FR2878962A1 - DEVICE FOR CONTROLLING THE STATUS OF AN ASSEMBLY COMPRISING TWO ORGANS FOR CONNECTION BETWEEN THEM IN A RELEASABLE MANNER - Google Patents

Abstract

This device comprises first (18) and second (44) choke circuits carried respectively by the two members. The first (18) and second (44) circuits are magnetically coupled together when the components are connected together. The first circuit (18) is an oscillating circuit of the LC type. The control device also comprises an oscillator (12) provided with an oscillating circuit formed by the first circuit (18). The second circuit (44) being an oscillating circuit of LC type capable of modifying the tuning frequency of the oscillator (12) by magnetic coupling of an inductor of this second circuit, called the tuning inductor (46), with at least a first choke of the first circuit, called the first oscillator choke (26).

Description

The present invention relates to a device for controlling the state of a

  set comprising two members intended to be releasably connected to one another.

  It applies in particular to an assembly comprising a fixed part (floor) of a motor vehicle and a seat of the vehicle to be removably connected to this fixed part.

  Several states of a removable seat can be distinguished. These states may correspond more particularly to the states of a device assigned to this seat such as the buckled and unfastened states of a seat belt. These states may also correspond to the states connected and not connected to the floor of this seat (presence or absence of the seat on the floor).

  If desired, it may be possible to process, for example by viewing them on a dashboard, information characterizing the various states of a removable seat. The processing of this information generally requires establishing communication between means carried by the removable seat and means carried by the fixed part of the vehicle. Given the removability of the seat, the use of means of communication by electric cables is relatively inappropriate.

  It has therefore been proposed in the state of the art, in particular in US-A2004 / 0008036, a device for monitoring the state of an assembly comprising two members intended to be releasably connected to one another, the control device being of the type comprising first and second self-circuits carried respectively by the two members, these first and second circuits being magnetically coupled to each other when the members are interconnected, the first circuit being an LC-type oscillating circuit.

  In US-A-2004/0008036, the first member is formed by a fixed part of a motor vehicle and the second member is formed by a seat of the vehicle to be removably connected to this fixed part of the vehicle.

  The first and second self-circuits form means of communication by magnetic coupling between the removable seat and the fixed part of the vehicle (there is no electric cable connecting the removable seat and the fixed part of the vehicle).

  US-A-2004/0008036 proposes to detect the presence of the seat (seat connected to the fixed part of the vehicle) from the measurement of a parameter related to the oscillation frequency of the first circuit when this first circuit is subjected to an impulse excitation. Indeed, the oscillation frequency of the first circuit differs depending on whether the seat is connected to the floor or not, that is to say according to whether the first and second self circuits are coupled together or not.

  However, the pulse excitation generation means proposed in US-A-2004/0008036 comprise relatively complex switching means.

  The object of the invention is notably to propose a control device of the type described in US-A-2004/0008036 which is simple and reliable and which makes it possible to distinguish at least two states of a removable seat, for example two states of a equipment assigned to this seat, such as the buckled and unfastened states of a seat belt, and / or two states respectively connected and not connected to the floor of this seat.

  For this purpose, the invention relates to a control device of the aforementioned type, characterized in that it comprises an oscillator provided with an oscillating circuit formed by the first circuit, the second circuit being an LC type oscillating circuit capable of to modify the tuning frequency of the oscillator by magnetic coupling of a choke of this second circuit, called chord self, with at least a first choke of the first circuit, said first oscillator choke.

  Thanks to the oscillator, the oscillations of the first oscillating circuit are maintained and stabilized. This eliminates the relatively complex switching means proposed in the state of the art to pulse excitation of the first oscillating circuit.

  Moreover, since the tuning frequency of the oscillator can be modified by magnetic coupling with the second LC-type oscillating circuit, it is possible to easily distinguish two states of the set comprising the two members intended to be connected to each other in such a way that releasably. These two states respectively correspond to a first tuning frequency of the oscillator when the latter is magnetically isolated from the first oscillating circuit and to a second tuning frequency of the oscillator when the latter is magnetically coupled to the second oscillating circuit.

  Each state of the set can therefore be characterized by a stable value of a control parameter, for example a voltage, linked to a tuning frequency (stable) of the oscillator.

  In addition, additional states of the set can be distinguished by associating with these additional states different values of the capacitive or inductive parameter of the second oscillating circuit. These additional states can be distinguished by measuring a control parameter, for example a voltage, related to the tuning frequency of the oscillator. This control parameter takes different values which are a function of the different values of the tuning frequency of the oscillator coupled to the second oscillating circuit.

  According to other optional features of this control device: the device comprises means for discrete or continuous variation of a capacitive or inductive parameter of the second oscillating circuit; the device comprises means for discretely varying the capacitive parameter of the second oscillating circuit, the capacitive parameter being imposed by a first tuning capacitor connected in parallel with the tuning inductor and a second tuning capacitor able to be connected. in parallel with the first tuning capacitance, the connected and unconnected states of the second tuning capacitance corresponding to two different states of the second organ; the oscillator comprises a second oscillator choke magnetically coupled to the first oscillator choke, the second oscillating circuit being capable of modifying the tuning frequency of the oscillator by magnetic coupling of the chord chord with the first and second oscillator chokes; the coupling coefficient between the second oscillator choke and the tuning choke is greater than 30%; the coupling coefficient between the first and second oscillator chokes is less than 10%; the coupling coefficient between the first oscillator choke and the tuning choke is greater than 30%; the first circuit comprises an oscillator capacitor connected in parallel with the first oscillator choke; the device comprises means for converting the frequency of the oscillator into voltage; the first member is formed by a fixed part of a motor vehicle and the second member is formed by a seat of the vehicle to be removably connected to this fixed part of the vehicle; the seat can adopt two states respectively corresponding to the unfastened and buckled states of a seat belt assigned to the seat; - The second tuning capacity is connected in parallel with the first tuning capacity when the belt is in the looped state.

  The invention will be better understood on reading the description which follows, given solely by way of example and with reference to the appended drawings in which: FIG. 1 is a schematic view of a device according to the invention for control of the state of an assembly comprising first and second members to be releasably connected to each other; FIG. 2 is a graph representing voltages provided by the means for converting the frequency of the oscillator into voltage as a function of time.

  There is shown in Figure 1 a device, designated by the general reference 10 for the control of the state of an assembly comprising first and second members to be releasably connected to each other. The two members of the assembly are not shown in the figure.

  In the example described, the first member is formed by a fixed part of a motor vehicle and the second member is formed by a seat of the vehicle to be removably connected to this fixed part of the vehicle.

  The seat can adopt two states respectively corresponding to the states connected and not connected to the floor of this seat (presence or not of the seat on the floor). In addition, the seat can adopt two states respectively corresponding to uncapped and buckled states of a seat belt assigned to the seat.

  The control device 10 comprises an oscillator 12 and means 14 for converting the frequency of the oscillator into voltage.

  The oscillator 12 and the conversion means 14 are carried by the fixed part of the vehicle (first member of the assembly).

  The oscillator 12 comprises amplification means, comprising a transistor 16, and a feedback loop comprising a first LC-type oscillating circuit 18.

  More particularly, it can be seen that the oscillator transistor 16 is of the NPN type and conventionally comprises three electrodes respectively forming a base 16B, a collector 16C and a transmitter 16E. The oscillator transistor 16 is mounted in a common base.

  The oscillator 12 is electrically powered between a positive terminal P and an intermediate terminal N connected, via a resistor 20, to a ground M. The base 16B of the transistor 16 is supplied with voltage by means of a bridge of resistors 22, 24.

  The base 16B of the transistor 16 is connected, on the one hand, to the positive terminal P, via a first resistor 22 of the bridge and, on the other hand, to the intermediate terminal N via the second resistance 24 of the bridge.

  The first oscillating circuit 18 comprises a first oscillator choke 26, connecting the collector 16C of the oscillator transistor 16 to the positive terminal P, and a capacitor 28, connected in parallel with the first oscillator choke 26, connecting an output S oscillator 12 to the positive terminal P supply.

  The first oscillating circuit 18 also comprises a connection capacitor 29 connecting the collector 16C of the oscillator transistor 16 to the output S of this oscillator. This connecting capacitance 29 also forms a tuning capacitor influencing, with the capacitance 28, the oscillation frequency of the oscillator 12.

  A second oscillator choke 30 connects the emitter 16E of the oscillator transistor 16 to the intermediate terminal N via a gain resistor 32 in series with the choke 30. This resistor 32 imposes the current intensity in the oscillator transistor 16 and therefore the gain of this transistor 16.

  The oscillator 12 also comprises a capacitor 34 for decoupling the oscillator, a capacitor 36 for decoupling the second resistor 24 from the bridge and a capacitor 38 for decoupling the gain resistor 32.

  The first 26 and second 30 oscillator chokes are positioned in the space to be magnetically coupled together. The coupling coefficient between these first 26 and second 30 oscillator chokes is preferably less than 10%, for example equal to 5%; It will be noted that the oscillations of the oscillator 12 are maintained (the oscillator 12 is tuned) by virtue of the magnetic coupling of the first 26 and second 30 oscillator chokes.

  As a variant, the oscillator transistor 16 could be mounted as a common emitter or as a common collector. In each of these cases, the first 26 and second 30 oscillator chokes will be respectively connected to the two electrodes of the transistor 16 which are not common.

  The output S of the oscillator 16 is connected to an input E of the means 14 for converting the frequency of the oscillator 12 into voltage.

  These conversion means 14 comprise static switching means comprising, in the example described, a PNP transistor 40. This transistor 40 conventionally comprises three electrodes respectively forming a base 40B, a collector 40C and a transmitter 40E.

  The input E of the conversion means 14 is connected to the transmitter 40E of the conversion transistor 40.

  The positive terminal P is connected to the base 40B of the conversion transistor 40. The intermediate terminal N is connected to the collector 40C of the conversion transistor 40.

  A diode 42, passing to the emitter 40E of the conversion transistor 40, connects the positive terminal P to this emitter 40E.

  In accordance with the conventional switch operation of the conversion transistor 40, the voltage at the intermediate terminal N is substantially proportional to the oscillation frequency of the oscillator 12, the output voltage S of this oscillator 12 and the capacitance of the oscillator 12. liaison 29.

  Indeed, the switching of the conversion transistor 40 is imposed by the frequency of the signal emitted at the output S of the oscillator 12, so that the intermediate terminal voltage N is proportional to the oscillation frequency of the oscillator 12 .

  The control device 10 also comprises a second LC-type oscillating circuit 44, carried by the removable seat (second member of the assembly).

  The second oscillating circuit 44 comprises a tuning inductor 46, a first tuning capacitor 48 connected in parallel with the tuning choke and a second tuning capacitor 50 connectable in parallel with the first tuning capacitor. tuning 46 by closing a switch 52.

  The tuning inductor 46 comprises, for example, a winding wound around a ferrite core, all of which is embedded in a resinous residue hung on the seat.

  The second oscillating circuit 44 is capable of modifying the tuning frequency of the oscillator 12 by magnetic coupling of the tuning inductor 46 with the first 26 and second 30 oscillator chokes. For this purpose, the coupling coefficient between the first oscillator inductor 26 and the tuning inductor 46 is preferably greater than 30%, for example equal to 40%, and the coupling coefficient between the second inductor 30 of oscillator and the tuning inductor 46 is preferably greater than 30%, for example equal to 40%.

  In the example described, the second tuning capacitor 50 is connected in parallel with the first tuning capacitor 48 (switch 52 closed) when the seat belt of the removable seat is in the looped state. Conversely, the second tuning capacitor 50 is not connected to the second oscillating circuit 44 (switch 52 open) when the seat belt of the removable seat is in the uncapped state.

  It will therefore be noted that the first 48 and second 50 tuning capacitors and the switch 52 form means for discretely varying the capacitive parameter of the second oscillating circuit 44 and thus means for discretely varying the oscillation frequency of the oscillator. 12.

  The main aspects of the operation of the control device 10 related to the invention will be specified below, with particular reference to FIG. 2 representing voltages supplied to the intermediate terminal N by the conversion means 14.

  The curve C1 represents the voltage at the intermediate terminal N when the second oscillating circuit 44 carried by the removable seat is not magnetically coupled with the oscillator 12 (seat not connected to the floor). The oscillator 12 is activated, following a brief transient period, the voltage at the intermediate terminal N reaches a mean value V1 substantially constant. This voltage V1 makes it possible to check the correct operation of the oscillator 12.

  The curve C2 represents the voltage at the intermediate terminal N when the second oscillating circuit 44 carried by the removable seat is magnetically coupled with the two oscillator chests 26, 30 (seat connected to the floor), the switch 52 being open (belt not buckled). The oscillator 12 is activated, following a brief transient period, the voltage at the intermediate terminal N reaches a mean value V2 substantially constant.

  The curve C3 represents the voltage at the intermediate terminal N when the second oscillating circuit 44 carried by the removable seat is magnetically coupled with the two oscillator chokes 26, 30 (seat connected to the floor), the switch 52 being closed (belt loop). The oscillator 12 is activated, following a brief transient period, the voltage at the intermediate terminal N reaches a mean value V3 substantially constant.

  Note that when the second oscillating circuit 44 is not magnetically coupled with the oscillator 12 (curve C1), the oscillation frequency of the oscillator 12 is high and the output voltage S of this oscillator 12 is relatively low. Then, when the second oscillating circuit 44 is magnetically coupled with the two oscillator chokes 26, 30 (curve C2), the switch 52 being open, the oscillation frequency of the oscillator 12 decreases but the voltage at the output S of this oscillator 12 increases. Finally, when the switch 52 is closed, the oscillation frequency of the oscillator 12 weakens further.

  The differences between the different values V1, V2 and V3 of the voltage at the intermediate terminal N are sufficient to distinguish the different cases mentioned above.

  The N terminal being carried by the fixed part of the vehicle, the voltage at this terminal N can easily be transmitted and processed in view for example to display on a dashboard information characterizing the various states of the removable seat.

  In particular, the analog voltage data at the terminal N can be converted into digital data transmitted, via a conventional network, to an on-board computer.

  Where appropriate, each removable seat of the vehicle may be equipped with a control device 10 according to the invention. In this case, the oscillators 12 of the different control devices 10 may be supplied one after the other, and / or the voltages at the various intermediate terminals N may be measured one after the other.

  The invention is not limited to the embodiment described above.

  In particular, one could provide in the oscillator only one self, namely that of the first oscillating circuit, provided that the frequency of the oscillator is stabilized by means other than the second oscillator choke, this means allowing however the modification of the tuning of the oscillator by the second oscillating circuit.

  It would also be possible to distinguish different states of the removable seat by associating with these states different values of the inductive parameter of the second oscillating circuit 44. The inductive or capacitive parameter of the second oscillating circuit 44 could also be varied in a discrete or continuous manner.

  Furthermore, the invention is not limited solely to the control of the state of an assembly comprising a fixed part of a motor vehicle and a seat of the vehicle to be removably connected to this fixed part of the vehicle. The invention can be applied to the control of the state of an assembly comprising any two bodies intended to be releasably connected to one another, in particular two complementary male and female parts forming a seat belt buckle for a car seat.

Claims (12)

  1. Device for controlling the state of an assembly comprising two members intended to be releasably connected to one another, the control device being of the type comprising first (18) and second (44) self-inductance circuits carried respectively by the two members, these first (18) and second (44) circuits being magnetically coupled to each other when the members are interconnected, the first circuit (18) being an LC type oscillating circuit, characterized in that it comprises a oscillator (12) provided with an oscillating circuit formed by the first circuit (18), the second circuit (44) being an LC type oscillating circuit capable of modifying the tuning frequency of the oscillator (12) by magnetic coupling a self of this second circuit, said self chord (46), with at least a first self of the first circuit, said first self oscillator (26).   2. Control device according to claim 1, comprising means (48, 50, 52) of discrete or continuous variation of a capacitive or inductive parameter of the second oscillating circuit (44).   3. Control device according to claim 2, comprising means for discretely varying the capacitive parameter of the second oscillating circuit, the capacitive parameter being imposed by a first tuning capacitor (48) connected in parallel to the tuning inductor (46). ) and a second tuning capacitance (50) connectable in parallel with the first tuning capacitance (48), the connected and unconnected states of the second tuning capacitance (50) corresponding to two different states of the second organ.   A control device as claimed in any one of the preceding claims, wherein the oscillator (12) comprises a second oscillator choke (30) magnetically coupled to the first oscillator choke (26), the second oscillator circuit ( 44) being capable of modifying the tuning frequency of the oscillator (12) by magnetic coupling of the tuning choke (46) with the first (26) and second (30) oscillator chokes.   The control device according to claim 4, wherein the coupling coefficient between the second oscillator choke (30) and the tuning choke (46) is greater than 30%.   6. Control device according to claim 4 or 5, wherein the coupling coefficient between the first (26) and second (30) oscillator chokes is less than 10%.   7. Control device according to any one of the preceding claims, wherein Io coupling coefficient between the first inductor (26) oscillator and the tuning inductor (46) is greater than 30%.   A control device as claimed in any one of the preceding claims, wherein the first circuit (18) comprises an oscillator capacitor (28) connected in parallel with the first oscillator choke (26).   9. Control device according to any one of the preceding claims, comprising means (14) for converting the frequency of the oscillator into voltage.   10. Control device according to any one of the preceding claims, wherein the first member is formed by a fixed part of a motor vehicle and the second member is formed by a seat of the vehicle to be removably connected to this part. fixed vehicle.   11. Control device according to claims 3 and 10 taken together, wherein the seat can adopt two states respectively corresponding to non-looped and buckled states of a seat belt assigned to the seat.   12. Control device according to claim 11, wherein the second tuning capacitance (50) is connected in parallel with the first tuning capacitance (48) when the belt is in the looped state.