FR2924286A1 - Electric supply power adjusting device for home automation, has isolation circuit provided with output exempt from galvanic contact with supply input, and adapting state that depends current circulating between internal nodes - Google Patents

Abstract

The device has a setpoint unit including an activation circuit (4) provided with an isolation circuit (8) and a supply circuit (7). The isolation circuit has internal nodes (801, 802) in which the node (801) is connected to a switch (6) and to a supply input (80) of the isolation circuit, and another node (802) is connected to a conductor (12). The isolation circuit has an output (41) constituting an output of an activation circuit, exempt from galvanic contact with the supply input of the isolation circuit, and adapting a state that depends current circulating between the nodes.

Description

1

DEVICE FOR ADJUSTING AN ELECTRIC POWER SUPPLY, HAVING IMPROVED IMMUNITY TO PARASITES.

The invention relates generally to electronic control techniques adapted to home automation.

More specifically, the invention relates to a device for adjusting a power supply power delivered to a load connected to a first conductor of an AC voltage source, this device being connected in operation between this load and a second conductor. the voltage source, and comprising: an electronic variator whose first and second terminals are, in operation, respectively connected to the load and to the second conductor; a control logic unit connected to the drive, having a setpoint input, and adapted to adjust, according to the state of its setpoint input, the power transmitted to the load by the drive; and setpoint means comprising an activation circuit whose output is connected to the setpoint input of the logic unit, a conductive line whose first end is connected to an input of the activation circuit, and a remote switch on a second end of the conductive line and selectively adopting a closed position or an open position in which this conductive line is respectively connected to the second conductor of the source and isolated from the second conductor, the activation circuit placing the setpoint input of the control unit in a first or a second state depending on whether the switch is in the closed or open position.

A known device of this type will be described in particular below with reference to the diagram of FIG.

More generally, the principle of adjustment, by means of a switch, of a supply power delivered to an electric load is well known to those skilled in the art, as shown in particular in the patent document FR 2 808 647.

In recent devices of this type, the ground of the circuit diagram is connected sometimes to the second conductor, brought to the phase potential of the electrical network, sometimes to the potential of the first terminal of the drive, also called "potential of the cut phase".

In addition, the conductive line carrying the switch is generally passed in the same technical sheath as the conductors of the electrical network.

Under these conditions, and as shown in Figure 1, a parasitic capacitance K appears across the switch, so that the state of the logic unit reference input can no longer be reliably controlled as soon as possible. that the length of the conductive line reaches several tens of meters.

In this context, the object of the present invention is to propose an electric power adjustment device that can be used under the current mounting conditions, even when the length of the conductive line exceeds 50 meters or even 100 meters.

To this end, the device of the invention, moreover, in accordance with the generic definition given in the preamble above, is essentially characterized in that the activation circuit comprises a circuit 30

power supply and an isolation circuit, in that the supply circuit is connected between the first and second terminals of the converter and is adapted to supply a supply current to a supply input of the isolation circuit, in that the isolation circuit comprises first and second internal nodes, the first of which is connected to the switch and the supply input of the isolation circuit and the second of which is connected to the second conductor, and that the isolation circuit has an output constituting the output of the activation circuit, free from galvanic contact with the supply input of this isolation circuit, and adopting a state dependent on the current flowing between said internal nodes.

In the preferred embodiment, the isolation circuit comprises an opto-coupler connected between the first and second internal nodes.

It is also advantageous to provide that the supply circuit comprises a low-pass filter and that the supply circuit comprises a rectifying diode, the supply current thus being continuous.

Preferably, the second internal node is connected to the second conductor via at least one impedance of value greater than the impedance of the conductive line. The first internal node can also be connected to the second conductor via a filtering capacitor rejecting the high frequency noise. 35 2530 4

A protection circuit can be connected to the first internal node, this protection circuit comprising a resistor connected in series with the switch on this first node, and a zener diode connecting this first node to the second conductor.

For optimum flexibility of use, the control unit comprises for example a microcontroller.

Other features and advantages of the invention will emerge clearly from the description which is given below, for information only and in no way limitative, with reference to the accompanying drawings, in which: - Figure 1 is a diagram illustrating a known device electric power control; and

FIG. 2 is a diagram partially illustrating an electric power control device according to the invention.

As previously announced, the invention relates to a device for adjusting the power supply power delivered to a load X.

In a conventional manner (FIG. 1), the load X is connected to a first conductor 11 of an AC voltage source, this conductor 11 being generally constituted by the neutral conductor.

In operation, the device is connected between this load X and another conductor 12 of the electrical network, this other conductor 12 being generally constituted by the phase conductor. This device comprises, in a manner also known, an electronic variator 2, a control logic unit 3, and various setpoint means, these setpoint means themselves including an activation circuit 4, a conductive line 5, and a remote switch 6.

In operation, the first terminal 21 of the electronic variator 2 is connected to the load X, while the second terminal 22 of this variator 2 is connected to the second conductor 12.

The control logic unit 3, which is generally constituted by a microcontroller, which is connected to the drive 2, and which has a setpoint input 31, is designed to drive the drive 2 according to the state of its setpoint input. 31, and to thereby adjust the electrical power that this drive transmits to load X.

A first end of the conductive line 5 is connected to an input 42 of the activation circuit 4, while the second end of this line, for example more than 50 meters from the first end, is equipped with the switch 6 .

This switch, which is generally constituted by a monostable pusher, defaults to an open position, but can adopt a closed position under the solicitation of a user. In the closed position of the switch 6, the conductive line 5 is connected to the second conductor 12, this line 5 being isolated from this conductor 12 in the open position of this switch 6. 3530 6

Furthermore, when the switch 6 is in the closed position, the activation circuit 4 places the setpoint input 31 of the control unit 3 in a first state.

On the other hand, when the switch 6 is in the open position, the activation circuit 4 places the setpoint input 31 of the control unit 3 in a second state, different from the first state, and this control unit interprets in a known manner as a different setpoint.

As shown again in FIG. 1, a power supply circuit ALIM is connected to the terminals of the variator 2 in order to supply the control unit 3 with the electrical energy necessary for its operation.

In addition, a SYNCHRO synchronization circuit is connected in parallel to the ALIM circuit to supply the control unit 3 with an image signal of the voltage at the terminals 21 and 22 of the drive 2 and to enable this control unit 3 to drive the drive 2 at times correlated with the zero crossing of this voltage.

FIG. 2, which represents a device according to the invention, uses the same reference numerals as FIG. 1 to designate identical or functionally equivalent means or circuits. For the sake of brevity and simplicity, the ALIM and SYNCHRO circuits, although also usable in a device according to the invention, have not been shown again in FIG.

According to the invention (FIG. 2), the activation circuit 4 comprises a supply circuit 7 and an isolation circuit 8.

The supply circuit 7, which is connected between the terminals 21 and 22 of the converter 2, is designed to supply a supply current to a supply input 80 of the isolation circuit 8.

For example, this circuit 7 comprises a resistor 7R1, a first capacitor 7C1, a rectifying diode 7D1 and a second capacitor 7C2, these components being connected in series between the terminals 21 and 22 of the variator 2, a Zener diode 7D2 being connected in parallel to the diode 7D1 and the second capacitor 7C2, and the supply input 80 of the isolation circuit 8 being connected to the common terminal between the diode 7D1 and the second capacitor 7C2.

The resistor 7R1 and the capacitor 7C1 together form a low-pass filter making it possible to extract the DC component of the voltage at the terminals of the variator 2, the rectifying diode 7D1 enabling the circuit 7 to supply a continuous supply current.

The isolation circuit 8 comprises two internal nodes, 801 and 802, the first 801 of which is connected both to the supply input 80 of the isolation circuit through a resistor 8R2 and to the switch 6, and the second 802 of which is connected to the second conductor 12.

This isolation circuit 8 has an output 41 which constitutes the output of the activation circuit 4 and which is therefore connected to the setpoint input 31 of the control unit 3.

The output 41 of this isolation circuit 8 is free from any galvanic contact with the supply input 80 of the same circuit 8, and adopts a state which depends on the current flowing between the internal nodes 801 and 802 of the circuit insulation 8.

Thus, when the switch 6 is in the closed position, the nodes 801 and 802 are connected to each other at least through the line 5, the switch 6 and the second conductor 12, so that no current flows between the nodes 801 and 802 and the setpoint input 31 of the unit 3 is placed in a first state.

On the other hand, when the switch 6 is in the open position, the supply current received at the input 80 of the isolation circuit flows between the nodes 801 and 802, so that the setpoint input 31 of the unit 3 is placed in a second state.

In the illustrated embodiment, which corresponds to the preferred embodiment, the isolation circuit 8 comprises an opto-coupler 81 which is connected between the internal nodes 801 and 802, and whose output 41 constitutes the output of the circuit of FIG. activation 4 connected to the setpoint input 31 of the control unit 3.

The second internal node 802 is preferably connected to the second conductor 12 via at least one impedance, such as a resistor 8R1, whose value is substantially greater than the impedance of the conductive line 5 so as to facilitate the dissipation of the supply current when the switch 6 is in the closed position.

For its part, the first internal node 801 is preferably also connected to the second conductor 12 by 9

via a filtering capacity 8C1 for rejecting high frequency noise.

The device of the invention may also comprise a protection circuit 9 connected to the first internal node 801 and comprising a resistor 9R1 and a zener diode 9D1, the resistor 9R1 being connected in series between this first node 801 and the switch 6, and the zener diode 9D1 connecting this first node 801 to the second conductor 12.

The operation of the device is as follows.

When the switch 6 is open and in the absence of interference on the line 5, the opto-coupler 81, permanently supplied by the supply current received from the circuit 7, is in a conductive state. A logical zero is therefore provided at the setpoint input 31 of the unit 3.

When the switch 6 is open and in the presence of interference on the line 5, the opto-coupler 81, intermittently powered by the supply current received from the circuit 7, alternately switches from the conductive state to the state blocked at the rate of parasitic voltages. The setpoint input 31 of the unit 3 then receives a variable signal, taking alternately the value 0 and the value 1.

Finally, when the switch 6 is closed, the line 5, whose impedance is very low in front of the resistor 8R1 by a value of 100 ohms for example, diverts the supply current supplied by the circuit 7 to the input 80. The opto-coupler 81 is thus blocked and delivers a permanent logic 1 to the setpoint input 31 of the unit 3.

Any high frequency parasitic voltages which may appear on line 5 are

filtered by the capacity 8C1, of a value of 1 nF for example. In summary, the state represented by a permanent logic 1 on the setpoint input 31 indicates to the unit 3, reliably, that the switch 6 is closed.

Claims (8)

. 1. Device for adjusting a power supply power delivered to a load (X) connected to a first conductor (11) of a source (11, 12) of alternating voltage, this device being connected in operation between this load (X) and a second conductor (12) of the voltage source, and comprising: an electronic variator (2) whose first and second terminals (21, 22) are, in operation, respectively connected to the load (X) and the second driver (12); a control logic unit (3) connected to the inverter (2), having a setpoint input (31), and adapted to adjust, according to the state of its setpoint input (31), the power transmitted to the load (X) by the drive (2); and setpoint means comprising an activation circuit (4) whose output (41) is connected to the setpoint input (31) of the logic unit (3), a conductive line (5) having a first end is connected to an input (42) of the activation circuit (4), and a switch (6) offset on a second end of the conductive line (5) and selectively adopting a closed position or an open position in which this conductive line (5) is respectively connected to the second conductor (12) and isolated from this second conductor (12), the activation circuit (4) placing the setpoint input (31) of the control unit (3) in a first or second state according to whether the switch (6) is in the closed or open position, characterized in that the activation circuit (4) comprises a supply circuit (7) and an isolation circuit (8) , in that the supply circuit (7) is connected between the first and second terminals (21, 22) of the iator (2) and is adapted to supply a supply current to a supply input (80) 12 of the isolation circuit (8), in that the isolation circuit (8) comprises first and second nodes internal (801, 802), the first (801) of which is connected to the switch (6) and to the supply input (80) of the isolation circuit and the second (802) of which is connected to the second conductor (12), and in that the isolation circuit (8) has an output (41) constituting the output of the activation circuit (4), free from galvanic contact with the supply input (80) of this isolation circuit (8), and adopting a state dependent on the current flowing between said internal nodes (801, 802). 2. Control device according to claim 1, characterized in that the isolation circuit (8) comprises an opto-coupler (81) connected between the first and second internal nodes (801, 802). 3. Control device according to any one of the preceding claims, characterized in that the supply circuit (7) comprises a low-pass filter (7R1, 7C1). 4. Control device according to any one of the preceding claims, characterized in that the supply circuit (7) comprises a rectifying diode (7D1), the supply current thus being continuous. 5. Adjusting device according to any one of the preceding claims, characterized in that the second internal node (802) is connected to the second conductor (12) via at least one impedance (8R1) of greater value than the impedance of the conductive line (5). 20 13 6. Adjusting device according to any one of the preceding claims, characterized in that the first internal node (801) is further connected to the second conductor (12) via a filtering capacitor (8C1) rejecting the high frequency parasites. 7. Adjusting device according to any one of the preceding claims, characterized in that it further comprises a protection circuit (9) connected to the first internal node (801) and comprising a resistor (9R1) connected in series between this first node (801) and the switch (6), and a zener diode (9D1) connecting this first node (801) to the second conductor (12). 8. Adjusting device according to any one of the preceding claims, characterized in that the control unit (3) comprises a microcontroller. 25