FR2599141A1 - CONTROL DEVICE, IN PARTICULAR RADIO-PHARE - Google Patents

Abstract

THE INVENTION RELATES TO A CONTROL DEVICE, FOR EXAMPLE OF A HEADLIGHT RADIO. IT INCLUDES FIRST AND SECOND DETECTION ELECTRODES S1, S2 CONNECTED TO A POWER SUPPLY SOURCE 7, AN AMPLIFIER CIRCUIT INCLUDING TWO TRANSISTORS 1, 3 CASCADE UP AND SWITCHING MEANS INCLUDING A BIPOLAR TRANSISTOR 5 AND WHICH RESPONSE TO CIRCUIT 5 AMPLIFIER, CONNECT THE POWER SOURCE TO A LOAD 9 FOLLOWING THE DETECTION OF A CONDUCTIVE LIQUID OR AN INDUCTIVE FIELD. FIELD OF APPLICATION: HEADLIGHT RADIO CONTROL, ETC.

Description

259,914-l

  The invention relates to a control device.

  According to a first aspect of the invention, there is provided a control device comprising means for detecting the presence of a conductive liquid and / or an inductive field and for producing an amplified switching signal when the

  liquid or field is detected, and switching means which, in response to the amplified switching signal, connects a power source to a load.

  According to a second aspect of the invention there is provided a control device comprising cascaded first and second transistors which, in response to an input signal applied to the base of the first transistor, produce an amplified signal, the input signal being representative of a predetermined detected state; and a switching transistor which, in response to the amplified signal, produces a

switched output.

  The second transistor advantageously produces

another switched output signal.

  The detected state is advantageously the presence of a conductive liquid between a first sensor terminal connected to the base of the first transistor 25 and a second sensor terminal arranged so as to be

  connected to a voltage supply.

  The first and second sensor terminals are advantageously arranged to behave like antennas so that the device responds in addition to the presence of an inductive field, the presence

  of this field establishing a second detected state.

  Alternatively, the device may comprise

  damping means, for example a capacitor, for preventing actuation of the device in response to an inductive field.

  In a preferred application, the device

  is arranged to connect a power supply source to a load which may include a light source or a radio beacon which is / are switched on when the sensor terminals come into contact with water.

  The invention will be described in more detail with reference to the accompanying drawings by way of non-limiting examples and in which: FIG. 1 is a diagram of a circuit embodiment according to the invention; Fig. 2 is a diagram showing a modification to the embodiment of Fig. 1; and FIGS. 3A and 3B are, respectively, an end view, along arrow A of FIG. 3B, and a longitudinal section of an embodiment

of the invention.

Figure 1 shows a diagram

  of a circuit of an embodiment of the invention.

  The device comprises a pair of NPN transistors 1, 3 (for example of the type BC109) in Darlington mounting. The common-connected collectors of the transistors 1, 3 are connected to the base of a power transistor PNP 5 (for example of the type BC327).

  Two sensor terminals S1, S2 are respectively connected to a positive power supply bar (connected to a power supply battery) and to the base

of transistor 1.

  A load 9 is mounted between the collector

  of the PNP transistor 5 and a negative power bar 13 connected to the power supply 7. Another low power load, illustrated in the form of a lamp 11, may optionally be connected between the transmitter of the transistor 3 and the bar negative.

  In use, the presence of a conductive path between the terminals S1, S2 circulates a current in the base of the transistor 1, which causes the PNP transistor 5 to be turned on by the effect of cascade of the pair of transistors 1, 3 in assembly

  Darlington, thereby connecting the battery pack 7 to the load 9 (and to the load 11 via the emitter-base junction of the PNP transistor 5 and the transistor 3). Deletion of the conductive path turns off the device.

  In a preferred application, the sensor terminals S1, S2 are arranged outside the device and arranged so that in the presence of a conductive liquid between these terminals S1, S2, a current 15 is activated which triggers the circuit. The presence of the pair of transistors 1, 3 in Darlington mounting has the notable advantage that very low currents are sufficient to trigger the circuit. Thus, the circuit can be operated not only by relatively good water-based conductors, such as seawater, but also by water having very low levels of impurities, for example deionized running water or water

training.

  In a particular application, the device may be arranged to trigger a lamp or radio beacon 9 and may be attached to a lifejacket as a distress device which is automatically switched on when water

  connects the sense terminals S1, S2.

  At least one diode 21 (for example of the IN4001 type) may be provided, if necessary, to lower

  the level of voltage applied to the loads 9, 11.

  In another application, the circuit may be arranged in such a way that the terminals S1, S2 behave as antennas and react to an inductive field.

  tif. Because of the sensitivity of the circuit, it suffices that such an inductive field has a force just large enough to generate a very low current so that the pair of transistors 1, 3 in Darlington circuitry switches the transistor 5. The circuit can therefore be arranged to react to the inductive field developed by a human being or an animal, or to the developed field by an active supply circuit. In this respect, the device is suitable for a particular application, for example as a triggering element for alarm systems.

  FIG. 2 illustrates a modification of the circuit of FIG. 1, designed to prevent activation of the circuit under the effects of an inductive field when these effects are undesirable for a particular application. The same elements are designated by corresponding numerals. In FIG. 2, a capacitor 19 is mounted between the base of the transistor 3 and the negative power bar 13. The capacitor is advantageously a silicon disk capacitor and prevents

  the terminals S1, S2 of the sensor behave like antennas. The capacitor 19 charges from the DC power supply and then forms an "obstacle" opposing any possible actuation of the device.

  It suffices that the value of the capacitor 19 is very small (for example 0.001 microfarad, type 1 kV) for the dissipation of energy of the capacitor

19 is practically negligible.

  FIG. 2 also shows another arrangement of the load, in which a lamp constitutes the load 9, the second switched output, via

  of transistor 3, being connected to ground and not used.

  FIGS. 3A and 3B show a practical embodiment of the device shown in FIGS. 1 and 2 for use as a water detector 22, in which the main constituents are mounted on a resin-coated circuit board 23 and fixed, with batteries 7 power supply, inside a box 25. The space surrounding the batteries and the circuit is filled with material of the type "Silastic 916 RTV". The casing 25 is hermetically sealed by a stopper 27 made of thermosetting material, from which three pins 13, 15 and 17 covered with insulators emerge. The pin 13 is connected to the negative voltage supply bar, the pins 15 and 17 being respectively connected to the collector of the transistor 5 and to the emitter of the transistor 3, these pins constituting the switched outputs. The pins 13, 15 and 17 protruding are arranged to be connected to another block which comprises the charges 9, 11. The terminals S1, S2 are also provided through the plug 27 and 20 are arranged to flush with the In use, the block comprising the charges 9, 11 is attached to the detector 22 so as to be spaced from the surface 29 which is open to the outside. Therefore, if the detector 22 is immersed in water, a connection is established between the terminals S1, S2, which triggers the circuit and supplies power to the

fillers 9, 11.

  Although the device is shown as being connected to a source 7 consisting of a battery 30 or a battery, it is understood that this is not limiting and that the device can be used in connection with the mains. In such a use, the device may advantageously comprise a light-emitting diode indicator. In addition, it will be appreciated that with an alternating current source, the capacitor 19 does not produce a damping effect with respect to inductive field interference. However, the presence of damping means for alternating current

is within the scope of the invention.

  In addition, although particular applications of the device have been cited, this device is not limited to such applications and it can be used in other applications for which

  The detection and switching function 10 as described can be applied.

  It goes without saying that many modifications

  can. be made to the device described and shown without departing from the scope of the invention.

Claims (11)

  1. Control device, characterized in that it comprises detection means for detecting the presence of a conductive liquid and / or an inductive field, said detection means comprising first and second electrodes (S1, S2) connected to a power supply source (7), an amplification circuit coupled to one of the electrodes and a switching means coupled to the switching circuit 10 and responsive thereto for connecting the source   feeding to a load (9) following detection of said liquid and / or said field at said electrodes.   2. Device according to claim 1,   characterized in that the amplification circuit comprises two cascaded transistors (1, 3).   3. Device according to claim 1,   characterized in that the switching means comprise a bipolar transistor (5).   4. Device according to claim 1, characterized in that the amplification circuit is   further arranged to connect the power source to another load (11) requiring less power than the load connectable to the power source through the switching means.   5. Device according to claim 1,   characterized in that it further comprises damping means (19) connected to the amplification circuit for preventing tripping of the device in response to an inductive field.   6. Device according to claim 5,   characterized in that the damping means comprises a capacitor (19) connected to the amplification circuit.   7. Device according to claim 1, characterized in that the power supply source comprises at least one battery (7) and in that the device further comprises a stack (25) housing the battery, the circuit of amplification and switching means, the first and second electrodes protruding from the casing. 8. Set consisting of a device   control according to claim 1 and a load (9) connected to the switching means (1, 3).   9. Assembly according to claim 8, characterized in that the load comprises a light source for a radio-beacon.   10. The assembly of claim 8, charac- terized in that it further comprises a second load   (11) connected to the amplification circuit.   11. An assembly according to claim 8, characterized in that the charge is maintained in a separate block of the device, the latter and the block being connected electrically by means of connectors (13, 15, 17) protruding from the device.