KR20080109551A - Driver for controlling of light emitting polymer - Google Patents

Abstract

An organic light-emitting display driver is provided to operate LEP sheet regardless of AC power or DC power source so that LEP sheet is operated without being restricted by place. An organic light-emitting display driver operates an organic light-emitting display. The organic light-emitting display driver convert input power source into DC power source of 100V ~ 160V having the frequency of 300Hz ~ 3kHz and supplies the DC power source to a LEP sheet(2). The organic light-emitting display driver comprises a AC controller(10) and a DC controller(50). The AC controller converts AC power source into DC power source of 100V ~ 160V having the frequency of 300Hz ~ 3kHz and supplies the DC power source to the LEP sheet. The DC controller converts DC power source into DC power source of 100V ~ 160V having the frequency of 300Hz ~ 3kHz and supplies the DC power source to the LEP sheet.

Description

Organic Light Emitting Display Driver {Driver for Controlling of Light Emitting Polymer}

1 is a block diagram illustrating an organic light emitting display driving driver according to an exemplary embodiment of the present invention.

FIG. 2 is a block diagram illustrating an AC controller among the OLED display driver shown in FIG. 1.

FIG. 3 is a circuit diagram illustrating the AC controller shown in FIG. 2.

FIG. 4 is a block diagram illustrating a DC controller among the organic light emitting display driving driver shown in FIG. 1.

FIG. 5 is a circuit diagram illustrating the DC controller shown in FIG. 4.

<Brief description of symbols for the main parts of the drawings>

2: LEP Sheet 10: AC Controller

12, 52: power input unit 14: DC voltage rectifier

16, 56: SMPS controller 18, 58: trans matching unit

20, 60: high frequency switching circuit 22, 62: DC output control unit

24, 64: output monitoring circuit 26, 66: electromagnetic wave protection circuit

28, 68: illuminance detection circuit section 30, 70: microprocessor

32, 72: power control unit

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an organic light emitting display driving driver, and more particularly, to an organic light emitting display driving driver capable of driving an LEP sheet regardless of an AC power supply or a DC power supply.

In general, the billboard is to provide the information the advertiser wants to catch the attention of the consumer. Accordingly, billboards are attracting consumer attention by expressing unique characters, figures, or colors. Such advertising boards have often been used by writing or engraving desired letters or figures on acrylic plates or synthetic resin sheets, but the visibility at night was greatly reduced, and thus the desired advertising effects could not be expressed at night. As a result, recently, backlights such as neon lamps, fluorescent lamps, and cold cathode fluorescent lamps (CCFLs) are used to view advertisement contents even at night.

On the other hand, the electroluminescent sheet EL which has self-luminous in recent years has been developed. The electroluminescent device is a surface light emitting device having a structure in which a protective film is inserted between a transparent conductive film and a back electrode. When an alternating voltage is applied to the light emitting layer, light generated in the fluorescent layer is radiated through the transparent conductive film. It is an ultra-thin plane and has an operating frequency of 400 kHz to 2 kHz at an operating temperature of -35 ° C to 70 ° C.

Such electroluminescent devices are classified into ELD and LEP, and ELD is coated on the back of polyester transparent film and polyester transparent film, which is a kind of polymer film having excellent flexibility, high permeability and heat resistance, and have conductive properties and transmittance of light. A front electrode layer formed of this excellent indium oxide (ITO), a fluorescent layer formed on the back surface of the front electrode layer, an organic dielectric layer formed on the back of the fluorescent layer, a back electrode layer formed on the back of the organic dielectric layer, and a protective layer formed on the back electrode layer. The ELD is operated to emit phosphor of a specific pixel by applying a predetermined external voltage to the front electrode layer and the back electrode layer. In this ELD, the polyester transparent film is extruded to a thickness of 50 to 150 μm to suit the purpose, and discharges one side, and to attenuate the problem of shrinkage due to the thermal stress charging stress according to the manufacture of the inorganic electroluminescent device. Heat treatment is performed at 150 ° C. for about 30 minutes.

The front electrode layer is formed by sputtering lithium oxide-tin to a thickness of several hundreds to thousands of micrometers in consideration of light transmittance on the discharged surface. At this time, the sheet resistance value of the indium oxide-tin is preferably set to about several tens to several hundred mm 2. The organic dielectric layer is formed by dissolving a polymer resin of a polyester resin in a solvent, preparing a paste using a plasticizer, printing a thickness of about 30 to 70 μm, and drying at about 100 to 140 ° C. for 30 minutes. At this time, the transmittance of the dielectric layer is preferably set to about 70 to 80%.

On the other hand, LEP (Light Emitting Polymer) is composed of a fluorescent layer, a dielectric layer, a back electrode layer and a special synthetic resin layer. Fluorescent layer is a fluorine-based binder, has a dielectric constant of 30㎌ or more, has excellent durability and moisture resistance, and has high adhesiveness and brightness with a fabric. The fabric is composed of a conductive polymer layer and a conductive mesh layer. The surface resistance is very low, around 100m². Such fabrics have high UV blocking and light diffusing power and have been used for various purposes. The dielectric layer has excellent light diffusion and reflection, and is designed with a dielectric constant of more than 30 Hz. The back electrode is treated with Al and Cu films, and has a large area and a resistance of about 10 m 2. The protective layer can protect the entire device by UV and IR, and a flexible film treatment resistant to moisture resistance is provided.

However, the above-described ELD and LEP cannot directly connect and use AC power supplied from a general home or business site, and also have a problem in that they cannot directly connect and drive DC power supplied from a battery due to their light emission characteristics.

Accordingly, an object of the present invention is to provide an organic light emitting display driving driver capable of driving an LEP sheet regardless of an AC power supply or a DC power supply.

In order to achieve the above object, the organic light emitting display driving driver according to an embodiment of the present invention converts the input power into a 100V ~ 160V DC power source having a frequency of 300 ~ 3kHz in accordance with the pulse width modulation method to the LEP sheet It is characterized by the supply.

An organic light emitting display driving driver according to an embodiment of the present invention includes an AC controller for converting an AC power source into a 100V ~ 160V DC power source having a frequency of 300 ~ 3kHz according to the pulse width modulation method to supply to the LEP sheet; And a DC controller converting the DC power supply into a DC power supply of 100V to 160V having a frequency of 300 Hz to 3 Hz according to the pulse width modulation scheme and supplying the DC power to the LEP sheet.

In the organic light emitting display driving driver according to an embodiment of the present invention, the AC controller includes: an AC / DC converter for converting input commercial power into a DC driving voltage of 18V to 20V and a DC voltage of 180V to 200V; When a DC voltage of 180V to 200V is supplied from the AC / DC converter and converted into a sine wave, when an overcurrent and an overtemperature are detected at a DC voltage of 180V to 200V supplied to the AC / DC converter, a DC voltage of 180V to 200V is supplied. High frequency switching circuit to cut off; A DC output control unit for converting a sine wave supplied from the high frequency switching circuit into a 100V to 160V PWM DC power source having a frequency of 300 Hz to 3 Hz according to a pulse width modulation scheme; An output monitoring circuit configured to monitor an output voltage, an output current, and a pulse width of a 100V to 160V PWM DC power supply having a frequency of 300 Hz to 3 Hz supplied from the DC output controller; An electromagnetic wave prevention circuit unit for removing noise of a 100V to 160V PWM DC power supply having a frequency of 300Hz to 3kHz supplied from the output monitoring circuit and supplying the noise to a LEP sheet; When the overcurrent and overtemperature are detected, the AC / DC converter and the high frequency switching circuit are controlled to shut off the operation of the AC / DC converter and the high frequency switching circuit, and 100V to 160V PWM DC has a frequency of 300 kHz to 3 kHz. The output of the output voltage, output current, and pulse width of any one of the power supply or the 100V ~ 160V PWM DC power source having a frequency of 300 ~ 3 kHz according to the change in ambient illumination, so that the output is not supplied to the LEP sheet A microprocessor for controlling the supervisory circuit.

In the organic light emitting display driving driver according to an embodiment of the present invention, the AC controller is driven by a DC driving voltage of 18V to 20V supplied from the AC / DC converter to provide a PWM control signal for driving the microprocessor to the microprocessor. It further includes a power supply control unit for supplying.

In the organic light emitting display driving driver according to an embodiment of the present invention, the AC controller further includes an illuminance detection circuit unit configured to detect peripheral illuminance of the LEP sheet and supply the detected illuminance value to the microprocessor.

In the organic light emitting display driving driver according to an embodiment of the present invention, the AC / DC controller removes noise of the commercial power and prevents inrush current of the commercial power input, and prevents overcurrent of the output power from which the noise is removed. A power input unit; A DC voltage rectifying unit receiving power from which noise is removed from the power input unit and rectifying the DC voltage with a high voltage; An SMPS controller which senses its own temperature and an overcurrent of the DC voltage supplied from the DC voltage rectifier and controls the supply of the DC voltage supplied from the DC voltage rectifier; And a transformer matching unit generating a DC driving voltage of 18V to 20V and a DC voltage of 180V to 200V for driving a circuit using the DC voltage supplied from the SMPS controller.

In the organic light emitting display driving driver according to an embodiment of the present invention, the power input unit includes a noise filtering circuit for removing noise by commercial power; An inrush current prevention circuit for preventing inrush current of the commercial power supply; And an overcurrent prevention circuit for preventing overcurrent of the power source from which the noise is removed.

In the organic light emitting display driving driver according to an embodiment of the present invention, the DC voltage rectifying unit includes a bridge rectifying circuit for rectifying the power from which the noise is removed to a high voltage DC voltage; And a filtering circuit for removing the noise of the rectified high voltage DC voltage.

In the organic light emitting display driving driver according to an embodiment of the present invention, the DC controller includes a DC / DC converter for converting DC power supplied from a battery into a DC driving voltage of 18V to 20V and a DC voltage of 180V to 200V; A charging circuit unit which detects a voltage and a current of the battery and cuts off the DC / DC converter so that DC power is not supplied from the battery when the battery is overcharged or overdischarged; A high frequency circuit that receives the DC voltage of 180V to 200V from the DC / DC converter and converts it into a sine wave, and cuts off the DC voltage supply of the 180V to 200V when an overcurrent and an overtemperature are detected at the DC voltage of 180V to 200V. Switching circuits; A DC output control unit for converting a sine wave supplied from the high frequency switching circuit into a 100V to 160V PWM DC power source having a frequency of 300 Hz to 3 Hz according to a pulse width modulation scheme; An output monitoring circuit configured to monitor an output voltage, an output current, and a pulse width of a 100V to 160V PWM DC power supply having a frequency of 300 Hz to 3 Hz supplied from the DC output controller; An electromagnetic wave protection circuit unit for removing noise of a 100V to 160V PWM DC power supply having a frequency of 300Hz to 3kHz supplied from the output monitoring circuit and supplying the noise to the LEP sheet; And

100V to 160V PWM having a frequency of 300 kHz to 3 kHz and controlling the DC / DC converter and the high frequency switching circuit so that driving of the DC / DC converter and the high frequency switching circuit is cut off when overcurrent and over temperature are detected. The output voltage, output current and pulse width of the DC power supply is abnormal or any change in the illuminance so that the 100V ~ 160V PWM DC power source having a frequency of 300 ~ 3kHz is not supplied to the LEP sheet A microprocessor for controlling the supervisory circuit.

In the organic light emitting display driving driver according to an embodiment of the present invention, the DC controller is driven by a DC driving voltage of 18V to 20V from the DC / DC converter to supply a PWM control signal for driving the microprocessor to the microprocessor. The apparatus further includes a power control unit.

In the organic light emitting display driving driver according to an embodiment of the present invention, the DC controller further includes an illuminance detection circuit unit that detects the peripheral illuminance of the LEP sheet and supplies the peripheral illuminance value of the LEP sheet to the microprocessor.

In the organic light emitting display driving driver according to an embodiment of the present invention, the DC / DC converter includes a power input unit for removing noise of DC power supplied from the battery; An SMPS controller which senses its own temperature and an overcurrent of the DC power supplied from the power input unit and controls the DC power supply from the power input unit; And a transformer matching unit configured to generate a DC driving voltage of 18V to 20V and a DC voltage of 180V to 200V for driving a circuit by using the DC power supplied from the SMPS controller.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. 1 is a block diagram illustrating an organic light emitting display driving driver according to an exemplary embodiment of the present invention.

Referring to FIG. 1, an organic light emitting display driving driver according to an exemplary embodiment of the present invention uses an input power source having a frequency of 300 V to 3 V according to a pulse width modulation (PWM) scheme. Is converted to the LEP sheet 2 and supplied. In this case, as the input power, both a commercial power source, that is, an AC power source of 110V or 220V and a DC power source input through a battery (eg, 12V or 24V) may be used. To this end, the organic light-emitting display driving driver and the AC controller 10 for converting the commercial power supply to a DC power supply of 100V ~ 160V having a frequency of 300 ~ 3kHz according to the pulse width modulation method and supplying to the LEP sheet (2) and It includes a DC controller 50 for converting the DC power supply to a DC power supply of 100V ~ 160V having a frequency of 300 ~ 3kHz to supply to the LEP sheet (2). AC controller 10 is supplied with AC power of 110V or 220V, which is commercial power, and converts the supplied commercial power into DC power of 100V to 160V having a frequency of 300 kHz to 3 kHz according to the pulse width modulation method. Supply to 2).

The AC controller 10 removes noise of the commercial power source (AC) and prevents inrush current of the commercial power source that is input as shown in FIGS. 2 and 3, and prevents overcurrent of the output power source from which the noise is removed. DC voltage rectifier 14 for receiving noise-free power from the power input 12 for rectifying to a high voltage DC voltage, DC supplied from its own temperature and DC voltage rectifier 14 Switching Mode Power Supply (SMPS) controller 16 which controls the supply of the DC voltage supplied from the DC voltage rectifier 14 by sensing the overcurrent of the voltage, and drives the circuit using the DC voltage supplied from the SMPS controller 16. It converts into a sine wave by receiving a DC voltage of 180V to 200V from a transformer matching section 18 and a transformer matching section 18 generating a DC driving voltage of 18V to 20V and a DC voltage of 180V to 200V. And tran When an overcurrent and an over temperature are detected at a DC voltage of 180 V to 200 V supplied from the switch matching unit 18, a high frequency switching circuit 20 and a high frequency switching circuit 20 are provided to cut off a DC voltage supply of 180 V to 200 V. 300 kHz to 3 kHz of DC output controller 22 and DC output controller 22 for converting a sine wave into a PWM DC power supply having a frequency of 300 kHz to 3 kHz according to the pulse width modulation scheme. Output monitoring circuit 24 for monitoring the output voltage and output current and pulse width of a PWM DC power supply having a frequency of 100V to 160V, 100V to 160V having a frequency of 300 kHz to 3 kHz supplied from the output monitoring circuit 24 The electromagnetic wave prevention circuit section 26 for removing the noise of the PWM DC power supply of the power supply to the LEP sheet 2, the illuminance detecting circuit section 28 for detecting the peripheral illuminance of the LEP sheet 2, and the overcurrent and overtemperature are detected. SMPS controller (16) and high frequency switch The SMPS controller 16 and the high frequency switching circuit 20 are controlled so that the driving of the latching circuit 20 is cut off, and the output voltage, output current, and pulse of a 100 V to 160 V PWM DC power supply having a frequency of 300 kHz to 3 kHz If an abnormality occurs in any one of the widths or according to the illuminance detection signal supplied from the illuminance detection circuit unit 28, the 100V to 160V PWM DC power supply having a frequency of 300 Hz to 3 Hz is not supplied to the LEP sheet 2. The microprocessor 30 is driven by a DC driving voltage of 18V to 20V supplied from the microprocessor 30 and the transformer matching unit 18 to control the output supervisory circuit 24 to output a PWM control signal for driving the microprocessor 30. It consists of the power supply control part 32 supplied to 30.

At this time, since the power input unit 12, the DC voltage rectifying unit 14, the SMPS controller 16, and the transformer matching unit 18 convert the AC power into a DC voltage of 180V to 200V and a DC driving voltage of 18V to 20V. It can be called a / DC converter. Detailed description of the AC controller 10 will be described later.

The DC controller 50 receives a DC power supply (for example, 12V or 24V) from a battery and converts the supplied DC power into a DC power supply of 100V to 160V having a frequency of 300 Hz to 3 Hz according to a pulse width modulation method. To the LEP sheet 2. As shown in FIGS. 4 and 5, the DC controller 50 detects a voltage and a current of the power input unit 52 that removes noise of the DC power supplied from the battery, and the battery may be overcharged or overdischarged. In case of concern, the charging circuit unit 54 cuts off the power input unit 52 so that the DC power is not supplied from the battery, and detects its own temperature and an overcurrent of the DC power supplied from the power input unit 52 to detect the power input unit 52. SMPS controller 56 for controlling the DC power supply from the control panel, and a DC driving voltage of 18V to 20V and a DC voltage of 180V to 200V for driving the circuit using the DC power supplied from the SMPS controller 56 180V to 200V DC voltage is supplied from the transformer matching unit 58 and the transformer matching unit 58, and is converted into a sine wave, and 180V to 200V DC is supplied from the transformer matching unit 58. When overcurrent and overtemperature are detected in the voltage, the sine wave supplied from the high frequency switching circuit 60 and the high frequency switching circuit 60 which cuts off the DC voltage supply of 180 V to 200 V is 300 ㎐ to 3 따라 according to the pulse width modulation method. A DC output controller 62 for converting a PWM DC power supply having a frequency of 100 V to 160 V, an output voltage of a 100 V to 160 V PWM DC power supply having a frequency of 300 Hz to 3 Hz supplied from the DC output controller 62, and Output monitoring circuit 64 for monitoring output current and pulse width, and 100V to 160V PWM DC power supply having a frequency of 300 kHz to 3 kHz supplied from output monitoring circuit 64 to remove noise of LEP sheet 2 To the electromagnetic wave prevention circuit unit 66 to supply to the light source, to the illuminance detection circuit unit 68 to detect peripheral illuminance of the LEP sheet 2, and to drive the SMPS controller 56 and the high frequency switching circuit 60 when overcurrent and overtemperature are detected. SMPS control to block (56) and the high frequency switching circuit 60, an abnormality occurs in any one of the output voltage, output current and pulse width of the 100V ~ 160V PWM DC power supply having a frequency of 300 ~ 3kHz Microprocessor 70 for controlling output supervisory circuit 64 such that a 100V to 160V PWM DC power source having a frequency of 300 Hz to 3 Hz is not supplied to the LEP sheet 2 according to the illuminance detection signal supplied from 68. ) And a power control unit 72 which is driven by a DC driving voltage of 18V to 20V supplied from the transformer matching unit 58 and supplies a PWM control signal for driving the microprocessor 70 to the microprocessor 70. do.

At this time, since the power input unit 52, the SMPS controller 56 and the transformer matching unit 58 converts the DC power of 12V or 24V into a DC voltage of 180V to 200V and a DC driving voltage of 18V to 20V. It can be called a converter. Detailed description of the DC controller 50 will be described later.

FIG. 2 is a block diagram illustrating an AC controller among an organic light emitting display driving driver according to an exemplary embodiment of the present disclosure illustrated in FIG. 1, and FIG. 3 is a circuit diagram of the AC controller illustrated in FIG. 2.

2 and 3, an AC controller of an organic light emitting display driving driver according to an exemplary embodiment of the present invention removes noise of an AC power source of 110 V to 220 V, which is a commercial power source, and receives an inrush current of a commercial power source. A power input unit 12 for preventing an overcurrent of an output power source from which noise is removed; A DC voltage rectifying unit 14 receiving power from which the noise is removed from the power input unit 12 and rectifying the DC voltage with a high voltage; An SMPS controller 16 for controlling the supply of the DC voltage supplied from the DC voltage rectifier 14 by sensing its own temperature and the overcurrent of the DC voltage supplied from the DC voltage rectifier 14; The transformer matching unit 18, which generates a DC driving voltage of 18V to 20V and a DC voltage of 180V to 200V for driving the circuit using the DC voltage supplied from the SMPS controller 16, 180V from the transformer matching unit 18 High frequency switching that receives a DC voltage of ~ 200V and converts it into a sine wave, and cuts off the DC voltage supply of 180V to 200V when an overcurrent and an overtemperature are detected at a DC voltage of 180V to 200V supplied from the transformer matching unit 18. DC output control part 22, DC which converts the sine wave supplied from the circuit 20 and the high frequency switching circuit 20 into 100V-160V PWM DC power supply which has a frequency of 300 Hz-3 Hz according to a pulse width modulation system. From an output monitoring circuit 24 and an output monitoring circuit 24 for monitoring the output voltage and output current and pulse width of a 100 V to 160 V PWM DC power supply having a frequency of 300 kHz to 3 kHz supplied from the output controller 22; supply Illuminance detection for detecting the ambient illuminance of the electromagnetic wave prevention circuit section 26 and the LEP sheet 2, which removes noise of a 100V to 160V PWM DC power supply having a frequency of 300 Hz to 3 Hz and supplies the LEP sheet 2 to the LEP sheet 2. When the circuit unit 28 and the overcurrent and the overtemperature are detected, the SMPS controller 16 and the high frequency switching circuit 20 are controlled so that the driving of the SMPS controller 16 and the high frequency switching circuit 20 is cut off. 300 kHz to 3 kHz according to the illumination detection signal supplied from the illuminance detection circuit section 28 or abnormality occurs in any one of the output voltage, the output current and the pulse width of the PWM DC power supply having a frequency of 100 V to 160 V 18V to 20V DC drive voltage supplied from the microprocessor 30 and the transformer matching section 18 to control the output supervisory circuit 24 so that a 100V to 160V PWM DC power supply having a voltage is not supplied to the LEP sheet 2. Powered by micro It consists of a PWM control signal for driving the processor 30 to the power control unit 32 to be supplied to the microprocessor 30.

The power input unit 12 removes noise of commercial power input through the power cord, that is, 110V to 220V AC power when the power cord is connected to an outlet installed in a home or a business, and prevents inrush current of the commercial power input. Prevents overcurrent of noise-free output power. As shown in FIG. 3, the power input unit 12 includes noise filtering circuits C1 to C6 for removing noise of commercial power, inrush current preventing circuit TNR1 for preventing inrush current during commercial power input. It consists of an overcurrent prevention circuit F1 for preventing the overcurrent of the output power supply.

The DC voltage rectifier 14 receives the power from which the noise is removed from the power input unit 12 and rectifies the DC voltage at a high voltage. As shown in FIG. 3, the DC voltage rectifier 14 includes a high voltage rectifier circuit (bridge rectifier circuit) for rectifying a high voltage and voltage filtering circuits C8 and C10-1 for filtering the rectified voltage.

The SMPS controller 16 itself controls the supply of the DC voltage supplied from the DC voltage rectifier 14 by sensing the temperature and the overcurrent of the DC voltage supplied from the DC voltage rectifier 14. The SMPS controller 16 includes a soft start circuit C11 for preventing the supply of overcurrent, a temperature sensing circuit TLP521 for sensing temperature, and a feedback circuit for compensating the input voltage. The control circuit 7M0880 is configured to cut off the supply of power by detecting an overcurrent and cut off the supply of power according to the temperature sensed by the temperature sensing circuit TLP521.

The transformer matching unit 18 generates a DC driving voltage of 18V to 20V and a DC voltage of 180V to 200V for driving the circuit using the DC voltage supplied from the SMPS controller 16. To this end, the transformer matching unit 18 generates a DC driving voltage generation circuit (a lower circuit including the MC34063A) and a DC voltage of 180V to 200V, as shown in FIG. 3, to generate a DC driving voltage of 18V to 20V. DC voltage generation circuit (upper circuit not included MC34063A). At this time, since the power input unit 12, the DC voltage rectifying unit 14, the SMPS controller 16 and the transformer matching unit 18 convert the AC power into a DC voltage of 180V to 200V and a DC voltage of 18V to 20V. It can be called a DC converter.

The high frequency switching circuit 20 receives a DC voltage of 180V to 200V from the transformer matching unit 18 and converts it into a sine wave, and overcurrent and overtemperature are generated at a DC voltage of 180V to 200V supplied from the transformer matching unit 18. If detected, cut off the DC voltage supply from 180V to 200V. As shown in FIG. 3, the high frequency switching circuit 20 includes an H-bridge circuit for converting a DC voltage of 180 V to 200 V supplied from the transformer matching unit 18 into a sine wave, and a circuit during over current and over temperature operation. It consists of a protection circuit that cuts off the DC voltage supply from 180V to 200V for protection.

The DC output control unit 22 converts a sine wave supplied from the high frequency switching circuit 20 into a 100V to 160V PWM DC power supply having a frequency of 300 Hz to 3 Hz according to the pulse width modulation method PWM. The DC output controller 22 converts the sine wave supplied from the high frequency switching circuit 20 into a 100V to 160V PWM DC power supply having a frequency of 300 Hz to 3 Hz according to the PWM. It consists of a high voltage PWM output circuit (IR2101) for.

The output monitoring circuit 24 monitors the output voltage, the output current, and the pulse width of the PWM DC power supply of 100 V to 160 V having a frequency of 300 kHz to 3 kHz supplied from the DC output control section 22. As shown in FIG. 3, the output monitoring circuit 24 is a result of a comparator UM2904 and a comparator UM2904 for comparing a reference value with an output voltage, an output current, and a pulse width of a PWM DC power supply of 100V to 160V. It consists of indicators (LED2, LED3, LED4) that indicate whether the output voltage, output current, and pulse width of the PWM DC power supply of 100V to 160V are abnormal.

The electromagnetic wave prevention circuit part 26 removes the noise of the 100-160V PWM DC power supply which has the frequency of 300 kHz-3 kHz supplied from the output monitoring circuit 24, and supplies it to the LEP sheet 2. As shown in FIG. As shown in FIG. 3, the electromagnetic wave prevention circuit unit 26 includes a resistor (R50, R51, R52), a capacitor (C34) to remove noise of a PWM DC power supply having a frequency of 300 V to 3 V with a frequency of 300 V to 3 V. FIG. , C35, C36) and inductors L6, L7.

The illuminance detection circuit unit 28 detects the peripheral illuminance of the LEP sheet 2 and is composed of an illuminance sensor for detecting the peripheral illuminance.

The microprocessor 30 is driven by the PWM control signal supplied from the power controller 32 so that the SMPS controller 16 and the high frequency switching circuit 20 are cut off when the overcurrent and the overtemperature are detected. And the high frequency switching circuit 20, and abnormality occurs in any one of an output voltage, an output current, and a pulse width of a 100 V to 160 V PWM DC power supply having a frequency of 300 Hz to 3 Hz, The output monitoring circuit 24 is controlled so that a 100V to 160V PWM DC power supply having a frequency of 300 Hz to 3 Hz is not supplied to the LEP sheet 2 in accordance with the illuminance detection signal supplied from the?

To this end, the microprocessor 22 is supplied with the peripheral illuminance value from the illuminance detection circuit unit 22, and whether the current and the temperature are abnormal from the SMPS controller 16 and the high frequency switching circuit 20, and the output monitoring circuit 24. ), The output voltage, output current, and pulse width of the 100V ~ 160V PWM DC power supply with a frequency of 300㎐ ~ 3㎑ is supplied. The microprocessor 22 monitors each system, that is, the SMPS controller 16, the high frequency switching circuit 20, and the output monitoring circuit 24, respectively, and switches the mode of the LEP sheet 2, and 180V to 200V. The DC voltage of is converted into a sine wave, and the overcurrent and overvoltage of the 100V to 160V PWM DC power supply having a frequency of 00㎐ to 3㎐ are prevented. Here, the mode conversion of the LEP sheet is to operate the LEP sheet 2 to blink or to turn it off after a predetermined time operation by a dimming signal or to continuously operate the LEP sheet 2. The operation mode of the LEP sheet 2 is described.

The power control unit 32 is driven by a DC driving voltage of 18V to 20V supplied from the transformer matching unit 18 to supply the PWM control signal for driving the microprocessor 30 to the microprocessor 30.

4 is a block diagram illustrating a DC controller among the organic light emitting display driver shown in FIG. 1, and FIG. 5 is a circuit diagram illustrating the DC controller shown in FIG. 4.

4 and 5, the DC controller of the organic light emitting display driving driver according to an embodiment of the present invention detects the voltage and current of the power input unit 52 to remove noise of the DC power supplied from the battery, and the battery. If there is a risk of overcharging or overdischarging the battery, the charging circuit unit 54 cuts off the power input unit 52 so that DC power is not supplied from the battery, and the temperature of the DC power supplied from the power input unit 52 and its own temperature. 18V to 20V DC drive voltage and 180V to drive the circuit using the DC power supply supplied from the SMPS controller 56 and the SMPS controller 56 to control the DC power supply from the power input unit 52 by detecting an overcurrent The transformer matching unit 58, which generates a DC voltage of ˜200 V, receives a DC voltage of 180 V to 200 V from the transformer matching unit 58, and converts the signal into a sine wave. When an overcurrent and an overtemperature are detected at a DC voltage of 180V to 200V supplied from the lance matching unit 58, a high frequency switching circuit 60 and a high frequency switching circuit 60 are provided to cut off a DC voltage supply of 180V to 200V. 300 kHz to 3 kHz of DC output controller 62 and DC output controller 62 for converting a sine wave into a 100 VDC to 160 V PWM DC power supply having a frequency of 300 kHz to 3 kHz according to the pulse width modulation scheme. Output monitoring circuit 64 for monitoring the output voltage and output current and pulse width of a PWM DC power supply having a frequency of 100V to 160V, 100V to 160V having a frequency of 300 kHz to 3 kHz supplied from the output monitoring circuit 64 The electromagnetic wave prevention circuit unit 66 to remove the noise of the PWM DC power supply of the supply to the LEP sheet 2, the illuminance detection circuit unit 68 for detecting the peripheral illuminance of the LEP sheet 2, when the overcurrent and the overtemperature are detected SMPS controller (56) and high frequency The SMPS controller 56 and the high frequency switching circuit 60 are controlled so that the driving of the positioning circuit 60 is cut off, and the output voltage, the output current and the pulse of the 100 V to 160 V PWM DC power supply having a frequency of 300 kHz to 3 kHz The output is such that 100V to 160V PWM DC power supply having a frequency of 300 Hz to 3 Hz is not supplied to the LEP sheet 2 when an error occurs in any one of the widths or according to the illumination detection signal supplied from the illumination detection circuit unit 68. It is driven by a DC driving voltage of 18V to 20V supplied from the microprocessor 70 for controlling the supervisory circuit 64 and the transformer matching unit 58 to output a PWM control signal for driving the microprocessor 70. And a power supply control unit 72 for supplying it to 70.

The power input unit 52 removes the noise of the DC power supplied from the battery. The power input unit 52 includes a connector CN1 to which power is input and a noise filtering circuit (the noise preventing circuit unit 53 of FIG. 5) as shown in FIG. 5. It is composed.

The charging circuit unit 54 detects a voltage and a current of the battery and blocks the power input unit 52 so that DC power is not supplied from the battery when the battery is overcharged or overdischarged. The charging circuit unit 54 detects the presence or absence of the battery and converts the voltage supplied from the battery into a constant DC voltage, and prevents power from being supplied from the battery when the battery is over discharged or overcharged. Block it.

The SMPS controller 56 itself controls the supply of the DC voltage supplied to the power input unit 52 by sensing the temperature and the overcurrent of the DC voltage supplied from the power input unit 52. It includes a soft start circuit to prevent the supply of power, a temperature sensing circuit to sense the temperature, and a feedback circuit to compensate the input voltage, and detects over current to cut off the supply of power, and senses the temperature detected from the temperature sensing circuit. The control IC (SG3524) to cut off the power supply according to the configuration.

The transformer matching unit 58 generates a DC driving voltage of 18V to 20V and a DC voltage of 180V to 200V for driving the circuit using the DC voltage supplied from the SMPS controller 56. To this end, the transformer matching unit 58 is composed of a DC drive voltage generation circuit for generating a DC drive voltage of 18V ~ 20V and a DC voltage generation circuit for generating a DC voltage of 180V ~ 200V. At this time, the power input unit 52, the SMPS controller 56 and the transformer matching unit 58 converts a DC power of 12V or 24V into a DC voltage of 180V to 200V and a DC driving voltage of 18V to 20V. Can be named

The high frequency switching circuit 60 receives a DC voltage of 180V to 200V from the transformer matching unit 58 and converts it into a sine wave, and the overcurrent and overtemperature are increased at a DC voltage of 180V to 200V supplied from the transformer matching unit 58. If detected, cut off the DC voltage supply from 180V to 200V. As shown in FIG. 5, the high-frequency switching circuit 58 includes an H bridge circuit for converting a DC voltage of 180 V to 200 V supplied from the transformer matching unit 18 into a sine wave, and a circuit during overcurrent and overtemperature operation. It consists of a protection circuit that cuts off the DC voltage supply from 180V to 200V for protection.

The DC output control unit 62 converts the sine wave supplied from the high frequency switching circuit 60 into a 100V to 160V PWM DC power supply having a frequency of 300 kHz to 3 kHz according to the pulse width modulation method PWM. The DC output controller 62 converts the sine wave supplied from the high frequency switching circuit 60 into a 100V to 160V PWM DC power supply having a frequency of 300 Hz to 3 Hz according to the PWM. It consists of a high voltage PWM output circuit (IR2101) for.

The output monitoring circuit 64 monitors the output voltage, the output current, and the pulse width of the PWM DC power supply of 100 V to 160 V having a frequency of 300 Hz to 3 Hz supplied from the DC output control unit 62.

The electromagnetic wave prevention circuit part 66 removes the noise of the PWM DC power supply of 100V-160V which has the frequency of 300 Hz-3 Hz from the output monitoring circuit 64, and supplies it to the LEP sheet 2. As shown in FIG. As shown in FIG. 5, the electromagnetic wave prevention circuit unit 66 is configured as an inductor LF1 to remove noise of a PWM DC power supply having a frequency of 300 V to 3 V and a 100 V to 160 V voltage.

The illuminance detection circuit unit 68 detects the peripheral illuminance of the LEP sheet 2 and is composed of an illuminance sensor to detect the peripheral illuminance.

The microprocessor 70 is driven by a PWM control signal supplied from the power control unit 72 so that the SMPS controller 56 and the high frequency switching circuit 60 are shut off when an overcurrent and an overtemperature are detected. And the high frequency switching circuit 60, and abnormality occurs in any one of the output voltage, the output current, and the pulse width of the PWM DC power supply of 100 V to 160 V having a frequency of 300 kHz to 3 kHz, or the illuminance detection circuit section 68 The output monitoring circuit 64 is controlled so that the PWM DC power supply of 100 V to 160 V having a frequency of 300 kHz to 3 kHz is not supplied to the LEP sheet 2 according to the illuminance detection signal supplied from the? To this end, the microprocessor 70 receives the peripheral illuminance value from the illuminance detection circuit unit 68, receives the current and temperature abnormalities from the SMPS controller 56 and the high frequency switching circuit 60, and outputs the output monitoring circuit 64. ), The output voltage, output current, and pulse width of the 100V ~ 160V PWM DC power supply with a frequency of 300㎐ ~ 3㎑ is supplied. The microprocessor 70 monitors each system, that is, the SMPS controller 56, the high frequency switching circuit 60, and the output monitoring circuit 64, and converts the mode of the LEP sheet 2, and 180V to 200V. The DC voltage of is converted into a sine wave, and the overcurrent and overvoltage of the 100V to 160V PWM DC power supply having a frequency of 00㎐ to 3㎐ are prevented.

The power control unit 72 is driven by a DC driving voltage of 18V to 20V supplied from the transformer matching unit 58 to supply the PWM control signal for driving the microprocessor 70 to the microprocessor 70. Here, the mode conversion of the LEP (2) sheet means to operate the LEP sheet 2 to blink, to turn it off after a predetermined time operation by a dimming signal, or to cause the LEP sheet 2 to continuously operate. LEP sheet 2, etc. operation mode.

As described above, the organic light emitting display driving driver according to the exemplary embodiment of the present invention can drive the LEP sheet 2 regardless of the AC power source or the DC power source.

As described above, the present invention can drive the LEP sheet regardless of the AC power source or the DC power source, so that the LEP sheet can be driven anywhere.

Claims (12)

An organic light emitting display driving driver for driving an organic light emitting display, wherein the input power is converted into a DC power supply of 100 V to 160 V having a frequency of 300 kHz to 3 kHz and supplied to the LEP sheet according to a pulse width modulation method. Driver driven organic light emitting display. The display device of claim 1, wherein the organic light emitting display driving driver comprises: an AC controller converting AC power into a DC power supply of 100V to 160V having a frequency of 300 Hz to 3 Hz according to a pulse width modulation scheme and supplying the AC power to the LEP sheet; And a DC controller converting the DC power into a DC power supply of 100V to 160V having a frequency of 300 Hz to 3 Hz according to a pulse width modulation scheme, and supplying the DC power to the LEP sheet. The AC controller of claim 2, wherein the AC controller comprises: an AC / DC converter for converting input commercial power into a DC driving voltage of 18V to 20V and a DC voltage of 180V to 200V; When a DC voltage of 180V to 200V is supplied from the AC / DC converter and converted into a sine wave, when an overcurrent and an overtemperature are detected at a DC voltage of 180V to 200V supplied to the AC / DC converter, a DC voltage of 180V to 200V is supplied. High frequency switching circuit to cut off; A DC output control unit for converting a sine wave supplied from the high frequency switching circuit into a 100V to 160V PWM DC power source having a frequency of 300 Hz to 3 Hz according to a pulse width modulation scheme; An output monitoring circuit configured to monitor an output voltage, an output current, and a pulse width of a 100V to 160V PWM DC power supply having a frequency of 300 Hz to 3 Hz supplied from the DC output controller; An electromagnetic wave prevention circuit unit for removing noise of a 100V to 160V PWM DC power supply having a frequency of 300Hz to 3kHz supplied from the output monitoring circuit and supplying the noise to a LEP sheet; When the overcurrent and overtemperature are detected, the AC / DC converter and the high frequency switching circuit are controlled to shut off the operation of the AC / DC converter and the high frequency switching circuit, and 100V to 160V PWM DC has a frequency of 300 kHz to 3 kHz. Monitor the output so that no abnormality occurs in any one of the output voltage, output current, and pulse width of the power supply, or 100 V to 160 V PWM DC power supply having a frequency of 300 kHz to 3 kHz according to the change in ambient illumination. And a microprocessor for controlling the circuitry. The AC controller of claim 3, wherein the AC controller further includes a power control unit which is driven by a DC driving voltage of 18V to 20V supplied from the AC / DC converter to supply a PWM control signal for driving the microprocessor to the microprocessor. An organic light emitting display drive driver, characterized in that. The organic light emitting display driving driver of claim 3, wherein the AC controller further comprises an illuminance detection circuit unit configured to detect an ambient illuminance of the LEP sheet and to supply the detected illuminance value to the microprocessor. The AC / DC controller of claim 3, wherein the AC / DC controller comprises: a power input unit configured to remove noise of the commercial power and prevent inrush current of the commercial power input, and to prevent overcurrent of the output power from which the noise is removed; A DC voltage rectifying unit receiving power from which noise is removed from the power input unit and rectifying the DC voltage with a high voltage; An SMPS controller which senses its own temperature and an overcurrent of the DC voltage supplied from the DC voltage rectifier and controls the supply of the DC voltage supplied from the DC voltage rectifier; And a transformer matching unit configured to generate a DC driving voltage of 18V to 20V and a DC voltage of 180V to 200V for driving a circuit by using the DC voltage supplied from the SMPS controller. The apparatus of claim 6, wherein the power input unit comprises: a noise filtering circuit for removing noise by commercial power; An inrush current prevention circuit for preventing inrush current of the commercial power supply; And an overcurrent prevention circuit for preventing overcurrent of the power source from which the noise is removed. The apparatus of claim 6, wherein the DC voltage rectifier comprises: a bridge rectifier circuit rectifying the power source from which the noise is removed to a high voltage DC voltage; And a filtering circuit for removing the noise of the rectified high voltage DC voltage. The DC controller of claim 2, wherein the DC controller comprises: a DC / DC converter for converting DC power supplied from a battery into a DC driving voltage of 18V to 20V and a DC voltage of 180V to 200V; A charging circuit unit which detects a voltage and a current of the battery and cuts off the DC / DC converter so that DC power is not supplied from the battery when the battery is overcharged or overdischarged; A high frequency circuit that receives the DC voltage of 180V to 200V from the DC / DC converter and converts it into a sine wave, and cuts off the DC voltage supply of the 180V to 200V when an overcurrent and an overtemperature are detected at the DC voltage of 180V to 200V. Switching circuits; A DC output control unit for converting a sine wave supplied from the high frequency switching circuit into a 100V to 160V PWM DC power source having a frequency of 300 Hz to 3 Hz according to a pulse width modulation scheme; An output monitoring circuit for monitoring an output voltage, an output current, and a pulse width of a PWM DC power supply having a frequency of 300 Hz to 3 Hz from a DC output controller; An electromagnetic wave protection circuit unit for removing noise of a 100V to 160V PWM DC power supply having a frequency of 300Hz to 3kHz supplied from the output monitoring circuit and supplying the noise to the LEP sheet; And controlling the DC / DC converter and the high frequency switching circuit so that driving of the DC / DC converter and the high frequency switching circuit is cut off when an overcurrent and an over temperature are detected, and having a frequency of 300 kHz to 3 kHz. The 100V to 160V PWM DC power having the frequency of 300Hz to 3kHz is not supplied to the LEP sheet due to any abnormality in any one of the output voltage, the output current, and the pulse width of the PWM DC power. And a microprocessor for controlling the output supervisory circuit. The DC controller of claim 9, further comprising a power controller configured to be driven by a DC driving voltage of 18V to 20V from the DC / DC converter to supply a PWM control signal for driving the microprocessor to the microprocessor. An organic light emitting display drive driver, characterized in that. The organic light emitting display driving driver of claim 9, wherein the DC controller further comprises an illuminance detection circuit unit configured to detect a peripheral illuminance of the LEP sheet and supply a peripheral illuminance value of the LEP sheet to the microprocessor. 10. The apparatus of claim 9, wherein the DC / DC converter comprises: a power input unit for removing noise of DC power supplied from the battery; An SMPS controller which senses its own temperature and an overcurrent of the DC power supplied from the power input unit and controls the DC power supply from the power input unit; And a transformer matching unit configured to generate a DC driving voltage of 18V to 20V and a DC voltage of 180V to 200V for driving a circuit using the DC power supplied from the SMPS controller.

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