RU2788629C2 - Driver for led lamp - Google Patents

Abstract

FIELD: electrical engineering.

SUBSTANCE: invention relates to power supply devices for LED lamps, namely to three-phase drivers. The driver for the LED lamp powered from a three-phase alternating current network includes a circuit board, which includes a network rectifying diode bridge, a block for output current stabilization, an electromagnetic compatibility node consisting of a block for protection from microsecond pulse interference of large energy of more than 1500 V and including varistors, thermistor, and discharger located on the circuit board, while the block for output current stabilization includes a node for protection from high voltage. The node for protection from high voltage is installed at an input of the driver, while an induction coil, varistors, and gas discharges are sequentially connected to each phase. Each pair formed by the varistor and the gas discharger sequentially connected between each phase, as well as each pair formed by the varistor and the gas discharger connected between each phase and a grounding conductor form protective circuits.

EFFECT: increase in a power coefficient, driver performance, elimination of output current pulsation, and increase in the reliability of operation of the device in general.

5 cl, 1 dwg

Description

The present invention relates to power supply devices for LED lamps, namely to three-phase drivers, in particular, to a node for protecting a three-phase LED driver from overcurrent and voltage transients.

Drivers for LED fixtures must provide current limiting and some degree of current control. LED current control includes two tasks: current limiting to prevent thermal failure due to elevated LED temperature, and current regulation to keep the LED current within a certain range to account for fluctuations in the LED parameters and fluctuations in the input voltage of the LED driver.

As used herein to describe the present invention, the term "LED" is to be understood as any electroluminescent diode or other form of charge carrier injection/coupling system that is capable of generating radiation in response to an electrical signal. Thus, the term "LED" includes various semiconductor structures that emit light in response to current, light emitting polymers, organic light emitting diodes (OLEDs), electroluminescent strips, and the like.

It should be appreciated that LEDs can be configured (and/or controlled) to emit different bandwidths (e.g., full width at half maximum or duration at half amplitude) for a given range of spectrum (e.g., in a narrow band). frequency band, in a wide frequency band) and with a variety of dominant wavelengths that determine the main color tone.

An LED light source is known according to a utility model patent No. RU113105 (IPK N05V 37/02, 01/27/2012), which is aimed at eliminating power surges, increasing the reliability and service life of the LED illuminator, and reducing power consumption from a stationary AC network. The LED light source contains a step-down voltage converter, which is connected through a rectifier diode bridge to at least one LED, and between the rectifier diode bridge and the LED, a capacitive filter is connected in parallel with it, the step-down voltage converter is made of a chain of series-connected capacitors, where the rectifier diode the bridge is connected to break the chain of series-connected capacitors of the voltage converter.

The disadvantage of this solution is: low power factor (less than 0.9), low efficiency, high dependence of the LED supply current on changes in the supply voltage of the 220V network, poor protection against high-energy microsecond impulse noise, high pulsation of the luminous flux, lack of protection against overheating.

An invention is known according to the patent of the Russian Federation No. 2742050 (IPK H05B 45/325, 06/07/2020) from which a driver for an LED lamp powered by a three-phase AC mains is known, including a board on which a rectifier, an electromagnetic compatibility common-mode filter, a stabilization unit are installed output current, current sensor. The known driver includes a surge protection unit, an EMC differential filter, an auxiliary low voltage power supply, and an LED module. In this case, the rectifier is made three-phase full-wave, the output current stabilization unit consists of a power switch, a power ultrafast diode, a power inductor, a current sensor and a PWM controller, which has an output for controlling a power transistor and an input to which voltage is supplied from the current sensor, and the sensor current is connected in series with the inductor. The surge protection unit, EMC common mode filter, three-phase full-wave rectifier, EMC differential filter and output current stabilization unit are connected in series, and the auxiliary low-voltage power supply is connected in parallel with the input current stabilization unit.

The disadvantage of this solution is the low reliability of the device driver in the event of external and/or internal surges.

The problem to be solved by the invention is the creation of a driver with protection against microsecond impulse noise of high voltage and high energy in order to prevent its failure.

The technical result of the claimed invention is the creation of a driver with the function of protecting the LED lamp from power surges, increasing the power factor, increasing the efficiency of the driver, eliminating output current ripple, protecting against an open load circuit, protecting against polarity reversal, and also increasing the reliability of the device as a whole.

The specified technical result is achieved by the fact that the driver for the LED lamp powered by a three-phase AC mains includes a board on which a network rectifier diode bridge is installed, an output current stabilization unit, an electromagnetic compatibility unit consisting of a high-energy microsecond impulse noise protection unit more than 1500 V and including varistors, a thermistor, and a spark gap located on a printed circuit board, the output current stabilization unit includes a high voltage protection unit. In this case, the high voltage protection unit is installed at the input of the driver, while each phase is connected in series with an inductor, a varistor and a gas discharger, while each pair formed by the varistor and the gas discharger is connected in series between each phase, as well as each pair formed by a varistor and a gas arrester connected between each phase and the ground conductor form protective chains.

In addition, bidirectional diodes located in series between the phases are additionally included in the circuit of the high voltage protection unit.

In addition, additionally, thermistors with a positive temperature coefficient are included in the circuit of the high voltage protection unit.

In addition, thermistors with a negative temperature coefficient are additionally included in the circuit of the high voltage protection unit.

In addition, bidirectional diodes are included in series with each phase in the circuit of the high voltage protection unit.

The introduction into the device circuit of the driver for the LED lamp of the protection unit, made and connected in the claimed manner, makes it possible to increase the reliability of the device.

The introduction of the first protective circuits into the driver device circuit for the LED lamp serves to limit the inrush currents of the power source that occur in the first seconds of operation and are due to the charge of capacitors from the power source.

Introduction to the driver device circuit for an LED lamp of the second protective circuits for damping high-energy impulse noise that occurs in the power supply circuit.

The essence of the invention is illustrated by drawings, where in Fig. 1 shows a schematic diagram of a three-phase driver protection unit for an LED lamp.

The three-phase driver for the LED lamp includes a board on which a network rectifier diode bridge is installed, an output current stabilization unit, an electromagnetic compatibility unit consisting of a high-energy microsecond impulse noise protection unit of more than 1500 V, and including varistors, a thermistor, and arrester located on the printed circuit board. In this case, the output current stabilization unit includes a high voltage protection unit.

The driver for the LED lamp, the circuit diagram of which is shown in Fig.1, contains inductors 1 (FB1, FB2, FB3), varistors 2 (RU1, RU2, RU3, RU4, RU5, RU6), gas dischargers 3 (HL1, HL2 , HL3, HL4), bidirectional TVS diodes 4 (VD1, VD2, VD3), positive temperature coefficient (PTC) thermistors 5 (RI1, RI2, RI3), negative temperature coefficient (NTC) thermistors 6 (RT1, RT2, RT3 ).

A high voltage protection unit is installed at the driver input, with an inductor, a varistor and a gas discharger connected in series in each phase.

Varistors RU1, RU2, RU3 and gas dischargers HL1, HL2, HL3, connected in series between phases, form protective chains RU1HL1, RU2HL2, RU3HL3.

Varistors RU4, RU5, RU6 and gas arrester HL4, connected in series between each phase and the ground conductor, form protective chains RU4HL4, RU5HL4, RU6HL4.

Inductors FB1, FB2, FB3 are used to reduce the slew rate of a high-voltage interference pulse due to their inductive reactance, allowing more time for the protective circuits to operate.

Additionally, thermistors with positive and negative (negative) temperature coefficients can be included in the circuit of the high voltage protection unit.

Thermistors RI1, RI2 with a positive temperature coefficient are used to protect against short circuits in the driver circuits.

Thermistors RT1, RT2, RT3 with a negative (negative) temperature coefficient are used to prevent resonant charging of the capacitor at the output of a three-phase rectifier through the equivalent differential inductance of the electromagnetic compatibility (EMC) filter, which can occur when the driver is connected to the mains.

Also included in the circuit of the high voltage protection unit are bidirectional TVS diodes located in series between the phases.

The driver for the LED lamp works as follows.

A driver for an LED lamp powered by a three-phase AC network is connected to a source of electrical energy. With a sharp increase in voltage in the circuit, failure of any of the elements of the circuit may occur. The protection node, made and connected in the claimed manner, provides protection of the driver from microsecond impulse noise of high voltage and high energy, in order to prevent the driver from failing, and radiating elements from possible voltage surges.

All security chains work on the same principle, so let's consider the operation of one of them, for example, RU1HL1. When a high-voltage microsecond impulse interference occurs at the input of the circuit between phases L1 and L2, the voltage on the RU1HL1 chain begins to increase. The rate of rise of this voltage is limited by the inductors FB1 and FB2. When the voltage on the circuit reaches the trigger voltage of the arrester HL1 (this voltage must be higher than the amplitude value of the line voltage in order to avoid false triggering of the chain), the arrester breaks through and the voltage across it drops to several tens of volts. Excess voltage after ignition of the arrester falls on the varistor RU1, which also limits the current through the arrester. The arrester actuation voltage must be lower than the value that will be dangerous for subsequent driver nodes.

The varistor operation voltage must be selected in such a way that the total voltage on the protective circuit after its operation is higher than the peak value of the line voltage and in total with the voltage on the arrester after the discharge occurs, and below the value that will be dangerous for subsequent driver nodes.

After the end of the interference with a decrease in voltage, the discharge in the arrester goes out, and the circuit returns to its original state.

To cancel the residual interference in the protection unit, the second stage of interference suppression is used on TVS diodes VD1 ... VD3. They work like fast high power bi-directional zener diodes and limit the residual noise voltage. The response voltage of TVS diodes must be greater than the peak value of the line voltage of the network.

Depending on the specific application conditions, the protection scheme can be simplified.

In addition, arresters can be removed from the interphase protective circuits, in which case the corresponding varistors are connected between the phase wires, these circuits themselves may be absent, and their role is taken by serial connections of two of the three varistors RU4, RU5, RU6.

You can also remove the arrester HL4 by connecting the lower (according to the diagram) outputs of the varistors RU4, RU5, RU6 directly to the ground conductor and the inductor FB1, FB2, FB3.

Bidirectional TVS diodes can be replaced by a chain of two back-to-back unidirectional TVS diodes.

If there is no need for additional interference suppression, then VD1, VD2, VD3 may be absent.

In severe operating conditions, after the EMC filter (between the filter and the rectifier), protective circuits similar to those described above can be connected, either only varistors, or protection circuits from TVS diodes.

Thermistors RI1, RI2 with a positive temperature coefficient are used to protect against short circuits in the driver circuits. With such a short circuit, the short circuit current heats up the thermistors, which causes their resistance to increase and current limitation, but this current limitation should not be too strong. The latter is necessary so that the circuit breaker in the supply network can operate and break the circuit. If the function of protection against short circuits is completely assigned to equipment external to the driver, thermistors RI1, RI2, RI3 may also be absent.

NTC thermistors RT1, RT2, RT3 are used to prevent resonant charging of the capacitor at the output of the three-phase rectifier through the equivalent differential inductance of the EMC filter, which can occur when the driver is connected to the mains. Having a large resistance at the moment the driver is turned on, thermistors reduce the quality factor of the circuit to values less than one, and the resonant charge does not occur. It also reduces the starting current. In the future, the thermistors are heated by the current flowing through them, their resistance decreases, and they do not affect the operation of the driver. If NTC thermistors are installed in the DC circuit (after the rectifier) or there is no resonant charge and there is no need to limit the starting current, then thermistors RT1, RT2, RT3 may be absent.

The invention can be carried out under production conditions on standard equipment using known components and materials.

Claims (5)

1. Driver for LED lamp powered by a three-phase AC network, including a board on which a network rectifier diode bridge is installed, an output current stabilization unit, an electromagnetic compatibility unit consisting of a high-energy microsecond impulse noise protection unit, more than 1500 V , and includes varistors, a thermistor and a spark gap located on the printed circuit board, while the output current stabilization unit includes a high voltage protection unit, characterized in that the high voltage protection unit is installed at the driver input, while in each phase an inductor, varistors and gas dischargers are connected in series, and each pair formed by a varistor and a gas discharger connected in series between each phase, as well as each pair formed by a varistor and a gas discharger connected between each phase and the ground conductor, form protective circuits. 2. The driver for the LED lamp according to claim 1, characterized in that, in addition, bidirectional diodes located in series between the phases are included in the circuit of the high voltage protection unit. 3. The driver for the LED lamp according to claim 1, characterized in that, in addition, thermistors with a positive temperature coefficient are included in the circuit of the high voltage protection unit. 4. The driver for the LED lamp according to claim 1, characterized in that, in addition, thermistors with a negative temperature coefficient are included in the circuit of the high voltage protection unit. 5. The driver for the LED lamp according to claim 1, characterized in that bidirectional diodes are included in series with each phase in the circuit of the high voltage protection unit.

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