FR2734118A1 - DEVICE FOR REMOTE CONTROL AND MONITORING OF A DISCHARGE LAMP - Google Patents

Abstract

A remote controlling and monitoring device (10) for a discharge lamp powered by an electricity distribution line is installed adjacent a lamp (11) and comprises means for transmitting and receiving messages carried by the electric line (15, 16) supplying power to the lamp (11) by a modulated bi-directional carrier current so as to communicate with a central station (3), means for controlling the switching on and switching off as well as the lighting intensity of the lamp according to instructions from the central station (3) and means for detecting a failure in the lamp (11) and for informing the central station (3) accordingly.

Description

DEVICE FOR REMOTE CONTROL AND MONITORING
OF A DISCHARGE LAMP.

The present invention relates to a device for the remote control and monitoring of a discharge lamp.

It applies in particular, but not exclusively, to public lighting, which consists of a large number of candelabras each equipped with a discharge lamp. Such candelabras are generally supplied via electrical distribution cabinets located at relatively short distances.

However, discharge lamps have a certain lifespan. They must therefore be replaced regularly, which poses some problems in the case of public lighting. Indeed, when it comes to monitoring the operation of a large number of candelabras distributed for example, in a city, it is necessary to have a lighting maintenance team which regularly carries out a test campaign consisting of to light the candelabras during the day in order to be able to visually check that the lamps are working properly, and possibly replace the faulty lamps. To ensure good lighting quality with a low rate of faulty lamps, these campaigns must be carried out frequently. In practice, the maintenance team moves to change a reduced number of lamps, resulting in a high maintenance cost.

In addition, it was found that the lighting requirements according to the seasons and the time of the night were not constant. Thus, for example, during certain hours of the night, it is not necessary to have a light intensity as high as at other times. Substantial savings could therefore be made if the intensity of public lighting could be controlled. It goes without saying that such an operation can only be envisaged if it can be carried out remotely.

To overcome these drawbacks, apparatuses equipped with a telephone transmitter were used which were placed in the electrical distribution cabinets. These devices are designed to detect variations in consumption at the level of the power supply lines of the candelabra, such a variation revealing a lighting fault, and to automatically transmit a fault signal on a telephone line.

 I1 turns out that this device has many drawbacks. First of all, it requires a telephone link with a monitoring station, which presents a significant installation, subscription and telecommunications cost. In addition, it does not make it possible to precisely determine the defective candelabrum, given that an electric line supplies several candelabras at the same time.

In addition, to achieve energy savings, dimmers were placed in the electrical cabinets on each line to simultaneously vary the intensity of the lighting of all the candelabra connected to the line.

However, this solution does not allow the light intensity of each lamp to be adjusted separately.

Furthermore, in an attempt to eliminate the installation and use of specific communication channels, we thought of using carrier currents as a means of transmission. However, it turns out that the range of this means of transmission is limited to a few hundred meters. It is therefore not applicable to the remote control and remote monitoring of candelabras which may be located several kilometers from a central station.

The present invention aims to eliminate these drawbacks. To this end, it offers a device for the remote control and monitoring of a discharge lamp supplied by an electrical distribution network.

This device is characterized in that it is installed near the lamp, and that it comprises means for transmitting and receiving messages conveyed via the electric power supply line of the lamp, by bidirectional carrier current modulated, allowing it to communicate with a central station, said device comprising means for controlling the switching on and off of the lamp, according to instructions issued by the central station, and means for detecting lamp failures and notify the central station.

Thanks to these provisions, each candelabrum is controlled and monitored independently of the others, and it is not necessary to provide a telephone link between each electrical distribution cabinet and the central station.

Advantageously, the control and monitoring device comprises means for controlling the light intensity of the lamp as a function of instructions issued by the central station.

According to a feature of the invention, the control and monitoring device comprises means for detecting the degradation of the operating state of the lamp.

According to another feature of the invention, the device comprises means for counting the operating time of the lamp.

Thanks to these features, it is possible to determine precisely when the lamp should be replaced before it actually breaks down.

According to another feature of the invention, the device receives all the messages conveyed by the power line and retransmits messages which are not intended for it. The device can therefore play the role of repeater. As each candelabrum is generally close (a few tens of meters) to another candelabrum, this ensures the transmission of messages from their sender to their recipient regardless of the distance between them, and despite the short range of transmission by carrier current.

An embodiment of the device according to the invention will be described below, by way of nonlimiting example, with reference to the accompanying drawings in which
Figure 1 shows schematically the architecture
tecture of an electricity distribution network
using the control and
surveillance according to the invention
Figure 2 shows the connection diagram of the
control and monitoring device with
a discharge lamp
Figure 3 shows in detail the electrical diagram
control and monitoring device;
Figure 4 shows a set of timing diagrams
illustrating the operation of the
control and monitoring
Figure 5 shows a transmission and
reception of digital messages on the
electrical distribution.

Figure 1 shows an electrical substation 1 for transforming the electricity into high voltage it receives, into low voltage (220 V) three-phase, to supply a set of 2.6 electrical distribution cabinets, including the cabinets distribution 6 allocated to public lighting.

Each distribution cabinet 6 for lighting receives as input the three-phase low-voltage electric current, and supplies a set of electric lines 7 with single-phase low voltage. Each of these lines 7 comprises two wires 15, 16 making it possible to supply a plurality of discharge lamps 11 each associated with a control and monitoring device 10 according to the invention.

The device 10 is designed to transmit and receive information by carrier current, in phase modulation, for example at a frequency of 132 kHz, via the electrical distribution network, to communicate with a central station 3 connected to another distribution cabinet electrical 2. For this purpose, the central station is equipped with a computer 5, connected to the electrical network via an interface module 4 which ensures the exchange of information between the computer 5 and the electrical network .

In FIG. 2, the control and monitoring device 10 is connected to the two wires, phase 15 and neutral 16 of an electric line, the neutral being also connected to one of the terminals of the discharge lamp 11.

To operate such a lamp, use is made in a known manner of a priming circuit 13 connected in parallel with the lamp 11, and a ballast 14 with high self-impedance ticks applying a supply voltage supplied by the device 10 to the lamp 11 and to the ignition circuit 13, the ballast 14 having the purpose of limiting the current passing through the lamp 11 when the latter is on.

When the lamp 11 is off, no current flows through it. The voltage applied to the input of the ballast 14 is then transferred to the ignition circuit 13 which makes it possible to apply to the terminals of the lamp 11 a voltage pulse (of the order of 2000 V) greater than the ignition threshold of the lamp, causing the lamp 11 to ignite, and therefore the passage of current therein. Once the lamp 11 is on, the lamp then being supplied only by means of the ballast 14.

As the impedance of the ballast 14 is strongly self ic, it is imperative to have in parallel a capacitor 12 for correcting the cosine phi.

In practice, a starting pulse generator is associated with the lamp 11 and ballast 14 assembly.

In FIG. 3, the control and monitoring device 10 comprises three stages, namely - a first stage ensuring the supply of the device,
its coupling to the electricity distribution network, and
generation of a synchronization signal from
the voltage Us supplied by the electrical network, - a second stage providing control and monitoring
of the discharge lamp 11, and - a third stage organized around a microprocessor
23 ensuring the control of the entire device.

The first stage comprises - a supply circuit 21 which, from the voltage
Us between phase 15 and neutral 16, provides the
supply voltages required for different
organs of the device 10, - a coupling circuit 22 connected between phase 15 and
neutral 16, designed to exchange information
between the microprocessor 23 and the electrical network, and - a synchronization circuit 22 also connected between
phase 15 and not neutral 16, designed to generate a
SS synchronous logic signal of the electrical voltage Us
supplied by the electrical network, this logical signal SS
being applied to an input of the microprocessor 23.

The coupling circuit 22 can be produced using a transformer or a resonant circuit of the LC type calibrated on the frequency of the carrier for transmission of messages by carrier current.

The second stage, or output stage comprises, in series between phase 15 and ballast 14, an inductor Z1, followed by two switches K1, K2 in series.

The first switch K1, of the relay or triac type, is controlled by the microprocessor 23, from the synchronization signal SS supplied by the synchronization circuit 27, and is intended to apply the voltage Us supplied by the network to the discharge lamp 11, and in particular to the correction capacitor 12 connected to the junction point between the two switches K1, K2. The load then being capacitive, the command of K1 is applied to the zero crossing of the network voltage Us.

The second switch K2, of the thyristor or triac type, is intended to supply the lamp 11 via the ballast 14. It is controlled by a logic signal CK2 from a comparator 30. It is also connected to neutral 16 by via a capacitive impedance Z3 intended to establish a current Iz when the lamp 11 is absent or has failed.

In parallel with the second switch K2, there is a second synchronization circuit Z2, called the lamp synchronization circuit, which delivers a logic lamp synchronization signal SL at 0 when the switch K2 is open, and at 1 when the latter is closed.

The mains synchronization circuits 27 and lamp Z2 can be produced on the basis of photo-couplers so as to ensure good electrical insulation between the second and third stages.

The third stage, or control stage, comprises, around the microprocessor 23 - an EEPROM memory 24 making it possible to save
information, including information related to the
configuration of the device 10, - a transmission / reception circuit 25 designed to modulate
the information to be sent, provided by the microproces
sor 23, and send the signal thus obtained to the
coupling 22, and for demodulating and amplifying the signals
information transmitted by the coupling circuit 22, and
deliver the information thus obtained to the microproces
sor 23, - a digital / analog converter 29 making it possible to
convert an angle setpoint into an analog signal
opening provided by the microprocessor 23, - the comparator 30 with two states which compares the setpoint
supplied by converter 29 to the sawtooth signal
IF generated by an integrator 28 controlled by the signal
SL synchronization from circuit Z2.

Furthermore, the microprocessor 23 is connected to two indicators, a red indicator 31 for signaling faults, and a green indicator 32 for signaling the operating states. It is also connected to an on / off button 33, and a button 34 which, when the lamp 11 is changed, triggers the transmission of an initialization signal to the central station 3, indicating the effective replacement of the lamp 11, and allowing the reset of a lamp usage time counter 11.

As previously mentioned, the microprocessor 23 communicates with the central station 3 by messages transmitted by carrier current, in phase modulation, for example at a frequency of 132 kHz, via the electrical distribution network. To this end, each lamp 11 controlled by the central station 3 is identified by an identification code which is inserted in each message exchanged with the central station.

The operation of the control and monitoring device is illustrated by the timing diagrams in FIG. 4.

Curve C1 shows that the voltage Us between phase 15 and neutral 16, or else the voltage Uc at the junction point between the two switches K1, K2, has a sinusoidal shape. Curve C2 shows the form of the logic sector synchronization signal SS from circuit 27, which changes logic state each time the mains voltage
They cancel each other out.

On a run command from the central station 3, the microprocessor 23 controls the switch K1 at the zero crossing of the mains voltage Us, thanks to the mains synchronization signal SS shown by the curve C2. The detection of a voltage UK2 at the terminals of the switch K2 by the lamp synchronization circuit Z2 leads to the release of the integrator 28. When the output of the integrator 28 reaches a set value 46, the comparator 30 delivers a voltage of command CK2 which allows the ignition of switch K2. The switch K2 is controlled in turn with a zero setpoint, implying a zero opening angle 41. As the load of K2 is self ic, the current
IB passing through it is therefore delayed by a certain phase shift 42 with respect to the voltage Uc (curve C4).

Before the triggering of K2, the voltage UK2 at its terminals is very much higher than its triggering threshold 45, and K2 becomes conducting for the alternation in progress (curve C5).

In fact, the current IB which flows through the switch K2 determines the alternation. K2 therefore remains on as long as the current IB has not reached a value close to zero. The voltage UB (curve C3) at the terminals of the ballast 14 is then practically identical to the mains voltage Us.

The lamp synchronization circuit Z2 delivers a logic signal SL at 1 each time that the absolute value of the voltage UK2 at the terminals of the switch K2 exceeds the threshold 45, that is to say, during the periods when the switch K2 is located blocked (curve C6). This logic signal SL is sent to the microprocessor 23, and is applied at the input of the integrator 28 which delivers a sawtooth signal which remains zero when the lamp synchronization signal SL is at logic level 0 (curve C7).

The circuit described above makes it possible to reduce the voltage applied to the lamp 11, in order to reduce the intensity of the lighting. In fact, the microprocessor 23 can impose a setpoint in the form of binary data applied to the input of the analog / digital converter 29. If this setpoint data is not zero, a logic signal is obtained at the output of the comparator 30 at 1 when the signal at the integrator's output exceeds the threshold 46 defined by this setpoint, and at zero otherwise, the signal
CK2 from comparator 30 used to control switch K2 (curve C8).

It can be noted on the curve C8 that, thanks to the sawtooth shape of the signal SI, the switch K2 receives control pulses CK2 late with respect to the voltage pulses UK2 at its terminals, which delays the tripping of the switch K2. The periods during which the current IB (curve C4) and the voltage UB (curve C3) remain zero, corresponding to the opening angle 41, are thus lengthened, which causes a reduction in the effective intensity of the current
IB and of the effective voltage applied to the terminals of the lamp 11, and therefore a reduction in the intensity of the lighting produced by the lamp 11. We can thus vary the opening angle from 0 to a value close to 450, which makes it possible to reduce the effective supply voltage of the lamp 11 from 0 to around 20% of the voltage Us, corresponding to a reduction in energy consumption from 0 to 60%.

Furthermore, it is necessary to gradually reduce the supply voltage of the discharge lamp 11 in order to avoid untimely stalls, and therefore the extinction of the latter. This is why this reduction is controlled by the microprocessor 23 in small successive stages, by gradually increasing the value of the setpoint applied at the input of the digital / analog converter 29. In practice, to improve this progressiveness, a time constant can be added at the output of converter 29.

Curves C9 to C13 illustrate the detection of lamp stalls.

The stall or a breakdown of the lamp results in the absence of current IB at the input of the ballast 14. The load is then solely determined by the impedance Z3 placed between the switch K2 and the neutral 16, this load being insufficient to maintain switch K2 in the on state. The capacitive impedance Z3 is then crossed by a current Iz in phase advance 43, and practically in phase quadrature with the voltage Uc at the input of the switch K2 (curve C9). The resistive impedance of Z2 and the capacitive impedance of Z3 then form a voltage divider bridge so that the resulting voltage UK2 across the terminals of switch K2 is less than the triggering voltage threshold 45 thereof (curve C10 ).

Since the detection threshold 44 of the lamp synchronization circuit Z2 is much lower than the triggering threshold 45 of the switch K2, the lamp synchronization signal SL is therefore at logic level 1 in the vicinity of each zero crossing of the mains voltage Us (curve C11 ).

The curve C12 shows the signal SI at the output of the integrator 28, obtained from the lamp synchronization signal SL having the shape of the curve C11. Curve C13 shows the shape of the switch command signal CK2
K2, which is at logic level 1 when the curve C12 exceeds the setpoint threshold 46. However, as previously mentioned, the voltage UK2 at the terminals of the switch K2 is lower than the triggering threshold 45 thereof, it therefore remains blocked regardless of the command applied to it.

The microprocessor 23 can determine whether the lamp 11 is off or on by comparing the sector synchronization signals SS and lamp SL. If the instants of the rising and / or falling edges of the signal SS correspond to instants when the signal SL is zero (curves 2 and 6), the lamp is detected on. Otherwise (curves 2 and 11) the lamp is detected off.

There is thus thus a simple and effective device for controlling the light intensity of the lamp 11 and determining the proper functioning of the latter.

Indeed, when the lamp 11 is in good working order, the load is self-inductive. The switch K2 therefore has a hundred volts at its terminals to be triggered, and when the mains voltage Us crosses zero, the lamp synchronization signal SL is also at zero.

When the lamp goes off, the load becomes capacitive. The switch K2 therefore no longer has enough holding current IB, and the voltage at its terminals UK2 is insufficient to be able to be triggered. In addition, when the mains voltage Us crosses zero, the synchronization signal
SL lamp is at 1.

Furthermore, the programming instructions of each control and monitoring device 10 are fixed.

However, each device 10 has variable instructions which can change depending on the state of the lamp it controls. This state is determined during the reduction regime: if the microprocessor 23 realizes that during the reduction in lighting intensity, the lamp goes off, it then decreases the reduction rate expected. The microprocessor 23 advantageously has 7 reduction rates, and when it reaches a predetermined alert rate, it warns the central station 3 of the degradation of the lamp 11.

The microprocessor 23 is further designed to declare faulty a lamp 11 which no longer tolerates reduction or which can no longer strike at the maximum voltage. In practice, a time delay of a few minutes is left to the ignition circuit 13 before declaring the lamp 11 faulty and notifying the central station 3.

When changing the lamp 11, the operator actuates the button 34, making it possible on the one hand to warn the central station 3 of the lamp change, and on the other hand to reset the variable parameters such as the reduction rate of the lamp lighting.

The computer 5 of the central station 3 is connected to a database 8 where information concerning each lamp is stored and in particular - a lamp identification code, - the lamp on and off times, - intensity reduction period and rate
the duration of use of the lamp since it was switched on
service, and - the condition of the lamp, in good working order, degraded or in
breakdown.

Thus, knowing the hours of ignition and extinction of each lamp 11, the computer 5 of the central station 3 can count the duration of operation of each lamp, and compare this duration to an alert threshold, the crossing of this threshold indicating that the lamp is to be replaced. The central station 3 can thus establish a list of lamps to be replaced by grouping together the information for exceeding this alert threshold, for lamp degradation detection, and for lamp in failure, so as to prepare and trigger replacement interventions, when the lamps to be replaced are in sufficient number. It is thus possible to group interventions in order to reduce the unit cost, the maintenance team being warned of the lamp changes to be planned before they are really out of service.

These provisions therefore make it possible to considerably reduce the unit cost of maintenance per candelabrum, and to adapt to the needs the light intensity of each candelabrum, and thus to achieve significant energy savings.

In FIG. 5, the transmission / reception circuit 25 shown in FIG. 3 is a phase modulation modulator / demodulator, of the synchronized asynchronous type, comprising for example, a first EXCLUSIVE OR gate 53 which combines a carrier Ft with the signal of the data to be transmitted from the connection terminal Tx of the microprocessor 23, and delivers a signal modulated in phase or in phase opposition with the carrier as a function of the logic level 0 or 1 of the data to be transmitted.

The output of gate 53 is connected to coupling circuit 22 which is either positioned in transmission or in reception thanks to a signal TxRx transmitted by microprocessor 23 and applied to the E / R input of coupling circuit 22.

When the coupling circuit 22 is positioned in transmission, it has a low output impedance, of the order of a few Ohms. It also makes it possible to filter the signal emitted to transform it into a sinusoidal signal.

The carrier Ft is obtained by means of an oscillator 54 controlled in frequency and in phase by a control loop applying a control voltage U0 at the input of the oscillator 54. This control loop comprises: - an EXCLUSIVE OR gate 52 of which an entry is connected to the
output of oscillator 54, - a sampler-blocker constituted by a generator
of pulses 56 which controls a switch 60 of which
the input is connected to the output of gate 52, and which
allows to charge a capacitor Cd connected to the ground, - an EXCLUSIVE OR gate 51 whose inputs are connected
at the outputs of door 52 and of switch 60, and - a filter-integrator 62 having a constant of
RC time, connected to the output of gate 51, and supplied
the control signal U0.

The pulse generator 56 delivers a signal d (Ft) consisting of one pulse at each edge of the input signal Ft, that is to say, two pulses per signal period
Ft. When the switch 60 is open between two pulses of the signal d (Ft), the voltage across the capacitor Cd remains blocked at logic level 0 or 1 of the last value of the voltage drawn by the switch 60 when the latter it was closed during a pulse supplied by the generator 56.

Furthermore, the signal TxRx also serves to control a switch 57 which makes it possible to select either the data signal Fx received by the coupling circuit 22, or a signal Fg generated by an oscillator 58, preferably driven by a quartz. This signal Fg has a periodic rectangular voltage having a constant frequency, equal to that of the carrier.

The signal Fg or Fx selected by the switch 57 is sent to the input of the EXCLUSIVE OR gate 52. The control loop thus makes it possible to calibrate the frequency and the phase of the signal Ft delivered by the oscillator 54, at the transmission, on those of the signal Fg, and on reception, on those of the received signal Fx.

On transmission, the switch 57 is positioned by the signal TxRx so as to apply the output signal Fg from the oscillator 58 to an input of the gate 52. The signal Fg being constant, the signal Ft generated by the oscillator 54 is also constant, as is the signal d (Ft) generated by the pulse generator 6 and which controls the switch 10.

Thus, the signal passing through the switch 60 charges the capacitor Cd at logic level 0 or 1, which blocks the voltage across the capacitor at logic level 0 or 1 from the last sample taken to the next sample. The filter 62 makes it possible to obtain a voltage U0 for controlling the oscillator 54 so that the signal Ft corresponds in frequency to the signal Fg.

The signal Tx emitted by the microprocessor 23 begins with a start bit to allow the recipient of this signal to remove the uncertainty on the initial phase of the signal. On reception, the value of this start bit can be used to determine whether or not to reverse the value of the following bits contained in the received signal.

It follows from the truth table of the EXCLUSIVE OR function that during the time intervals when the data signal Tx emitted by the microprocessor 23 is at logic level 0, the voltage at the output of gate 53 corresponds exactly in shape and in phase to the carrier Ft. When the data signal Tx is at logic level 1, the signal Ft + TX at the output of gate 53 corresponds in shape and in phase to the carrier Ft phase shifted by 1800 (phase inversion).

On reception, the coupling circuit 22 is positioned on reception by the signal TxRx, it then has a high input impedance, of the order of a few hundred ohms, so as to transmit the data signal Fx from the electrical network. to an amplifier 59 which also performs a filtering of the parasitic frequencies circulating on the electrical distribution network. The switch 7 is positioned by the signal TxRx so as to apply the signal Fx to the input of the gate 52.

The EXCLUSIVE OR gate 52 then combines the carrier with the received signal Fx, to obtain a signal Ft + Fx at logic level 0 or 1 depending on whether the received signal Fx is in phase or in phase opposition with the carrier Ft, the signal
Ft + Fx being introduced into the control loop described above.

The sampler-blocker constituted by the generator 56 which controls the switch 60, as well as the capacitor
Cd makes it possible to reset the received signal Fx at constant phase with respect to the frequency Ft, and supplies the microprocessor 23 with the demodulated signal Ud available at the terminals of the capacitor Cd. This demodulated signal is applied via an inverter 63, d firstly at the input Rx of the data received from the microprocessor 23, and secondly at the input P for detecting the carrier of the microprocessor 23, through a pulse generator 64 and a circuit time constant 65. In this way, the microprocessor 23 can determine whether it must wait for reception of a message in the event of detection of the carrier on its Rx input, and whether it can transmit a message in the event absence of carrier.

The use of a sample and hold device therefore makes it possible to perform very rapid demodulation of the received signal. Thus the digital transmission speed expressed in kilobits per second, can theoretically reach the speed of the carrier.

Thus, for example, with a carrier frequency equal to 135 kHz, this circuit can transmit and receive a digital signal at the speed of 90 kilo-bits per second.

To overcome the reduced range (a few hundred meters) of the transmission by carrier current, the microprocessor 23 receives all the messages detected by the coupling 22 and reception 25 circuits, and commands the re-transmission of the messages which are not given to it. not intended.

This solution makes it possible to order and monitor a large number of candelabras, thanks to the demodulation principle which makes it possible to achieve high transmission speeds.

Claims (17)

 1. Device for the remote control and monitoring of a discharge lamp supplied by an electric line of an electrical distribution network, characterized in that it is installed near the lamp (11), and that it includes means (22,23,25) for transmitting and receiving messages conveyed via the electric line (15,16) supplying the lamp (11), by modulated bidirectional carrier current, allowing it to communicate with a central station (3), said device comprising means for controlling the switching on and off of the lamp, according to instructions issued by the central station (3), and means for detecting lamp failures (11) and notify the central station (3).  2. Device according to claim 1, characterized in that it comprises means for controlling the light intensity of the lamp (11) according to instructions issued by the central station (3).  3. Device according to claim 1 or 2, characterized in that it comprises means for detecting the degradation of the operating state of the lamp (11).  4. Device according to one of the preceding claims, characterized in that it comprises means for detecting that the lamp (11) is on.  5. Device according to one of the preceding claims, characterized in that it comprises means for counting the operating time of the lamp (11).  6. Device according to one of the preceding claims, characterized in that the means (22,23,25) for communicating with the central station (3) transmit and receive messages transmitted by carrier current, in phase modulation, via the electrical distribution network.  7. Device according to one of the preceding claims, characterized in that the means (22,23,25) for communicating with the central station (3) transmit and receive messages transmitted by carrier current, in phase modulation, to a 132 kHz frequency, via the electrical distribution network.  8. Device according to one of the preceding claims, characterized in that the means (22,23,25) for communicating with the central station (3) are designed to receive all the messages conveyed by the power line (15,16) , and reissue messages that are not intended for them.  9. Device according to one of the preceding claims, characterized in that it comprises a first switch (K1) for triggering the switching on and off of the lamp (11), controlled by a microprocessor (23), and a second switch (K2) associated with a control circuit (Z2,28,29,30) making it possible to vary the light intensity of the lamp (11) as a function of a setpoint emitted by the microprocessor (23).  10. Device according to claim 9, characterized in that said second switch (K2) remains blocked in the open state when the lamp (11) has failed, said device comprising, in parallel with the second switch (K2), a detection circuit (Z2) supplying the microprocessor (23) a signal representative of the state of the second switch (K2) and therefore of the off / on state of the lamp (11).  11. Device according to one of claims 9 and 10, characterized in that the degraded state of the lamp (11) is detected by the second switch (K2) associated with the control circuit (Z2,28,29,30) , by gradually lowering the voltage applied to the terminals of the lamp (11), the lamp being declared in degraded state by the microprocessor (23), when the extinction of the lamp (11) is detected before having reached a certain rate reduction in lighting intensity.  12. Device according to one of the preceding claims, characterized in that the central station (3) comprises a computer (5) connected to the electrical network via an interface module (4) allowing the transfer of data between the computer (5) and the electrical network, and to a database (8) where information relating to each lamp (11) controlled and monitored by the central station (3) is stored, this information comprising for each lamp - a lamp identification code, - lamp switching on and off times, - intensity reduction period and rate  the duration of use of the lamp since it was switched on  service, and - the state of the lamp, in good working order, degraded, or in  breakdown.  13. Device according to one of the preceding claims, characterized in that the setpoint for reducing the light intensity of the lamp (11) is applied progressively by the microprocessor (23), so as to avoid the extinction of the lamp (11).  14. Device according to one of the preceding claims, characterized in that the computer (5) of the central station comprises means for comparing the duration of use of each lamp (11) with an alert threshold and establishes a list of lamps to be replaced, including faulty or degraded lamps, and lamps whose duration of use exceeds the alert threshold.  15. Device according to one of the preceding claims, characterized in that the means (22,23,25) for transmitting and receiving comprise a modulator / demodulator circuit with phase modulation of the synchronized asynchronous type, capable of transmitting digital data to using a carrier (Ft) in the form of slots, this circuit comprising a first OR EXCLUSIVE gate (53) on which are applied as an input, the carrier (Ft) and the signal (Tx) containing the data to be transmitted, and whose output voltage is in phase or in phase opposition with the carrier (Ft) as a function of logic level 1 or 0 of the data transmitted; and a second EXCLUSIVE OR gate (52) to which the carrier (Ft) and the received signal (Fx) are applied at input, and whose output voltage is at logic level 0 or 1 depending on whether the received signal (Fx) is in phase or in phase opposition with the carrier (Ft).  16. Device according to claim 15, characterized in that the modulator / demodulator circuit further comprises - an oscillator (54) generating the carrier (Ft) and of which  the phase is controlled by a voltage (Ug), so that  be synchronous in frequency and in phase in transmission, with  a signal of (Fg) generated by an oscillator (58), and in  reception, with the signal (Fx) received; and - a sampler-blocker to which the signal is applied  from the second door OR EXCLUSIVE (52), designed to  take samples of the signal from the oscillator  controlled in phase (54), at a frequency twice that  of the carrier (Ft), and deliver an output voltage  which remains blocked at logical level 0 or 1 of the last  sample taken, so as to demodulate the signal  (Fx) transmission of digital data received.  17. Device according to claim 16, characterized in that the phase-controlled oscillator (54) is controlled in phase by a voltage (UO) supplied by a control loop comprising - the second gate OR EXCLUSIVE (52), - 1 sampler-blocker, - a third OR EXCLUSIVE door (51), and - an integrating filter (62).