FR2550356A1 - Multiplex control circuit for lamps and motors - Google Patents

Abstract

The electric motor (9) of a roller blind system is controlled from a pair of pushbuttons (15,16) for rotation in either direction. The outputs of the push buttons are coupled over diodes (18,19) to a signal transmission line (21). The signals are transmitted as positive or negative pulse sequences to a control unit (5) that has separate detector stages to a memory module with three states. Two of the memory outputs are amplified to control triac stages controlling the direction of rotation of the motor. Both signal lines are coupled to a timer module that provides a necessary time delay in the operation of the motor to achieve a required end position.

Description

MULTIPLEXED CONTROL DEVICES FOR AC POWER SUPPLIES, SUCH AS LAMPS AND
ENGINES.

 The present invention relates to installations for the multiplexed control of members intended to be supplied with alternating electric current, such as lamps and motors, in order to control the changes of states of these members, of their environment, or of the least one other organ or mechanism that they manipulate, in one or the other of two different states.

 Installations of this type, generally comprising several control members and an electronic control module for each member or group of members intended to be supplied with electric current, have already been proposed in order to ensure, for example, multiplexed control blinds, curtains, or automatic shutters, each moved from a closed position to an open position, and vice versa, by a reversible AC motor, powered from the mains, one of the two directions of rotation of the motor corresponding for example to the rise of the blind and the other direction of rotation to the descent of the blind.

 These installations are particularly advantageous when it comes to equipping premises with a large number of openings (windows and French windows) provided with automatic blinds which it is desired to be able to control the operation individually or locally, that is to say -to say store by store, and also by group, for example by simultaneously controlling the operation of the blinds on the same floor of a building, or the operation of the blinds with which the openings that have the same facade of a building are fitted, a certain hierarchy being preferably established between different distributed commands of the same blind or group of blinds, which one wishes to be able to control from several places, and priority commands being provided for bringing all the blinds simultaneously - from one - group, for example all the blinds of a building, in closed or open position, regardless of the position in which each of the blinds is before the actuation of a corresponding priority order.

 Known installations of this type, produced by traditional cabling, have the drawback of being complex to produce and install, and of delicate maintenance, the complexity increasing moreover with the number of blinds to be controlled. Consequently; these installations are expensive and their price quickly becomes prohibitive when the number of blinds increases.

 In a second application example, installations of the aforementioned type have been proposed in order to provide multiplexed control of the lamps of building lighting installations. Such installations include electromechanical remote control switches, of a well-known embodiment, whose analysis of the operation shows that they do not offer the possibility of easily controlling the operating or stopping state of all the remote control switches of a local, of a building floor or of a whole building, whatever the state of each of these remote control switches, when such a possibility is of undeniable interest for example for a night watchman, who said to light all the parts of a building at once, or for the last person to leave the building and who wants to extinguish all the parts that have remained on at once, regardless of local or individual commands.

 By the present invention, it is proposed to remedy these drawbacks by an installation of simple and inexpensive structure, easy to install and maintain, and capable of development taking into account desired modifications in the hierarchy of orders, the installation according to the invention can be applied not only to the control of blinds or lamps, but also to the control of other organs consuming electrical energy, supplied with alternating current, and capable of changing state or causing changes in the state of their environment or the organs they manipulate.

 To this end, the installation according to the invention, of the type presented above, is characterized in that at least one of the control members is of the passive dipole type comprising at least one rectifier element and having a single terminal input connected by a single wire to neutral or to the phase of an AC power supply line connected to the members intended to be supplied, and a single output terminal connected by a single control wire to at least one module control unit to which the passive dipole type control unit delivers impulse control signals when the latter is actuated, each control module having at least two power inputs connected to the AC power line, a single input control connected to the output terminal of at least one control member of the passive dipole type by the corresponding control wire, and at least one control output connected to at least one power switch of the corresponding member or group of members intended to be supplied with electric current, said control module comprising a positive half-wave detector block and a negative half-wave detector block, each having an input connected to the control input, and an output connected to a corresponding input of an interpretation block which decodes the impulse control signals received and which is itself connected by at least one output to an input of at least one amplifier-adapter connected by the corresponding control output or to the corresponding power switches, so that the absence of at least half-wave of a given polarity, resulting from the actuation of at least one control member control of the passive dipole type, and detected by one of the two detector blocks, activates, if necessary, at least one output from the interpretation block delivering a control order which arrives amplified at or at the switches corresponding supply, in order to actuate this or these so as to supply the corresponding organ or group of organs intended to be supplied with electric current so that the latter or its environment or at least one organ that it maneuver is set or maintained in that of the two different states which corresponds to the polarity of the half-cycle (s) whose absence has been detected.

 Such an installation therefore has the very important advantage that the control orders are transmitted by a single wire, which facilitates wiring, and which also makes it possible to connect several control modules in parallel on a single control wire, in order to carry out grouped orders of members or groups of members intended to be supplied with electric current, to connect several control members in series on a single control wire, which makes it possible to carry out multiple or distributed orders of the same member or group of members intended to be supplied with electric current, and finally to connect several control members in parallel on the single control wire, which, by combination with the connection possibilities specified above, makes it possible to carry out general and hierarchical commands.

 Likewise, the installation according to the invention advantageously comprises at least one priority control member, which inhibits all the other control members downstream of the priority control member with respect to the various control modules to which this priority control member is connected, when the latter is actuated, and, for example, such a priority control member may be a rocker switch mounted on the single control wire.

 Advantageously, at least one of the passive dipole type control members comprising at least one rectifier element is a block with two pushbuttons with contacts closed at rest and connected in series, and such that no diode is mounted in parallel on each of the two pushbuttons, the two diodes being in opposition, so that when one of the two pushbuttons is pressed, there is no half-wave of a given polarity and that the other is pressed push button corresponds to the absence of half-alternations of other polarity. In this case, a priority control member can be constituted by any block with two push buttons of which the depressing of at least one push button is maintained.

 Such an embodiment has the advantage that the control members are very simple in structure since they are produced only by means of passive components of low cost.

In a first particular example of application, the installation according to the invention is intended for the multiplexed control of reversible AC motors, and it is characterized in that, when one or the other of the two detector blocks detects the absence of half-alternations of one or the other of the polarities, the interpretation block issues a command order controlling the drive respectively in one or the other of the two directions of rotation of a motor or group of motors1 while when the two detector blocks detect the absence of half-vibrations of the two polarities, the interpretation block issues a command order controlling the stopping of the motor or group of motors and when absence of any detection by the two detector blocks, the interpretation block does not issue any command
In this case, in order to facilitate the production of the control modules, it is advantageous that the control orders issued by the interpretation block and which correspond respectively to the absence of half-vibrations of one or / and of the other polarities respectively actuate a first or / and a second switch for supplying the motor or of the corresponding group of motors in order to control the driving of the latter in one direction of rotation or the other, or the stopping of the rotation.

When the motors are not intended to operate continuously after their rotation in one or the other direction has been triggered, as is the case for example with motors for driving blinds, curtains or shutters, the l the power supply must be cut off after a certain operating time, which corresponds to the total stroke at the closing or opening of the blind, curtain or shutter, the interpretation block of the control module of an installation according to the invention further comprises a timer, which interrupts the drive of the motor or group of motors corresponding to the end of a predetermined time interval
According to a simple embodiment variant of this case, the interpretation block can include a memory with three states which correspond respectively to stopping, to driving in one direction of rotation and to driving in the other direction of rotation of the corresponding motor or group of motors, the memory having two inputs each of which is connected to the output of one of the two detector blocks, and two outputs each of which is connected to an input of one of two amplifier-adapters which are each connected by its output to one of two electronic switches of the Triac type which, when one or the other is actuated, supplies the motor or group of motors so as to drive it respectively in the one or the other direction of rotation The timing device is advantageously a timer with clock having two inputs each connected to one of the two outputs of the memory and one output connected in parallel to an inhibition input of each es two amplifier-adapters, in order to interrupt the control commands communicated to the switches at the end of the predetermined time interval.

 In a second particular example of an application intended for the multiplexed control of organs with two states, such as lamps, which are supplied or not supplied, the interpretation block of a control module according to the invention comprises a logic gate OR to inputs of which the outputs of the two detector blocks are connected, and at least one flip-flop controlled by the OR gate and commanding, by a first output corresponding to one of the two states of an organ or group of organs with two states1 and by means of a single amplifier-adapter, the actuation of a single switch for supplying the organ or group of organs with two states, one or the other of the detector blocks being inhibited from a flip-flop when the half-waves whose absence is detected correspond to an order for controlling a state which is that in which the organ or group of organs with two states is already found. Such an embodiment therefore makes it possible to detect the state in which an organ to be controlled is located so that an order for change of state will only be transmitted if the commanded state is different from the state in which this organ is located .

 According to a first alternative embodiment of this second application example, the interpretation block comprises a single flip-flop, the first output of which is connected in parallel to the input of the amplifier-adapter and to an inhibition input of a detector block 0 while the second output of the flip-flop is connected only to a muting input of the other detector block. Such an embodiment makes it possible not only to control the switching on or off of a lamp, but also to obtain that the latter flashes when the two push-buttons of a corresponding control member are held down.

 According to a second alternative embodiment of this second application example, the interpretation block comprises two flip-flops connected in parallel to the output of the OR gate, and by means of an inverter for one of the two flip-flops; the first output of the flip-flop directly connected to the OR gate being connected to the amplifier-adapter, while the first output and a second output of the flip-flop connected to the OR gate via the inverter are connected to an input inhibition of one and the other of the two detector blocks respectively. This latter embodiment makes it possible to avoid the operation as an oscillator which the first variant can fulfill when the two detector blocks detect the absence of half-vibrations of the two polarities.

 In an installation of the type of the second application example, some of the control members can be simple push-button switches.

To better understand the object of the invention, we will now describe, by way of illustrative example, two embodiments shown in the accompanying drawing
On this drawing
FIG. 1 is a diagram of a basic blind control installation comprising a control member, a control module and a motor for operating a blind,
FIGS. 2A to 2D are representations of the signals received by the control module of the installation of FIG. 1 as a function of the positions of the control member of this installation,
FIG. 3 is a block diagram of the control module of the installation of FIG. 1,
FIG. 4 is a diagram of a complete installation with a priority command,
FIG. 5 is a diagram of a lamp control installation, and
FIGS. 6 and 7 are block diagrams of two examples of control modules which can be fitted to the installation of FIG. 5.

 In Figure 1, there is shown in 1 a three-wire AC power supply line, one of which 2 is the ground wire, a second 3 is the neutral wire and the third 4 is the wire of the phase.

 A control module, generally designated by the reference 5, has three supply terminals, one of which 6 is connected to the ground wire 2, another of which 7 is connected to the neutral wire 3 and the third of which 8 is connected to the phase wire 4. The terminals 6 and 7 of the control module 5 are also connected to the two corresponding terminals of a reversible AC motor 9 which turns in one direction or the other depending on whether one or the other. terminals 10 and 11 of module 5 is connected to the phase. Terminal 7 of module 5 is finally connected by a single wire 12 to a single input terminal 14 of a control member 13 which is a block with two pushbuttons 15 and 16, with closed contacts instead, and mounted in series between the input terminal 14 and the single output terminal 17. A diode 18,19 is mounted in parallel on each push button 15,16 so that the diodes are in opposition to the opening of the buttons - pushers. The output terminal 17 is connected to a control input 20 of the module 5 by a single control wire 21, which extends the wire 12 connected to the neutral.

 The block 13 thus constitutes a double push-button control member delivering to the module 5, by a single control wire 21, control signals in the form of short pulses produced by the introduction of the rectifying elements that are the diodes 18 and 19 on the single wire connects to the sector neutral, by pressing push-buttons 15 and 16.

 In FIGS. 2A to 2D, - the different signals received on the control input 20 of the module 5 are shown. If none of the two push-buttons 15 and 16 is pressed, which corresponds to an absence of control, the signal at 20 is a complete periodic signal as shown in FIG. 2A. If 1 one of the push buttons is pressed for example 16, which corresponds to the control of the drive of the motor 9 in the direction of the awning rise that this engine maneuvers; the diode 19 is inserted between the two terminals 4 and 17 and control iqen-.ree 20 of the module 5 receives only positive half-cycles, like -} - ep, ~ flsenté in FIG. 2B, while conversely, if the push button 15 is pressed which corresponds to the command to lower the blind by the motor q 12 diode 18 is switched on 0 and the control input 20 of the nodule 5 receives only negative half-cycles, as shown in Figure 2C.

On the other hand, if the two push buttons 15 and 16 are simultaneously pressed, the two diodes 18 and 19 are switched on and the input 20 receives a zero signal, as shown in FIG. 2D which corresponds to the command of the engine shutdown 9.

 In summary, the complete alternating signal corresponds to the absence of control, the absence of the negative half-resistances corresponds to the command to raise the blind the absence of the positive half-vibrations corresponds to the command to lower the blind, and the absence of signal corresponds to the command to stop the motor 9 and therefore the blind in the position it occupies at this moment.

 As shown in FIG. 3, the control module 5, produced in the form of a printed circuit comprises a regulated power supply 22, connected to the phase 4 and neutral 3 wires of the supply line 1, by example at 220 V, and delivering to the printed circuit a direct voltage of 6.8 V, with the least grounded of the printed circuit The latter includes two half-wave detector blocks, one of which detects the absence of the half -negative alternations and the other 24 of which detects the absence of positive half-alternations. The two blocks 23 and 24 are connected in parallel by their input to the control input 20 of the module 5, and their single output is connected to a corresponding input of a memory 25 with three states1 which correspond to the stop, at raising and lowering the blind. The memory 25 has two outputs which are each connected in parallel to an input of one of two amplifier-adapters 26 and 27 and to one of the two inputs of a timer 28 with clock, the single output of which is connected in parallel to the muting input of the two amplifiers 26 and 27. The output of each of the latter is connected to the switching input of one. electronic switch type Triac 29 or 30 both connected to phase wire 4 of the power line 1 and one 29 to terminal 10 and the other 30 to terminal 11 of module 5.

The operation of this module is as follows following the pressing of the push button 16, the detection by the block 23 of the absence of negative half-cycles is transmitted by the corresponding input to the memory 25 whose corresponding output is activated and starts the timer 28 as well as the switching of the Triac 29, after amplification in 26 of the command to raise the blind. The Triac 29 supplies the motor 9
by terminal 10 in the direction of rotation which corresponds to the rise of the blind. Conversely, if block 24 detects the absence of positive half-waves, the output of memory 25 which is connected to timer 28 and amplifier 27 is activated and the Triac30 switches and allows the supply of terminal 11 to drive the motor in the direction of the awning lowering.

 Following the activation of an output of memory 25, and after the predetermined time interval, of the order of 3 minutes for example, which corresponds to the time necessary for the blind to be operated from one position extreme at the other, the timer 28 inhibits that of the two amplifiers 26 and 27 which is working, which cuts the power supply to the corresponding Triac 29 or 30, and the motor 9 is stopped.

 On the other hand, if the two blocks 23 and 24 detect a total absence of signal at the input 20, the two outputs of the memory 25 are deactivated, which immediately interrupts the supply of the motor 9 by one or the other. Triac 29 and 30.

 FIG. 4 shows the complete installation for multiplexed control of blinds operated by motors 31, 32 and 33 which are identical to motor 9 in FIG. 1, and which are controlled by control modules 34, 35 and 36 identical to the control module 5 of FIGS. 1 and 3. These motors and modules are supplied from the supply line 1, as explained above for the motor 9 and the module 5.

The installation also comprises control members 37 to 42, which are each identical to the block 13 with two pushbuttons of FIG. 1, as well as a control member 43, which is a rocker switch, appearing as a block such as 13 in which each of the two push-buttons has been replaced by a rocking contact.

 The input of block 37 is directly connected to neutral 3 of the supply line 1, and the output of block 37 is connected to the input of block 43, the output of which is connected in parallel to the input of blocks 38 and 39.

The output of block 38 is connected to the control input of module 34 while the output of block 39 is connected in parallel to the inputs of blocks 40 and 41. The output of block 40 is connected to the control input of module 35, while the output of block 41 is connected to the input of block 42, the output of which is connected to the control input of module 36.

 This gives a multiple and hierarchical control installation. Indeed, the control module 34, and therefore the motor 31, are under the effect of the control members 37, 43 and 38 mounted in series on the same control wire, the control module 35, and therefore the corresponding motor. 32, are under the effect of the control members 37, 43, 39 and 40, also mounted in series on the same control wire, and finally the module 36, associated with the corresponding motor 33, are under the effect of the control members. control 37,43,39,41 and 42 mounted in series on the same control wire. The control member 38 provides individual control on the module 34 and the motor 31, the control member 40 allows 'also provide individual control of the module 35 and the motor 32, while the control members 41 and 42 each provide individual control of the module 36 and the associated motor 33. On the other hand, the control member 39 allows to ensure a grouped command on the modules 35 and 36, while the control members 37 and 43 allow assu rer of general orders. The multiple combinations allowed in the assembly of the various control members make it possible to prioritize the latter. As the control member 43 is produced by means of a rocker switch, it constitutes a priority control member which prohibits all other controls when this member 43 is tilted. Indeed, the tilting of one of its contacts ensures the maintenance of the corresponding order. This type of priority control member is interesting because it makes it possible to simultaneously bring all the blinds to a particular position, for example in the raised position, in order to allow the windows to be washed.

 In such an installation, it should also be noted that it is possible to decode the impulse orders transmitted by a single control wire by connecting to the latter several control modules mounted in parallel, which makes it possible to carry out grouped controls of these modules. control. Multiple or distributed control of a module or a group of control modules can be achieved by placing several control members in series on a single control wire. It should also be noted that, when operating a push button block, holding in the depressed position of at least one of the push buttons makes it possible to carry out priority control. In an installation comprising control members mounted in series and in parallel to each other, the hierarchy of commands results from the fact that all the modules located downstream of an actuated control member undergo the command thus produced.

 The multiplexed lamp control installation, shown in FIG. 5, comprises lamps 50, 51, 52, controlled respectively by electronic control modules or remote switches 53, 54 and 55. Each of the lamps is connected on the one hand to the neutral 3 of the AC power supply line from the sector and on the other hand to the corresponding remote control switch, while the remote control switches are each connected on the one hand to neutral 3 and on the other hand to phase 4 of the line power supply.

The installation also includes four control members 56 to 59, which are simple push-button switches, --------- and which in this case constitute control devices for reversing the state of the lamps. , as well as a state control member 60, which has priority and whose operation makes it possible to switch all the lamps on or off simultaneously. The member 60 is analogous to the control member 13. Thus, the remote control switch 53 is normally controlled by the switch 56, the remote control switch 54 is controlled by one of the two switches 57 and 59 mounted in series on the single control wire leading to the remote control switch 54, and the remote control switch 55 is controlled by the switch 58, all the remote control switches 53 to 55 being however dependent on the priority control 60, by the operation of which the extinction can be controlled or the lighting of all the lamps 50 to 52, regardless of their initial state.

 As in the previous example, each of the remote control switches or control modules 53 to 55 is an electronic box connected to the mains and able to supply one or more lamps, so that grouped commands can be provided. In addition, each of these remote control switches has a single input terminal receiving the various impulse orders from either the switches --- ------------------------ --------------- 56 to 59 either from the state control unit 60. For each of the remote control switches 53 & 55, the control orders are transmitted by a single control wire , which offers the possibility of placing remote control switches under the effect of distributed or multiple and hierarchical commands.

 The electronic remote switches 53 to 55 are each controlled by the operation of at least one of the bsubons-pouynirs of the switches 56 to 59 montEs, as in the previous example, on a wire connected to the neutral of the supply line, and each of these remote switches 53 to 55 has the property of going into a well-defined state when lton suppresses a single half-wave by the operation of one of the switches.

 In Figures 6 and 7, two variants are shown. of making a remote control switch usable within the framework of the installation shown in FIG. 5.

In FIG. 6, the remote control switch includes, like the control module in FIG. 3, a regulated power supply 22 and two detector blocks 23 and 24 detecting respectively the absence of negative and positive half-waves in the signals received on the control input 20 to which the two detector blocks are connected by their input. By their output, the two blocks 23 and 24 are connected to the two inputs of a logic gate
OR 61 whose single output attacks a flip-flop 62 with two outputs. One of the outputs is connected on the one hand, via an amplifier-adapter 63, to an electronic switch of the Triac 64 type and, on the other hand, to an inhibit input of the detector unit 23.

When switching, the Triac 64 controls the supply or interruption of supply to an associated lamp.

The other output of flip-flop 62 is connected only to a muting input of the detector block 24.

 Assuming that the associated lamp is off, and therefore that the Triac 64 is not driving and that the rocker 62 is in the inhibit position of block 24, if the extinction order is issued by pressing the push button which removes the half-cycles positive, the absence of these half-cycles is detected by the block 24, but this is inhibited and cannot switch the flip-flop 62 via the OR gate 61. The remote control switch therefore does not change configuration, because the commanded state corresponds to the existing state. On the other hand, if the ignition order is issued by pressing the push button which removes the negative half-waves, the absence of these half-half-waves is detected by the uninhibited block 23. The OR gate 61 therefore transmits a signal to flip-flop 622, the activated output of which becomes that connected to the Triac 64 and to the inhibit input of block 23. so that the Triac 64 drives and lights the lamp, and that block 23 is inhibited, so that any subsequent order ignition is of no consequence on the configuration of the remote control switch, since it now corresponds to the existing state.

 Therefore, the flip-flop 62 switches to the reception of a positive edge at its input, and without the inhibition return on the two detectors 23 and 24, the suppression of a positive, negative half-wave or of the total signal controls l 'sending by one of the two detectors 23 and 24 or by both of a pulse to the OR gate 61, which transmits this pulse to the flip-flop 62 and therefore causes the device to switch. The role of the two inhibition returns is to prevent the arrival of the inverting pulse on the flip-flop 62 when the state of the latter corresponds to the commanded state, by blocking the corresponding detector 23 or 24. the suppression of the total signal, for example by simultaneous pressing of the two pushbuttons of a control unit or by pressing on a simple pushbutton, has the effect of Z activating the two detectors 23 and 24, which causes the arrival of an inverting pulse on the flip-flop 62 since only one of the two detectors 23 and 24 is blocked at a time. As the flip-flop 62 switches, it is therefore the other detector which is activated, if the suppression of the total signal continues, from where the sending of a new inverting pulse on the flip-flop 62, which switches again, so that the circuit behaves like an oscillator maintaining the inversion command as long as the suppression of the total signal continues. During this phase, the associated lamp therefore tends to flash. For this reason, a remote control switch such as the one whose block diagram is shown in FIG. 7 is preferably used, on which the output of the OR gate 61 is connected in parallel on the input of two flip-flops 65 and 66, the door 61 being connected to flip-flop 66 by means of an inverter 67. As before, one of the outputs of flip-flop 65 is connected to Triac 64, which controls the supply of the associated lamp 68, via an amplifier-adapter 63, while the corresponding output of the other flip-flop 66 is connected to the inhibition input of the detector block 23, and the second output of flip-flop 66 is connected to the inhibit input of detector block 24.

 In this example, a positive edge emitted by one and / or the other of the two blocks 23 and 24 having detected the absence of half-alternations of one and / or the other of the polarities, is transmitted by the OR gate 61 only at the flip-flop 65 which switches by causing the switching of the Triac 64 and therefore the change of state of the lamp 68, because the inverter 67 prevents the switching of the flip-flop 66, so that it does not dlmuennn of inhibition does not occur. On the other hand, on passing the following negative edge, the inverter 67 commands the switching of the flip-flop 66, and therefore the inversion of the inhibition of one of the two blocks 23 and 24 to the other, without switching the flip-flop 65, and therefore without changing the state of the lamp 68, and the oscillating effect present by carrying out the previous example is eliminated.

 It is further noted that, in this example also, a command maintained is a priority command.

 It is understood that the installations described above may give rise to any desirable modifications without departing from the scope of the invention.

Claims (19)

 1. Installation for the multiplexed control of organs (9,31,32,33,50,51,52) intended to be supplied with alternating electric current, such as lamps or motors, in order to control the changes of states of these organs, their environment or at least one organ which they operate, in one or the other of two different states, said installation comprising at least one control member (13, 37 to 43, 5 & 60 ), and an electronic control module (5,34,35,36,53,54,55) for each member or group of members intended to be supplied with electric current, characterized in that at least one of the control members (13) is of the passive dipole type comprising at least one rectifier element (lu, 193 and having a single input terminal tel4) connected by a single wire (12) to neutral (3) or to phase t4 ) an AC power supply line (1) connected to the members intended to be supplied, and a single output terminal (17) connected by a single control wire e (21) to at least one control module (53, to which the control member (13) of the passive dipole type delivers impulse control signals when the latter is actuated, each control module (5) having at least two power inputs (7,8) connected to the AC power line, a single control input (20) connected to the output terminal 117) of at least one passive dipole type control member (13 ) by the corresponding control wire (21), and at least one control output (10,11) connected to at least one power switch (29,30) of the corresponding organ or group of organs intended for be supplied with electric current, said control module (5) comprising a positive half-wave detector block (23), and a negative half-wave detector block (24), each having an input connected to the control input (20) and an output connected to a corresponding input of an interpretation block (25) that i decodes the impulse control signals received and which is itself connected by at least one output to an input of at least one amplifier-adapter (26,27) connects to the corresponding control output (s) (10,11) by l 'Intermediate supply switch (s) (29,30) corresponding, so that the absence of at least half-wave of a given polarity, resulting from the actuation of at least one control member of the passive dipole type (13), and detected by one of the two detector blocks (23,24), activates, if necessary, at least one output of the interpretation block (25) delivering a control order which arrives amplified or to the corresponding supply switches (29, 30), in order to activate this or these so as to supply the corresponding member or group of members (9) intended to be supplied with electric current so that the latter, or its environment, or or at least one organ which it operates, is put or maintained in that of es two different states which corresponds to the polarity of the half-wave (s) whose absence has been detected.  2. Installation according to claim 1, characterized in that at least one of the passive dipole type control members (13) comprising at least one rectifier element is a block with two push-buttons (15,16) with contacts closed at rest and connected in series, and such that a diode (18,19) is mounted in parallel on each of the two push buttons (15,16), the two diodes (18,19) being in opposition, so that when one of the two push-buttons (15,16) is pressed, the absence of half-cycles of a given polarity corresponds and that when the other push-button is pressed corresponds to absence of half-waves of the other polarity.  3. Installation according to one of claims l and 2, characterized in that several control modules are connected in parallel on a single control wire.  4. Installation according to one of claims 1 to 3, characterized in that it comprises several control members (37,43,39,41,42) connected in series on a single control wire.  5. Installation according to one of claims 1 to 4, characterized in that it comprises several control members (38,39) connected in parallel on a single control wire.  6. Installation according to one of claims 1 to 5, characterized in that it comprises at least one priority control member (43.60), which inhibits all other control members when actuated.  7. Installation according to claim 6, characterized in that the priority control member is a rocker switch (43).  8. Installation according to one of claims 3 to 7, as attached to claim 2, characterized in that the priority control member is constituted by any block (13) with two push buttons (15,16 ) of which at least one push-button is depressed.  9. Installation according to one of claims 1 to 8, for the multiplexed control of reversible AC motors (9,31,32,33), characterized in that when one or the other of the two blocks detectors (23,24) detects the absence of half-cycles of one or the other of the polarities, the interpretation block (25) delivers a command order controlling the drive respectively in one or in the other of the two directions of rotation of a motor (9,31,32,33) or group of motors, while when the two detector blocks (23,24) detect the absence of half-vibrations of the two polarites, the block of interpretation (25) delivers a command order controlling the stopping of the engine (9,31,32, 33) or group this engines, and that in the absence of any detection by the two detector blocks (23,24 ), the interpretation block 125) does not issue any command order.  10. Installation according to claim 9, characterized in that the control orders issue = s by the interpretation block (25), and which correspond respectively to 11 absence of half-vibrations of one or / and of the other of the polarities, respectfully actuate a first or / and a second power switch (29,30) of the motor (9,31,32,33) or of the group of motors in order to control the drive of this last in one direction of rotation or in another 11, or stopping the rotation.  11. Installation according to one of claims 9 and 10, characterized in that the interpretation block (25) comprises timing member (28) which interrupts the drive of the motor (9,31,32,33) or group of motors corresponding to the end of a predetermined time interval.  12. Installation according to one of claims 9 to 11, characterized in that the interpretation block comprises a memory 125) with three states which correspond respectively to the stop, to the drive in a direction of rotation. and to drive in the other direction of rotation of the motor (9,31,32,33) or of the corresponding group of motors, the memory (25) having two inputs each of which is connected to the output of one of the two detector blocks (23,24), and two outputs each of which is connected to an input of one of two amplifier amplifiers (26,27) which are each connected by its output to one of two electronic switches of the type Triac (29,30) which, when one or the other is actuated, supply the motor or group of corresponding motors so as to drive it respectively in one or the other direction of rotation.  13. Installation according to claim 12, as attached to claim 11, characterized in that the timer member (28) is a clock timer having two inputs each connected to one of the two outputs of the memory ( 25) and an output connected in parallel to an inhibit input of each of the two amplifier-adapters (26,27) in order to interrupt the control orders communicated to the switches (29,30) at the end of the interval of predetermined time.  14. Installation according to one of claims 9 to 13, characterized in that the motors (9,31,32, 33) or group of motors operate blinds, curtains, shutters or other similar mechanical components.  15. Installation according to one of claims 1 to 8, intended for the multiplexed control of two-state organs (50,51,52), characterized in that the interpretation block (61,62,65,66 , 67) comprises an OR logic gate (61) to the inputs of which the outputs of the two detector blocks (23,24) are connected, and at least one flip-flop (62,65,66) controlled by the OR gate (61) and controlling, by a first output corresponding to one of the two states of an organ (50,51,52) or group of organs with two states, and by means of a single amplifier-adapter (63), Actuation of a single power switch (64) of the organ or group of organs with two states, one or the other of the detector blocks (23, 24) being inhibited from a flip-flop (62,66) when the half-waves whose absence is detected, correspond to an order for controlling a state which is that in which the organ or group of organs with two states is already found.  16. Installation according to claim 15, characterized in that the interpretation block comprises a single rocker (62), the first output of which is connected in parallel to the input of the amplifier (63) and to an input of inhibition of a detector block (23) and a second output of which is connected only to an inhibition input of the other detector block (24).  17. Installation according to claim 15, characterized in that the interpretation block comprises two flip-flops (65,66) connected in parallel to the output of the OR gate (61), and by means of an inverter ( 67) for one of the two flip-flops (65,66), the first output of the flip-flop (65) directly connected to the OR gate (61) being connected to the amplifier-adapter (63) while the first output and a second output of the flip-flop (66), connected to the OR gate (61) via the inverter (67), are connected to the inhibition input of one and of the other of the two detector blocks (23,24).  18. Installation according to one of claims 15 to 17, characterized in that the bodies in two states are lamps (50,51,52,62).  19 - Installation according to one of claims 1 to 8 and 15 to 18, characterized in that certain control members (56 to 59) are simple push button switches.