounted. At this is by means of several fastening bolts 13 on one side (shown in section on the right) a cylinder 11 and on the other side a disc 12 attached. The disc 12 wears most of the rotating part 1 attached parts, in particular the X-ray tube 4 as well as in the detector arrangement 5 , The cylinder 11 wears a slip ring 16 , which by means of screws 17 on the cylinder 11 is attached. At this slip ring is exemplified here a coupler 8th mounted on a support member 18 which by means of screws 19 on slip ring 16 is attached. This coupler 8th Here, for example, has a U-shaped core made of soft magnetic material, such as iron or ferrite material. For energy transfer is the coupler 8th engaged with the conductor assembly 7 , The Leiteran order shown here 7 exemplifies two parallel conductors 9a and 9b on. These ladders are by means of the supports 23a and 23b at the stationary part 2 attached. For clean positioning and easy assembly of the conductor arrangement 7 is still a carrier plate 22 , which is advantageously made of soft magnetic material provided.

In 4 an electrical block diagram of an exemplary device according to the invention is shown. The supply of the entire arrangement is advantageously carried out via a 3-phase network with the usual mains frequency, here for example 50 Hz. Of course, a two-phase or DC power supply is possible. The input circuit 30 has the usual filters as well as a rectifier circuit, preferably with power factor correction (PFC). The rectified current at the output 31 is powered by an inverter (inverter) 32 which typically has 2.4 or more semiconductor power switches converted into a high frequency alternating current. These semiconductor power switches may be configured, for example, in the known half-bridge or full-bridge circuits. As a semiconductor switch IGBTs or MOSFETs are preferably suitable. The preferred frequency range is above the human hearing threshold ie 20 kHz and extends to an upper frequency of about one MHz, to the modern semiconductor switch for high performance are economically used. The high frequency alternating current is at the output 33 delivered and by means of a series inductance 34 as well as a serial capacity 35 in the ladder arrangement 7 fed.

The resonance frequency of the arrangement results from the inductance 34 and the inductance of the conductor arrangement 7 along with the capacity 35 , Is the inductance of the conductor arrangement 7 sufficiently large, so can the inductance 34 omitted. The inductance of the conductor arrangement 7 is composed of an inductance of the conductor itself as well as the transformed inductance 36 of the coupler 8th and the coupling factor between the conductor arrangement 7 and the coupler 8th , The one from the coupler 8th tapped output current can now be the high voltage generator 38 which is a high voltage 39 for feeding the X-ray tube 4 be supplied generated. Parallel to the high voltage generator 38 can also have more consumers 40 be fed. The connection to the coupler 8th can be done either directly or with the interposition of a series capacity. This results in a second secondary-side resonant circuit. Operation of the inverter is conveniently at or near the resonant frequency of the system. Control of the transmitted power may, for example, be accomplished by controlling the operating frequency of the inverter so that, at a lower power requirement, a frequency away from the resonant frequency is selected. Likewise, however, a control of the power could be done by the input circuit, which according to the power demand their DC voltage 31 established. In this case, the following inverter can be operated with optimum efficiency at the resonant frequency of the circuit.

To adapt the impedance ratios, it may be necessary to switch at various points of the arrangement Ü transformer (transformer). This can be especially between the inverter 6 and the conductor arrangement 7 , as well as between the coupler 8th and the load will be necessary. If the inverter is used to power the coupler 8th used, so a transformer between change judge and coupler or provide between the conductor arrangement and load. Likewise, it makes sense to use, in particular behind the inverter or on the conductor arrangement, a balancing transformer (with a soft magnetic core of high quality) or a common mode filter with a lossy soft magnetic core.

In addition, on the load side, a regulation of the output voltage or the current delivered, such as be provided by a switching power supply. So certainly the high voltage generator 38 as well as the auxiliary supply 40 have a control of the output voltage.

In 5 an arrangement with a single conductor is shown. A carrier of the entire ladder arrangement 41 , which consists for example of metal for shielding or also of an insulating material, carries an electrical conductor 9 by means of a support 23 , For tapping the current along the conductor runs a coupler comprising a core of soft magnetic material 42 as well as a winding 43 for decoupling the electrical current.

6 shows an arrangement with two electrical conductors. The conductor arrangement here comprises a carrier 41 and a soft magnetic material located thereon 44 for guiding the magnetic field. The parallel electrical conductors 9a and 9b be supported by means of 23a and 23b stored. The coupler here has a U-shaped configured core 42 made of soft magnetic material with at least one winding 43 on.

In 7 a corresponding arrangement with three conductors is shown. The ladder 9a . 9b . 9c are by means of supports 23a . 23b . 23c attached to the carrier. The coupler points here on the core 42 three windings 43a . 43b . 43c on.

8th shows a carrier 41 with plates of soft magnetic material attached 44 , By such an arrangement, a simple assignment of the carrier with prefabricated plate pieces, which are optionally rectangular or rounding done, take place. Conveniently, not only and for the sake of simplicity in the drawing shown a part of the circumference, but the entire circumference occupied with pieces of plate.

In 9 is an embodiment of the invention with three parallel conductors 9a . 9b . 9c shown. These are on the carrier 41 arranged. The open ends are powered by the inverter. By way of example, the three conductors are connected together here at one end. The feed currents from the inverter are expediently phase-shifted by 120 degrees in each case. Of course, in addition to the gezeig th here arrangement with three conductors every other number of conductors can be used.

10 shows an embodiment of the invention, in which the conductors in conductor segments 10a . 10b . 10c are divided. This exemplified three conductor segments shown, but also two or more conductor segments can be used. The conductor segments may each consist of one or more parallel conductors. Power is supplied by a common inverter or individual inverter for individual conductor segments or groups of conductor segments. In addition to a frequency multiplex, a local multiplex in the transmission is also possible here. For this purpose, advantageously several couplers 8th used. Thus, several supply currents, for example, for the X-ray tube and for the detector array or other consumers can be transmitted separately from each other at the same time.

1

rotating part

2

stationary part

3

camp

4

X-ray tube

5

detector array

6

inverter

7

conductor arrangement

8th

coupler

9

electrical ladder

10

conductor segments

11

cylinder

12

disc

13

mounting bolts

14

screw for mounting the bearing

15

hollow profile

16

slip ring

17

screw for slip ring attachment

18

Carrier of the coupler

19

screw for carrier attachment

20

engine

21

Schleifringabgriff

23

Support

30

Input

31

output for direct current

32

inverter

33

output for HF alternating current

34

Series inductance, stationary part

35

Train Capacity, Stationary Part

36

Inductance of the coupler 8th

37

Serial capacity, rotating part

38

High voltage generator

39

output for high voltage

40

auxiliary supply

41

Carrier of conductor arrangement

42

core made of soft magnetic material

43

winding of the coupler

44

soft magnetic material

Claims (13)

Computed tomography system comprising a rotating part ( 1 ) for receiving at least one x-ray tube ( 4 ) and a detector arrangement ( 5 ), as well as a stationary part ( 2 ) - a warehouse ( 3 ) for rotatably supporting the rotating part ( 1 ), and - at least one inverter ( 6 ) for generating an alternating current of a first frequency, characterized in that the stationary part ( 2 ) a conductor arrangement ( 7 ), which of the alternating current of one or more inverters ( 6 ) and the rotating part ( 1 ) at least one inductive coupler ( 8th ), which only position-dependent with a portion of the entire length of the conductor arrangement ( 7 ) is engaged and decoupled from this electrical energy. Device according to the preamble of claim 1, characterized in that the rotating part ( 1 ) a conductor arrangement ( 7 ) and decouples from this electrical energy, as well as the stationary part ( 2 ) at least one inductive coupler ( 8th ), which of the alternating current of one or more inverters ( 6 ) and which is exclusively position-dependent with a portion of the entire length of the conductor arrangement ( 7 ) is engaged. Device according to claim 1 or 2, characterized in that the conductor arrangement ( 7 ) 1, 2 or 3 parallel conductors ( 9a . 9b . 9c ) through which currents flow such that the sum of the currents through all conductors at each point of the conductor arrangement is equal to zero. Device according to one of the preceding claims, characterized in that the conductor arrangement ( 7 ) in the circumferential direction several segments ( 10a . 10b . 10c ) having. Device according to one of the preceding claims, characterized in that a plurality of couplers ( 8a . 8th . 8th ) are provided, wherein at any time at least one coupler in engagement with the conductor arrangement ( 7 ). Device according to one of the preceding claims, characterized in that at least one coupler ( 8th ) comprises soft magnetic material for concentration of the magnetic flux. Device according to one of the preceding claims, characterized in that several inverters ( 6 ) for feeding one conductor and / or one segment of the conductor arrangement ( 7 ) are provided. Device according to one of the preceding claims, characterized in that at least one inverter ( 6 ) for feeding one conductor and / or one segment of the conductor arrangement ( 7 ) is formed at or near the respective resonance frequency. Device according to one of the preceding claims, characterized in that optionally at least some series capacitance in series with the conductor arrangement 7 or to the tap 8th and / or optionally at least one parallel capacitance parallel to the conductor arrangement 7 or to the tap 8th is switched. Device according to one of the preceding claims, characterized in that at least one inverter ( 6 ) is configured to detect a condition in which the conductor arrangement ( 7 ) or a segment of the conductor arrangement ( 7 ) not in engagement with at least one coupler ( 8th ) and in the absence of intervention the inverter switches off or controls to an idle frequency. Device according to one of the preceding claims, characterized in that at least one inverter ( 6 ) is designed to deliver an alternating current to at least a second frequency, to feed other consumers and at least one coupler ( 8th ) or the wiring of a coupler ( 8th ) Frequency selective for selection of the second frequency is formed and predominantly the tapped signal of the second frequency at least one further consumer supplies. Device according to one of the preceding claims, characterized in that at least one inverter ( 6 ) is designed for emitting an alternating current with a variable duty cycle and further provided on the rotating side of a filter unit for selecting frequency components with even multiples of the first frequency and for feeding at least one further consumer with the selected frequency components. Device according to one of the preceding claims, characterized in that at least one inverter ( 6 ) is designed to deliver an alternating current with modulated output frequency, wherein the frequency deviation is chosen so small that there are no significant fluctuations in the amplitude of the output current and at the same time the modulation frequency is greater than or equal to 100 Hz.