FR2779889A1 - Capitative effect contact detector for electrical switch - Google Patents

Abstract

The detector comprises a tactile plate (10) in capitative coupling with three electrodes. An emission electrode (14) is connected to an oscillator (20), and the reception electrode is connected to an amplifier (22) via a bandpass filter (24) centered on the frequency of oscillator. A feedback electrode (18) is connected to the output of the amplifier. The feedback is preferably positive with respective to the reception electrode. The electrodes are insulated from the tactile plate by a substrate (12), which is fabricated from wood, glass or plastic. The oscillator output amplitude is 3-10 volts and its frequency is 20-200 kHz. The output of the amplifier is connected to a threshold detector (26). In absence of physical contact with the tactile plate (10), the output of the detector (26) is a DC voltage of 5 volts. In the case of physical contact with the tactile plate, the coupling falls, and the output of the detector falls to zero. This condition can be inverted. In a variant of the device, the tactile plate is covered with a second substrate and connected to a through connection passing via the substrate.

Description

The present invention relates to a capacitive effect contact detector.

  contact detector by capacitive effect intended to replace conventional electric switches or switches or to control electronic circuits such

  than power variators or equivalent.

  Such contact detectors are known in the art. For example, document US-A-4 087 702 describes an electronic power variator whose control is ensured by direct contact of the user with one or more precise points of the circuit, these points being electrically connected with this latest. This results in a risk of electric shock in the event of failure of the electrical insulation, and, at least, an unpleasant tactile sensation when the user touches one of these points under voltage, in particular since the tactile plates are directly

  connected to the power elements.

  Document GB-A-1 529 862 describes a device which overcomes this drawback. The touch plate is isolated from the power circuit associated with the transmission electrode, but this device requires an oscillator operating at approximately 120 Volts at 50 kHz electrically connected to a summing circuit directly connected to the reception electrode. On the one hand, there is therefore here no electrical isolation of a circuit with respect to the other, which poses a serious problem in the event of failure of one of its components, in particular a diode. On the other hand, such a device imperatively requires a means of adjusting the equilibrium position in the form of a potentiometer accessible to the user. Now this position of equilibrium must

  be readjusted at any time by the very fact of the drifts due to the thermal differentials applied to each of the electronic components.

  In the device described in GB-A-2,080,536, the touch plate is also isolated, and this circuit also solves the problem of electrical isolation between the two circuits, but it still requires a potentiometer for the system setting. The oscillator delivers a high frequency rectified sinusoidal alternating voltage at high frequency which, by its very nature, generates radiation

electromagnetic interference.

  The present invention is situated in this context and proposes a contact detector which overcomes the aforementioned drawbacks. A detector

  in accordance with the present invention can thus be, without danger, placed in a hostile environment, while ensuring intrinsic security for the user.

  The invention therefore relates, more specifically, to a capacitive effect contact detector comprising a conductive touch plate capacitively coupled, on the one hand, to a transmission electrode and, on the other hand, to a reception electrode, the electrodes transmission and reception being electrically isolated from each other. The transmission electrode is connected to an oscillator, while the reception electrode is connected to the input of an amplifier. 25 According to the invention, the output of the amplifier is connected to a feedback electrode capacitively. coupled to the touch plate and

  electrically isolated from the transmit and receive electrodes.

  Preferably, the reaction electrode determines a positive reaction applied to the receiving electrode.

  Advantageously, the reaction electrode is physically disposed between the emission and reception electrodes.

  In a preferred embodiment, the receiving electrode is connected to the input of the amplifier via a pass filter

  band centered on the frequency of the signal delivered by the oscillator. Advantageously, this filter is an active filter with multiple feedback. In the preferred embodiment, the oscillator delivers a square signal with a steep front at high frequency whose amplitude is between 3 and 10 volts approximately, and the frequency is between about 20 and 200 kHz. The invention will be better understood, and other aims, advantages and characteristics thereof will appear more clearly on reading the

  description which follows of a preferred embodiment given by way of non

  limiting and to which a drawing sheet is attached in which: FIG. 1 schematically represents a contact detector according to a preferred embodiment of the present invention; and

  Figure 2 illustrates an alternative embodiment of the touch plate.

  Referring now to Figure 1, there is illustrated a contact detector by capacitive safety effect according to the present invention. This detector essentially comprises an electrically conductive touch plate 10 directly accessible to the user. Such a plate can be produced in the form of a metal sheet

  electrically insulated and bonded to a wall of an electrically insulating substrate 12.

  Such a substrate 12 is preferably chosen from wood, glass and plastics. Indeed, these materials have low dielectric performance and high loss angle tangents. In addition, they provide isolation up to an inherent breakdown voltage which is generally very high and, in any event, significantly higher than the voltages involved in the detector of the invention. This, of course, taking into account a possible mode of supply from the

distribution of electricity.

  Thus, the detector can be connected, for its own power supply, to a voltage whose potential with respect to the earth is much higher than that necessary for its operation. For example, at one of the supply poles can be at the potential of a phase of the network

  electrical distribution (630 Volts relative to earth).

  The thickness of the substrate 12 essentially depends on the material chosen to constitute it and can reach up to 20 mm.

  On the opposite wall of the substrate 12, there are three electrodes 14, 16 and 18, which can also be produced in the form of metal or electrically conductive strips or sheets bonded to the substrate 12 by any suitable adhesive means. They can also be produced by copper films deposited on a sub-substrate bonded to the substrate 12

  and obtained, like a printed circuit, by photogravure or appropriate chemical attack.

  These three electrodes are, of course, electrically separated

each other.

  The electrode 14, called the emission electrode, is connected to the output of an oscillator 20. This oscillator 20 is of the astable type, and delivers, by

  example, a square wave signal with a high frequency steep edge.

  In a preferred embodiment, this signal has an amplitude on the order of 5 Volts, and a frequency on the order of 100 kHz. Such a signal has the advantage of good transmission in substrates

of the type specified above.

  The electrode 16 is called the reception electrode. In fact, due to the capacitive coupling, an electric field is created between the transmitting electrode 14 and the touch plate 10, and between the touch plate 10 and the receiving electrode 16: Thus, except modification of the plate state

  touch 10, as will be seen, the signal on the transmission electrode 14 is transmitted to the reception electrode 16, in a manner, admittedly, altered.

  - Thus, the reception electrode 16 normally receives, that is to say in the absence of any external contact, a periodic pulse signal

  with an amplitude between 100 and 600 mV depending on the thickness of the substrate 12.

  This high frequency periodic signal is applied to a conventional amplifier 22 via an active pass filter.

  band 24 centered on the frequency of the oscillator 20. Such a filter 24 is, for example, a multiple feedback filter of the Rauch type, which delivers to the amplifier 22 a signal filtered from its harmonics and rendered pseudo- 15 sinusoidal whose amplitude is close to that of the signal collected by the reception electrode 16, at a frequency of 100 kHz (with the values

  above of the signal delivered by the oscillator 20).

  Such an active filter is desirable to eliminate or at least greatly attenuate the spurious signals that may be. introduced via the touch plate 10. In particular, such a filter can strongly attenuate the parasitic signals resulting from the magnetic field at or 60 Hz which bathes any domestic environment. For example, a

  attenuation of these signals of the order of 40 dB is desirable.

  The output of amplifier 22 is applied to a threshold detector 26 which will generate a logic signal of the 0-5 Volts type in the example shown. This logic signal is the one that will be used to control

  a static electric switch, a power variator or any other electronic control element of an external fact.

  - In accordance with the invention, the output of the amplifier 22 is also applied to the so-called reaction electrode 18. This reaction electrode 18 being capacitively coupled to the reception electrode 16 by

  through the touch plate 10, a positive reaction is thus obtained which will be taken into account by the reception electrode 16 to promote and amplify ab initio the signal received by this last electrode 16.

  By physically placing this reaction electrode 18 between the emission 14 and reception 16 electrodes, any direct capacitive coupling between these last two electrodes 14 and 16 is avoided or at least greatly attenuated. Note that direct coupling between the emission electrode 14 and the reaction electrode 18 has no significant effect, and that a direct coupling between the reaction electrode 18 and the electrode

  reception 16 is rather favorable to the functioning of the detector.

  In addition, such an arrangement of the three electrodes 14, 16 and 18 also avoids any random or parasitic triggering due to the environment, which completely dispenses with the device using a potentiometer intended to adjust the gain of the amplifier 22 as a function of this environment. Therefore, the detector according to the invention is, in addition, not bound by the thickness of the substrate 12. to a reasonable extent, of course. So, if the substrate is quartz glass, the detector can work

  up to a thickness of around 15 mm, which is already considerable.

  In operation, in the absence of physical contact with the touch plate 10, the signal applied to the transmission electrode 14 is received by the reception electrode 16 and the threshold detector 26 outputs a DC voltage from the order of the detector supply voltage, for example of the order of 5 Volts. During physical contact with the plate

  touch 10, the latter is substantially grounded and the capacitive coupling drops. The signal received by the reception electrode 16 becomes unusable because of too low an amplitude, and the threshold detector 26 delivers a zero voltage at output. Obviously, the output signal from the threshold detector 26 can also be inverted.

  We have therefore well described a contact detector whose operation is completely silent, since comprising no moving parts, operating under a low voltage (of the order of 5 Volts), consuming a current of the order of a few milliAmpers, does not generating

  no electromagnetic interference, and offering total safety for the user.

  In addition, since the reaction electrode 18 is disposed between the emission 14 and reception 16 electrodes, the coefficient of direct coupling between the emission 14 and reception 16 electrodes is greatly reduced, which significantly improves the rate of discrimination of the bandpass filter 24. By way of example, the discrimination rate is of the order of 1.7 when the reaction electrode 18 is absent, while it increases to more than 4 when

  this reaction electrode 18 is present.

  This avoids the presence of an expensive and unnecessary potentiometer for adjusting the gain of the amplifier 22, so as to determine

  a standard contact detector, as long as the thickness of the substrate 12 remains reasonable (for example less than 20 mm). For greater thicknesses of the substrate 12, it will obviously be necessary to modify the amplifier 22 so that it has a greater gain.

  As those skilled in the art will have understood, the detector according to the invention makes it possible to ensure the intrinsic safety of the user, even if he is in a hostile environment, for example humid, dusty or explosive, since the substrate 12 can favorably be achieved in a way

  completely sealed, the electronic circuits of the detector then being outside this hostile environment. In addition, the power dissipated by these electronic circuits is extremely low, which means that they can favorably be encapsulated.

  In addition, the touch plate 10 can take any shape and, therefore, the detector according to the invention can, therefore, constitute

  a security device making it possible, for example, to easily observe an intruder presence in a dangerous zone.

  In Figure 2, there is shown an alternative embodiment of the touch plate 10 allowing to keep the concept of intrinsic security while being substantially free from the thickness of the substrate 12. Thus, a second substrate 32 covers the touch plate 10 which is therefore sandwiched between the two substrates 12 and 32. An electrically conductive nail 30 is connected to the tactile lacquer and passes through the second substrate 32 and allows the user to come into contact with the tactile plate

  10. Such an arrangement also makes it possible to protect the touch plate 10 in an environment liable to vandalism.

  Although we have represented and described what are currently considered to be the preferred embodiments of the present invention, it is obvious that those skilled in the art will be able to make various changes and modifications thereto without departing from the scope of the present invention as defined below. In particular, the design of the touch plate 10 is thus completely open to adapt to the desired function of such a detector

of contact.

*

Claims (8)

  1 - Capacitive effect contact detector comprising a capacitively conductive touch plate (10) coupled through a substrate (12), on the one hand, to an emission electrode (14) and, on the other hand, to an electrode receiving (16), said transmitting and receiving electrodes (14, 16) being electrically isolated from each other, said transmitting electrode (14) being connected to an oscillator (20), while that the receiving electrode (16) is connected to the input of an amplifier (22), characterized in that the output of said amplifier (22) is connected to a reaction electrode (18)   capacitively coupled to said touch plate (10) and electrically isolated from said transmit and receive electrodes (14, 16).   2- contact detector according to claim 1, characterized in that said reaction electrode (18) determines a   positive reaction applied to said receiving electrode (16).   3- Non-contact detector according to claim 1 or 2, characterized in that said reaction electrode (18) is physically arranged between said transmission and reception electrodes (14, 16) .20 4- Contact detector according to claim 1, 2 or 3, characterized in that said receiving electrode (16) is connected to the input of said amplifier (22) by means of a bandpass filter (24) centered on the frequency of the signal delivered by said oscillator (20). 5 - Contact detector according to claim 4, characterized in that said filter (24) is an active filter with multiple feedback.   6- contact detector according to any one of the preceding claims, characterized in that said oscillator (20)   delivers a square signal with steep edge at high frequency.   7- Contact detector according to any one of   previous claims, characterized in that the output signal from said oscillator (20) has an amplitude between 3 and 10 volts approximately, and a   frequency between approximately 20 and 200 kHz.   8- contact detector according to claim 6, characterized in that the output signal of said oscillator (20) has a   amplitude of the order of 5 Volts, and a frequency of the order of 100 kHz.   9- Contact detector according to any one of   previous claims, characterized in that the output of said   amplifier (20) is connected to the input of a threshold detector (26) whose output delivers a logic signal.   - Contact detector according to any one of the preceding claims, characterized in that a second substrate (32)   covers said touch plate (10), an electrically conductive nail (30) being connected to said touch plate (30) and completely passing through said second substrate (32) to allow contact with said touch plate (10).   11- Contact detector according to any one of the preceding claims, characterized in that the substrate (12, 32)   electrically insulating is chosen from wood, glass and plastic.