FR3071378B1 - WIRING RECOGNITION METHOD - Google Patents

Abstract

The subject of the present invention is a method for recognizing the wiring of an assembly (1) of at least two dimmers (10, 20, 30) of light, called first dimmer (10) and second dimmer (20), each dimmer (10, 20, 30) comprising at least one transistor (12, 22, 32) and an output (14, 24, 34), the second inverter (20) further comprising a voltmeter (28), the output (14) the first inverter (10) being connected to a first light source (100), the output (24) of the second inverter (20) being connected to the first light source (100), to another light source or to any light source.

Description

DESCRIPTION

The present invention provides a method for recognizing cabling of a set of at least two dimmers comprising a first dimmer having a transistor and an output and a second dimmer having a transistor and an output, the output of the first dimmer being connected to a first light source.

Inverters such as those forming part of such an assembly can be used to vary the light intensity of the light emitted by the first light source, including compact fluorescent lamps and light-emitting diode lamps, which nowadays replace a large extent traditional incandescent bulbs, especially because they consume much less energy. The variable power supply of the light loads is effected in practice by means of an output signal cut in the phase according to a switching mode which depends on the nature of the load, that is to say if is a rather resistive, inductive or capacitive load. For this purpose, the existing drives generally propose at least two operating modes, that is to say a mode of operation called cut-off angle and a mode of operation said conduction angle. In the angle cut mode, the converter closes the transistor at a time of zeroing of the voltage from the AC voltage source and the transistor is open at a time in the half-period following said passage to zero. The difference between the instant when the transistor is closed and the instant when the transistor is open defines the cutoff angle. In the angle conduction mode, the variator opens the transistor at a time when the voltage coming from the AC voltage source is zero and the transistor is closed at a time in the half-period following said transition to zero. The difference between the instant when the transistor is open and the instant when the transistor is closed defines the cutoff angle.

It is also known to group several dimmers so as to form a set of dimmers as described above. These drives can be physically coupled or physically separated from each other. The set of at least two dimmers and / or dimmers can be installed in a box.

The set of at least two dimmers as described above can be configured, if they comprise for example n dimmers, to control n light sources that is to say one per drive present in the set of minus two dimmers.

It is also known to connect several of these inverters in parallel between a power source and a light source. Thus, high power light loads can be controlled by this plurality of inverters connected in parallel.

The present invention aims to put into operation such a set of at least two dimmers, so that the latter can drive one or more light loads at high power. For this purpose, the subject of the invention is a method for recognizing cabling of a set of at least two dimmers, called first dimmer and second dimmer, each dimmer comprising at least one transistor and one output, the second dimmer further comprising a voltmeter, the output of the first inverter being connected to a first light source, the output of the second inverter being connected to the first light source, to another light source or to any light source.

The method according to the invention is characterized by the following successive steps: operating the assembly of at least two drives, either in an operating mode of cut at the angle, or in a mode of operation of conduction to the angle, in a first wiring recognition step and in the angle cut operation mode, from at least two consecutive cycles, open the transistor of the first inverter after opening of the transistor of the second inverter in the first cycle and open the transistor of the second drive after opening the transistor of the first drive in the second cycle, in the first step of wiring recognition and in the operating mode of conduction at the angle, from to minus two consecutive cycles, close the transistor of the first drive after closing the transistor of the second drive in the first cycle and close the transistor or the second drive after the closing of the transistor of the first drive in the second cycle, in the first step of wiring recognition and in the mode of operation of cut to the angle, for the second drive, measure in the first cycle, the voltage present on its output using the voltmeter to determine a moment of drop to zero of the voltage on the possible light source to which its output is connected, to involve, in the second following cycle, the closing of its transistor at the instant of fall to zero thus determined and observe if the instant of closing of the transistor of the second converter converges towards the closing time of the transistor of the first converter, in the first step of recognition of wiring and in the mode of angle-conduction operation, for the second inverter, measure, in the first cycle, the voltage present at its output using the voltm to determine a moment of jump of voltage on the possible light source to which its output is connected and to involve, in the second following cycle, the opening of its transistor at the moment of voltage jump thus determined and observe if the instant of opening of the transistor of the second converter converges towards the instant of closing of the transistor of the first variator.

This operating method has the advantage of being able to detect the wiring used with the set of at least two dimmers, that is to say to detect which of the outputs of the set are connected to the same light source, to be able to synchronize them with each other.

Thus, if a convergence of the instant of closing of the transistor of the second converter to the closing instant of the transistor of the first drive is observed or if a convergence of the instant of opening of the transistor of the second drive to the instant of As the transistor of the first variator is opened, it can be deduced that the second drive is connected in parallel with the first drive to the first light source.

If, on the other hand, a divergence of the instant of closing of the transistor of the second converter towards the instant of closing of the transistor of the first variator is observed or if a divergence of the moment of opening of the transistor of the second drive towards the instant of As the transistor of the first variator is opened, it can be deduced that the second drive is not connected in parallel with the first drive to the first light source.

According to one possibility, the assembly further comprises a third drive, the output of the second drive being connected to a second light source and the output of the third drive being connected to the second light source, to another light source or to any light source .

The method further comprises the following successive steps, in a second wiring recognition step and in the angle-breaking operating mode, from at least two consecutive cycles, opening the transistor of the second drive after the opening of the transistor of the third drive in the first cycle and opening the transistor of the third drive after opening of the transistor of the second drive in the second cycle, in the second step of wiring recognition and in the operating mode of conduction at the angle, from at least two consecutive cycles, close the transistor of the second drive after closing the transistor of the third drive in the first cycle and close the transistor of the third drive after closing the transistor of the second drive in the second cycle, in the second stage of wiring recognition and in the operating mode of co angle setting, for the third variator, to measure, in the first cycle, the voltage present on its output using the voltmeter in order to determine a moment of drop to zero of the voltage on the possible light source to which its output is connected and involve, in the second following cycle, the closing of its transistor at the instant of fall at zero thus determined and observe if the closing time of the transistor of the third converter converges to the closing time of the transistor in the second wiring recognition step and in the angle-conduction operation mode, for the third inverter, measuring, in the first cycle, the voltage at its respective output using the voltmeter to determine a moment of jump of voltage on the possible light source to which its output is connected and to involve, in the second following cycle, the opening of its transistor at the instant of jump of voltage thus determined and observe if the instant of opening of the transistor of the third converter converges towards the instant of closing of the transistor of the second drive.

Thus, if a convergence of the closing moment of the transistor of the third variator to the instant of closing of the transistor of the second drive is observed or if a convergence of the instant of opening of the transistor of the third drive to the instant of As the transistor of the second drive is opened, it can be deduced that the third drive is connected in parallel with the second drive to the second light source.

If, on the other hand, a divergence of the instant of closing of the transistor of the third variator towards the instant of closing of the transistor of the second variator is observed or if a divergence of the moment of opening of the transistor of the third variator towards the instant of As the transistor of the second drive is opened, it can be deduced that the third drive is not connected in parallel with the second drive to the second light source. The subject of the invention is also a set of at least two inverters, referred to as the first inverter and the second inverter, each drive comprising at least one transistor and an output, the second drive further comprising a voltmeter, the output of the first drive being connected. to a first light source, the output of the second variator being connected to the first light source, to another light source or to no light source, the set of light dimmers being suitable for implementing the method according to the invention . The invention will be better understood, thanks to the following description, which relates to a preferred embodiment, given by way of non-limiting example, and explained with reference to the appended diagrammatic drawings, in which: FIG. a diagram showing the method of operating a set of at least two dimmers according to the embodiment; Figure 2 is a schematic representation of the set of at least two dimmers.

FIG. 2 discloses an assembly 1 of at least two dimmers 10, 20, 30 of light comprising a first dimmer 10 comprising a transistor 12 and an output 14, a second dimmer 20 comprising a transistor 22 and an output 24 and a third dimmer 30 having a transistor 32 and an output 34. The output 14 of the first drive 10 is connected to a first light source 100 between a phase Ph and a neutral N.

To control the first light source 100 of high power, one or more outputs 24, 34 of the other inverters 20, 30 of the assembly 1 can also be connected to the first light source 100 between the phase Ph and the neutral N.

Each drive 10, 20, 30 may comprise a microcontroller 16, 26, 36. The second drive 20 and the third drive 30 may further comprise a voltmeter 28, 38 able to monitor the voltage at their output 24, 34 respectively. , in order to measure, when these outputs 24, 34 are also connected to the load 100, the voltage present on the light source 100.

When more than two output channels 14, 24, 34 of the light variation assembly 1 are combined, one of the inverters 10 becomes the master dimmer and the other of the dimmers 20, 30 become slave dimmers.

When the three inverters are connected in parallel to the same first light source 100, in an angle-cut operating mode, in a first time slot, each of the transistors 12, 22, 32 of the drives 10, 20, 30 is closed so as to turn on the light source 100. In a second time interval, each of the transistors 12, 22, 32 of the variators 10, 20, 30 is open so as to turn off the light source 100.

In the angle cut mode, from at least three successive cycles, namely a first cycle, a second cycle and a third cycle, in the first cycle, between the first time interval and the second time interval. time, the transistor 12 of the first variator 10 is open after the opening of the transistor 22 of the second drive 20 and after the opening of the transistor 32 of the second drive 30. In the second cycle, between the first time interval and the second interval time, the transistor 22 of the second drive 20 is open after the opening of the transistor 32 of the third drive 30 and after the opening of the transistor 12 of the first drive 10. In the third cycle, between the first time interval and the second time interval, the transistor 32 of the third drive 30 is open after the opening of the transistor 12 of the first drive 10 and after the opening of the transistor 22 of the first drive 20.

In an angle conduction mode, in the first cycle, between the second time slot and the first time slot, the transistor 12 of the first inverter 10 is closed, ie it switches, after the closing of the transistor 22 of the second drive 20 and after the closing of the transistor 32 of the third drive 30. In the second cycle, between the second time slot and the first time slot, the transistor 22 of the second drive 20 is closed, that is, it switches, after the closing of the transistor 12 of the first inverter 10 and after the closing of the transistor 32 of the third variator 30. In the third cycle, between the second time interval and the first interval of time, the transistor 32 of the third drive 30 is closed, that is to say it switches, after the closing of the transistor 12 of the first drive 10 and after the closing of the transistor 22 of the second drive 20 In the case wherein the method is applied to a set of n drives 10, 20, 30, the method comprises n successive cycles. In the angle cut mode, in the nth cycle, the switching of the transistor of the nth drive occurs after the switching of the transistors 12, 22, 32 of the remaining drives 10, 20, 30. In the angle conduction mode, in the nth cycle, the switching of the transistor of the nth drive occurs before the switching of the transistors 12, 22, 32 of the remaining drives 10, 20, 30.

In the angle cut mode, the second time interval occurs after the first time interval. The first time interval and the second time interval can occur once for each half current period of current from the voltage source.

In the angle conduction mode (not shown), the first time interval occurs after the second time interval.

In order to allow automatic wiring recognition, the set of at least two light dimmers 1 can be operated using the wiring recognition method according to the invention. This method is characterized by the following successive steps: operating the assembly of at least two inverters 10, 20, 30, either in a mode of operation of cut at the angle, or in a mode of operation of conduction to the angle, in a first step of wiring recognition and in the mode of operation of cutting at the angle, from at least two consecutive cycles, open the transistor 12 of the first converter 10 after the opening of the transistor 22 of the second drive 20 in the first cycle and open the transistor 22 of the second drive 20 after the opening of the transistor 12 of the first drive 10 in the second cycle, in the first step of wiring recognition and in the operating mode of conduction to the angle, from at least two consecutive cycles, close the transistor 12 of the first converter 10 after the closing of the transistor 22 of the second converter 20 in the first r cycle and close the transistor 22 of the second converter 20 after the closing of the transistor 12 of the first converter 10 in the second cycle, in the first step of recognizing wiring and in the mode of operation of cutting at the angle, for the second inverter 20, measuring, in the first cycle, the voltage present at its output 24 by means of voltmeter 28 in order to determine a moment of drop to zero of the voltage on the possible light source at which its output 24 is connected, in the second following cycle, the closing of its transistor 22 at the instant of fall at zero determined and observe whether the closing time of the transistor 22 of the second converter 20 converges towards the closing time of the transistor 12 of the first inverter 10, in the first step of wiring recognition and in the mode of operation of angle conduction, for the second variator 20, measure, in the first cycle, the voltage on its output 24 using the voltmeter 28 to determine a moment of voltage jump on the possible light source to which its output 24 is connected and involve, in the second following cycle, the opening of its transistor 22 at the instant of jump of voltage thus determined and observe if the instant of opening of the transistor 22 of the second converter 20 converges towards the closing time of the transistor 12 of the first variator 10.

According to one possibility, in a second wiring recognition step and in the angle-cut operation mode, from at least two consecutive cycles, open the transistor 22 of the second inverter 20 after the transistor 32 has opened. of the third drive 30 in the first cycle and open the transistor 32 of the third drive 30 after the opening of the transistor 22 of the second drive 20 in the second cycle, in the second step of wiring recognition and in the operating mode of conduction to the angle, from at least two consecutive cycles, closing the transistor 22 of the second converter 20 after the closing of the transistor 32 of the third drive 30 in the first cycle and closing the transistor 32 of the third drive 30 after the closing of the transistor 22 of the second converter 20 in the second cycle, in the second wiring recognition step and in the operating mode at the angle, for the third variator 30, to measure, in the first cycle, the voltage present at its output 34 by means of a voltmeter 38 in order to determine a moment of drop to zero of the voltage on the possible light source at which its output 34 is connected and involve, in the second following cycle, the closing of its transistor 32 at the instant of fall at zero thus determined and observe if the closing time of the transistor 32 of the third drive 30 converges to the closing instant of the transistor 22 of the second drive 20, in the second step of wiring recognition and in the operating mode of conduction at the angle, for the third drive 30, measure in the first cycle , the voltage has on its output 34 respective using the voltmeter 38 to determine a moment of voltage jump on the possible light source to which its output 34 is connected and f to intervene, in the second following cycle, the opening of its transistor 32 at the instant of jump of voltage thus determined and observe if the instant of opening of the transistor 32 of the third variator 30 converges towards the closing time of the transistor 22 of the second variator 20.

Thus, using this method, it can be detected how many outputs 14, 24, 34 are connected to the first light source 100 and if, if necessary, one or more of the outputs 24, 34 of the drives 20, 30 remaining are connected to the same second light source.

Of course, the invention is not limited to the embodiment described and shown in the accompanying drawings. Modifications are possible, particularly from the point of view of the constitution of the various elements or by substitution of technical equivalents, without departing from the scope of protection of the invention.

Claims (2)

A method of recognizing the wiring of an assembly (1) of at least two dimmers (10, 20, 30) of light, called first dimmer (10) and second dimmer (20), each dimmer (10, 20, 30) comprising at least one transistor (12, 22, 32) and an output (14, 24, 34), the second inverter (20) further comprising a voltmeter (28), the output (14) of the first inverter (10). ) being connected to a first light source (100), the output (24) of the second inverter (20) being connected to the first light source (100), to another light source or to any light source, characterized by the steps successive steps: to operate the assembly (1) of at least two inverters (10, 20, 30), either in a mode of operation of cutting at the angle, or in a mode of operation of conduction to the angle, in a first step of wiring recognition and in the mode of operation of cutting at the angle, at firing at least two consecutive cycles, open the transistor (12) of the first inverter (10) after opening of the transistor (22) of the second drive (20) in the first cycle and open the transistor (22) of the second drive (20) after opening of the transistor (12) of the first inverter (10) in the second cycle, in the first wiring recognition step and in the angle conduction operation mode, starting from at least two consecutive cycles, close the transistor (12) of the first inverter (10) after the closing of the transistor (22) of the second inverter (20) in the first cycle and closing the transistor (22) of the second inverter (20) after closing of the transistor (12) of the first inverter (10) in the second cycle, in the first wiring recognition step and in the angle-breaking operating mode, for the second inverter (20), measuring in the first cycle, the tension present on its release e (24) using the voltmeter (28) to determine a time of zero drop of the voltage on the possible light source (100) to which its output is connected, to involve, in the next second cycle, the closing of its transistor (22) at the instant of fall at zero thus determined and observe whether the closing moment of the transistor (22) of the second converter (20) converges towards the closing instant of the transistor (12) of the first inverter (10), in the first wiring recognition step and in the angle conduction operation mode, for the second inverter (20), measuring, in the first cycle, the voltage present at its output (24); ) with the aid of the voltmeter (28) to determine a moment of voltage jump on the possible light source (100) to which its output (24) is connected and to involve, in the second following cycle, the opening of his transistor (22) at the moment of jump of te nsion thus determined and observe if the instant of opening of the transistor (22) of the second drive (20) converges towards the closing time of the transistor (12) of the first drive (10). 2. Method of recognizing cabling according to the preceding claim, the assembly (1) further comprising a third drive (30), the output (24) of the second drive (20) being connected to a second light source and the output ( 34) of the third inverter (30) being connected to the second light source, to another light source or to no light source, characterized by the following successive steps, in a second wiring recognition step and in the operating mode of cut at the angle, from at least two consecutive cycles, open the transistor (22) of the second inverter (20) after opening the transistor (32) of the third drive (30) in the first cycle and open the transistor (32) of the third inverter (30) after the transistor (22) of the second drive (20) is opened in the second cycle, in the second wiring recognition step and in the operating mode conduction ionization at the angle, from at least two consecutive cycles, closing the transistor (22) of the second inverter (20) after the closing of the transistor (32) of the third drive (30) in the first cycle and close the transistor (32) of the third inverter (30) after the closing of the transistor (22) of the second drive (20) in the second cycle, in the second step of wiring recognition and in the operating mode of cut at the angle for the third inverter (30), measuring, in the first cycle, the voltage present at its output (34) with a voltmeter (38) to determine a time of zero drop of the voltage on the possible light source at which its output (34) is connected and involve, in the second following cycle, the closing of its transistor (32) at the instant of fall at zero thus determined and observe if the instant of closure of the transistor (32) of the third variate ur (30) converges to the closing instant of the transistor (22) of the second inverter (20), in the second wiring recognition step and in the angle-driving mode of operation, for the third inverter (30). ), measuring, in the first cycle, the voltage present on its output (34) using the voltmeter (38) to determine a moment of voltage jump on the possible light source at which its output (34) is connected and involve, in the second following cycle, the opening of its transistor (32) at the instant of jump of voltage thus determined and observe if the instant of opening of the transistor (32) of the third drive (30) converges towards the instant of closure of the transistor (22) of the second variator (20).