FR2539941A1 - Remote control by frequency of public lighting via the electrical network - Google Patents

Abstract

The invention allows energy savings to be made in public lighting, without modifying the present electrical network. This is an electronic circuit which is placed in the chosen lamppost; this circuit is a receiver which is controlled by a frequency carried by the electrical network. This frequency is given by the transmitter which is itself set into operation by the hourly and weekly breaker switch in order to choose and carry out its programme for turning off and turning on the lighting circuit. The transmitter comprises two stabilised supplies 1, a high-frequency oscillator 2, a filter 3, an hourly and weekly breaker switch 4, and two monostable delay timers 5. The receiver includes a stabilised supply 6, three high-pass filters 7, a pre-amplifier, amplifier stage 8, a bistable delay timer 9 and a power interface between the circuit and the circuit of the lamppost 10.

Description

The present invention is a remote control for public lighting, this to save electrical energy. This remote control automatically turns off or on the candelabra light at any time.

This invention will allow great savings in electrical energy.

Why leave all the candelabras lit at certain hours of the night when you can put out one out of two or one out of three while letting it light up at crossroads and turns, and this without modifying the current network? It is an electronic circuit which is added to the electrical circuit of the public lighting pole.

The operation is done by a transmitter circuit and a receiver circuit which is incorporated in the post. The transmitter sends a frequency to the power line which is picked up by the receiver. The latter, according to the order given, extinguishes or re-lights the candelabrum. The transmitter is controlled by a time and weekly switch. At 10 p.m., an impulse was given to the tutor and the tutor turned off the light. At 6 o'clock, another pulse is given to the receiver which turns the light back on. A saving of 72% is made on the equipped candelabra. An inductor must be connected in series on the condensers to stop the carrier frequency.

Example program for switching off and switching on Monday, Tuesday, Wednesday, Thursday, Friday - switching off at 10 p.m.
ignition at 6 o'clock
Saturday - switch off at 1 o'clock
ignition at 6 o'clock
Sunday - 24 hour shutdown
ignition at 6 o'clock.

The attached drawing is a block diagram of the circuit: 1/1.

The transmitter circuit is made up of 5 distinct parts 1 - stabilized power supplies 2 - high frequency oscillator 3 - separator filter 4 - hourly and weekly switch 5 - moneatablas timers.

The receiver circuit is also composed of 5 distinct parts 6 - stabilized power supply 7 - high pass filters 8 - preamplifier stage, signal amplifier 9 - bistable timer 10- power interface between the circuit and the candelabrum circuit.

The transmitter circuit includes two stabilized power supplies I one for the oscillator; the other for monostable timers. The first miter is built around a step-down transformer 1 which reduces the voltage from 220 V to 15 V. The alternating current is rectified by the diode bridge 3. The capacitor stores energy and filters the current. The capacitors 2 and 4 absorb the parasites due to the network. The assembly is followed by the voltage regulator 6 which stabilizes the voltage at 12 Volts DC, and the capacitor 7 smooths the output voltage. The second power supply has the same operation as the first and consists of a step-down transformer 8 , capacitors 9, 11, 12, 14, the diode bridge 10 and the voltage regulator 13.

The oscillator is built around an integrated circuit 21 which is mounted in astabla. It is the discharge of the capacitor 20 through the network of resistors 15, 16, 19 and of the diodes 17, 18 which gives the time base for the frequency at the circuit 21. The capacitor 23 makes it possible to have regular pulses, The signal is amplified by transistor 25 via resistor 24 connected to terminal 3 of circuit 21. A second power tranaistor 27 retransmits the signal to inductor 28. Transistor 27 is controlled by transistor 25 via resistance 26. The frequency of the signal is 60 Kilohertz. A filter separates the oscillator circuit from the power supply network. This filter consists of two capacitors fi 29, 30, which oppose the network frequency (50 Hertz); on the other hand, they let through the high frequency given by the oscillator.

The non-stable timer circuit gives two distinct pulses: one of 2 seconds; the other 3 seconds for switching off and switching on.

The first timer is continuous from two of the four non-logic gates or from the integrated circuit 36. The monostable is triggered by a logic level 0 applied to its input. The cycle time is given prr the discharge of the capacitor 43 through the resistor 42. The input of the first monostable is biased by the resistor 35 and is controlled by the contact 33 of the time switch 31. The output signal of the first monostable timer controls the transistor 41 via the resistor 40. The second timer r the grandma operates as its predecessor. It is composed of two logic gates not or coming from the integrated circuit 36, the time in seconds of which is given by the discharge of the capacitor 38 through the resistor 37. The input of the second timer is biased by the resistor 34, and is controlled by a logic level 0 given by the contact 32 of the time switch 31. The output signal of the second timer is amplified by 1 transistor 41 via the resistor 40. The diodes 39, 44, connected respectively to the output of each timer 1 avoid the short-circuit at the time of the operation of one of the two timers, and allow not to add to the circuit an amplifier (resistance and transistor). The amplifier built by the transistor 41 controls the relay 46 protected by the diode 45 which avoids self-induction. The relay 46 has a working contact 22 which operates the oscillator1 for the time required for the receiver to turn off or on.

 The receiver is protected from the electrical network by capacitors 47, 59 which allow the frequency of the transmitter to pass. For proper operation of the receiver, its input is made up of three high pass filters. The first is built by 1 capacitor 47 and the resistor 48 and has a cutoff frequency of 20 Kilohertzs. The second avoids the parAsites of the electrical network and is formed by the capacitor 49 at the resistor 50. The third filter is constructed by the capacitor 51 and the resistor 52 and controls the transistor 53 which is 1 preamplifier. The latter activates the amplifier via the resistor 55, the transistor 56. The capacitor 54 transforms the high frequency into direct current for better operation of the amplifier. The bistable timer comprises an integrated circuit 63 having four non-or logic gates. The first uses two non-or logic gates and its time is given by the discharge of the capacitor 65 through the resistors 66, 67. The diode 64 prevents the capacitor from discharging in the output of the first non-or logic gate. Terminals 1, 2, 5, 6, 8, 9, 12, 13 of circuit 63 are connected to the ground of the circuit by resistors 58, 60, 67, 68, 61, 62, 76, 77. The output signal of the first timer is amplified by the capacitor 69 in order to control the transistor 71 via the resistor 70. The second timer includes the other two non-logic or circuit gates 63. The time base is given by the discharge of the capacitor 74 through resistors 75 and 76.

The diode 73 prevents the capacitor 74 from discharging through the output of the non-or logic gate. The output signal controls the transistor 79 via the resistor 78. For the operation of the bistable timer, a logic level l is required at the terminals 1, 13 of the circuit 63. The logic level 1 is given by the transistor 56 by means of the resistor 57. For bonding the power relay 84, the transistors 71, 82 must title excited, This relay 84 is self-sustaining by its working contact 72 connected in parallel to the transistor 71. The diode 83 absorbs the reverse voltage due to the self-induction of the relay 84. The take-off of the relay 84 is due to the transistor 79 via the resistor 78 controlled by the second timer which cuts the supply of the transistor 82 by the resistor 80. As a result, the relay 84 returns to its initial position (rest). Contact 85 controls the extinguishing or lighting of the candelabra lamp. The stabilized power supply of the receiver is composed of a step-down transformer 86 which has a secondary voltage of 15 Volts alternating. This voltage is rectified by the diode bridge 88 then smoothed by the capacitor 90. The voltage passes through the voltage regulator 91 which stabilizes at 12 Volts DC. The voltage is again smoothed by the capacitor 92. The capacitors 87, 89 absorb the noise.

An inductor must be connected in series with the capacitor located in the lighting pole.

Claims (6)

1) Remote control by frequency of public lighting by the electrical network  trique, caractérixéa in that it comprises two electronic circuits  which: the first is a transmitter and the second a receiver. The transmitter  is composed of two stabilized power supplies (1), an oscillator  high frequency (2), a filter (3). a time switch and  weekly (4) and by two monostable timers (5).  tor is composed of a stabilized power supply (6), pass filters  top (7), one stage preamplifier, amplifier (8), one tempo  bistable riser (9), and a power interface between the circuit  and the candelabra circuit or any other device. 2) Remote control by frequency of public lighting by the electrical network  as claimed in claim 1, characterized by two power supplies sta  stabilized formed by the transfrmators 1, 8 step-down  which is rectified respectively by the diode bridges 3 and 10 then  smoothed by capacitors 4 and 11. Stabilization of the voltage  ae made by the voltage regulators 6 and 13 whose outputs are  gills to capacitors 7, 14 for a final smoothing. These two  stabilized power supplies are for oscillator (2) and timers  monostable jumpers (5). Capacitors 2, 5, 9, 12 absorb the  noise from different devices. 3) Remote control by frequency of public lighting by the electrical network  that according to claim 1, characterized by a high bscillator  frequency built around an integrated circuit 21 mounted in astable.  The frequency is given by the discharge of the capacitor 20 through  resistors 15, 16, 19 and diodes 17, 18. Capacitor 23  allows you to have regular pulses. The amplified signal goes to  across choke 28 for better frequency. The frequency is  6o Kilohertz. Another choke must be connected in series  with the lamp circuit capacitor. 4) Remote control by frequency of public lighting by the electrical network  that according to claim 1, characterized by a filter consisting of  two capacitors 29, 30. These two capacitors oppose the fre  due to the high impedance. However, the filter  lets the high frequency pass very well. This filter is also used to  separate the electronic circuit from the mains voltage. 5) Remote control by. frequency of public lighting by the electrical network  that according to claim 1, characterized by a time switch  and weekly with forty eight hours of power reserve. We can  choose extinction and ignition frequencies according to the hours  and the days. This time switch controls the timers  mono stable.  Frequency control of public lighting by the electrical network  that according to claim 1, characterized by two timers  monostables constructed by an integrated circuit 36 comprising four por  your logic no-or. The first monostable is constituted by the res  tance 37 and the capacitor 38 whose discharge time is 2 seconds  condes. The first logic gate not or is polarized by the resis-  tance 34.  The second monostable uses the last two logical doors non-or  the time base is given by the discharge of the capacitor 43 through tra  towards the resistor 42. The discharge of the capacitor 43 is 3 seconds.  Resistor 35 polarizes the input of the first logic gate of the  second monostable. The two monostables control relay 46 by the in  intermediate of transistor 41 which is supplied by resistor 40.  The diodes 39, 44 avoid short circuits between the output of the two  monostable. The self-induction due to relay 46 is absorbed by the  diode 85. Contact 22 of relay 46 operates the oscillator.  Frequency control of public lighting by the electrical network  that according to claim 1, characterized by a power supply sta  tagged for the receiver. This stabilized diet is composed  a voltage booster transformer 86, the secondary voltage of which  is rectified by the diode bridge 88. The voltage is smoothed by the  capacitors 90 and 92. The voltage regulator 91 stabilizes the voltage  of the circuit at 12 Volts DC The capacitors 87 ot 89 avoid  electrical noise.  Frequency control of public lighting by the electrical network  that, according to claim 1, -car 'activated by low-pass filters  constructed by three high pass filters with different cutoff frequency  annuity. The first is made by the capacitor 47 and the resistor  48 which eliminates the frequency of the electrical network. The second built  by the capacitor 49 and the resistor 50, blocks the frequencies para-  Site (s. The third includes the capacitor 51 and the resistor 52 and  only passes the carrier frequency of 60 Kilohertz which includes  ; requires the preamplifier, amplifier stage.  Remote control by frequency of public lighting by the electrical network  that according to claim l, characterized by a preamplification stage  er, amplifier. The preamplifier is constituted by the tranai-  tor 53 which operates the amplifier produced by the resistor  55 and the transistor 56. The capacitor 54 smoothes the output voltage  the preamplifier for better operation. The transistor  56 controls via the resistor 57 the timer  bistable. 10) Remote control by frequency of public lighting by the electrical network, according to claim l, characterized by a bistable timer composed by the integrated circuit 63 which has four non-or logic gates. Two timers are made of two logical ports, not each. The first is used for extinction and has a time base of 2.5 seconds due to the discharge of the capacitor 65 through the resistors 66, 67. The second is used for ignition, and the time is 3, 5 seconds x given by the discharge of the capacitor 74 through the resistors 75, 76. The diodes 64, 73 prevent the capacitors 65, 74 from discharging through the logic gates non-or. Inputs 1, 2, 5, 6, 8, 9, 12, 13 of circuit 63 are connected to the ground of the circuit by resistors 58, 60, 67, 68, 61, 62, 76, 77. For the operation of the two timers, a logic level 1 at terminals 1 and 13 of circuit 63 is necessary. Logic level 1 is given by the amplifier (8). This bistable timer prevents untimely operation from parasites passing over 1 network.  Remote control by frequency of public lighting by the electrical res  that, according to claim 1, characterized by an interface then  session controlled by the bistable timer. This interface then  sance comprises a relay 84 which has at its terminals a diode 83 for nbsor-  ber auto-induction at cut-off. Transistor 82 is still powered  ted by resistance 81 put on the positive pole. The extinction is ordered  by transistor 71 via resistor 70, sticks relay 84 which  self-maintain by its work contact 72 connected in parallel on the  transistor 71 and switches off the light from the lighting pole by contact  85.  The ignition switches on, via. resistance  78, transistor 79 to cut power to transistor 82 via  resistor 80. As a result, relay 84 takes off and resumes ignition  of light by its contact 85.