KR102074480B1 - A Converter Circuit for LED Lamps - Google Patents

Abstract

The present invention is to provide a converter circuit for a multi-channel type constant current type LED lamp in which each LED array is connected in series, which is extremely simple and minimizes the cost. Converter circuit for the LED lamp of the present invention for achieving the above object, the filter unit for receiving and filtering commercial AC power; Rectifying unit for rectifying the AC power filtered by the filter unit; A constant current circuit unit 300 for controlling the current while inverting the DC power rectified by the rectifier; A voltage converter 400 which receives the DC power rectified by the rectifier and converts the voltage into the voltage of the lighting unit of the LED lamp while being inverted by the constant current circuit unit; A first lighting unit 500 and a second lighting unit 700 connected to the secondary side of the voltage conversion unit in series and lighting an LED lamp; A first bypass unit 600 and a second bypass unit 800 connected to the first lighting unit and the second lighting unit to bypass current flow when an abnormality occurs in each lighting unit; A feedback unit 900 connected to the voltage conversion unit to sense a current on an output side and feed back to the constant current circuit unit; Characterized in that it comprises a.

Description

Converter circuit for LED lamps {A Converter Circuit for LED Lamps}

The present invention relates to a converter circuit for an LED lamp, and more particularly to a converter circuit for an LED lamp of the multi-channel type.

An array type LED lamp, also called an LED fluorescent lamp, is formed by arranging a plurality of LEDs on a substrate to form a conventional fluorescent lamp, which is generally configured to mount one LED array to one power supply. Therefore, it is also configured to mount multiple LED arrays in one power supply, which is called a converter for multi-channel LED lamps.

The most common multi-channel power supply for LED lamps is Korean Patent No. 882734 (multi-channel inductor and LED backlight multi-drive circuit using the same) (first prior art) and Patent No. 1197934 (power supply for light emitting diode driving) Device) (second prior art).

As a power supply for a multi-channel LED lamp, the first prior art, as shown in Fig. 1, supplies power from each of the dependent coils 301, 302, 303 in which each LED array 214a, ... 214n is coupled in parallel. Each LED array is supplied with a constant current controller 216a, ... 216n for current control.

Also in the second prior art, as shown in Figure 2, each of the LED (LED1, ... LEDn) is a plurality of first secondary winding (L2-1, .. Inductively coupled in parallel to the primary winding (L1). It is powered from L2-n), and each LED has a current balance circuit.

However, since the first prior art and the second prior art naturally inductively couple the respective coils to each array, when either LED causes a problem, a problem arises in the current balance. Complex circuits for current regulation or balance control must be added to each branch line of the parallel circuits, and this requires a high cost, in particular, the use of expensive elements only by the secondary coil itself for power conversion.

On the other hand, as a power supply for a multi-channel type LED lamp, Korean Patent No.1568776 (Two-Channel Converter for LED Lighting Devices) (Third Prior Art) has been disclosed. Since the power is distributed in parallel to each LED module by the control circuit 130 and the power supply unit (trans and ADC), the power generation is improved from the first and second prior arts, but the PWM driving circuits 150 and 160 are still present for each LED module. Since it must be provided, it is still necessary to make an expensive payment. That is, at least one driving chip is required for the PWM driving circuits 150 and 160 (see FIGS. 4A and 4B of the third prior art), and for driving, which requires at least 1000 won for each channel. Chips and peripheral circuits are needed.

On the other hand, as a power supply device for a multi-channel type LED lamp, Korean Patent No. 1215982 (LED driving circuit) (the fourth conventional technology), Korean Patent No. 1217682 (internal component and load damage due to short circuit of LED load) Power supply device for LED lighting that provides a protection function (5th prior art) and Korean Patent Publication No. 2015-14592 (multi-channel LED driving circuit) (6th prior art) have been proposed.

Hereinafter, referring to the accompanying drawings, FIGS. 4 to 5, the parallel-connected constant voltage power supply apparatus according to the fourth to sixth prior arts will be described.

First, as shown in FIG. 4, the DC / DC converters 404, 406, and 408 for compensating for the current fluctuation are provided for each LED array LED1,. It must be connected. In other words, if a problem occurs in one LED array, a change in the current flowing to the branch line occurs, and thus, the current of the other branch line is also changed, which of course adversely affects the LED array of the other branch line. To compensate for this, an expensive DC / DC converter is required for each branch line.

As shown in FIG. 5, the fifth conventional technology requires expensive constant current control circuits 110a, 110b, and 110c for each of the LED arrays 300a, 300b, and 300c. As shown in FIG. 2, the constant current control operational amplifier 241 and the transistors Q1,... Qn are required for each array of the second LED strings 225.

Furthermore, since all of the third to sixth prior arts are based on constant voltage circuits to the last, the fundamental problem that it is difficult to maintain a complete balance against the change of current of parallel-connected branch lines or to bear a large additional cost. Will be carried.

Republic of Korea Patent No. 882734 (Multi-channel inductor and LED backlight multi-drive circuit using the same) Republic of Korea Patent No. 1197934 (Power Supply for Driving LED) Korean Patent No.1568776 (2-channel Converter for LED Lighting Device) Republic of Korea Patent No. 1215982 (LED Driving Circuit) Republic of Korea Patent No. 1217662 (Power Supply for LED Lighting that Provides Prevention of Damage to Internal Components and Loads by Shorting of LED Loads) Republic of Korea Patent Publication No. 2015-14592 (Multi-channel LED driving circuit)

The present invention, as a countermeasure for the problems of the first to the sixth prior art, a converter circuit for a multi-channel constant current type LED lamp, each LED array is connected in series, an extremely simple and minimized cost converter circuit It is to provide.

Converter circuit for an LED lamp according to an aspect of the present invention for achieving the above object, the filter unit for receiving and filtering commercial AC power; Rectifying unit for rectifying the AC power filtered by the filter unit; A constant current circuit unit 300 for controlling the current while inverting the DC power rectified by the rectifier; A voltage converter 400 which receives the DC power rectified by the rectifier and converts the voltage into the voltage of the lighting unit of the LED lamp while being inverted by the constant current circuit unit; A first lighting unit 500 and a second lighting unit 700 connected to the secondary side of the voltage conversion unit in series and lighting an LED lamp; A first bypass unit 600 and a second bypass unit 800 connected to the first lighting unit and the second lighting unit to bypass current flow when an abnormality occurs in each lighting unit; A feedback unit 900 connected to the voltage conversion unit to sense a current on an output side and feed back to the constant current circuit unit; The first stabilizing capacitor C12 is connected to both ends of an input side of the first lighting unit 500 to provide a stable voltage to the first LED lamp LED1, and to both ends of an input side of the second lighting unit 700. A second stabilizing capacitor C13 is connected to provide a stable voltage to the second LED lamp LED2, and the first bypass unit 600 and the second bypass unit 800 are switched in normal operation, respectively. In the off state, when the lamp malfunctions, each switching element is switched on to bypass the current without passing current to the lamp terminal, thereby protecting other lighting units and LED lamp elements while protecting the overall circuit diagram. In the first bypass unit 600, the upper power supply terminal of the first switching device is connected to the upper power supply terminal of the first lighting unit 500 through the first backflow prevention diode D6. Form a path and pass In the second bypass unit 800, the lower power supply terminal of the second switching element is connected to the lower power supply terminal of the second lighting unit 700 through the second backflow prevention diode D7 to form a bypass path. While the voltages of the first and second stabilizing capacitors of the lighting unit are configured to not flow back to the power supply terminals of each bypass unit, when an abnormality occurs in each lighting unit, the first and second stabilizing capacitors are charged more than necessary. The first and second switching elements are turned on, so that current is bypassed without flowing to the LED lamp.

Preferably, the voltage conversion unit 400, the primary side (T1-1) of the transformer is coupled to the rectifier 200, the secondary side (T1-3) is the upper power terminal of the first lighting unit 500 And a lower power supply terminal of the second lighting unit 700, a tertiary side T1-2 is connected to a feedback unit 900, and the primary side T1-1 of the transformer is simultaneously switched. It is also connected to the constant current circuit unit 300 through (Q1), the control signal of the switching transistor (Q1) is configured to come from the control IC (S-U1) of the constant current circuit unit 300, the constant current circuit unit 300 The control IC of S-U1 senses the sensing current of the primary side T1-1 of the transformer and the secondary side current sensed by the feedback circuit unit 900 to switch the switching transistor Q1 at regular intervals. Inverting by controlling, characterized in that to control the output current of the voltage converter in a kind of PWM method.

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More preferably, the first bypass unit 600 and the second bypass unit 800 each use thyristors Q2 and Q6 as switching elements, and the control terminal of the thyristor is stabilized through a reverse zener diode. When the abnormality of each lighting unit occurs, the stabilizing capacitor is charged more than necessary to cause breakdown of the zener diode, thereby turning on the thyristor, so that current does not flow into the LED lamp. It is characterized by passing.

Most preferably, each of the first bypass unit 600 and the second bypass unit 800 uses two or more thyristors Q2, Q2 '; Q6, Q6' as switching elements. do.

Also preferably, each of the first bypass unit 600 and the second bypass unit 800 may use transistors Q2 ″ and Q6 ″ as switching elements, and the control terminal of the transistor may include a reverse zener diode. Connected to the stabilizing capacitor, and when an abnormality occurs in each lighting unit, the stabilizing capacitor is charged more than necessary, causing breakdown of the zener diode, thereby turning on the transistor, so that current does not flow to the LED lamp. It is characterized by being bypassed without.

According to the converter circuit for LED lamps according to the present invention, as a constant current type LED lamp converter circuit in which each LED array is connected in series, it is possible to implement a multi-channel type, but only a single constant current circuit, and each array needs only a switching circuit The converter circuit for multi-channel LED lamps is extremely simple and minimizes cost.

Other objects and advantages of the present invention in addition to the above objects and effects will become apparent from the detailed description of the embodiments with reference to the accompanying drawings.

1 is a circuit diagram of a power supply for a multi-channel type LED lamp according to the first prior art.
2 is a circuit diagram of a power supply for a multi-channel type LED lamp according to the second prior art.
3 is a circuit diagram of a power supply for a multi-channel type LED lamp according to the third prior art.
4 is a circuit diagram of a power supply for a multi-channel LED lamp according to the fourth prior art.
5 is a circuit diagram of a power supply for a multi-channel type LED lamp according to the fifth prior art.
6 is a circuit diagram of a power supply for a multi-channel type LED lamp according to the sixth prior art.
7 is a block diagram of a converter circuit for an LED lamp according to an embodiment of the present invention.
8 is a converter circuit diagram for an LED lamp according to the first embodiment of the present invention.
9 is a converter circuit diagram for an LED lamp according to a second embodiment of the present invention.
10 is a converter circuit diagram for an LED lamp according to a third embodiment of the present invention.

Hereinafter, with reference to the accompanying drawings will be described in detail a preferred embodiment according to the present invention.

First, a converter circuit for a high voltage and high frequency LED lamp according to an exemplary embodiment of the present invention will be described with reference to FIGS. 7 to 10.

7 is a block diagram of a converter circuit for an LED lamp according to an embodiment of the present invention, FIG. 8 is a converter circuit diagram for an LED lamp according to a first embodiment of the present invention, and FIG. 9 is a second embodiment of the present invention. Fig. 10 is a circuit diagram of a converter for an LED lamp, and Fig. 10 is a converter circuit diagram for an LED lamp according to a third embodiment of the present invention.

The converter circuit for LED lamps of the preferred embodiment of the present invention, as shown in Figure 7, the filter unit 100 for receiving and filtering commercial AC power; Rectifying unit for rectifying the AC power filtered by the filter unit; A constant current circuit unit 300 for controlling the current while inverting the DC power rectified by the rectifier; A voltage converter 400 which receives the DC power rectified by the rectifier and converts the voltage into the voltage of the lighting unit of the LED lamp while being inverted by the constant current circuit unit; A first lighting unit 500 and a second lighting unit 700 connected to the secondary side of the voltage conversion unit in series and lighting an LED lamp; A first bypass unit 600 and a second bypass unit 800 connected to the first lighting unit and the second lighting unit to bypass current flow when an abnormality occurs in each lighting unit; A feedback unit 900 connected to the voltage conversion unit to sense a current on an output side and feed back to the constant current circuit unit; It consists of

In the voltage conversion unit 400, preferably, the primary side T1-1 of the transformer is coupled to the rectifying unit 200, and the secondary side T1-3 is an upper power supply terminal of the first lighting unit 500. And the lower power supply terminal of the second lighting unit 700, and the tertiary side T1-2 is connected to the feedback unit 900. At the same time, the primary side T1-1 of the transformer is simultaneously connected to the constant current circuit unit 300 through the switching transistor Q1, and again the control signal of the switching transistor Q1 is for controlling the constant current circuit unit 300. From the IC (S-U1), the control IC (S-U1) of the constant current circuit unit 300 senses the sensing current of the primary side (T1-1) of the transformer and the secondary side sensed through the feedback circuit unit 900. By sensing the current and switching the switching transistor Q1 at regular intervals, the inverter inverts it into a kind of triangular waveform and controls the output current of the voltage converter by a kind of PWM method.

Meanwhile, when the first lighting unit 500 and the second lighting unit 700 are described in detail, the first lighting unit 500 may be connected to the voltage conversion unit through the backflow prevention diode D6 and the capacitor C11. Connected to the upper power supply terminal of the secondary side T1-3 of the transformer of 400, while the lower power supply terminal of the second lighting unit 700 is also connected through the backflow prevention diode D7 and the capacitor C11A. The lower power terminal of the secondary side (T1-3) of the transformer of the voltage conversion unit 400, the lower power terminal of the first lighting unit 500 and the upper power terminal of the second lighting unit 700. This common connection is made. The inside of each lighting unit is composed of line filter (LF2, LF3) and LED lamps (LED1, LED2) terminals similar to the conventional LED lamp lighting unit, and the stabilizing capacitors (C12, C13) are connected in parallel with this. .

On the other hand, when the first bypass unit 600 and the second bypass unit 800 are described in detail, they are switched off in the normal operation, but are switched on when an abnormality occurs in the lamp. The short circuit allows bypass to be performed without current flowing to the lamp terminal, thereby protecting other lighting units and LED lamp elements while also protecting the entire circuit.

Detailed configurations of the first bypass unit 600 and the second bypass unit 800 will be described in detail with reference to FIGS. 8 through 10 for each embodiment.

First, in the first embodiment, as shown in FIG. 8, when the thyristor Q2 is used as the switching element, the thyristor Q2 is described with the first lighting unit 500 and the first bypass unit 600. An anode and a cathode of Q2) are respectively connected to the upper terminal and the lower terminal of the lighting unit to form a bypass path, and the control terminal of the thyristor Q2 is connected to the stabilizing capacitor C12 through the reverse zener diode ZD1. Lose. Of course, it is preferable that the backflow prevention diode D8 is connected. Thus, when an abnormality of the first lighting unit occurs, the stabilizing capacitor C12 will be charged more than necessary, which causes breakdown of the zener diode, causing the thyristor Q2 to turn on, so that the current It is bypassed without flowing to LED lamp. In this case, the breakdown voltage of the zener diode ZD1 may be set slightly higher than the voltage across the stabilizing capacitor C12 during normal operation. For example, when using an LED lamp (LED1) having a rated voltage of 36V, the constant current IC of the constant current circuit portion is 90V slightly higher than the output voltage of the voltage converter 400 is 72V (36V + 36V = 72V when using two LEDs) In this case, the maximum voltage at each end of each stabilizing capacitor C12 will be 45V, and it is preferable to use a zener diode ZD1 having a breakdown voltage of about 50V. Therefore, in the normal operation, the zener diode does not cause breakdown, and the bypass unit does not affect the normal operation at all, but when one side lighting unit is abnormal (opened), a voltage of 36 V in the lighting unit that is normally operated is generated. Since the lighting unit that has an abnormality (opening) naturally has a maximum voltage of 50V or more (54V), the zener diode connected to the lighting unit that has an abnormality (opening) causes breakdown, and the corresponding switching Bypassing occurs as the device turns on. The resistor R16 and the capacitor C14 of the thyristor Q2 control stage are a kind of time constant circuit.

On the other hand, the second lighting unit 700 and the second bypass unit 800, the anode and the cathode of the thyristor (Q6) is connected to the upper terminal and the lower terminal of the second lighting unit, respectively, to form a bypass path, The control stage of the thyristor Q6 is connected to the stabilizing capacitor C13 through a reverse zener diode ZD2, and other more detailed circuits are also used in the case of the first lighting unit 500 and the first bypass unit 600. similar.

Now, a second embodiment of the present invention will be described in detail with reference to FIG. 9, wherein the switching element is composed of two or more thyristors Q2 and Q2 ', and a second thyristor in parallel with the first thyristor Q2. By arranging (Q2 '), the stability is further increased, and the cost is also lowered by lowering the capacity of each thyristor.

Finally, when the third embodiment of the present invention is described in detail with reference to FIG. 10, the switching element is configured by a transistor Q2 ″, but in this case, a diode must be added due to the bidirectionality of the transistor. There is this.

Now, the operation of the converter circuit for LED lamps according to the present invention will be described. In normal operation, " the upper terminal of the voltage conversion part secondary side (T1-3)-diode and capacitor (D6, C11)-second line filter (LF2)-first LED lamp (LED1)-second line filter (LF2)-third line filter (LF3)-second LED lamp (LED2)-third line filter (LF3)-diode and capacitor (D7, C11A)-form a multi-channel path to the lower terminal of the voltage conversion part secondary side (T1-3).

However, if an abnormality occurs in one LED lamp or lighting unit, and a current change occurs, in order to prevent adverse effects on other lighting units in the prior art, power supply or PWM control may be independently performed for each channel, Alternatively, since the current stabilization circuit must be configured for each channel while adopting the constant voltage method of configuring the channels in parallel, the manufacturing cost is inevitably increased due to the complicated structure, but in the present invention, the constant current is formed by configuring each channel in series. By adopting a method, but by providing a bypass circuit in case of a problem in each channel to solve the problems of the prior art with a simple configuration, for example, the first LED lamp (LED1) or the first lighting unit ( If an abnormality occurs in 500) and a current change occurs, this may cause overcharge of the stabilizing capacitor C12 of the first lighting unit. 1 The bypass circuit caused by the turn-on of the first switching element such as the first thyristor Q2 is activated due to the breakdown of the zener diode ZD1, resulting in the " high-terminal terminal of the voltage conversion part secondary side T1-3- 1 Switching element Q2-Third line filter LF3-Second LED lamp LED2-Third line filter LF3-Diodes and capacitors D7 and C11A-Voltage conversion part secondary side (T1-3) Channel path to the lower terminal ". That is, the second lighting unit may be normally operated without any influence.

Also, when an abnormality occurs in the second LED lamp LED2 or the second lighting unit 700, and a current change occurs, this may cause overcharging of the stabilizing capacitor C13 of the second lighting unit and brake of the second zener diode ZD2. By operating the bypass circuit due to the turn-on of the second switching element such as the second thyristor (Q6) due to the down, the "terminal of the voltage converter secondary side (T1-3) upper terminal-diode and capacitor (D6, C11)- Form a channel path to the second line filter LF2-the first LED lamp LED1-the second line filter LF2-the second switching element Q6-the lower terminal of the voltage conversion part secondary side T1-3. As a result, the first lighting unit may be normally operated without being affected.

Although the present invention has been described above according to an embodiment of the present invention, such as having three or more lighting units, a person having ordinary knowledge in the technical field to which the present invention belongs does not depart from the technical spirit of the present invention. Modifications and variations in the belonging to the present invention is obvious.

DESCRIPTION OF SYMBOLS 100 Filter part 200 Rectification part 300 Constant current circuit part 400 Voltage conversion part
500: first lighting unit 600: first bypass unit
700: second lighting unit 800: second bypass unit
900: feedback unit

Claims (6)

A filter unit 100 for receiving and filtering commercial AC power;
Rectifying unit for rectifying the AC power filtered by the filter unit;
A constant current circuit unit 300 for controlling the current while inverting the DC power rectified by the rectifier;
A voltage converter 400 which receives the DC power rectified by the rectifier and converts the voltage into the voltage of the lighting unit of the LED lamp while being inverted by the constant current circuit unit;
A first lighting unit 500 and a second lighting unit 700 connected to the secondary side of the voltage conversion unit in series and lighting an LED lamp;
A first bypass unit 600 and a second bypass unit 800 connected to the first lighting unit and the second lighting unit to bypass current flow when an abnormality occurs in each lighting unit; And
A feedback unit 900 connected to the voltage conversion unit for sensing a current on an output side and feeding back to the constant current circuit unit;
Including;
A first stabilizing capacitor C12 is connected to both ends of an input side of the first lighting unit 500 to provide a stable voltage to the first LED lamp LED1, and a second stabilizing capacitor at both ends of an input side of the second lighting unit 700. (C13) is connected to provide a stable voltage to the second LED lamp (LED2),
Each of the first bypass unit 600 and the second bypass unit 800 is switched off in the normal operation, and when the lamp malfunctions, each switching element is switched on so that the lamp By bypassing without current flowing through the terminal, it protects the whole circuit and protects other lighting parts and LED lamp elements.
In the first bypass unit 600, an upper power supply terminal of the first switching element is connected to an upper power supply terminal of the first lighting unit 500 through a first backflow prevention diode D6 to form a bypass path. In the second bypass unit 800, a lower power supply terminal of the second switching element is connected to a lower power supply terminal of the second lighting unit 700 through a second backflow prevention diode D7 to form a bypass path. While the voltages of the first and second stabilizing capacitors of each lighting unit are configured not to flow back to the power supply terminals of each bypass unit, when an abnormality occurs in each lighting unit, the first and second stabilizing capacitors are charged more than necessary. And the first and second switching elements are turned on, so that current is bypassed without flowing into the LED lamp. The method of claim 1,
In the voltage converter 400, the primary side T1-1 of the transformer is coupled to the rectifier 200, and the secondary side T1-3 is turned on the upper power supply terminal and the second lit of the first lighting unit 500. It is connected to the lower power supply terminal of the unit 700, the tertiary side (T1-2) is connected to the feedback unit 900, the primary side (T1-1) of the transformer simultaneously switches the switching transistor (Q1). It is also connected to the constant current circuit unit 300, the control signal of the switching transistor (Q1) is configured to come from the control IC (S-U1) of the constant current circuit unit 300, the control IC of the constant current circuit unit 300 ( S-U1 detects the sensing current of the primary side T1-1 of the transformer and the secondary side current sensed by the feedback circuit unit 900, and switches the switching transistor Q1 at a predetermined interval to invert. And controlling the output current of the voltage conversion unit by a kind of PWM method. Emitter circuit. delete The method of claim 1,
The first bypass unit 600 and the second bypass unit 800 each use a thyristor (Q2; Q6) as a switching element, the control terminal of the thyristor is connected to the stabilizing capacitor through a reverse zener diode When an abnormality occurs in each lighting unit, the stabilizing capacitor is charged more than necessary to cause breakdown of the zener diode to turn on the thyristor, so that current is bypassed without flowing to the LED lamp. Converter circuit for two-channel LED lamps. The method of claim 4, wherein
Each of the first bypass unit 600 and the second bypass unit 800 uses two or more thyristors Q2, Q2 '; Q6 and Q6' as switching elements, respectively. Converter circuit for lamps. The method of claim 1,
The first bypass unit 600 and the second bypass unit 800 each use a transistor Q2 ";Q6" as a switching element, and the control terminal of the transistor is connected to the stabilizing capacitor through a reverse zener diode. When an abnormality occurs in each lighting unit, the stabilizing capacitor is charged more than necessary to cause breakdown of the zener diode to turn on the transistor, so that current is bypassed without flowing into the LED lamp. Converter circuit for two-channel type LED lamp, characterized in that.

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