FR2458953A1 - Proximity detector which transmits information to similar unit - varies magnetic field generated by like detector oscillator to modulate oscillator signal - Google Patents

Abstract

The inductive proximity detector is capable of transmitting and receiving information to and from an adjacent detector and comprises a resonant circuit of a coil (16) and series capacitor (17) controlled by a transistor switch (15) as well as an oscillator (4) coupled to an induction coil (5). Parallel information fed to the detector is converted into a series signal by an electronic circuit (10) and used to open and close the transistor switch. When the switch is closed the resonant circuit absorbs energy of the adjacent detector oscillator, thus modulating its signal. The modulated signal is then processed in the adjacent detector or a received signal. The oscillators of the two detectors operate at different frequencies.

Description

 The present invention relates to inductive proximity detectors making it possible to carry out 3! Replacement of information between two sets, this without contact or electrical connection between these two sets.

 Each inductive proximity sensor acts as a transmitter or receiver of information, with the important particularity of being able to be both transmitter and / or preceptor.

 Currently, the transfer of information is done by: a) reading mechanical cams using mechanical or electronic limit switches. Each cam / limit switch couple constitutes a bit of information to be transmitted.

b) Reception of a frequency generated by a transmitter and received by a receiver tuned to this frequency. Each transmitter / receiver pair constitutes a bit of information to be transmitted.

 Devices a) and b) have the common disadvantages of: 1) Promoting the transfer of information in one direction. Each constituent of the couple has a determined and fixed function.

2) Transmit this information in parallel form. Indeed, if the information contains n bit, n cam / limit switch or frequency transmitter / receiver pairs will be required.

 From then on, the concepts of size and short of implementation (wiring, mounting) are directly related to the number n of bits to be transmitted. Therefore the system is often unusable as soon as n becomes important.

 In addition, in device b) the frequencies of the transmitters are identical. So the distance between two successive couples must be large enough to avoid interference problems. This reinforces the drawbacks described in the previous paragraph.

 The device according to the invention makes it possible to avoid these drawbacks.

In it, there is no need to read mechanical channels or frequency transmitters.

Furthermore, the device is unique whatever the format (n bit) of the information and the transfer can be done in both directions. This makes it possible to establish a "dialogue" between the two sets and this, without contact or electrical connection between these two sets.

 The device which is the subject of the invention consists of two parts. Each part being named in the rest of the presentation: plot.

 Each pad can be a transmitter or receiver. A pad includes - An inductive proximity sensor.

- An active loop.

- As well as a means that allows you to write or read information from one pad to the other. The information to be transmitted is in serial or parallel form. The information returned appears in serial or parallel form.

 Furthermore, control bits are included at the time of transmission, their analysis during reception makes it possible to achieve or not the restitution of the information to be transmitted.

According to an embodiment of the invention, this means consists for each pad in:
a) An input device which makes it possible to interface the bits of information to be transmitted in order to increase immunity to parasites and to make them compatible with signals coming from mechanical or static limit switches.

 b) An output device which makes it possible to interface the bits of the information received in order to be able to directly control electromagnetic relays or programmable static inputs.

 c) An electronic device which converts parallel information into serial information by including start, end and parity bits.

d) An electronic device which makes it possible to convert serial information into parallel information and to validate this information towards the output device if the start, end and parity bits indicate that it is valid information.

 e) A static switch.

 f) The choice of oscillation frequencies of inductive proximity switches. Active loop tuning frequencies.

 g) The electrical control signals which make each stud emitter or receiver, and the electrical control signals.

 h) The protocol which allows the two studs to "dialogue" as soon as they are opposite each other. This, without additional external signal.

 The transmitter pad receives parallel information on its input device and eliminates any electrical noise. These parallel information bits pa are supplied to the electronic device which transforms them into a serial electrical signal which activates or not the static switch, the latter closes or opens at the rate of this serial information the active loop consisting of a tuned turn, forming a series resonant circuit, at the frequency of the electromagnetic field of the inductive proximity detector of the receiver pad.

 Therefore, and by eddy current, this series resonant circuit takes or not energy, at the rate of the serial information, from the inductive proximity detector of the receiver. This energy draw appears at the output of the inductive proximity detector as serial information. This serial information is translated into parallel information which appears on the output devices of the output device if and only if it is valid information, otherwise, a transmission failure signal is sent directly to a output element of the output device.

 The oscillation of the proximity detector of the transmitting pad is inhibited when the pad transmits and is restored when the pad receives.

 The accompanying drawings illustrate, by way of example, an embodiment of the device according to the present invention.

I. ACTIVE LOOP (transmission phase): The internal code (7) is blocked by the electrical switch signal (8), then the switch (9) sends the parallel information appearing to the electronic device (10) on the input lines (11) via the input device (1). Then, the signal (13) from the device (70) through the output device (32) makes it possible to prohibit the sending of other information on the lines (11).

An emission validation signal (2) has the double effect: a) of prohibiting by the switch (3) the oscillation of the inductive proximity detector (30) and thereby of prohibiting the emission by the coil (5) of an electromagnetic field of frequency f1 in the vicinity of the detection face (6).

b) to control the electronic device (10) which takes into account the parallel information available at the output of the switcher (9), to transform this parallel information into a serial signal (14) by including start and end bits and parity.

This serial signal controls the static switch (15), which closes or opens at the rate of the serial signal the active loop consisting of the coil (16) tuned to the frequency fQ by the capacitor (17). When the switch is closed, the active loop (15S16,17) absorbs the electromagnetic field at the frequency X created in the vicinity of the detection face (18) of the inductive proximity detector of the receiving pad when the latter is in look of the whorl and a distance less than or equal to the range. As soon as the serial signal (14) is completely emitted, the signal (13) changes state and indicates that other parallel information can be sent over the lines (11).

 II. INDUCTIVE PROXIMITY DETECTOR (reception phase): an oscillator (4) associated with an induction coil (5) maintenance in the vicinity of the detection face (6) an electromagnetic field at frequency fs, this field is absorbed or not by the active loop of the transmit pad when it is opposite the receive pad and at a distance less than or equal to the range. This has the effect of reducing or not the amplitude of the oscillation signal of the oscillator (4), this modulated signal is then rectified filtered by the cell (19), the variations in level of this signal are transmitted to a threshold detector (20) which translates them into an electrical signal (21) all or nothing, this all or nothing signal is the serial image of the parallel information emitted by the emission pad.

This signal (21) which comprises in addition to the information bits the start, end and parity bits is routed either on 1 output device (14) or on the electronic device (10), the latter converts the signal series (21) into a parallel signal. Furthermore, the examination of the start, end and parity bits generates or not a transmission fault signal (22) which, via the inhibitor (23), transmits or not to the output device (32j the parallel information and the signal (24). This signal (24) indicates that valid information is available on the output lines (25).

III. CHOICE OF FREQUENCIES: In order to reduce the size of the studs as much as possible, and in order to avoid interference, the coil (5) emits near its detection face (5) an electromagnetic field of frequency fX X then, the loop ( 27,28,29) is granted to the frequency f. Similarly, the coil (26) emits near its detection face (18) an electromagnetic field of frequency Then, the active loop (15,16,17) is tuned to the frequency fs. In this case, f and f have separate values.

 IV. DIALOGUE PROTOCOL: Without permanent control and without outside intervention, it allows the two studs to indicate that they are able to dialogue. To do this, we choose a marten plot and a slave plot. The master pad is in permanent reception, while the slave pad is in permanent transmission. The routing signal (8) associated with the transmission validation signal (2) allows the clock (12) to send internal information (7) to the electronic device (10). ) appears in serial form on the line (14) and implements or not the active loop (15,15,17). As soon as the clock signal (12) changes state the slave pad goes into reception then, if nothing happens, at the next change of state of the clock signal the slave pad goes back into transmission and this that the two studs are not correctly positioned. As soon as the two studs are facing each other, the mature stud receives the internal information (7) from the slave stud, which has the effect of causing the line (24) of the master stud to change state and indicate that the the master pad goes to transmission and on the clock phase (12) where the slave pad is in reception, returns the internal information (7) it has just received, the slave pad receives this information which modifies the state of the signal (24), then, the slave slave changes the state of the signal of referral (8) and sends towards the marten plot recognition information then passes to reception. As soon as the marten plot reviews this recognition signal, the "dialogue" can begin, otherwise, if on the clock phase (12) or the slave pad is in reception, selui does not review its internal information (7), emitted by the pad master, the signal state (24) is not modified and the slave pad does not modify the signaling signal state (nj nt sends on the next change state of the clock (12) its internal infermatinn (7) different from the recognition information that the maltre plot 'awaits to receive, the assembly (plot + supervisor) then takes the decisions to modify the relative displacements of the two studs. At the end of the dialog, the marten plot sends "slave exchange" information to the slave plot and goes into reception. When the two pads are no longer opposite, a faulty transmission signal appears on the line (22), then the slave pad returns to transmitting its internal information (7) by the appropriate signals on the lines (2) and (8). This phase only takes place when the master end information has been received from the master pad and the transmission fault signal appears on line (22) of the slave pad.

 The device which is the subject of the invention can be used in all cases where it is necessary, without contact and electrical connection between two sets: - to transmit and restore parallel or serial information, in one direction or in two directions, - to communicate between two programmable controllers , - send orders or control their effects, - communicate codes linked to models (identifications) or positions (coding).

Claims (18)

CLAIM5  1) Device making it possible to exchange information in serial and parallel form in one direction or in two directions by an inductive proximity detector (receiver) associated with an active loop (transmitter). Characterized by the fact that it includes a means which allows the active loop to influence the inductive proximity detector so that the parallel or serial information present on the transmitter is restored in secure form and parallel to the output of the receiver and this without contact and / or electrical connections between the transmitter and the receiver. Also characterized by the fact that a single transmitter and a single receiver can transmit information appearing as electrical signals on several distinct inputs and reproduce it in the form of electrical signals on several distinct outputs.  2) Device according to claim 1, characterized in that the parallel information is translated into serial information.  3) Device according to claim 1, characterized in that the serial signal is transmitted, without contact or electrical connection, to the inductive proximity detector by the closing or opening of the static switch which operates or not a series resonant circuit consisting of urea turn and a capacitor. This series resonant circuit absorbs or not, and by eddy current, the electromagnetic field emitted by the inductive proximity detector.  4) Device according to claim 1, characterized in that the absorption or not of the electromagnetic field leads to a reduction or not of the amplitude of the oscillation of the inductive proximity detector.  5) Device according to claim 1, characterized in that the reduction or not of the amplitude of the oscillation of the inductive proximity detector is rectified, filtered and translated into an electrical all or nothing serial signal faithful to the serial signal which controls the static switch of the active transmission loop.  6) Device according to claim 1, characterized in that the signals constituting the parallel information are compatible with the signals put by mechanical or electrical limit switches.  7) Device according to claim 1, characterized in that the output signals constituting the parallel or serial output information are capable of directly controlling electromagnetic relays or static inputs of programmable controllers.  8) Device according to claim 1, characterized by the fact that the serial information uses the infcr rell1 contains end and parity start bits.  9) Device according to claim 1, characterized in that the sense signal received from the threshold device rssoci to the inductive proximity detector is treated with dewlap to restore towards the ties of the electrical signals constituting the output information.  10) Device according to claim 1, characterized in that the parallel output information oteot available only if and only if - no transmission fault has been detected.  11) Device according to claim 1, characterized in that the oscillator of the inductive proximity detector of the transmitter is disconnected as soon as the active loop of the transmitter acts.  12) Device according to claim 1, characterized in that by external signals, the transmitter can become receiver and vice versa.  13) Device according to claim 1, Characterized by the fact that electrical signals make it possible to indicate whether information is finished transmitting or if information is received.  14) Device according to claim 1, characterized in that in the event of a transmission fault an electrical signal is emitted in order to indicate this state.  15) Device according to claim 1, characterized in that an electrical signal. allows the transmission of internal information.  16) Device according to claim 1, characterized in that the turn of the active loop consists of an engraving on a printed circuit.  17) Device according to claim 1, characterized in that the static switch consists of a highly saturated transistor.  18) Device according to claim 1, characterized in that a procedure makes it possible to indicate automatically that the two sets are ready to dialogue.  15) Device according to claim 1, characterized in that this procedure consists in transmitting an internal code which, as soon as it is received, is returned to the transmitter, the latter being passed to the receiver.  2,.) Device according to claim 1, characterized in that the transmitter and receiver devices can be physically separated or resembled.