EP0290314A1 - Operating circuit for electric remote-control apparatuses, especially remotely controlled brakers, and apparatuses incorporating this circuit - Google Patents

Abstract

The circuit is arranged inside the circuit (bb) fed via the network with push-buttons (BP) associated with neon indicator lamps (N), and is connected to the coil (B) of the remote-control apparatus. It comprises a diode bridge (D) associated with a thyristor (Th) and a resistor (R), first means with a resistor R2, a capacitor (C2) in parallel with a Zener diode for disabling the gate transistor (T) after a specified period following the impedance drop caused by operating the push-button, and second means comprising a capacitor (C1) in parallel with the terminals of the bridge (D) for returning the whole to the conductive state. <IMAGE>

Description

The present invention relates to a control circuit for electrical remote control devices with bistable mechanism such as remote control switches, and comprising motor means, such as a coil, and intended to be traversed by an electric motor current from the network to cause a change. state of the device, the new state remaining maintained without requiring consumption of electrical driving energy.

The invention also relates to electrical remote control devices of this type, and in particular remote control switches, timers, relays, time relays, incorporating this circuit.

In French patent application FR-A-2 583 192, filed on June 11, 1985 by the applicant, an electrical remote control device, such as a remote control switch, with a bistable mechanism and comprising wound motor means intended to be traversed by an electric motor current from the network to cause a change of state of the apparatus, the new state remaining maintained without consumption of electric motive energy, and means of control actuated for a random period or not to address the electric motor current to the wound motor means, characterized in that the dimensioning of said wound motor means is less than that which would support a continuous passage of the electric motor current or the highest relative voltage to the supply of said motor means, and in that said control means complete an electronic circuit sensitive to a control member which can be actuated, from a current source of the network, for a random duration to deliver, to said means wound motors, a driving pulse of electrical current from the network motor, of short duration. The present invention proposes to provide such a particularly improved electronic circuit.

An objective, in particular of the invention is to provide such a circuit making it possible to deliver, to said motor means, such as a coil, a short pulse of well calibrated duration.

Another objective of the invention is to produce such a circuit which is particularly reliable.

Another objective of the invention is to produce such a circuit making it possible to supply the motor means with the energy necessary for the tilting of a bistable mechanism, which is capable of detecting the release of a manual control member such as a button -pusher, making the device it controls again ready to receive the next command.

The invention relates to an electronic circuit for controlling remote control devices, said circuit being intended to be actuated by a control member, for example a push button, associated with an impedance, for example one or more indicator lamps. , said electronic control circuit being arranged in the circuit, supplied for example by the network, supplying a motor means, for example a coil, to the remote control device, by means of said control member, characterized in that it comprises first means sensitive to a drop in impedance of said supply circuit, to remain conductive for a short determined period allowing the motor supply of said motor means, then to cease to be conductive at the end of said duration, and second means sensitive to an increase in impedance of said supply circuit, to become conductive again.

In a preferred embodiment, the electronic control circuit can comprise a thyristor associated with a resistor in series, with its trigger control means, said thyristor being associated with a diode bridge to be maintained in the conducting state according to each alternating network.

The first means may advantageously include a detection circuit sensitive to the drop in impedance in the supply circuit, said detection circuit being associated with the thyristor trigger control means for inhibiting the thyristor at the end of said short determined duration .

Advantageously, this detection circuit can comprise a resistor and a capacitor in series, said capacitor being in parallel with a Zener diode controlling a gate control transistor of the thyristor, said capacitor being normally discharged below the conduction threshold of the Zener diode; which then keeps the transistor in the off state, the thyristor trigger then being in the activated state, said capacitor gradually charging in the event of a drop in impedance of the supply circuit until exceeding the conduction threshold of the Zener diode, then causing the inhibition of the thyristor trigger, making the electronic circuit non-conductive.

The second means sensitive to an increase in impedance of the supply circuit preferably include a capacitor in parallel with the alternative terminals of the diode bridge to apply, in the event increase in impedance of the supply circuit, a lower voltage on said alternating terminals of the diode bridge, preventing the thyristor control means from inhibiting the trigger current.

• la figure 1 représente un schéma d'un circuit électronique de commande selon l'invention,
• la figure 2 représente un diagramme de fonc­tionnement de ce circuit dans lequel les courbes l, m, n, o, p représentent respectivement l'état, au cours du temps, du bouton-poussoir, du condensateur C2, du courant moteur, du transistor T et du thyristor Th.

Other advantages and characteristics of the invention will appear on reading the following description, given by way of nonlimiting example and referring to the appended drawing in which:

• FIG. 1 represents a diagram of an electronic control circuit according to the invention,
• FIG. 2 represents a diagram of the operation of this circuit in which the curves l, m, n, o, p respectively represent the state, over time, of the push button, of the capacitor C2, of the motor current, of the transistor T and thyristor Th.

The remote control device intended to be controlled is a remote control switch represented, schematically, in A and incorporated in a circuit of use aa. This remote control switch A comprises a coil B actuating a bistable mechanism M. The coil B is interposed in the supply circuit bb of the alternating network, for example 220 Volts.

In the supply circuit bb there is interposed a plurality of control members B1, B2, ... Bn each comprising a push button BP in parallel with a neon lamp serving as indicator lamp N. When at least one push buttons is actuated by a user, it short-circuits its indicator lamp N, causing a drop in the impedance of the supply circuit bb. In the absence of the electronic control circuit according to the invention, the coil B of the remote control switch is then subjected to the full power of the supply circuit for the entire period during which the push button is activated, which would require a dimensioning of coil B capable of withstanding this power, clearly superfluous since the bistable mechanism M then tilted for a long time.

The electronic circuit according to the invention comprises a diode bridge D interposed on the supply circuit bb, the junctions 1 and 2 of the bridge being connected to the supply circuit bb and the perpendicular junctions 3, 4 to electronic circuit conductors 5, 6.

Between the conductors 5 and 6, there is a thyristor Th with its blocking diode d and a low resistance in series R. This arrangement allows the thyristor to be traversed by the supply current at each alternation of the network.

The gate g of the thyristor Th is actuated by a gate control transistor T interposed between the conductors 5 and 6 with a resistance in series R1 of significant value.

The base of transistor T is connected via a resistor R3 to a Zener diode Z leading to the junction between a resistor of significant value R2 and a capacitor C2, this assembly forming said first means, sensitive to a drop in impedance in the supply circuit bb.

The second means, sensitive to an increase in impedance of the supply circuit, are constituted by a capacitor C1 in parallel with the diode bridge D.

The operation is as follows:

In the idle state, no push button BP is actuated and the power supply circuit bb has a high impedance, of the order of a few kilo-ohms to infinity, depending on the number of organs P1- PN connected. In this state, the thyristor Th is maintained in the conducting state by means of the trigger resistance R1 at each alternation of the sector coming from the diode bridge, the capacitor C2 being discharged below the conduction threshold of said Zener diode Z, so that the gate current through transistor T is not inhibited.

At the closing (instant tO) of one of the push-buttons BP, the impedance in the supply circuit bb drops suddenly, allowing the passage of the motor current in the coil B of the remote control switch A so that the bistable mechanism M rocking. In addition, a high alternating voltage appears across the diode bridge D, so that the capacitor C2 gradually charges (curve m). After a short determined period, preferably between 5 and 20 ms, the DC voltage of the capacitor C2 exceeds the threshold of the Zener diode Z (instant t1). The transistor T then turns on and inhibits the gate current of the thyristor Th. Consequently, at the next voltage alternation (instant t2), the thyristor Th is no longer conductive and the motor current of the coil B is interrupted, the only current remaining being that, very weak, which flows, on the one hand, the capacitor C1 and, on the other hand, the resistors R2 and R1 which in fact impose a non-conductive state on the electronic control circuit. This state remains maintained as long as at least one of the BP pushbuttons remains activated either intentionally or through a malfunction.

When the push button BP is released (instant t3), its neon lamp N is switched on again and the impedance of the supply circuit bb is increased. The capacitor C1 placed at the terminals of the diode bridge D detects this increase in impedance by taking a moderately high voltage which it imposes on the junctions 3, 4 of the bridge D. Consequently, the DC voltage of the capacitor C2 decreases until below the threshold of the Zener diode (instant t4). The transistor T is then blocked and can no longer inhibit the gate current of the thyristor Th which becomes conductive again at the next alternation of the supply sector bb (instant t5). The electronic circuit is then found in the conductive state which remains maintained until the next actuation of a push button.

Although the invention has been described in connection with a particular embodiment, it is understood that it can be made various modifications; thus the Zener diode, for example, can be replaced by any threshold device, such as for example neon lamp, diac, programmable unijunction transistor etc ...

Claims (8)

1. Electronic circuit for controlling remote control devices, said circuit being intended to be actuated by a control member (BP) associated with an impedance (N), said control circuit being arranged in the supply circuit (bb) motor means (B) of the remote control device, via said control member (BP), characterized in that it comprises first means (R2, C2, Z) sensitive to a fall in impedance of said supply circuit (bb), to remain conductive for a short determined period allowing the motor supply of said motor (B), then to cease to be conductive at the end of said duration, and second sensitive means (C1) an increase in impedance of said supply circuit (bb), to become conductive again. 2. Circuit according to claim 1, characterized in that it comprises a thyristor (Th) with its trigger control means (R1, T), said thyristor being associated with a diode bridge (D) to be maintained at the conductive state at each alternation of the network. 3. Circuit according to claim 2, characterized in that said first means comprise a detection circuit (R2, C2, Z) sensitive to the drop in impedance in the supply circuit, said detection circuit being associated with means of thyristor trigger control (T) for inhibiting the thyristor at the end of said predetermined short duration. 4. Circuit according to claim 3, characterized in that said detection circuit comprises a capacitor (C2) in parallel with a Zener diode (Z) connected to the thyristor trigger control means. 5. Circuit according to claim 4, characterized in that said detection circuit is connected to a trigger control transistor (T) (g) of thyristor (Th). 6. Circuit according to any one of Claims 2 to 5, characterized in that said second means, sensitive to an increase in the impedance of the supply circuit, comprise a capacitor (C1) in parallel with the AC terminals of the diode bridge. 7. Circuit according to any one of claims 1 to 6, characterized in that the control member is a push button (BP) associated with a control lamp (N). 8. Electrical remote control devices with bistable mechanism, in particular remote control switches, timers, relays, time relays, incorporating the electronic control circuit according to any one of claims 1 to 7.

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