KR101254712B1 - Power control apparatus of light emitting diode lamp for sectional lighting - Google Patents

Abstract

The split lighting LED bulb power supply control apparatus according to the present invention includes an input terminal connected to any one power line of an alternating current applied from an AC filter unit, and a switch formed of an application terminal 1, 2, or 3 that can be connected to the input terminal, respectively. A lighting selection unit; A reverse current blocking unit configured to conduct an alternating current applied from the lighting selection unit and block a reverse current to the power supply line connected to the applying terminal 1; A voltage regulating unit comprising a voltage regulating unit 1 connected to an application terminal 2 and a voltage regulating unit 2 connected to an application terminal 2 to control voltage drop by inputting an alternating current applied from the reverse current blocking unit; AC / DC converter 1 and connected to the output line of the voltage regulator 1 and voltage regulator 2 and connected to the other line of the input power, respectively, to convert AC current into DC current, and constitute a bridge rectifier circuit 1 and An AC / DC converter configured of an AC / DC converter 2; Input the DC current applied from each of AC / DC converter 1 and AC / DC converter 2, and to silicon controlled rectifiers (SCR1, SCR2) connected in series with the power line and the diacs (TD1, TD2) connected to the input power. A low voltage light prevention unit comprising a low voltage light prevention unit 1 and a low voltage light prevention unit 2 formed; A lighting unit comprising a plurality of LED arrays connected to the low voltage light preventing unit 1 and the low voltage light preventing unit 2, respectively; According to the power input (ON) of the application terminal 3, the LED array is fully lit or divided cross lit, and the energy is saved.

Description

Power Control Apparatus of Light Emitting Diode Lamp for Sectional Lighting

The present invention relates to a light emitting diode (LED) light bulb power supply control device, and in particular, a plurality of LED arrays are configured to be divided according to the power supply line of the power source, the divided LED array is configured to cross arrangement The present invention relates to a divided lighting LED bulb power supply control device which can save energy by causing the LED array to be divided and cross lit when necessary.

Currently, discharge lamps such as fluorescent lamps, incandescent lamps and halogen lamps are used as light sources for indoor lighting in homes and offices. Since the discharge lamp has a high driving voltage, the energy consumption is large due to the boost of the power, and when discharged, the discharge lamp discharges discharge gas such as mercury, which is harmful to the human body or the environment.

In particular, in the European Union, heavy metals such as lead, mercury, cadmium, hexavalent chromium (Cr6 +), and hazardous substances such as polybrominated diphenyl ether (PBB) and polybrominated diphenyl ether (PBDE) Restoring the use of Hazardous Substances (RoHS) and the Waste Electrical and Electronic Equipment Directive (WEEE) that require producers to bear the costs of recycling waste electrical and electronic products. The law was enacted and has been in effect since July 1, 2006.

Accordingly, the necessity of research and development of a new luminaire that can replace a luminaire such as a fluorescent lamp currently used is emerging.

In addition, as the technology related to LED (Light Emitting Diode) is rapidly developed, white LEDs emitting white light by using blue LEDs and phosphors have emerged. Small size, low power consumption, semi-permanent life, no harmful emissions such as ultraviolet light, no environmentally friendly lighting source without mercury and discharge gas. have.

Looking at the LED array configuration of the LED lighting ballast circuit configured in the prior art Patent Publication No. 10-1040833 (2011. 06. 14.), as shown in FIG.

A current limiting means consisting of a capacitor (C1) and a resistor (R1) connected in parallel to charge and discharge at 60HZ period of AC power supply (AC 220V) and regulate the LED use current, and the AC voltage through the current limiting means to DC voltage. In the LED lighting ballast circuit provided with the rectifying bridge diode (BD), a capacitor (C3) and a resistor (R3) are connected in series between both ends of the bridge diode (BD), and the bridge diode (BD) The positive terminal connects the silicon-controlled rectifier (SCR) in parallel to a resistor (R5) and a capacitor (C4) connected in series to form a surge upserver circuit to protect the LED from surges generated when power is turned on and off. LED arrays DA1, DA2 .... DAn having a plurality of forward LEDs connected in series are connected to an output terminal of the surge upserver circuit, and a plurality of reverse LEDs are connected to a negative terminal of the bridge diode BD. end The series connected LED arrays DA11, DA12 .... DA1n are connected to each other.

Looking at the configuration of the LED lighting of the RC power control device for a large-power LED bulb configured in the patent application No. 10-2011-0095132 (2011. 09. 21) of the present inventors as another prior art,

An RC power supply control apparatus for a high power LED bulb, comprising: an AC filter unit for protecting a circuit from an instantaneous overvoltage or surge current of an alternating current applied from a power source for supplying the LED bulb; A voltage regulating unit comprising a plurality of individual voltage regulating units configured in parallel to input and lower the voltage with respect to the input alternating current by inputting the alternating current applied from the AC filter unit; An AC / DC converter comprising a plurality of individual AC / DC converters connected to one line of the individual voltage controller and an input power and converting the AC currents applied from the individual voltage controllers into DC currents; A current controller configured of a plurality of individual current controllers for limiting the direct current applied from each of the individual AC / DC converters to a current suitable for each LED light source; The voltage control unit is composed of n RC power circuits are configured in n parallel to minimize the variation of the commercial input voltage of the large power LED light source supplied from the power source to emit a plurality of large power LEDs.

The prior arts have a problem in that when all LED arrays or LEDs are connected to one power line of a switch and power is input (ON), all the LED arrays or LEDs are turned on at the same time so that they are not cross lit or divided lit.

In addition, the conventional technologies have a problem in that all LED arrays or LEDs are turned on at the same time when the power is input (ON), thereby saving energy.

In addition, the prior art is that the LED array is composed of a predetermined region or a certain direction only when a problem occurs in a particular LED is not the entire LED array connected to the problem is connected to the LED is illuminated in a certain region or a certain direction There is a problem that can not be.

The present invention was created in order to solve the above problems, and configures the terminal 1, the terminal 2 and the terminal 3 to the input switch to configure a plurality of LED arrays connected to the terminal and alternately arranged in the terminal 1 When the power is turned on, all LED array's LEDs are turned on.When power is turned on, the LEDs of the LED array connected to the low voltage lighting prevention part 1 are turned on. ON), only the LED of the LED array connected to the low voltage lighting prevention unit 2 is turned on, but the LED array connected to the low voltage lighting prevention unit 1 and the LED array connected to the low voltage lighting prevention unit 1 are arranged to cross each other. Split lighting LED bulb power control that saves energy by setting LED array to split cross lighting according to power input of ON In providing a device.

In the LED lighting power control device is divided LED lighting power control device comprising an AC filter unit and the LED array, the input terminal connected to any one of the AC line of the AC current applied from the AC filter unit, A lighting selection unit comprising a switch formed of an application terminal 1, an application terminal 2, and an application terminal 3 that can be connected to the input terminal, respectively; A reverse current blocking unit configured to conduct an alternating current applied by the lighting selection unit and block a reverse current to a power supply line connected to an application terminal 1; Input the alternating current applied from the reverse current blocking unit, respectively, and adjusts the voltage to the input alternating current, and is configured in parallel, the voltage adjusting unit 1 connected to the applying terminal 2 and the voltage adjusting unit connected to the applying terminal 3 A voltage adjusting unit consisting of; Connected to each of the output line of the voltage regulator 1 and the voltage regulator 2 and connected to the other one of the input power source, respectively, converts AC current into DC current, and parallel AC / DC conversion consisting of a bridge rectifier circuit An AC / DC conversion unit comprising an auxiliary unit 1 and an AC / DC conversion unit 2; Silicon controlled rectifiers (SCR1, SCR2) connected in series with a DC current input from each of the AC / DC converter 1 and AC / DC converter 2, and a power supply line, and diacs (TD1, TD2) connected to an input power source. A low voltage light prevention unit comprising a low voltage light prevention unit 1 and a low voltage light prevention unit 2 formed of (Diac: a phase control trigger element); The lighting unit includes a plurality of LED arrays connected to the low voltage light preventing unit 1 and the low voltage light preventing unit 2, respectively.

In addition, the reverse current blocking unit of the present invention forms a diode (D31) to the power supply line of the application terminal 1 to connect the power supply line configured with the diode (D31) to the power supply line of the application terminal 2, the power supply configured with the diode (D31) The diode D32 is formed on the extended power line by extending the line, and the extended power line including the diode D32 is connected to the power line of the application terminal 3.

 In addition, the present invention, the voltage adjusting unit 1 is composed of a capacitor (C1) configured in the power supply line connected to the application terminal 2, and a resistor (R1) for discharging the capacitor (C1) in series with the power supply line; The voltage adjusting unit 2 includes a capacitor C2 formed on a power supply line connected to an application terminal 3, and a resistor R6 for discharging the capacitor C2 in series with the power supply line.

In addition, the present invention, the low voltage light prevention unit 1 is a capacitor (C3) connected in parallel to the positive electrode and the negative electrode, a resistor (R2) connected in parallel to the negative electrode and the positive electrode of the AC / DC converter 1, and a resistor (R2) ) Is connected in series, but connected in parallel to the negative electrode and the positive electrode (C4), connected between the resistor (R2) and the capacitor (C4), the diaak (TD1), the diaak (TD1) and silicon controlled rectifier ( A resistor R3 connected at the same time with the gate of SCR1 connected in series and connected to the cathode of the AC / DC converter; The low voltage light prevention unit 2 is connected in series with a capacitor (C5) connected in parallel to the positive electrode and the negative electrode, a resistor (R7) connected in parallel to the negative electrode and the positive electrode of the AC / DC conversion unit 2, and a resistor (R7) The capacitor (C6) connected in parallel to the cathode and the anode, and the gate of the diaak (TD2), the diaak (TD2) and the silicon control rectifier (SCR2) connected between the resistor (R7) and the capacitor (C6) At the same time, it consists of a resistor (R8) connected in series and connected to the cathode of the AC / DC converter.

In addition, the LED array of the present invention is composed of a plurality of series LED arrays each connected to the low voltage light prevention unit 1 and the low voltage light prevention unit 2, the plurality of LEDs are configured.

In addition, the present invention, the low voltage light prevention unit 1 is configured in the rear of the resistor (R5) and the resistor (R5) connected in series to the rear of the silicon control rectifier (SCR1) and the positive and negative poles of the AC / DC converter 1 A resistor R4 connected in parallel is further configured; The low voltage lighting prevention unit 1 includes a resistor R10 connected in series to the rear of the silicon control rectifier SCR2 and a resistor connected to the positive and negative poles of the AC / DC converter 2 in parallel with the resistor R10. R9) is further configured.

In addition, the present invention is configured such that the LED array connected to the low voltage light prevention unit 1 and the LED array connected to the low voltage light prevention unit 2 are arranged cross.

The split lighting LED bulb power supply control apparatus according to the present invention has the effect that the LED array is fully lit or divided cross lighting by the power input (ON) according to the applied terminal 1, the applied terminal 2 and the applied terminal 3.

In addition, the present invention is configured such that the LED array connected to the low voltage light prevention unit 1 and the LED array connected to the low voltage light prevention unit 2 are arranged to cross each other when the power is input (ON) to the terminal 2 or the terminal 3 applied. The arrays are not lit but jumped one by one, and the LED array is cross lit to save energy depending on the lighting environment.

In addition, the present invention has the effect that the LED array is cross-lighted so that the LED array connected to the terminal 2 and the terminal 3 is cross-configured, even if a problem occurs in any one of the terminal is illuminated in a predetermined region or a certain direction.

In addition, according to the present invention, the resistors R5 and R10 limit the current applied from the silicon controlled rectifiers SCR1 and SCR2 to a current value suitable for turning on the LED, and the resistors R4 and R9 direct the overcurrent. Bypassing the negative part of the current, there is an effect that the overcurrent is not transferred to the LED.

1: LED ballast circuit diagram of the LED bulb of the prior art.
2 is a block diagram of a split lit LED bulb power supply control device of the present invention;
3 is a circuit diagram of a divided lighting LED bulb power supply controller of the present invention.
4 is a state diagram in which all LED arrays are turned on while a power source is connected to the terminal 1 of the present invention.
5 is a state diagram in which the LED array is cross lit in the state that the power supply is connected to the terminal 2 of the present invention.
Figure 6 is a state diagram in which the LED array is cross lit in the state that the power supply is connected to the terminal 3 of the present invention.

2 is a block diagram of a split lighting LED bulb power control device of the present invention of FIG. 2 attached to a configuration and operation according to an embodiment of the present invention, and a circuit diagram of the split lighting LED bulb power control device of the present invention of FIG. 4 is a state diagram in which all the LED arrays are turned on while the power supply is connected to the terminal 1 of the present invention, and FIG. 5 is a state diagram in which the LED arrays are cross lit in the state where power is connected to the terminal 2 of the present invention, and FIG. Referring to the state diagram in which the LED array is cross lit in the state that the power supply is connected to the terminal 3 of the present invention will be described in more detail as follows.

In the present invention, an LED array power control device comprising an AC filter unit (1) LED array includes a lighting selector (2), a reverse current interrupter (3), a voltage regulator (4), and an AC. / DC conversion section 5, low voltage lighting prevention section 6 and lighting section (7).

The AC filter unit 1 includes an overvoltage protection surge absorber (SA1) configured in parallel to an input AC power, and an overvoltage protection configured in parallel to an AC power input configured behind the surge absorber SA1. It is composed of varistors (VR1).

The AC filter unit 1 is composed of input protection elements of a circuit of a divided lighting LED bulb power control device, and an overcurrent protection fuse FUSE1 configured at any one input line IN1 of an AC power source, and the An overvoltage protection surge absorber SA1 configured in parallel to the AC power sources IN1 and IN2 that are configured behind the fuse FUSE1 and an AC power source IN1 that is configured and input behind the surge absorber SA1. And an overvoltage protection varistor VR1 configured in parallel to IN2).

The AC filter unit 1 attenuates and absorbs an instantaneous overvoltage or surge current generated from an alternating current applied from a power source to supply a plurality of LED arrays that are turned on when current flows to generate light. Protect the circuit of the bulb power control.

The surge absorber SA1 attenuates the initial instantaneous overvoltage or surge current among the instantaneous overvoltage or surge current applied from the power supply, and the varistor VR1 receives the late instantaneous overvoltage or surge current from the instantaneous overvoltage or surge current applied from the power supply. Absorbs and protects the circuit of the LED bulb power supply control by split lighting.

The surge current is a very short time, but the waveform and amplitude change according to the flow time. Initially, the waveform is high, i.e., the peak is high and the amplitude is small, but as time goes by, the waveform is low and the amplitude is large, and the current component becomes larger toward later stages.

The surge current inputted by the surge absorber SA1 is first attenuated, and the varistor VR1 absorbs the surge current flowing without being attenuated by the surge absorber SA1.

Among the surge currents inputted to the AC filter unit 1, the initial surge current, i.e., the surge current having a high peak and short period, is attenuated by the surge absorber SA1, and the surge current that has a low late peak and a longer period is used. The varistor VR1 absorbs and completely attenuates and absorbs the surge current input to the AC filter unit 1.

The surge absorber SA1 causes the current to flow through the surge absorber SA1 itself when the AC power sources IN1 and IN2 input from the power supply exceed a predetermined voltage, thereby causing excessive voltage drop in the load. Protects the load by preventing it from rising.

In other words, when a surge current enters the split lighting LED bulb power controller, a surge current flows through a passage having low impedance, that is, a surge absorber SA1, that is, a bypass is itself. To prevent circuit failure.

The varistor VR1 does not attenuate the surge absorber SA1 and when the AC power inputs IN1 and IN2 that flow into the input exceeds a predetermined voltage, the resistance is lowered to flow a current, that is, by-pass by itself. To prevent circuit failure.

That is, the varistor VR1 is configured to suppress the instantaneous voltage and discharge the high voltage current, and exhibits a high resistance value up to a predetermined voltage, but when the voltage exceeds the predetermined voltage, the resistance suddenly decreases to flow a large current to input the AC power supply IN1 and IN2. Protect the circuit from momentary overvoltage or surge current.

The fuse FUSE1 is configured to short-circuit to protect the circuit when any one of the allowable voltage or the allowable current exceeds the allowable value, and configure the fuse FUSE1 at the rear of the surge absorber SA1 or the varistor VR1. However, in this case, since the surge absorber SA1 and the varistor VR1 are difficult to protect even if the fuse FUSE1 is shorted, it is necessary to configure the fuse FUSE1 in front of the surge absorber SA1 and the varistor VR1. desirable.

The varistor VR1 may be any one of a symmetrical varistor whose resistance is determined by the magnitude of a voltage and an asymmetrical varistor whose polarity depends on the polarity of the applied voltage, irrespective of the polarity of the applied voltage.

The lighting selector 2 is an input terminal connected to any one power line of an alternating current applied from the AC filter unit 1, that is, a power line including a fuse FUSE1, and is applied to each of the input terminals. It consists of a switch formed of a terminal 1, an applying terminal 2 and an applying terminal 3.

By the external operation of the switch, the input terminal is in contact with any one of the applying terminal 1, the applying terminal 2, the applying terminal 3.

As an example, when the user presses the switch button once to turn on the LED arrays 7-11, 7-12, 7-21, and 7-22, the input terminal is contacted to the terminal 1 to supply power. When the terminal is pressed twice, the input terminal contacts the terminal 2 when it is pressed twice, and the power is turned on to the terminal 2, and when pressed three times, the terminal contacts the terminal 3 and the power is turned on to the terminal 3 .

In other words, when the user selects an application terminal by means of a switch button, the user selects a lighting method of the LED arrays 7-11, 7-12, 7-21, and 7-22 described below. 7-11, 7-12, 7-21, 7-22) can be turned on or over.

The reverse current blocking unit 3 includes diodes D31 and D32 which conduct an alternating current applied by the lighting selection unit 2 and block a reverse current to a power supply line connected to the applying terminal 1.

The reverse current blocking unit 3 forms a diode D31 to the power supply line of the application terminal 1, connects the power supply line configured with the diode D31 to the power supply line of the application terminal 2, and the power supply line configured with the diode D31. Extends to form a diode D32 in the extended power supply line, and the extended power supply line in which the diode D32 is configured is connected to the power supply line of the applying terminal 3.

The diodes D31 and D32 flow current in the forward direction but block the current in the reverse direction. Therefore, when the power supply is turned ON, the diodes D31 and D32 are forwarded in the forward direction. The current flows through the power supply line of the applying terminal 2 and the power supply line of the applying terminal 3.

 When power is applied to the applying terminal 2 (ON), the current is blocked to flow in the reverse direction by the diode (D31) so that no current flows through the power supply line of the application terminal 1 and the power supply line of the application terminal 3, When the power is turned on, current is blocked from flowing in the reverse direction by the diode D32 so that no current flows through the power supply line of the application terminal 1 and the power supply line of the application terminal 2.

The reverse current does not flow to the application terminal 1 even when the power is input (ON) to the application terminal 2 or the application terminal 3, the LED array (7-11) connected to the application terminal 2 when the power supply is turned on (ON). 7-12) and the LED arrays 7-21 and 7-22 connected to the applying terminal 3 are all turned on, and when the power supply is turned on to the applying terminal 2, the LED arrays 7-11 and 7 connected to the applying terminal 2 are If only -12) is turned on and power is applied to the application terminal 3, only the LED arrays 7-11 and 7-12 connected to the application terminal 3 are turned on to enable full lighting and split lighting.

The voltage regulator 4 is configured to be in parallel with each other by inputting the alternating current applied from the reverse current blocking unit 3 to drop the voltage with respect to the input alternating current, the voltage adjusting unit 1 ( 4-1) and the voltage adjusting unit 2 (4-2) connected to the applying terminal 3.

Each of the voltage regulator 1 (4-1) and the voltage regulator 2 (4-2) inputs an alternating current applied from the reverse current blocking unit 3 to adjust the voltage drop with respect to the input alternating current.

The voltage adjusting unit 1 (4-1) is configured in series with a power supply line connected to an application terminal 2 and a condenser (C1) in series, and is connected in series with the power supply line connected to the application terminal 2 and discharges the capacitor (C1). It consists of a resistor (R1: Resistance) and consists of an RC power circuit that generates a power supply voltage for the LED to operate properly by the capacitor (C1).

The resistor R1 becomes conductive when the AC current charged in the capacitor C1 becomes a predetermined value or more, and connects + and-of the capacitor C1, and the capacitor C1 becomes conductive so that a current flows and the capacitor C1 flows. The electric current charged in the discharge will discharge.

The voltage adjusting unit 1 (4-1) is a component for dropping an AC input voltage with the capacitor C1 as a main axis and can adjust a voltage value falling according to the capacity of the capacitor. It can be configured as a parallel capacitor (eg C1-₁, C1-₂ .... C1-n).

The alternating current applied to the voltage regulating unit 1 (4-1) is stored and charged in the capacitor C1, and the surplus current remaining after being charged in the capacitor C1 is a plurality of parallel capacitors C1-₁ and C1-₂. ... stored in C1-n) and charged.

That is, the alternating current applied to the voltage regulator 4 is sequentially charged in the order of condenser C1-> condenser C1-C ... condenser C1-n, and is charged in condenser C1. Since there is no way for the alternating current to flow, the alternating current does not flow.

The voltage adjusting unit 2 (4-2) is configured in series with a power supply line connected to an application terminal 3 and a condenser (C2) in series with the power supply line connected to the application terminal 3 and discharges the capacitor (C2). It consists of a resistor (R6: Resistance) and consists of an RC power circuit that generates a power supply voltage for the LED to operate properly by the capacitor (C2).

The resistor R6 becomes conductive when the AC current charged in the capacitor C2 becomes a predetermined value or more, and connects + and-of the capacitor C2 while the capacitor C2 becomes conductive so that the current flows and the capacitor C2 flows. The electric current charged in the discharge will discharge.

The voltage adjusting unit 2 (4-2) is a component for dropping an AC input voltage with a capacitor C2 as a main axis, and can adjust a voltage value falling according to the capacity of the capacitor. It can consist of parallel capacitors (eg C2-₁, C2-₂ .... C2-n).

The alternating current applied to the voltage regulator 2 (4-2) is stored and charged in the capacitor (C2), and the excess current remaining after being charged in the capacitor (C2) is a plurality of parallel capacitors (C2-₁, C2-₂) ... stored in C2-n).

That is, the alternating current applied to the voltage adjusting unit 4 is sequentially charged in the order of the capacitor (C2) → capacitor (C2-₁) ... capacitor (C2-n) and is charged to the capacitor (C2) Since there is no way for the alternating current to flow, the alternating current does not flow.

The AC / DC converter 5 is composed of an AC / DC converter 1 (5-1) and an AC / DC converter 2 (5-2), and the AC / DC converter 1 (5-1). And AC / DC converter 2 (5-2) are connected to the output lines of voltage regulator 1 (4-1) and voltage regulator 2 (4-2), respectively, and the other of AC input power IN1, IN2. It is connected to the line IN2 and converts the AC current into the DC current, respectively, and consists of a bridge rectifier circuit.

The AC / DC converter 1 (5-1) inputs an alternating current applied from the voltage regulator 1 (4-1) to convert it into a direct current, and rectifier diodes (D1, D2, D3, and D4: Diodes). It is composed of a bridge rectifier circuit composed of (Bridge Rectifier).

The AC / DC converter 1 (5-1) converts an alternating current dropped from the voltage regulator 1 (4-1) into a direct current, and the bridge rectifier circuit includes a cathode of the diode D1 and the diode D3. The (Cathode) part is composed of the + part of the direct current and is connected to the LEDs (LED1 to LED20) of the LED arrays 7-11 and 7-12.

The AC / DC converter 2 (5-2) inputs an alternating current applied from the voltage regulator 2 (4-2) to convert it into a direct current, and rectifies diodes (D5, D6, D7, and D8: Diodes). It is composed of a bridge rectifier circuit composed of (Bridge Rectifier).

The AC / DC converter 2 (5-2) converts the alternating current dropped from the voltage regulator 2 (4-2) into a direct current, and the bridge rectifier circuit includes a cathode of the diode D5 and the diode D7. The (Cathode) part is composed of the + part of the DC current and is connected to the LEDs (LED21 to LED40) of the LED arrays 7-21 and 7-22.

The AC / DC converter 1 (5-1) and the AC / DC converter 2 (5-1) use a bridge diode in the voltage regulator 1 (4-1) and the voltage regulator 2 (4-2). The supplied alternating current (AC) is converted into direct current (DC) and output.

That is, even if the supply current supplied to the AC / DC converter 1 (5-1) and AC / DC converter 2 (5-1) is direct current or alternating current, the current output by the bridge rectifier circuit is direct current. Even if the polarity of DC is reversed due to carelessness of the user, the current output through the bridge rectifier circuit has DC.

The low voltage light prevention unit 6 is composed of a low voltage light prevention unit 1 (6-1) and a low voltage light prevention unit 2 (6-2), the low voltage light prevention unit 1 (6-1) and the low voltage light prevention unit 2 (6-2) inputs a DC current applied from each of the AC / DC converter 1 (5-1) and the AC / DC converter 2 (5-2), respectively, and is a silicon controlled rectifier connected in series with the power line ( SCR1 and SCR2 and diaacs TD1 and TD2 (Diac: trigger elements for phase control) connected to an input power source.

The low voltage light prevention unit 6 is configured between the AC / DC converter 5 and the lighting unit 7, that is, the AC / DC converter 5 and the LED arrays 7-11, 7-12, and 7-21. , 7-22) inputs a DC current applied from the AC / DC converter 5, and is connected in parallel to a silicon controlled rectifier and an input power source connected in series to any one power line (Diac : It consists of power circuit using phase control trigger element to prevent LEDs (LED1 ~ LED40) from being lighted up minutely and causing half- fire phenomenon.

The low voltage light prevention part 1 (6-1) is a capacitor (C3) connected in parallel to the positive electrode and the negative electrode, and a resistor (R2) connected in parallel to the negative electrode and the positive electrode of the AC / DC converter 1 (5-1) And a capacitor (C4) connected in series with a resistor (R2) but connected in parallel to a cathode and a cathode, a diaak (TD1) and a diaak (TD1) connected between a resistor (R2) and a capacitor (C4). And a gate of the silicon controlled rectifier (SCR1) are connected in series at the same time and a resistor (R3) connected to the cathode of the AC / DC converter.

The low voltage lighting prevention part 1 (6-1) is configured between the AC / DC conversion part 1 (5-1) and the lighting part 7, that is, the AC / DC conversion part 1 (5-1) and the LED array 7-. 11, 7-12, and input the DC current applied from the AC / DC converter 1 (5-1), and parallel to the silicon control rectifier (SCR1) and the input power source connected in series to any one power line. It consists of a power circuit using a diaac (Diac: phase control trigger element: TD1) connected to the LED to prevent the LEDs (LED1 ~ LED20) from being lighted up and the half-burning phenomenon.

The silicon controlled rectifier SCR1 is connected in series with the anode of the AC / DC converter 1 (5-1), and the diaak TD1 is connected to the gate of the silicon controlled rectifier SCR1, while the AC / DC converter 1 ( 5-1) is connected in parallel with the anode and the cathode, and the diaak (TD1) sends a trigger signal to the gate of the silicon controlled rectifier (SCR1) so that the current flows to the gate of the silicon controlled rectifier (SCR1). It is conducting.

The silicon controlled rectifier (SCR1) acts to open the gate when the anode and cathode are forward while current flows in the forward direction when the cathode and the gate turn-on voltage are applied to the gate. In this case, the current flows in the forward direction until the positive and negative voltages are lost or the reverse voltage is applied.

When the silicon control rectifier SCR1 is turned on by a gate pulse, that is, a trigger pulse, it can be regarded as a switch-on action by maintaining a conduction state. (Turn off) method should disconnect the power.

The low voltage lighting prevention unit 1 (6-1) simultaneously connects the gates of the diaak (TD1) and the silicon controlled rectifier (SCR1) in series, and is connected to a negative electrode of the AC / DC converter 1 (5-1) 3. A resistor R3 is configured, and the resistor 3 R3 bypasses the trigger signal to the cathode while suppressing and controlling the operation of the diaak TD1.

The low voltage light prevention part 1 (6-1) is composed of a resistor (R2) connected in parallel to the cathode and the anode of the AC / DC converter 1 (5-1), and is connected in series with the resistor (R2) AC The capacitor C4 connected in parallel to the cathode and the anode of the / DC converter 1 (5-1) is configured.

The diaak TD1 of the low voltage lighting prevention part 1 (6-1) is connected to a power source between the resistor R2 and the capacitor C4, and the current is initially charged in the capacitor C4 by the resistor R2. After that, the diaak TD1 sends a trigger signal to the gate of the silicon controlled rectifier SCR1.

The low voltage lighting prevention unit 1 (6-1) further includes a condenser (C3) connected in parallel to the anode and the cathode of the AC / DC conversion unit 1 (5-1) to form a condenser (C3). Supplies a stable current to the LEDs LED1 to LED20 configured in the LED arrays 7-11 and 7-12 of the lighting unit 7 by removing noise components that may be generated by the trigger signal of the diaak TD1. .

The diaak TD1 is a device in which a current flows while being turned on instantaneously when a voltage is higher than a certain degree, and is charged in a triangular waveform and the charged voltage is turned on, that is, a brake over voltage. When it is turned, the current is instantaneously discharged in the pulse waveform.

The diaak TD1 is a device capable of flowing current in both directions during normal operation, and is composed of two terminals, an anode and a cathode, and conducts when any polarity at both ends of the two terminals reaches a starting voltage. And turns off when the current falls below the holding current.

The operation of the low voltage light prevention part 1 (6-1) is controlled at the initial stage of lighting even though power is input through the AC / DC converter 1 (5-1), so that there is no trigger signal at the gate of the silicon control rectifier (SCR1). The rectifier SCR1 is not turned on, that is, the current is not energized by the LEDs LED1 to LED20, and the LEDs LED1 to LED20 are maintained as not lit.

The current controlled by the AC / DC converter 1 (5-1) is regulated by limiting the current applied from the resistor R2 to a current value suitable for the diaak TD1. Starts to charge, and as the current continues to be charged in the capacitor C4, the voltage of the capacitor C4 increases.

When the voltage of the capacitor C4 reaches the trigger start voltage of the diaak TD1, the diaak TD1 is temporarily turned on to discharge the pulse waveform current, and the discharged pulse waveform current is silicon. The silicon control rectifier SCR1 is turned on by being sent to the gate of the control rectifier SCR1 to become a trigger signal for turning the gate on.

When the gate of the silicon control rectifier SCR1 is turned on, the current input from the AC / DC converter 1 (5-1) flows in the forward direction of the cathode from the anode to the LED array 7-11 of the lighting unit 7. 7-12) reaches the LED (LED1 ~ LED20) configured to turn on the LED (LED1 ~ LED20).

When the gate of the silicon controlled rectifier (SCR1) is connected once, the current flows in the forward direction until the positive and negative voltages are lost or the reverse voltage is applied. Therefore, the trigger operation of the diaak (TD1) blocks the commercial voltage of the input. Since it is maintained continuously until the silicon control rectifier (SCR1) is also maintained in the conduction (Turn on) mode, the LED (LED1 ~ LED20) is continuously lit.

Since the silicon controlled rectifier SCR1 is electrically turned off by the trigger signal and then turned off by disconnecting the power supply, the interruption of the trigger signal is turned off by the LEDs LED1 to LED20.

Therefore, when the LEDs LED1 to LED20 are turned off, that is, when the power switch of the LEDs LED1 to LED20 is turned off, the trigger signal is cut off.

The resistor R3 suppresses the operation of the diaak TD1 and controls the output of the diaak TD1. The resistor R3 bypasses the trigger signal to the cathode according to the resistance value.

That is, the resistor R3 regulates the current output from the diaak TD1 and controls the current smaller than the resistance value, that is, the trigger signal smaller than the resistance value is bypassed to the cathode, so that the gate of the silicon control rectifier SCR1 is controlled. Is not turned on, and a current larger than the resistance value, that is, a trigger signal greater than the resistance value, is sent to the gate of the silicon controlled rectifier SCR1 so that the gate of the silicon controlled rectifier SCR1 is turned on. The driving current is supplied to the LEDs LED1 to LED20 so that the LEDs LED1 to LED20 are turned on.

Therefore, it is possible to control the resistance value of the resistor R3 so that the silicon controlled rectifier SCR1 conducts to the desired voltage by using the resistor R3, thereby increasing the initial lighting voltage.

The capacitor C3 is to remove noise components that may occur during turn-on in the silicon control rectifier SCR1 and to stabilize the DC level of the power supply.

That is, since the capacitor C3 of the silicon control rectifier SCR1 flows or is blocked according to the operation of the gate, the gate of the silicon control rectifier SCR1 is switched so that the gate is turned on by the trigger signal. on) That is, the capacitor C3 accumulates the noise that may occur when the switch is turned on, thereby lowering the noise voltage, thereby stabilizing the DC current inputted by the AC / DC converter 1 (5-1).

The plurality of resistors R2 in parallel (eg R2- R, R2-₂ ... R2-n), and the plurality of resistors R3 in parallel (eg R3-₁, R3-₂ ... R3-n)), multiple capacitors (C3) in parallel (e.g. C3-₁, C3-₂ ... C3-n), multiple capacitors (C4) in parallel (eg C4-₁, C4 -₂ ... C4-n) can be adjusted more finely.In case of configuring a plurality of resistors (R2), the current applied from the AC / DC converter 1 (5-1) is the resistance (R2- 에서) and are sequentially limited in order of resistance (R2-₂) ... resistance (R2-n) to finely control.When a plurality of resistors (R3) are configured, the trigger signal is resistor (R3). -3) and are sequentially controlled in the order of resistance (R3-₂) ... resistance (R3-n) .In case of condenser C3, noise generated by trigger signal C3-₁), sequentially charged in order of condenser (C3-₂) ... condenser (C3-n), and the condenser (C4) If it is, the current applied from the AC / DC converter 1 (5-1) is charged in the capacitor (C4-₁) and sequentially charged in the order of the capacitor (C4-₂) ... capacitor (C4-n). .

The low voltage lighting prevention part 1 (6-1) further includes a resistor R5 connected in series to the rear of the silicon controlled rectifier SCR1, and is configured at the rear of the resistor R5, and the AC / DC converter 1 (5). A resistor R4 connected in parallel to the positive electrode and the negative electrode of -1) is further configured.

The resistor R5 limits the current applied from the silicon controlled rectifier SCR1 to a current value suitable for lighting the LEDs LED1 to LED20 configured in the LED arrays 7-11 and 7-12 of the lighting unit 7. The regulated and regulated current is applied to the LED arrays 7-11 and 7-12 of the lighting unit 7 so that the LEDs LED1 to LED20 are turned on.

The resistor R4 bypasses the current applied from the silicon controlled rectifier SCR1 to the negative portion of the DC current, that is, the overcurrent, which is not controlled by the resistor R5.

The resistor R4 bypasses the tube current to the cathode once more when there is an instantaneous overcurrent that is not controlled by the resistor R5 to stabilize the lighting of the LED once again from the surge current.

The plurality of resistors R4 in parallel (e.g. R4- R, R4-₂ ... R4-n), and the plurality of resistors R5 in parallel (e.g. R5-₁, R5-₂ ... R5-n) can be more finely adjusted, and when a plurality of resistors (R4) are configured, the overcurrent applied from the resistor (R5) is limited in the resistor (R4-₁) and the resistor (R4-₂). In this case, the resistors are sequentially limited in the order of the resistors R4-n to finely control the bypass to the cathode, and when the resistors R5 are configured in plural, the current applied from the silicon controlled rectifier SCR1 is applied to the resistors R5. -₁) and conduction by restricting in order of resistance (R5-₂) ... resistance (R5-n).

In general, LED bulbs do not need lighting at a voltage of 35 ~ 120V. If LEDs are not turned on in this section, the LED bulb does not have fine lighting or afterglow, so the starting voltage of DIAC (TD1) is set to LED (LED1). When the lighting voltage of the LED20, that is, the diaak TD1 is configured to operate at 120V or more, the LEDs LED1 to LED20 do not light when the trigger starting voltage of the diaak TD1 is 120V or less.

That is, when the phase of the commercial power input to the LEDs (LED1 to LED20) is changed, the current or the leakage current is much lower than 120V, and the human body does not feel the low voltage and thus does not reach the trigger starting voltage of the DIA (TD1). LED (LED1 ~ LED20) can not be turned on to prevent the LED (LED1 ~ LED20) is turned on by the low voltage is not finely lit or half-burning phenomenon.

The low voltage light prevention part 2 (6-2) is a capacitor (C5) connected in parallel to the positive electrode and the negative electrode, and a resistor (R7) connected in parallel to the negative electrode and the positive electrode of the AC / DC converter 2 (5-2) And a capacitor (C6) connected in series with a resistor (R7) but connected in parallel to a cathode and a cathode, a diaak (TD2) and a diaak (TD2) connected between a resistor (R7) and a capacitor (C6). And the gate of the silicon controlled rectifier (SCR2) are connected in series at the same time and consists of a resistor (R8) connected to the cathode of the AC / DC converter.

The low voltage lighting prevention part 2 (6-2) is formed in the rear of the resistor (R10) and a resistor (R10) connected in series with the rear of the silicon control rectifier (SCR2) and the AC / DC converter 2 (5-2) The resistor R9 is further configured to be connected in parallel to the anode and the cathode of the.

The resistor R10 restricts and controls the current applied from the silicon controlled rectifier SCR2 to a current value suitable for lighting the LEDs LED21 to LED40, and the resistor R9 bypasses the overcurrent to a negative portion of the DC current.

Since the low voltage light prevention unit 1 (6-1) and the low voltage light prevention unit 2 (6-2) have the same configuration and operation, the AC / DC converter 1 in the low voltage light prevention unit 1 (6-1) described above. (5-1), LED arrays (7-11, 7-12), LEDs (LED1 to LED20), diaak (TD1), silicon controlled rectifier (SCR1), resistor (R2), resistor (R3), resistor ( R4), resistor (R5), capacitor (C3), capacitor (C4) configuration of AC / DC converter 2 (5-2), LED array (7-21, 7-22), LED (LED21 ~ LED40) , Low voltage lighting prevention part when it is corresponded as diaak (TD2), silicon controlled rectifier (SCR2), resistor (R7), resistor (R8), resistor (R9), resistor (R10), capacitor (C5), capacitor (C6) Since the configuration and operation of 2 (6-2) will be described, the description of the configuration and operation of the low voltage lighting prevention unit 2 (6-2) will be omitted.

The lighting unit 7 is connected to the low voltage light prevention unit 6, LED low array 1 (6-1) LED array 1 (7-11) and LED array 2 (7-12) in series, The LED array 3 (7-21) and the LED array 4 (7-22) are connected in series to the low voltage lighting prevention unit 2 (6-2).

A plurality of LEDs (LED1 to LED10) are mounted in the LED array 1 (7-11), a plurality of LEDs (LED11 to LED20) are mounted to the LED array 1 (7-12), LED array 3 (7-21) ), A plurality of LEDs (LED31 ~ LED40) is mounted, and a plurality of LEDs (LED21 ~ LED30) are mounted on the LED array 4 (7-22) to power input (ON) of the licensed terminal 1, licensed terminal 2 and licensed terminal 3. ) LED array turns on full or divided cross lighting.

When power is applied to the terminal 1, all LED arrays 7-11, 7-12, 7-21, 7-22 of the LED (LED1 ~ LED40) is turned on, the power is input to the terminal 2 When it is turned on, only the LEDs (LED1 ~ LED20) of the LED arrays 1, 2 (7-11, 7-12) connected to the low voltage lighting prevention part 1 (6-1) are turned on, and the power is supplied to the terminal 3 (ON). ), Only the LEDs (LED21 to LED40) connected to the LED arrays 7-21 and 7-22 connected to the low voltage lighting prevention unit 2 (6-2) are turned on and divided.

The LED array 1, 2, 3, 4 (7-11, 7-12, 7-21, 7-22) may be composed of two or more LEDs (LED1 ~ LED40) may also be composed of more than 40. have.

LED arrays 1 and 2 (7-11, 7-12) connected to the low voltage light prevention unit 1 (6-1) and LED arrays 3 and 4 (7- 7) connected to the low voltage light prevention unit 2 (6-2). 21, 7-22 are arranged to cross each other, when the power supply is turned ON (applied terminal 2) of the LED array 1, 2 (7-11, 7-12) connected to the low voltage lighting prevention unit (1-1) When only LEDs (LED1 ~ LED20) are turned on and power is applied to the terminal 3, the LEDs (LED21 ~ LED40) connected to the LED arrays 7-21 and 7-22 connected to the low voltage preventing part 2 (6-2). When only) is turned on, when the power is input (ON) to the application terminal 2 or the application terminal 3, adjacent LED arrays are not turned on, but are turned on one by one, and the LED arrays are cross-lit.

Although the present invention has been described in detail with reference to the specific embodiments thereof, it will be understood by those skilled in the art that various changes and modifications may be made without departing from the scope of the present invention.

Therefore, the scope of the present invention should not be limited to the described embodiments, but should be determined not only by the claims below but also by the equivalents of the claims.

1: AC filter unit 2: lighting selector
3: reverse current blocking unit 4: voltage adjusting unit
4-1: Voltage regulator 1 4-2: Voltage regulator 2
5: AC / DC converter 5-1: AC / DC converter 1
5-2: AC / DC converter 2 6: Low voltage lighting prevention unit
7: Lighting part 7-11: LED array 1
7-12: LED Array 2 7-21: LED Array 3
7-22: LED Array 4

Claims (7)

In the divided lighting LED bulb power supply control device comprising an AC filter unit and an LED array,
A lighting selection unit comprising an input terminal connected to any one power line of the AC current applied from the AC filter unit, and a switch formed of an application terminal 1, an application terminal 2, and an application terminal 3 that can be connected to the input terminal, respectively; ;
The AC applied from the lighting selector is conducted, and the diode D31 is formed on the power supply line of the applying terminal 1 to connect the power supply line configured with the diode D31 to the power supply line of the applying terminal 2, and the diode D31 A diode D32 is formed on the extended power line by extending the configured power line, and an extension power line configured with the diode D32 is connected to the power line of the applying terminal 3, and power is input to the applying terminal 2 or the applying terminal 3 ( A reverse current blocking unit for preventing a reverse current from flowing to the application terminal 1 even when the signal is ON);
The voltage regulating unit includes a voltage regulating unit 1 connected to an applied terminal 2 and a voltage regulating unit 2 connected to an applied terminal 2, and regulating a voltage with respect to the input AC current by inputting the alternating current applied from the reverse current blocking unit, respectively. Wealth;
AC / DC conversion unit 1 connected to each output line of the voltage regulator 1 and voltage regulator 2 and connected to the other line of the input power, respectively, converts the AC current into DC current, and constitutes a bridge rectifier circuit 1. And an AC / DC converter configured as an AC / DC converter 2;
Silicon controlled rectifiers (SCR1, SCR2) connected in series with a DC current input from each of the AC / DC converter 1 and AC / DC converter 2, and a power supply line, and diacs (TD1, TD2) connected to an input power source. A low voltage light prevention unit comprising a low voltage light prevention unit 1 and a low voltage light prevention unit 2 formed of (Diac: a phase control trigger element);
Each LED array is connected to the low voltage light prevention unit 1 and the low voltage light prevention unit 2, and includes a plurality of series LED arrays including a plurality of LEDs. When the power is input to terminal 2 (ON), only the LED array connected to the low voltage light prevention unit 1 is turned on, and when the power is input (ON) to terminal 3, only the LED array connected to the low voltage light prevention unit 2 is turned on. ;
The LED lighting bulb power supply control device, characterized in that the LED array is all lit or divided cross lighting according to the power input (ON) of the terminal 1, the terminal 2 and the terminal 3 applied.
delete The method of claim 1,
The voltage adjusting unit 1 includes a capacitor C1 formed on a power supply line connected to an application terminal 2, and a resistor R1 for discharging the capacitor C1 in series with the power supply line;
The voltage adjusting section 2 includes a capacitor C2 formed on a power supply line connected to an application terminal 3, and a resistor R6 for discharging the capacitor C2 in series with the power supply line;
Each of the voltage adjusting unit 1 and the voltage adjusting unit 2 inputs an alternating current applied from a reverse current blocking unit to adjust a voltage drop with respect to the input alternating current.
The method of claim 1,
The low voltage preventing unit 1 is connected in series with a capacitor (C3) connected in parallel to the positive electrode and the negative electrode, a resistor (R2) connected in parallel to the negative electrode and the positive electrode of the AC / DC converter 1 The capacitor (C4) connected in parallel to the negative electrode and the positive electrode, the gate of the diaak (TD1), the diaak (TD1) and the silicon control rectifier (SCR1) connected between the resistor (R2) and the capacitor (C4) A resistor R3 connected in series at the same time and connected to the cathode of the AC / DC converter;
The low voltage light prevention unit 2 is connected in series with a capacitor (C5) connected in parallel to the positive electrode and the negative electrode, a resistor (R7) connected in parallel to the negative electrode and the positive electrode of the AC / DC conversion unit 2, and a resistor (R7) The capacitor (C6) connected in parallel to the cathode and the anode, and the gate of the diaak (TD2), the diaak (TD2) and the silicon control rectifier (SCR2) connected between the resistor (R7) and the capacitor (C6) A resistor R8 connected in series at the same time and connected to the cathode of the AC / DC converter;
The LED lighting bulb power supply control unit characterized in that the LED array is not lighted fine and does not occur half-burning phenomenon.
delete 5. The method of claim 4,
The low voltage lighting prevention unit 1 includes a resistor R5 connected in series to the rear of the silicon control rectifier SCR1 and a resistor connected to the anode and the cathode of the AC / DC converter 1 in parallel to the resistor R5. R4) is further configured;
The low voltage lighting prevention unit 1 includes a resistor R10 connected in series to the rear of the silicon control rectifier SCR2 and a resistor connected to the positive and negative poles of the AC / DC converter 2 in parallel with the resistor R10. R9) is further configured;
The resistors R5 and R10 limit the current applied from the silicon controlled rectifiers SCR1 and SCR2 to the lighting current value of the LED, and the resistors R4 and R9 bypass the overcurrent to the negative portion of the DC current. Split lighting LED bulb power control device characterized in that.
The method of claim 1,
An LED array connected to the low voltage light prevention unit 1 and an LED array connected to the low voltage light prevention unit 2 are arranged to cross each other;
When the power is input (ON) to the terminal 2 or the terminal 3, the adjacent LED arrays are not lighted one by one lighted across the LED array is characterized in that the LED array cross-lighting.

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