RU214807U1 - RESERVE LED LUMINAIRE - Google Patents

Abstract

The utility model relates to redundant LED lighting devices and can be used for street and outdoor lighting of protected areas and facilities. EFFECT: improved lighting characteristics and increased reliability. In case of malfunctions, the electronic switch disconnects the first adapter and the main group of LEDs from the power supply network at the command of the current sensor. Switching to the second adapter and the backup group of LEDs is carried out by: a pulse shaper, the first and second voltage comparators with the first and second reference voltage sources, a 2OR logic element, the first D-flip-flop. The switching circuits are powered by a power supply with the first power rail. The signal LED is turned on by: the battery, the time relay, the first and second logic elements 2I, the pulse generator, the second D-trigger. The switching circuits are powered by a battery recharging circuit with a second power rail. The current sensor, power source and battery recharging circuit are connected to the power supply network with a common neutral wire of the power supply circuit of the main and backup lighting, the first and second power buses. 1 ill.

Description

The utility model relates to redundant LED lighting devices and can be used for street and outdoor lighting of protected areas and facilities.

A device is known that contains LEDs, an adapter with a variable supply voltage used in the mode of adjusting the brightness of LEDs, a switch (see, for example, patent RU 197321 IPC H05V 35/00 for a utility model "LED lamp control device", authors Kuzmenko V.P. and others, published on April 21, 2020. Bull. No. 12).

The disadvantage of the known device is that in order to increase the service life of the lamp, the brightness of the LEDs is reduced, which leads to a deliberate decrease in the lighting characteristics inherent in the LEDs and, as a result, to a deterioration in the quality of lighting.

A luminaire with a backup light source is known, containing a power source connected to the power supply network, a main light source, a backup light source, a current sensor, an electronic switch, a pulse shaper, a signal light source (see patent No. reserve lamp ", authors Yudin V.V. and Yudin M.V. Published on September 10, 2005, Bull. No. 25).

The disadvantage of the known device is that redundancy is provided only for light sources. There is no redundancy for ballasts, and the reliability of redundancy decreases.

During operation of the luminaire in outdoor lighting networks, precipitation forms frost on the luminaire in winter. The ice shell disrupts the operation of the mechanical parts of the signaling device when switching to backup lighting. In this case, it is impossible to detect a lamp with a burnt out light source in the daytime, because signal light source works only in the dark.

The luminaire implements redundancy by replacement, when the backup light source is not loaded, is in storage and is connected as needed (see, for example, Shishmarev V.Yu. Reliability of technical systems: a textbook for students of higher educational institutions / V.Yu. Shishmarev - M.: Publishing Center "Academy", 2010, pp. 106-107). At the same time, the presence of a switch for switching to a backup light source reduces the reliability of redundancy.

The closest in purpose to the claimed utility model in terms of a combination of features is a redundant LED lamp connected to the power supply network, containing two groups of LEDs, the first and second adapters, a battery, a battery recharging circuit, a current sensor (key stage), the first comparator, an electronic switch, the first and second power rails (see, for example, patent RU No. 143060 MPK F21S 8/00 for the utility model "Elevator lamp", authors Roslyakov A.V. and Romanov A.V. Published on July 10, 2014. Bull. No. 19) and taken as a prototype.

The disadvantage of the known lamp, taken as a prototype, is that in the backup mode, the lamp does not shine at full brightness. The backup lighting cannot be switched on for a long time and depends on the battery capacity. The redundancy control circuitry is powered by the adapters, and the reliability of the redundancy depends on the reliability of the adapters and the electronic switch.

The technical result consists in improving the lighting characteristics and increasing the reliability of operation.

The specified technical result is achieved by the fact that in a redundant LED lamp connected to the power supply network and containing the first and second adapters, the outputs of which are connected to the main group and to the reserve group of LEDs, respectively, a current sensor, an electronic switch, the first voltage comparator, the first and second power rails, battery recharging circuit, battery, the difference lies in the fact that it additionally includes a power source, the first and second reference voltage sources, the second voltage comparator, the 2OR logic element, the pulse shaper, the first and second D-flip-flops, the time relay, a pulse generator, the first and second logic elements 2I, a signal LED so that the inputs of the power source, current sensor, battery recharging circuits are connected to the power supply network, the power input of the second adapter is connected to the output of the current sensor, and the power input of the first adapter is connected to the output of the current sensor via electronic com mutator, the first power bus is connected to the output of the power source, the power circuits of the first and second reference voltage sources, the first and second voltage comparators, the logic element 2OR, the pulse shaper, the first D-flip-flop and the electronic switch, and the outputs of the reference voltage sources are connected to the second inputs of the first and second voltage comparators, respectively, the first inputs of which are connected to the information output of the current sensor, and the output of each voltage comparator is connected to the corresponding input of the logic element 2OR, the output of which is connected to the inputs of the first and second D-flip-flops, and the information input of the D-flip-flops contains logical unit, and the output of the pulse shaper is connected to the zero setting inputs of the first and second D-flip-flops, and the output of the first D-flip-flop is connected to the control inputs of the electronic switch and the second adapter, the second power bus is connected to the output of the battery recharging circuit, battery terminals, power supply circuits of the time relay, pulse generator, first and second logic elements 2I and the second D-flip-flop, the output of which is connected to the second inputs of the first and second logic elements 2I, and the first input of the first logic element 2I is connected to the output of the time relay, and the first input of the second logic element 2I is connected to the output of the pulse generator, and the output of the first logic element 2I is connected to the input of the pulse generator, and the output of the second logic element 2I is connected to the signal LED, and the power supply circuits of the adapters, the first and second power buses have a common neutral wire.

The essence of the utility model is as follows. The LEDs of the fixtures are powered by adapters that convert alternating voltage to direct voltage. The failure rate of adapters exceeds the failure rate of LEDs, so it is necessary to provide for switching to both backup LEDs and a backup adapter to ensure uninterrupted operation of the luminaire. Luminaire failures can be associated with both open circuits and short circuits in the adapter and/or LEDs. In the first case, current does not flow through the current sensor 1 (see Fig.), in the second case, a sharp increase in current occurs. It is also possible that an overvoltage or undervoltage of the supply voltage may occur due to a malfunction in the adapter or in the LEDs. The alternating current is converted by the current sensor 1 into a constant voltage, which is taken from the information output of the current sensor, and its value changes in proportion to the change in the alternating current.

In the proposed utility model, the electronic switch 2 does not switch the first adapter 3 with the main group of LEDs 4 to the second adapter 6 with the backup group of LEDs 7, but disables the first adapter with the main group of LEDs in case of malfunctions. The switching of the electronic switch 2 is carried out at the input of the voltage control of the logic levels at the output of the first D-flip-flop 14. Logic zero puts the channel of the electronic switch 2 into a conducting state, and a logic one opens the channel. The second adapter 6, in the presence of a logical zero at the control input, operates in a light mode (see, for example, Shishmarev V.Yu. Reliability of technical systems: a textbook for students of higher educational institutions / V.Yu. Shishmarev. - M .: Publishing Center "Academy", 2010, p. 104). In this mode, the output of the adapter is set to a voltage that is lower than the voltage required for normal operation of the LEDs. The second adapter 6 and the second group of LEDs 7 heat up slightly, and the LEDs can emit light. The light mode improves redundancy reliability. When a logical unit is received at the control input of the second adapter, the full operating voltage is set at its output.

Short circuit currents can damage the adapter, LEDs, or switch by burning out these elements and creating an open circuit in the power circuit. This does not affect the reliability of switching to the backup group of LEDs, since an open in the circuit will turn on the backup group of LEDs 7 at full supply voltage. With minor changes in the supply current, but when the lower and upper limits of the current and, accordingly, the reference voltages of the voltage comparators go beyond the lower, the burnout probability decreases and the probability of switch failure decreases.

In addition to the power supply circuit of the adapters, the main and backup group of LEDs connected to the power supply network to the phase and common neutral wires, the luminaire uses two power buses with a common neutral wire to switch to the backup group of LEDs 7 and turn on the signal LED 21. The first power bus 23 connects output of power supply 5 and power supply circuit of the switching circuit to the redundant group of LEDs 7: reference voltage sources 8 and 10, voltage comparators 9 and 11, logic element 2OR 12, pulse shaper 13, first D-flip-flop 14 and electronic switch 2. Depending on circuit implementation of switching circuits and the used nomenclature of electro-radio components, the power supply 5 can have several outputs with different supply voltages. The second power bus 24 connects the output of the battery recharging circuit 15, combined with the battery terminals 16, with the power circuits of the signal LED 21 switching circuit: the time relay 17, the pulse generator 19, the first and second logic elements 2I 18 and 20, the second D-trigger 22. The load of the pulse generator 19 is the alarm LED 21, which lights up when a fault occurs in the first adapter 3 and/or the main group of LEDs 4. The time the alarm LED is turned on is set by the time relay 17. This time is tied to the time the service organization goes around the lamps during daylight hours. The signal LED 21 is switched by the pulse generator 19.

The figure shows a block diagram of a redundant LED luminaire connected to the power supply network.

The lamp contains a current sensor 1, an electronic switch 2, the first adapter 3, the main group of LEDs 4, the power supply 5, the second adapter 6, the backup group of LEDs 7, the first reference voltage source 8, the first voltage comparator 9, the second reference voltage source 10, the second voltage comparator 11, logic element 2OR 12, pulse shaper 13, first D-flip-flop 14, battery charging circuit 15, battery 16, time relay 17, first logic element 2I 18, pulse generator 19, second logic element 2I 20, signal LED 21 , the second D flip-flop 22, the first power rail 23, the second power rail 24.

The lamp works as follows. The luminaire is connected to the power supply network. In the initial state, after applying voltage to the lamp in the evening, power supply 5 is turned on. The output of power supply 5 is connected by the first power bus 23 to the power supply circuits of reference voltage sources 8 and 10, voltage comparators 9 and 11, electronic switch 2, logic element 2OR 12, the first D-flip-flop 14. A constant voltage from the power source 5 is also supplied to the pulse shaper 13. The pulse generated at power-up with a “negative” leading edge at the zero-setting input sets the outputs of the first 14 and second 22 D-flip-flops to a logical zero state. The second adapter 6 is set to the light mode of operation, the channel of the electronic switch 2 goes into a conductive state. Through the current sensor 1 and the electronic switch 2, the alternating voltage of the power supply network is supplied to the adapter 3, which converts the alternating voltage into a constant one to power the main group of LEDs 4. The second adapter 6 receives the voltage of the power supply network from the output of the current sensor 1. The reserve group of LEDs 7, which is the load of the second adapter 6 begin to glow in light mode. The general illumination of the luminaire is provided by the main group of LEDs 4, operating in normal mode, and the backup group of LEDs 7, operating in light mode.

The second power bus 24 is constantly energized, connected to the outputs of the battery recharging circuit 15 and the battery terminals 16, as well as to the power circuits of the time relay 17, the first 18 and the second 20 logic elements 2I, the pulse generator 19, the second D-trigger 22. Battery 16 after turning on the battery charging circuit 15 starts to recharge. Logic zero from the output of the second D-flip-flop 22 is supplied to the second inputs of the first 18 and second 20 logic elements 2I. At the first input of the first logic element 2I there is also a logic zero coming from the time relay 17. The pulse generator 19 is blocked by a logic zero from the output of the first logic element 2I 18. There is no pulse generation, and the signal light source 21 is turned off by the logic zero level from the output of the second logic element 2I 20. The time relay 17 is turned on at a given daytime for a given time interval.

The alternating current consumption is converted in the current sensor 1 into a DC voltage, which is supplied from the information output of the current sensor to the first inputs of the first 10 and second 12 voltage comparators. The second input of the first voltage comparator 10 receives the reference voltage from the reference voltage source 9 corresponding to the selected, for example, the lower limit current consumption of the lamp. The second input of the second voltage comparator 12 receives the reference voltage from the reference voltage source 11 corresponding to the selected upper limit current consumption of the lamp. When daylight comes, the voltage in the power supply network turns off and the power supply circuit of the adapter 3, the main group of LEDs 4, the second adapter 6, the backup group of LEDs 7, the first power bus 23 is de-energized.

In the absence of malfunctions of the lamp during daylight hours, the output of the first 18 and second 20 logic elements 2I has a logic zero, since the output of the second D-trigger 22 has a logic zero level. Logic zero blocks the inclusion of the pulse generator 19 and signal LED 21.

When the supply voltage is re-applied to the lamp the next day in the evening in an accident-free mode, the operation of the circuit is repeated.

In the event of an open, short circuit, or when the current consumption exceeds the lower or upper limits in the event of a malfunction in the adapter 3 or in the main group of LEDs 4, the constant voltage at the information output of the current sensor 1 will also increase or decrease. Accordingly, in the event of a break or a decrease in current consumption lamp below the threshold, comparator 9 will work, and in case of a short circuit or exceeding the current consumption of the response threshold, comparator 11 will work. which the logical unit "1" is always present. At the output of flip-flops, the level of a logical one is set. Logical unit at the output of the first D-flip-flop 14 switches the channel of the electronic switch 2 in a non-conductive state. The first adapter 3 and the main group of LEDs 4 are de-energized, and the second adapter 6 and the redundant group of LEDs 7 are switched from light mode to full voltage mode. The logical unit at the output of the second 22 D-flip-flop is transmitted to the second inputs of the first 18 and second 20 logic elements 2I. General illumination is provided by a second adapter and a redundant group of LEDs 7 switched to full supply voltage.

When the voltage in the power supply network is turned off during daylight hours, the lamp is de-energized in the power supply circuit of the main 4 and backup 7 groups of LEDs and in the first power bus 23. The second power bus 24 is energized by the battery 16. At a given time for a given time interval, the time relay 17 is on sets its output to a logic-one level. At the output of the first logic element 2I 18, the level of a logical unit is also set, which unlocks the pulse generator 19. The second logic element 2I 20 passes pulses from the generator 19 to the signal LED 21.

When the supply voltage is applied to the luminaire, which is in an emergency state for the next day in the evening, the operation of the circuit is repeated in an accident-free mode, followed by switching to a backup group of LEDs 8 in emergency mode.

Thus, the technical result of the utility model has been achieved, which consists in improving the lighting characteristics and increasing the reliability of operation. Switching the luminaire to backup lighting is provided in case of short circuits, breaks, increased or decreased current consumption in the LED power circuit. Switching the operation of the signaling LED from night time to daytime made it possible to increase the reliability of the signaling device, regardless of weather conditions. Backup lighting is carried out at full current consumption, which does not reduce the lighting characteristics of the lamp.

Claims (1)

A redundant LED luminaire connected to the power supply network and containing the first and second adapters, the outputs of which are connected to the main group and to the reserve group of LEDs, respectively, a current sensor, an electronic switch, the first voltage comparator, the first and second power rails, a battery recharging circuit, a battery , characterized in that it additionally includes a power source, the first and second reference voltage sources, the second voltage comparator, the 2OR logic element, the pulse shaper, the first and second D-flip-flops, the time relay, the pulse generator, the first and second 2I logic elements, signal LED so that the inputs of the power source, current sensor, battery recharging circuit are connected to the power supply network, the power input of the second adapter is connected to the output of the current sensor, and the power input of the first adapter is connected to the output of the current sensor through an electronic switch, the first power rail is connected to the output power source ii, by the power supply circuits of the first and second voltage reference sources, the first and second voltage comparators, the logical element 2OR, the pulse shaper, the first D-trigger and the electronic switch, and the outputs of the reference voltage sources are connected to the second inputs of the first and second voltage comparators, respectively, the first inputs which are connected to the information output of the current sensor, and the output of each voltage comparator is connected to the corresponding input of the logic element 2OR, the output of which is connected to the inputs of the first and second D-flip-flops, and there is a logical unit at the information input of the D-flip-flops, and the output of the pulse shaper is connected to zero-setting inputs of the first and second D-flip-flops, and the output of the first D-flip-flop is connected to the control inputs of the electronic switch and the second adapter, the second power bus is connected to the output of the battery recharging circuit, battery terminals, power circuits of the time relay, pulse generator, first and orgo logic elements 2I and the second D-flip-flop, the output of which is connected to the second inputs of the first and second logic elements 2I, and the first input of the first logic element 2I is connected to the output of the time relay, and the first input of the second logic element 2I is connected to the output of the pulse generator, and the output of the first logic element 2I is connected to the input of the pulse generator, and the output of the second logic element 2I is connected to the signal LED, and the power circuits of the adapters, the first and second power buses have a common neutral wire.

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