DE10161898A1 - Variable position car seat has active security systems with inductive electrical connection - Google Patents

Abstract

A variable position car seat has a integrated belt tightener (11) and airbag (8, 9) with seat position sensors (5) and inductive power and information transmission connections (4) to the car through the mechanical mounting rail (3).

Description

Inn automotive engineering is becoming more and more in terms of seating of motor vehicles Requires variability in the possible seating positions. Especially in buses or in so-called vans, minivans or compact vans is becoming more and more common for the rear seats required as fine as possible steepening of the seating position in the longitudinal direction to the vehicle. In addition, you want to be able to expand the seats as easily and comfortably as possible to make room for To create loading area. Therefore, the suitability for the vehicle interior floor Loading area required. The vehicle interior floor should therefore be as free of any unevenness as possible be and the vehicle-side seat mountings should as possible in the vehicle floor be eigelassen, inter alia, so that they against damage and against Pollution are protected by possible cargo.

In a known seating system has therefore been proposed in DE 199 24 579 A1, in to engage the vehicle floor rails, in which a carriage in the vehicle longitudinal direction is displaceable. The slide can be fitted with bolts that fit into the bolt heads Recesses along the vehicle-side rail intervene, in many different Positions are locked along the rail system. The recesses form the Bolt abutment. The distance of the bolt abutments from each other determines the gradation of varied, possible seating positions and the number of bolt abutment substantially the number of different possible seating positions. The seat itself is with a detachable Detent device each with a rear and a front foot on a carriage, the is in the rail system, attached. There are two rails per vehicle seat one carriage each for each of the two long sides of the seat needed.

This seating system allows variable seating of motor vehicles. If in the Motor vehicle seats are provided for the seat belts, the seat belts must be in the vehicle seats are integrated so that with the seat adjustment and the Attachment points of the seat belts are moved along. Would the seat belts on the Chasis of the motor vehicle fastened, could be at a displacement of the seats in the Track system, the functionality of the safety belts in a satisfactory manner be maintained.

The aforementioned seat system allows only the use of passive Personal safety systems. Active security systems, such as As belt tensioners or airbags namely need a Power supply and must be able to be controlled with control commands. The size Variability of seating leaves a conventional power supply in the Vehicle seats integrated systems with conventional plug-based contacts Wiring the seats appear too expensive. Especially if you remove the seats, Then the cable connections would still remain in the hold and there Be exposed to damage and dirt.

In connection with the variable seating of aircraft one has in the US 4,914,539 an inductive power distribution system proposed with the Entertainment systems in the aircraft seats can be powered. The energy supply The aircraft seats thus work effectively wireless and without electrical plug contacts between the aircraft seat and the fuselage. The passenger seats are equipped with a Resonance circuit inductively coupled to a primary conductor loop on the cabin floor.

In US 4,428,078 one has in connection with the weight reduction of Aircraft proposed wiring harnessed energy and information systems for To replace aircraft seats with an inductive energy and information transmission system. through of a pick-up resonator, the aircraft seats become one in the cabin floor embedded primary conductor path coupled. A low frequency flows in the primary conductor AC, which is superimposed on a radio signal. The low frequency alternating current is used for Power supply of integrated in the aircraft seats audio equipment, while the superimposed radio signal is used to transmit radio programs.

The aforementioned passenger seats or seating systems served mainly the Entertainment of the passenger and the displaceability of the individual passenger seats.

Based on the above-described prior art, the inventive Task to propose a seating system for motor vehicles, in which the seats as free as possible slidable, easily removable, without the need for active passenger restraint systems must be waived.

According to the invention this object is achieved by the features of the independent Claim. Further advantageous embodiment forms are included in the subclaims.

The solution succeeds with a seating system from a vehicle seat, in the at least one active person restraint system, in particular a belt tensioner or at least one Airbag system, integrated. The seating system includes an inductive energy and Information transfer from the motor vehicle chassis to the integrated in the seats Passenger restraint systems and a mechanical fastening system for the seats, whereby both the energy and information system as well as the mechanical fastening system as a rail system is trained.

With the invention mainly the following advantages are achieved:
The invention improves the safety of persons sitting on removable seats. It is now also possible to use active passenger restraint system such as belt tensioners or airbags for removable passenger seats in motor vehicles. Thus, the same safety standard is achieved even with removable seats as he was previously only possible for permanently installed seats.

The variability of the adjustable seating positions remains fully intact.

In one embodiment of the seat system is the rail system for the energy and Information transfer and the rail system for mounting the seats uniform educated. The slide on which the passenger seats are mounted, then contains both the mechanical fastener as well as the magnetic inference for the energy and Information transfer. The mechanical slide rail in which the carriage is locked is then formed as Primärleiterweg from an E-shaped aluminum profile. This has the Advantage that in the bottom of the passenger compartment only a rail system are admitted got to. Also, with a single rail system, its dimensions through the mechanical fasteners is determined, the electrical and magnetic Transmission devices are relatively generously dimensioned, so that electrical services can be transferred, not only the operation of passenger restraint systems but also sufficient for future advancements of expandable seats Leave room. For example, in the seat could also seat heaters or electric Actuators for the individual seat adjustment are integrated and with the inductive Power transmission system to be operated. With the one-piece rail system can Effortlessly achievements up to the 100 Watt range are transferred. With appropriate Sizing the one-piece rail system can also provide power up to 3 kilowatts be transmitted.

In another embodiment of the invention, the mechanical rail system for Attachment of seats and inductive transmission system separated. This Although requires an additional incorporation of the separate primary conductor in the vehicle floor, but has cost advantages, if only small services should be transferred. Of the Primary conductor can then be designed as a low-cost flat conductor. The flat conductor can optionally be formed as a laminated flexible film conductor. For one in the seat integrated controller and two squibs for two airbag systems and one squib for one The belt tensioner is sufficient for a power transfer of 100 milliwatts. If in the seat nor an energy storage is provided, the required power transmission can also be reduced to 10 milliwatts. The active safety systems could then only in Operation when the energy storage has been fully charged. This would be after Although take a certain amount of time to turn on the electrical system, but might be acceptable, provided that the charging time of the energy storage is still in the range smaller one Minute remains.

In a further advantageous embodiment of the seating system is in the energy and Information transmission integrates a detector arrangement with which it is possible to recognize with which orientation the seat is mounted on the rail system. The seat can be in Direction of travel and be installed against the direction of travel. The orientation of the seat relative to Direction of travel is important for the ignition of the airbag systems. With the change of Installation direction of the seat relative to the direction of travel changes namely the assignment of left and right seat side to the chassis structure, in particular to the side walls of the Vehicle. The ignition of a side airbag only makes sense. when the inflated airbag is abgestüzt against a surface. In the case of side airbags, this is a side panel of the vehicle body. A recognition of the seat orientation relative to the direction of travel is therefore important to be able to decide which of the two side airbags, if necessary are integrated in the vehicle seat, to be fired in the event of an accident. Namely always that airbag which is located on a seat side, the vehicle wall is facing. A side airbag in the center of the vehicle should not be ignited in an accident.

In a further advantageous embodiment, a seat occupancy recognition is in the seat with integrated alternative belt buckle query. Such seat occupancy detection systems with Alternative Gurtschloßabfrage are known from permanently installed seats. They serve the Detecting if the seat is occupied by a person or not. If the seat is not occupied, the the unoccupied seat assigned airbag systems are not activated and can at a Accident also not be detonated. Analogous to the seat occupancy identification is the Belt buckle interrogation of the activation of the belt tensioner, in the event that a safety belt was also locked in the buckle. Is no seat belt in the buckle engaged, the belt tensioner is not ignited. Seat recognition and belt buckle interrogation were so far not available in expandable seats, since you have so far no satisfactory Energy and information systems for the supply of such recognition systems Removable seats had been found. With the seat system disclosed herein, such Recognition systems also possible for removable seats.

Embodiments of the invention are described below with reference to drawings illustrated and explained in more detail. Show it:

Fig. 1 is a schematic overview representation of a seat system according to the invention, wherein the rail system for energy and information transmission is formed from the electrical system on the seats with the rail system for attachment of the seats defined,

Fig. 2 is a schematic overview representation of a seat system according to the invention, wherein the rail system for the transmission of energy and information from the electrical system on the seats and the rail system is designed for the fastening of seats separated from each other,

Fig. 3a) is a detailed representation of the single rail system according to the embodiment of FIG. 1,
b) and c) two possible embodiments of a separate rail system made of flat conductors for the energy and information transmission according to the embodiment of FIG. 2,

Fig. 4 is a block diagram of a suitable energy and information transmission system.

In Fig. 1, the cut-open rear of a motor vehicle 1 , in particular a bus, a van, a compact vans or a mini vans is shown in a highly simplified schematic representation. In the rear removable and sliding seats 2 are mounted and locked in a rail system 3 . The rail system 3 is embedded in the vehicle floor. The mechanical rail system for fastening the seats has been disclosed by way of example in DE 199 24 579 A1. The content of DE 199 24 579 A1 is therefore expressly included in the invention described here. The mechanical rail system is supplemented by an inductive energy and information transmission system. The inductive information transmission system consists of a respective primary conductor rail 4 , a secondary transducer resonant circuit 5 and associated primary-side power electronics 6 and secondary-side power electronics. 7 Depending on a two-track mechanical rail system 3 Rir clie attachment of the vehicle seats is assigned a primary conductor rail 4 . In the embodiment of FIG. 1, the primary conductor rail 4 is integrated in one of the two rails of the mechanical rail system. A detail of this embodiment will be found below in connection with the description of FIG. 3a.

There are two pick-up resonant circuits 5 per vehicle seat. A pick-up resonant circuit for each one left or right side of the vehicle seat. The pick-up resonant circuit is preferably integrated into a respective left or right seat foot. An energy and information transmission is possible only on that side of the seat on which engages the seat foot in the rail 3 with an integrated primary conductor rail 4 . Since only one of the two rails of the fastening system has an integrated primary conductor rail, exactly one pick-up resonant circuit 5 always receives an inductive coupling, while the second pick-up resonant circuit in the opposite seat base does not receive any inductive coupling with the primary conductor rail. This allows electronic detection of whether the seats have been fixed in the direction of travel or against the direction of travel in the rail system. By determining which seat side receives power through the inductive coupling, the orientation of the seat relative to the primary conductor rail 4 can be detected. Since the primary conductor rail 4 is arranged relative to the direction of travel "advance" by design either on the left or on the right rail 3 of the seat mounting system, a left and a right side of the vehicle relative to the direction of advance is already determined by the arrangement of the primary conductor rail. With the energy and information transmission system, the controller of the primary-side power electronics 6 is transferred an identifier to the seats, in which rail system they are installed. The identifier consists of a coded voltage signal, which codes the one rail system as left in the direction of travel rail system 1 and the other system as in the direction of travel right rail system r. The identifier is received by the secondary-side power electronics 7 and further processed in a controller. A block diagram of the primary-side and secondary-side power electronics follows in connection with the description of Fig. 4. By evaluation of the encoded signal of the secondary side controller detects in which rail system of the passenger seat installed, and by evaluation of the directional information, whether the energy and information transmission via the left or the right side of the passenger seat is made, there is an identifier of whether the seat is installed in the forward direction or in the reverse direction. In the embodiment shown, the seat is installed in the forward direction, when the power is supplied via the seat half designated R. By combining the identifier r, l of the respective rail system with the direction information R, L of the installation position of the seat, can be clearly determined in the secondary-side controller by a simple programmatically implemented query algorithm in which rail system, the seat with which orientation is installed. From the combination of both identifiers can also be decided by the query algorithm, which side airbag should be activated in the seat.

For detecting the installation position of the vehicle seats, whether in the forward direction or in Reverse direction can be incorporated in an alternative embodiment of the invention Also detector arrangements may be provided which are separated from the power supply system are. For example, the primary conductor rails or the mechanical Mounting rails to be provided with a magnetic coding, which read out of Hall sensors becomes. Magnetic encodings can have very large information contents, so that with such codes also a clear detection of the mounting position of the seats both in terms of orientation to the direction of travel as well as in terms of position detection, in which mounting rail the seat is installed, are possible. When using a if necessary, separate detector arrangement can be applied to a second pick-up resonant circuit to be waived at the seat. But would have the separate detector array in the Seat to be integrated.

An example of a query and decision algorithm is as follows:

If the secondary-side controller detects the identifier combination (r, R), the seat in the right rail system is installed in the forward direction and the right side airbag 8 of the seat is activated.

If the secondary-side controller detects the identifier combination (1, R), the seat is installed in the left rail system in the forward direction and the left side airbag 9 of the seat is activated.

If the secondary-side controller detects the identifier combination (r, L), the seat is installed in the right rail system in the rearward direction and the left side airbag 9 of the seat is activated.

If the secondary-side controller detects the identifier combination (1, L), the seat is installed in the left rail system in the reverse direction, and the right side airbag 8 of the seat is activated.

The first two installation options are shown in Fig. 1, the last two situations arise by playing through the possible installation combinations.

Basically, the electronic detection detection presented here is not parallel to two Side-by-side rail systems consisting of two mounting rails each limited. Should z. B. three rows of seats itn be installed in the rear of a vehicle, so must Three rail systems consisting of two mounting rails side by side in the bottom of the Vehicle are incorporated and each of the rail systems with a unique identifier be provided, for. B. l, m, r for left, middle, right. By extension of the programmatic interrogation algorithm on three rail systems can then be through the Combination of the identification for the rail system with the direction information of the mounting position of the rail Determine seat by simply counting all possible combinations, in which rail the seat is installed with which mounting position and therefore can also be decide which side airbag of the seat should be activated or not. At three juxtaposed seats, the only difference is that the airbags in the middle seat should not be activated because lack of side wall, these airbags at a Ignition in the event of a crash could not develop a positive retention effect.

For larger buses, inductive updating of the interrogation algorithm also has a electronic detection of four adjacent rows of seats possible, u. s. w.

From the secondary-side controller, which is integrated in the seat are controlled by means of control lines 10, the two side airbags 8 , 9 in the side rests of the seat and the belt tensioner 11 . Both the belt tensioner and the two side airbags are fired as needed depending on the selection rules described above. Strictly speaking, so-called squibs 12 are ignited, which cause a small explosive charge to explode. In the case of the belt tensioner is still a query whether in the buckle 13 and a seat belt is inserted. If so, the belt tensioner is ignited. The ignition signal itself is supplied on the primary side by a so-called CRASH sensor and initially transmitted to the primary-side power and control electronics 6 . About the inductive energy and information coupling between the primary conductor rail and secondary side transducer resonant circuit is supplied by the primary-side power and control electronics both the energy for the ignition of the connected airbags and belt tensioner as well as the control signal for ignition of the systems to the secondary-side control electronics 7 transmitted.

In Fig. 2 an alternative embodiment of the invention is shown. The embodiment of Fig. 2 differs from the seating system described above by the separate arrangement of primary conductor rail 4 b and mechanical rail system 3 for mounting the seats. Accordingly, the two secondary-side Aufnehmerschwingkreise the energy and information system on each side of the seat can no longer be integrated into a Sitzfuß, but must be attached to each side of the seat with a mounted atn seat 14 . The holder is designed so that, depending on the installation position of the seats either the left or the right Aufnehmerschwingkreis on the primary conductor rail 4 b comes to rest. The remaining elements of the seating system and the detection system for installation position of the seats and the identifier for the primary conductor rails remain identical to the embodiment as described in connection with FIG . A detailed illustration of the possible separate primary conductor rails 4 b is found in Fig. 3b and Fig. 3c. Although the embodiment of FIG. 2 has the disadvantage that in the cabin floor of the vehicle another rail system, namely the primary conductor rail, must be laid and that at the passenger seats an additional bracket 14 for receiving the secondary side transducer resonant circuit is necessary, but has the advantage. that with a separate version of the rail systems already existing purely mechanical seating systems, as they are already known from DE 199 24 579 A1, can be retrofitted to the inductive energy and information transmission. Another advantage consists in the cheaper embodiment of the invention, if for the primary conductor rails 4 b inexpensive flat conductor, flexible film as possible cables are used. Such simple ribbon conductor cables are useful if only powers up to 100 milliwatts are to be transferred. For the operation of a secondary-side controller and for the ignition of the squibs of a side airbag and a belt tensioner, this performance is sufficient, especially as will be explained in connection with FIG. 4, secondary energy storage can be provided so that no continuous power of 100 milliwatts transmitted must, but a power transmission of 10 milliwatts is considered sufficient to charge the energy storage over a period of time to the amount of energy required in the event of a crash.

In Fig. 3, three partial representations a), b) and c) various rail systems are shown, which are suitable for the seating system according to the invention. Partial representation a) shows an integrated rail system in which the primary conductor rail 4 of the energy and information system is integrated into the mechanical rail system for seat attachment from DE 199 24 579 A1. In the cabin floor 15 of the motor vehicle, a U-shaped aluminum profile rail 4 is embedded. The U-profile ends above the vehicle floor in an overhanging roof-shaped cover 16 , which contains a guide slot in the middle of the rail in the longitudinal direction, in which the seat bases can engage in the attachment of the seat. Together with the roof-shaped cover, the U-Prof 1 of the aluminum rail forms a box-shaped channel. In the channel runs a carriage 18 , on which the seat, as disclosed in DE 199 24 579 A1, is attached. In order to lock the carriage, tensioned retaining bolts 19 are incorporated on the carriage by spring force. The retaining bolts engage in the locking of the carriage in circular extensions of the guide slot 17 a. If the slide or the seat to be moved, the retaining bolts are depressed and thus solved the lock. The inventive extension of this known system is now carried out with the formation of the U-shaped aluminum rail to an E-shaped primary conductor rail. For this purpose, the U-profile is supplemented by a central web 20 on the yoke of the U-profile within and along the rail. The web consists in its lower half, with which it is connected to the U-shaped aluminum profile, first of an electrically insulating spacer 21st On the spacer, the web carries the center conductor or the forward line 22 as the first part of the primary conductor of the energy and information system. The return of the primary conductor is formed by the aluminum profile of the mechanical rail system, which is shown in Fig. 3a drawing by the current paths 23 in the legs of the U-profile. U-shaped at its end face inside the aluminum profile rail 4, a magnetic yoke 24 also consists of two U-shaped yoke 24 a magnetic on the carriages 18, 24 arranged and fixed b. The magnetic yoke encloses the center conductor 22 except for an upper slot in which the induction coil 25 of the secondary-side transducer resonant circuit 5 engages. To improve the transmission ratio, the induction coil 25 may be wound on a ferrite core 26 . Ferrite core 2 G and induction coil 25 are attached as shown in Fig. 1 to the seat feet. So that they can be introduced together with the seat feet through the guide slot 17 mechanical rail system and herausgenonnnen again, they must be designed accordingly constructive. Ie. they must not be wider than the clear width of the guide slot 17 .

In Fig. 3b), the simplest embodiment of a primary conductor rail 4 b is shown, as used in connection with the embodiment described in Fig. 2. In addition to the mechanical rail system for seat mounting a flat conductor arrangement of two film conductors, a forward conductor 22 b, a return conductor 23 b and a magnetic yoke 24 bb is laid below the cabin carpet floor 15 . Above the carpet, the magnetic field of the primary conductor rail 4 b is tapped with the induction coil 25 b of the secondary-side Aufnehmerschwingkreises Sb. To improve the transmission ratio and the secondary side is formed with a magnetic yoke 26 b.

In Fig. 3c) is compared to the embodiment of Fig. 3b) a slightly more expensive primary conductor rail 4 c shown, which has advantages over undesirable magnetic stray fields advantages over a two-wire arrangement of the sub-figure b). In the three-wire arrangement of a central conductor 22 c in which the total current flows and two outer return conductors, in which, to a good approximation, half the total current flows, the stray magnetic fields in the vicinity of the conductor arrangement are smaller. The induction coil 25 c is usefully designed as a so-called double loop transformer 5 c in a three-wire arrangement. Also, the double loop transformer has a secondary side magnetic feedback 26 c to improve the power transmission. A primary-side conclusion 24 cc improves the transmission behavior of the arrangement.

Irin primary-side conclusion allows it with the relative to the embodiment of Fig. 3a) simpler Primärleiterausführungen services in the range of 10 V to 100 watts to transmit. If the flat conductor embodiments of the embodiments of FIGS . 3b and 3c are formed as a foil conductor, the magnetic yoke is expediently formed by a plastic laminate, in whose plastic mass soft magnetic or ferritic powder materials are embedded.

FIG. 4 shows by way of example a block diagram of a possible energy and information transmission system, as can be used for the seat system according to the invention. A primary-side subsystem 40 is disposed 1111 vehicle interior and connected to the primary conductor rail 4 . On the movable seat is the subsystem 41 , which is coupled via the pick-up resonant circuit S of induction coil 25 and capacitor 43 to the primary conductor rail 4 .

The primary-side subsystem is supplied with energy from the vehicle electrical system. The usual in motor vehicles DC voltage is converted by an inverter into an alternating current with preferably 100 kHz carrier frequency. With a controller of the primary-side power and control electronics, the energy carrier frequency is superimposed on an information signal. Preferably, the information signal consists of a modulated information carrier frequency which is greater by a factor of 10 than the energy carrier frequency. In a less preferred embodiment, the energy carrier frequency can also be modulated directly. The information content is included in the modulation both times. In the preferred case of a separate information carrier frequency, a frequency generator which provides the information carrier frequency is also integrated in the two-channel modulator / demodulator. The information signal is superimposed with separation / Überlagerungstilter the energy carrier frequency. The controller of the primary-side power electronics 6 is connected to the data bus of the motor vehicle and is connected via this data bus with the crash sensor in combination.

On the secondary side, the energy and information system consists of the transducer resonant circuit 5, already mentioned several times, with induction coil 25 and resonance capacitance 43 . The transducer oscillator is present twice, once for the left seat half and once for the right seat half. The AC voltage picked up by the pick-up resonant circuits is converted back into a DC voltage in a secondary-side rectifier. With this DC voltage, the active elements on the seat are supplied with the necessary operating voltage. In addition, with this DC voltage, the ignition energy is provided for the integrated in the seat airbag systems and belt tensioners. This ignition energy can be tapped either directly from the rectifier or in an alternative embodiment can be interposed between the rectifier and airbag systems and belt tensioners an energy storage. In the simplest case, the energy store can be a suitably dimensioned capacitor or better a rechargeable battery.

With inductive pickups 44 , the modulated information signal is detected from the Aufnehmerschwingkreisen and separated by a separation / overlay filter from the energy carrier frequency. Subsequently, the modulated information signal is demodulated in a dual-channel modulator / demodulator and fed into the controller of the secondary-side power and control electronics 7 . Further query inputs of the secondary-side controller are connected to sensors for seat occupancy recognition, for the buckle query and current sensors 45 , which are detected with which of the two pick-up resonant circuits is active. With the query, which resonant circuit is coupled to the primary conductor rail, it is decided with a programmatically implemented query and decision algorithm in the secondary-side controller which airbag systems are to be activated. A possible decision algorithm has already been described in connection with FIG .

With the inductive energy and information transmission system is next to the Energy supply the data exchange between the primary and secondary side Control electronics accomplished. In particular, the control commands become activation and to ignite the active passenger restraint system in the seats with the inductive Energy and information system transmitted.

Claims (10)

1. Seat system comprising a vehicle seat, in which at least one active passenger restraint system, in particular a belt tensioner ( 11 ) or at least one airbag system ( 8 , 9 ), is integrated, comprising:
a primary conductor rail (4, 4 b) for an inductive energy and information transmission system (40, 41) are transmitted to the power and control commands from the motor vehicle chassis on which are integrated in the seats occupant restraint systems,
a mechanical fastening system ( 3 , 18 ) for the detachable and displaceable attachment of the seats to the vehicle floor,
wherein both the primary conductor rail and the mechanical fastening system as a rail system ( 3 , 4 , 4 a, 4 b) are formed in the vehicle floor. 2. Seating system according to claim 1, wherein the primary conductor rail ( 4 ) of the energy and information system with the mechanical fastening system ( 3 , 18 ) is formed uniformly. 3. Seat system according to claim 1, wherein the primary conductor rail ( 4 b, 4 c) of the energy and information system of the mechanical fastening system ( 3 , 18 ) is separated. 4. Seat system according to one of claims 1 to 3, wherein a detector arrangement ( 45 , 4 , 5 , 6 , 7 ) for detecting the installation position of the seat with respect to orientation to the direction of travel and positioning in the vehicle is integrated. 5. Seating system according to claim 4, wherein the Aufnehmerschwingkreise ( 5 ) are part of the detector arrangement. 6. Seating system according to claim 4, wherein the detector assembly consists of a magnetic coding of the mechanical fastening system ( 3 , 18 ) and an inductive sensor with which the magnetic coding is read. 7. Seating system according to claim 3, wherein the primary conductor rail ( 4 b) consists of a two-conductor flat conductor arrangement ( 22 b, 23 b). 8. Seating system according to claim 3, wherein the primary conductor rail ( 4 b) consists of a three-conductor flat conductor arrangement ( 22 c, 23 c). 9. Seating system according to claim 8, wherein the induction coil of the transducer resonant circuit ( 5 ) as a double loop transformer ( 25 c) is formed. 10. Seat system according to one of claims 1 to 9, wherein in the seat an energy storage is integrated.