RU2025911C1 - Outdoor lighting system - Google Patents

Abstract

FIELD: electrical engineering. SUBSTANCE: insertion of A.C. key, program control unit and pulse pickups with proper circuits makes it possible to simplify design of system, to save power depending on operating schedule of system and to prolong service life of light sources. System has remote control over lighting devices without laying control lines. EFFECT: improved efficiency of operation of outdoor lighting system. 4 dwg

Description

 The invention relates to electrical engineering and can be used in outdoor lighting networks to control the power of lighting installations.

 Known outdoor lighting network containing a power source connected through switching devices to the wires of the lighting network to which the lighting units are connected (Medvedev D.G. Voltage reduction in outdoor lighting without turning off the lights. Information leaflet N 81-0078. Ukr. NIINTI. Kiev , 1981).

 In this case, the power control of the lighting network is carried out by a combination of switching on switching devices introducing or shunting a diode into the power supply circuit of the network. This device is applicable only to a lighting network with incandescent lamps. The pulsations of the luminous flux of lamps at reduced power limit the use of the known device.

 Closest to the invention in technical essence and the achieved result is an outdoor lighting network containing lighting installations, each of which has a gas-discharge light source connected between the phase and zero wires of the lighting network through two series-connected ballast elements, one of which is shunted by the opening contact of the actuating relay whose coil is connected to the zero wire of the lighting network by one of the terminals (Sokolov V.F., Valuzhin V.S. Power control system and source of light in outdoor lighting plants. Fact Sheet N 83-0077. UkrNIINTI, Kiev, 1983). The known device allows you to control the power of the lighting network by changing the magnitude of the inductive resistance of the ballast of gas discharge lamps.

 A disadvantage of the known device is the need for laying an additional control wire, which makes the implementation of the lighting network difficult.

 The aim of the invention is to simplify.

 The goal is achieved by the fact that an AC key with two control pins and two output pins connected between one of the phase and zero wires of the lighting network, a program control unit with output pins connected to the control pins of the AC key, and two power leads connected respectively to the indicated one of the phase and zero wires of the lighting network, as well as current transformers for each lighting installation installed on said one of the phases wires of the lighting network, while the executive relays are equipped with make contacts, and each lighting installation is equipped with a pulse sensor, input leads connected to the secondary winding of the corresponding current transformer, the first of which is additionally connected to the specified one of the phase wires of the lighting network, the first output terminal of each the pulse sensor is connected to another terminal of the coil of the corresponding actuating relay and through its make contact to the second terminal of the pulse sensor, the alternating key current is made in the form of a triac, a current transformer and a load resistor, as well as a control transformer with two-section primary and secondary windings, a diode, two resistors, two thyristors, a capacitor and a rectifier bridge, the input terminals of which are connected to the secondary winding of the current transformer of an alternating current switch, at the weekend with a control electrode and a cathode of the second thyristor through the second resistor and with the diode cathode through the first resistor, the first terminal of the first section of the secondary winding of the control transformer is connected to the control electrode of the triac, and the second terminal is connected to the first terminal of the second section of the same winding of the control transformer, with the cathodes of the thyristor and through the capacitor with the cathode of the diode , an anode connected to the second terminal of the second section of the same winding of the control transformer, one of the opposite terminals of the primary winding section of which are connected to the output terminal of the alternating current switch, connected to the zero wire of the lighting network, and other opposite terminals are connected to the control terminals of the said key, the anode of the first thyristor of which is connected to another output terminal of the same key, the program control unit is made in the form of a program sensor connected between the power terminals with three switching contact groups, the common the output of the first of which is connected to the power output connected to the phase wire of the lighting network, the closing output is with the closing output of the third contact group and the first output output terminal, and the NC terminal with the common terminal of the second contact group, the terminal terminal of which is connected to the second output terminal of the program control unit, and the NC terminal with the common terminal of the third contact group, each pulse sensor is made in the form of two relays with switching contact groups and coils, shunted by buffer diodes, two resistors, four capacitors and two input diodes, which are opposite terminals connected to the input terminal, not connected to the phase wire of the lighting network, other opposite terminals of the input diodes are connected to the first terminals of the coils of the corresponding relays through the corresponding resistor and capacitor connected in parallel, and to the second terminals of the indicated coils through the third or fourth capacitor, respectively, the first terminal of the coil of the first relay is connected to the disconnecting terminal of the contact group of the second relay, the closing terminal of which connected to the first output terminal of the pulse sensor, the second output terminal of which is connected to the disconnect terminal of the contact group of the first relay , Normally open terminal connected to the second terminal of the second relay coil, a first terminal of which is connected with common contact terminals of the first group and the second relay and also to the input terminal of the pulse generator connected to the phase conductor of the network.

 In FIG. 1 shows a diagram of an outdoor lighting network; figure 2 is a diagram of a pulse sensor; figure 3 is a diagram of an alternating current switch and a program control unit; figure 4 shows a graph of the outdoor lighting network.

 The outdoor lighting network (Fig. 1) contains lighting installations 1, 2 and 3. Each lighting installation contains a gas-discharge power source 4 connected between phase 5 and zero 6 wires of the network through the first 7 and second 8 ballast elements. In the lighting installation there is an executive relay 9, the coil of which is connected to the ground wire 6 of the network by the first output. The sensor 10 of the pulses of the lighting installation with the first and second input terminals is connected to the secondary winding of the current transformer 11 installed by the primary winding in the phase wire 12, and the first input terminal of the pulse sensor is connected to the phase wire 12. The actuating relay 9 is equipped with an NC contact 13 connected in parallel with the second ballast element 8. The closing contact 14 of the Executive relay 9 is connected in parallel with the first and second output terminals of the sensor 10 pulses. The input terminals of lighting installations 2 and 3 are connected to the secondary windings of current transformers 15 and 16, respectively. The primary transformers 15 and 16 of the current are installed in the phase conductor 12. Lighting unit 2 is connected to the phase conductor 17 by the first power output 17. Lighting conductor 3 is connected to the phase conductor 12. The second power leads of lighting systems 2 and 3 are connected to the neutral conductor 6. First input the conclusions of the lighting installations 2 and 3 are connected to the phase conductor 12. The phase wires 5, 12, 17 are connected to the poles of the ABC of the power supply 19 through a switching device 18. The neutral wire 6 is connected to the neutral of the power source 19. At the end of the lighting network, the first output terminal to the phase wire 12, and the second output terminal to the neutral wire 6 is connected to an AC key 20. The wires 12 and 6 are connected to the power leads of the block 21 of the program control. The output terminals of the software control unit are connected to the control terminals of the AC key 20.

 The pulse sensor 10 (figure 2) contains the first 22 and second 23 input diodes, and the cathode of the diode 22 is connected to the anode of the diode 23, and their connection point is connected to the second input terminal of the lighting installation. The anode of the diode 22 through the parallel connected first resistor 24 and the capacitor 25 is connected to the connection point of the coil of the first relay 26 with the cathode of the first buffer diode 27. The anode of the diode 27 is connected to the second output of the coil 26 of the first relay and through the second capacitor 28 with the anode of the diode 22. The cathode of the diode 23 through a parallel connected second resistor 29 and a third capacitor 30 is connected to the connection point of the first output of the coil of the second relay 31 with the anode of the second buffer diode 32. The second output of the relay coil 31 is connected to the cathode of the diode 32 and through the fourth condensate 33 is connected to the cathode of the diode 23. The first input terminal of the pulse sensor 10 is connected to the switching contact 34 of the second relay 31 and the switching contact 35 of the relay 26. The disconnecting group of the switching contact 34 is connected to the first output of the zero relay coil 26, and the closing group to the first output output . The opening group of the switching contact 35 is connected to the second terminal of the pulse sensor, and the closing group is connected to the second terminal of the second relay coil 31.

 The AC key 20 (FIG. 3) contains a chain of triac 36, current transformer 37, and load resistor 38 connected to the output terminals of the AC key. The control transformer 39 has a primary winding having two sections. The opposite extreme terminals of the primary winding of the control transformer 39 are connected to the output terminals of the AC key. The middle terminal of the primary winding of the transformer 39 is connected to the neutral wire of the network. The middle terminal of the secondary winding of the transformer is connected to the cathode of the first thyristor 40. The anode of the thyristor 40 is connected to the cathode of the triac 36. The control electrode of the triac 36 is connected to the first terminal of the secondary winding of the transformer 39. The second terminal of this winding is connected to the anode of the diode 41. The cathode of the diode 41 through a series circuit from the first 42 and second 43 resistors connected to the control electrode of the thyristor 40. Between the connection point of the resistors 42 and 43 the anode of the second thyristor 44 is connected. The cathode of the thyristor 44 is connected to the secondary terminal of the secondary of the transformer winding 39. The control transition of the thyristor 44 is connected to the output terminals of the rectifier bridge 45. The input terminals of this bridge are connected to the secondary winding of the current transformer 37. A capacitor 46 is connected between the middle terminal of the secondary winding of the control transformer 39 and the connection point of the resistor 42 with the cathode of the diode 40.

 The program control unit 21 (FIG. 3) comprises a program controller 47 connected to the phase and neutral wires of the network through the first and second power leads. The common terminal of the first switching group 48 is connected to the first power terminal connected to the phase wire of the lighting network. The NC terminal of the contact group 48 is connected to the common terminal of the second switching group 49. The NC terminal of the contact group 49 is connected to the common terminal of the third switching group 50. The NC terminals of the first contact group 48 and the third terminal group 50 are combined and connected to the first output terminal. The second output terminal of the program control unit is connected to the closing terminal of the second contact group 49.

 The outdoor lighting network operates as follows.

When the contacts of the switching apparatus 18 are closed, the voltage from the power supply 19 is supplied to the phase wires 5, 12, 17. To lighting installations 1, 2, 3, voltage is supplied from phase 5, 17, 12, respectively, and zero 6 wires. Since when switching on the switching apparatus 18, it is possible to connect the phase wire 12 to the pole C of the power source 19 in any half-cycle of the mains voltage, the amplitude of the zero current in the wire 12 can be of any polarity, and this in turn causes arbitrary operation of one of the relays in the sensor 10 pulses. For example, at the moment T _on (Fig. 4), the switching device 18 is included in the half-wave of the current of negative polarity, so the first signal detected by the sensor 10 is a current pulse i _{n of} negative polarity (Fig. 4a). In this case, the relay 31 is activated in the sensor 10. When the relay 31 is triggered, its contact 34 disconnects the first input terminal from the relay coil 26 and connects this terminal connected to the phase wire 12 to the first output terminal of the pulse sensor. In this case, a phase voltage is applied to the actuating relay 9. Relay 9 trips. When the relay 9 is activated, the contact 13 opens and the contact 14 closes. After the contact 34 is set to its initial position, the relay 9 remains on, as it is connected through its contact 14 to the second output terminal connected through the terminal 34 to the first input terminal connected to the phase wire 12. Thus, at the moment of switching on the lighting network T _on in lighting installations 1, 2, 3, actuating relays 9 are turned on, which, by their contact 13, unload the inductor 8, thereby switching on the lighting installations in pony mode wife power f = 50% (pigv). From the moment T is turned _on , the program control unit 47 starts working in the program control unit 21, since the voltage of wires 12 and 6 is supplied to it. Considering the fact that in the evening the light sources must operate at full power Φ = 100%, and the inclusion the relay in the sensors 10 pulses of lighting installations is arbitrary, in the program control unit, after a short pause T _n = 2-5 s (Fig. 4c), the switching contact 50 is activated. In this case, the first section of the primary winding of the transformer 39 is connected between zero 6 and phase 12 by the waters. This connection provides the operation of the control circuit of the triac 36 of the key 20 of the alternating current in the positive half-cycle. Triac 36 generates a current pulse i _1y (4b), which causes an increase in operating current i _P1 of the wire 12 to the value i _1k (Figure 4a). The amplitude of the current i _{1k of} positive polarity in the pulse sensor 10 is detected by the operation of the relay 26. When the relay 26 is activated, contact 34 is switched, which is disconnected from the second output terminal, thereby breaking the power supply circuit of the actuator relay coil 9, and at the same time bypasses the relay coil, protecting it from false triggering. The executive relay 9 is set to its initial position, opens its contact 14 and closes the contact 13. Contact 13 bypasses the inductor 8, translating the lighting network into full power mode Φ = 100% (Fig. 4c). When the operating current in the network rises to i _рz as a result of shunting additional chokes in lighting installations by pulse sensors, the false signal is not detected, since the relay coil 31 is shunted by terminal 35 in the pulse sensors. Shunting by terminal 35 of relay coil 31 also allows capacitors 30 and 33 to be charged to an equal voltage amplitude, which eliminates the false operation of the relay 31 when it is removed by contact 35. In the case of switching on the lighting network by the switching device 18 from the positive half-cycle voltage, the mode Φ = 100% is established from the moment T _on. In this case, the re-formation of the signal does not cause changes in the lighting installations 1, 2, 3. Switching the network at night to the low power mode is performed when the switch 47 switches the contact program 49 (Fig.3). In this case, the mains voltage is removed from the first section of the primary winding of the AC transformer 39. This mains voltage is applied to the second section of the primary winding of the AC key 20. Triac 36 opens once in the negative half-wave of an AC network, and a current signal i _{2y is formed} . The signal i _{2y is} superimposed on the sine wave of the operating current i _p2 . Thus, the sensors 10 pulses of the lighting installations fix the current signal i _2k in a half-wave of negative polarity.

This impulse is fixed, the relay is activated in the 10 impulse sensor. According to the above technology, for the relay to operate, the contact of this relay activates the executive relay 9, by unloading the inductor 8 and putting the lighting network into low power mode Φ = 50%. In the morning hours, the program controller 47 switches the contact 48. In this case, the mains voltage is removed from the second section and supplied to the first section of the primary winding of the transformer 39. The AC key 20 in this case generates a pulse i _3y (Fig. 4b), providing a network transfer to full power mode Φ = 100%. After a certain time, depending on the network operating schedule, the switching device 18 is turned off and the entire device is provided and is set to its original position for a new operation cycle.

 An example of a specific implementation. The outdoor lighting network can be implemented in installations of 380/220 V with lighting installations having DRL-400 lamps equipped with two chokes. As an alternating current key, the device is used according to ed. N 955409. The program control unit is based on the BC-10 - 32U4 software time relay, current transformers installed in the control wire are adopted as IT-81. The pulse sensors contain receiving elements with capacitors of 0.1 and 1 μF. Receiving relays of the RP-7 type, buffer and input diodes of the D226D type. Executive relay type MKU-48.

 The outdoor lighting network allows you to adjust the lighting power in order to save electricity and increase the life of the light sources. The control of lighting installations is remote, without laying a control line, which allows to increase the economic effect during the modernization of the lighting network.

Claims (1)

 EXTERNAL LIGHTING NETWORK, containing lighting installations, each of which has a gas-discharge light source, connected between the phase and neutral wires of the lighting network through two series-connected ballast elements, one of which is bridged by the disconnecting contact of the executive relay, the coil of which is connected to the neutral wire of one of the terminals lighting, characterized in that, in order to simplify, an AC key with two control pins and two output pins connected between one of the phase and zero wires of the lighting network, a program control unit with output terminals connected to the control terminals of the AC key, and two power leads connected respectively to one of the phase and zero wires of the lighting network, as well as current transformers for each lighting installation, installed on the aforementioned one of the phase wires of the lighting network, while the executive relays are equipped with make contacts, and each lighting installation is equipped with pulse sensors, input terminals, connected to the secondary winding of the corresponding current transformer, the first of which is additionally connected to one of the phase wires of the lighting network, the first output terminal of each pulse sensor is connected to the other terminal of the coil of the corresponding actuating relay and, through its make contact to the second output terminal of the pulse sensor, an alternating current switch made in the form of series-connected and connected between its output terminals of the triac, current transformer and load resistor, as well as trans a control switch with two-section primary and secondary windings, a diode, two resistors, two thyristors, a capacitor and a rectifier bridge, the input terminals of which are connected to the secondary winding of the AC current transformer, and the output terminals are connected to the control electrode and the cathode of the second thyristor, the anode connected to the control the electrode of the first thyristor through the second resistor and with the cathode of the diode through the first resistor, the first output of the first section of the secondary winding of the control transformer is connected to the control with a triac of the triac, and the second terminal - with the first terminal of the second section of the same winding of the control transformer, with the cathodes of the thyristors and through the capacitor - with the cathode of the diode, an anode connected to the second terminal of the second section of the same winding of the control transformer, one of the opposite terminals of the section of the primary winding of which connected to the output terminal of the AC key connected to the zero wire of the lighting network, and other opposite terminals to the control terminals of the specified key, the anode of the first thyristor of which is connected to With the output output of the same key, the program control unit is made in the form of a program master connected between the power terminals with three switching contact groups, the general output of the first of which is connected to the power terminals connected to the phase wire of the lighting network, the closing output is with the closing output of the third contact group and the first output terminal, and the disconnect terminal with the common terminal of the second contact group, the terminal terminal of which is connected to the second output terminal of the program control unit, and short-circuit terminal - with a common terminal of the third contact group, each impulse sensor is made in the form of two relays with switching contact groups and coils, shunted by buffer diodes, two resistors, four capacitors and two input diodes, which are opposite terminals connected to the input terminal connected to the zero a wire of the lighting network, other opposite terminals of the input diodes are connected to the first terminals of the coils of the respective relays through the corresponding resistor and capacitor connected in parallel, the second outputs of these coils through the third and fourth capacitors, respectively, the first output of the coil of the first relay is connected to the disconnecting terminal of the contact group of the second relay, the closing output of which is connected to the first output terminal of the pulse sensor, the second output of which is connected to the disconnecting terminal of the contact group of the first relay, closing the output of the second relay coil connected to the second output, the first output of which is connected to the common outputs of the contact groups of the first and second relays, as well as to the input m pulse sensor output connected to the phase conductor of the network.

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