RU2015625C1 - Lighting installation - Google Patents

Abstract

FIELD: outdoor lighting systems. SUBSTANCE: lighting installation with gaseous-discharge lamp and pulse ignition unit is fitted with stand-by filament lamp and control device limiting no-load operation of pulse ignition unit and lighting up stand-by lamp when main one goes off. EFFECT: reduced time of operation of pulse ignition unit under emergency condition and provision for operational condition of lighting installation when gaseous-discharge lamp is disconnected. 1 dwg

Description

 The invention relates to electrical engineering, in particular to control circuits for lighting installations.

 Known lighting installation containing the main discharge lamp connected to the terminals for connecting the network through the inductor, and a backup incandescent lamp. The control circuit of this installation provides for the inclusion of a backup lamp in case of failure of the main [1].

 The closest in technical essence to the invention is a lighting installation containing a main high-pressure discharge lamp with a pulsed ignition unit, one of the terminals of which is connected to the first output of the main lamp, the second output connected through one winding of the inductor with the first output for connecting the network, two capacitors and a backup incandescent lamp, one of the terminals of which is connected to the second terminal for connecting the network and one of the terminals of the first capacitor [2].

 Known lighting system provides for the automatic inclusion of a backup lamp. However, during operation of the backup lamp, the pulse ignition unit cannot be switched off, and the compensation capacitor consumes additional power.

 Thus, the known lighting installation operates in an uneconomical mode.

 The aim of the invention is the efficiency of the lighting installation.

 This is achieved by the fact that an actuating relay with switching and opening contacts, positive and negative buses, a zener diode connected between the indicated buses by the anode to the negative bus, a two-stage thyristor, a rectifier and a diode diode, a base one, a timing one, two ballast and two limiting resistors are introduced into the installation , the first current relay with switching and opening contacts, the second current relay with a closing contact, a transformer with primary and secondary two-section windings, a light optocoupler unijunction diode and a phototransistor, and the other is provided with a choke coil. In this case, the first output of the main lamp through the other windings of the inductor and the coils of the first and second current relays connected in series is connected to the second terminal for connecting the network, which is connected to the negative bus to which one of the terminals of the second capacitor and the primary winding of the transformer are connected, the middle terminal of the secondary winding transformer and cathodes of a two-stage thyristor and an optocoupler LED, the anode of which is connected to one of the terminals of the primary limiting resistor and the anode of the diode, the current of which is connected to the anode of the two-stage thyristor, and through the coil of the executive relay to the positive bus; the other terminal of the second capacitor is connected to one of the terminals of the timing resistor and the emitter of the single-junction phototransistor of the optocoupler, the first base of which is connected to the other terminal of the primary winding of the transformer, and the second base is connected through the base resistor to the positive bus. The control electrode of the two-stage thyristor is connected to the common terminal of the switching contact of the executive relay, the opening and closing conclusions of which are connected respectively to the terminals of the first and second sections of the secondary winding of the transformer, the other terminal of the backup lamp through the parallel connected opening contact of the first and the closing contact of the second current relay is connected to the first terminal for connecting a network that is connected to the make-up terminal of the switching contact of the first current relay, and through the but the rectifier diode and the first ballast resistor are connected with its common output and the other output of the first capacitor, the positive bus is also connected to other outputs of the timing and first limiting resistors, and through the second ballast resistor to the disconnecting terminal of the switching contact of the first current relay, another pulse output the ignition unit is connected in parallel through a second limiting resistor and an NC contact of the actuating relay to a second terminal of the main lamp.

 The lighting installation is characterized by the presence of new elements - an executive relay with a switching and opening contact, positive and negative buses, two ballast and two limiting resistors, a two-stage thyristor, rectifier and isolation diodes, the first and second current relays with switching and opening contacts, a transformer with primary and two secondary windings, optocouplers from an LED and a two-stage transistor and a new construction of electrical connections between them.

 The drawing shows a diagram of a lighting installation.

 The lighting installation contains a main high-pressure discharge lamp 1, one of the terminals of which is connected to the first terminal of the pulse ignition unit 2, and the second terminal is connected to the first terminal through one winding 3 of the inductor to connect the network. The connection point of the first output of the main lamp 1 with the pulse ignition unit 2 through another winding 4 of the inductor and coil of the first 5 and second 6 current relays is connected to the second output for connecting the network.

 The second terminal of the first capacitor 7 and the first terminal of the backup glow lamp 8 are connected to the second terminal for connecting the network. The second output of the backup lamp 8 is connected to the first output for connecting the network through parallel connected disconnecting contact 9 of the first 5 current relay and making contact 10 of the second 6 current relay. A rectifier diode 11 is connected to the first terminal for connecting the network, the cathode of which is connected through the first ballast resistor 12 to the connection point of the second terminal of the first capacitor 7 with the switching contact 13 of the first current relay 5.

 The terminal of the switching contact is connected to the first terminal for connecting the network, and the terminal through the second ballast resistor 14 is connected to the positive bus 15. The negative bus 16 is connected to the second terminal for connecting the network. A zener diode 17 is connected between the negative 16 and positive 15 buses, connected by the anode to the negative bus 16. The cathodes of the two-stage thyristor 18, the optocoupler LED 19, the first output of the primary winding of the transformer 20 and the first output of the second capacitor 21 are connected to the negative bus 16, the second output of which is through the timing resistor 22 is connected to positive bus 15.

 The connection point of the capacitor 21 with the resistor 22 is connected to the emitter of a single junction transistor 23 of the optocoupler. The first base of this single-junction transistor is connected to the second terminal of the primary winding of the transformer, and the second base is connected through the base resistor 24 to the bus 15. The anode of the optocoupler LED 19 through the first limiting resistor 25 is also connected to the positive bus 15. The anode of the two-stage thyristor 18 through the coil 26 of the executive relay connected to the bus 15. To the connection point of the anode of the LED 19 with the resistor 25 is connected the anode of the diode diode 27, the cathode of which is connected to the connection point of the coil 26 of the Executive relay with a Odom thyristor 18.

 The control electrode of the two-stage thyristor is connected to the common terminal of the switching contact 28 of the executive relay 26. The disconnecting and closing conclusions of the switching contact 28 are connected respectively to the terminals of the first and second sections of the transformer winding. The average terminal of this winding is connected to the negative bus 16. The second terminal of the pulse ignition unit is connected in parallel through the second limiting resistor 29 and the disconnect terminal 30 of the executive relay 26 to the second terminal of the main lamp 1. The first current relay has a setting for operating on lamp current 1, the second current relay - to operate when the starting current of the lamp 1.

 Lighting installation works as follows. When summing up the conclusions for connecting the voltage network, the pulse ignition unit 2 generates high-voltage pulses, which are applied through the contacts 30 of the executive relay 26 to the main gas-discharge lamp 1. If lamp 1 is operational, then it ignites after 0.5-1 s. When ignited, the lamp consumes an inrush current, which is 1.6-2 times higher than the operating current. In the presence of an inrush current, current relays 5 and 6 are activated. Relay 5 switches contact 13. In this case, the capacitor 7 is connected in parallel to the terminals for connecting the network and plays the role of a compensation capacitor. Contact 10 of the current relay 6 closes and connects the backup lamp 8 to the mains voltage. When connecting the lamp 8 in the starting period - the period of ignition of the main lamp, its luminous flux increases slowly. When the lamp flashes up and its lamp current decreases to the value of the operating current, the relay 6 opens its contacts 10 and the backup lamp 8 is turned off, and the main lamp 1 operates with a nominal light flux. Thus, the lighting system is operating normally.

 In the event of an emergency mode - the extinction of the main lamp 1, for example, due to a sharp surge of the mains voltage in the direction of decrease on the coils 5 and 6 of the first and second current relays, the current decreases to zero. The contacts 9 of the de-energized current relay 5 return to their original position and connect the backup lamp 8 to the mains voltage. Contact 13 of relay 5 is also set to its initial position, connecting a circuit from diode 11, resistor 12, and capacitor 7 via a second ballast resistor 14 to positive bus 15. In this case, capacitor 7 carries the function of a storage capacitor, which supplies rectified mains voltage to buses 15 and 16. This voltage is stabilized by the zener diode 17. When voltage is applied to the buses 15 and 16, the capacitor 21 starts charging.

 When the switching voltage of the phototransistor 23 is reached on the capacitor, the value of which is determined by the light flux from the LED 19, a current passes through the LED, which is determined by the voltage on the buses 15 and 16 and the value of the resistor 27. At the maximum allowable current through the LED 19, the switching voltage of the phototransistor 23 in this optocoupler is minimal .

 The charge time of the capacitor 21 to the switching voltage of the transistor 23 is 5-10 s. After practicing this time delay, the transistor 23 switches and a current passes through the primary winding of the transformer 20, which generates a positive pulse in the first section of the transformer 20. Thus, a voltage pulse of positive polarity relative to the thyristor control electrode is supplied to the control transition of the thyristor 18 through the switching contact 28. The thyristor 18 opens and current flows through the coil 26 of the executive relay. The executive relay is activated, while the contact 28 connects the control electrode of the thyristor 18 to the output of the second section of the transformer, and the contact 30 opens, introducing a high-resistance resistor into the circuit of the pulse circuit block 2. In this case, the pulse ignition unit 2 stops the formation of high voltage pulses, limiting the idle operation of the unit.

 When thyristor 18 is open, the LED 19 is shunted by a chain of diode 27 and thyristor 18, as a result of which the backlighting by LED 19 of the phototransistor 23 is stopped, which increases the switching voltage of this phototransistor. As a result, the switching voltage of the phototransistor 23 on the capacitor 21 can reach after 2-4 minutes.

 After working out this time delay, the phototransistor switches, ensuring the passage of the discharge current of the capacitor 21 along the primary winding of the transformer 20, which causes the formation of a voltage pulse on the second section of the secondary winding of the transistor 20. Moreover, this pulse is negative with respect to the control electrode of the thyristor 18 and locks the latter. Locking the thyristor 18 leads to the cessation of current in the coil 26 of the Executive relay, the contacts 28 and 30 of this relay are returned to their original position. In this case, the contact 30 shunts the resistor 30, ensuring that the pulse ignition unit 2 is turned on. The LED of the optocoupler is also unloaded and current flows through it, causing a decrease in the switching voltage of the phototransistor 23. If the main lamp 1 lights up during the operation of the pulse ignition unit, the relay is activated 5, providing switching contact 13 and opening of contact 9. The relay 6 also works, providing the closure of contact 10, which ensures that the backup lamp 8 is connected to the network for the period of the main hydrochloric lamp 1. After the start-up period of the lamp current of one lamp decreases, the relay 6 is switched off by breaking its contacts 10, disconnecting a backup lamp 8 from the network.

 PRI me R. The lighting installation can be performed on the basis of the RCC 02 400 002 U1 lamp with the main lamp DNaT 400 and a backup lamp KG-1000, diode 11 type KD 202P, resistors 12 and 14 type PEVR 10 kOhm, zener diode 17 type D816A, capacitor 7 with a capacity of 40 μF, relay 26, type RES-32, relay 5, 6, type RT-80, optocoupler 19, 23 type AOT-102A, thyristor 18 type KU 101G, transformer 20 type TVV-2, resistor 22 type MLT-1 75 kOhm, diode 27 type D226A, resistor 25 type MLT-2 2.7 kOhm.

 The lighting installation is applicable in outdoor lighting networks, as well as in lighting networks of industrial enterprises, critical facilities.

Claims (1)

 LIGHTING INSTALLATION, containing the main high-pressure discharge lamp with a pulse ignition unit, the first output of which is connected to the first output of the main lamp, the second output connected through one winding of the inductor to the first output for connecting the network, two capacitors and a backup incandescent lamp, one of the outputs of which is connected with a second terminal for connecting the network and one of the terminals of the first capacitor, characterized in that, in order to increase efficiency, an actuating relay with a switching and a disconnect is introduced contacts, positive and negative buses, a zener diode connected between the indicated buses, anode to the negative bus, two-stage thyristor, rectifier and isolation diodes, base, timing, two ballast and two limiting resistors, the first current relay with switching and opening contacts, the second relay current with a make contact, a transformer with primary and secondary two-section windings, an optocoupler from an LED and a single-junction phototransistor, and the inductor is equipped with another winding, while the output of the main lamp through the other windings of the inductor and the coils of the first and second current relays connected in series is connected to the second terminal for connecting the network, which is connected to the negative bus to which one of the terminals of the second capacitor and the primary transformer winding is connected, the middle terminal of the secondary transformer winding and cathodes of a two-stage thyristor and an optocoupler LED, the anode of which is connected to one of the terminals of the first limiting resistor and the anode of the diode, whose cathode it is connected to the anode of the two-stage thyristor, and through the coil of the executive relay to the positive bus, the other terminal of the second capacitor is connected to one of the terminals of the timing resistor and the emitter of the single-junction phototransistor of the optocoupler, the first base of which is connected to the other terminal of the primary winding of the transformer, and the second base is connected through the base resistor to the positive bus, the control electrode of the two-stage thyristor is connected to the common terminal of the switching contact of the executive relay, opening and closing the first terminals of which are connected respectively to the terminals of the first and second sections of the secondary winding of the transformer, the other terminal of the backup lamp through the parallel connected opening contact of the first and the closing contact of the second current relay is connected to the first terminal for connecting the network, which is connected to the closing terminal of the switching contact of the first current relay, and through a rectifier diode and a first ballast resistor connected in series, with its common terminal and another terminal of the first capacitor, the positive bus also is connected to the other ends of the timing and a first limiting resistor and through the second ballast - with break contact terminal of the first current switching relay, the other terminal of the ignition pulse unit through parallel connected second limiting resistor and executive relay break contact connected to a second terminal of the main lamp.

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