KR100487326B1 - Organic electroluminescence device of current driving type - Google Patents

Abstract

The present invention relates to an organic EL, and more particularly, to a power saving circuit of a passive matrix organic EL device. The power saving circuit of the organic EL device according to the present invention is composed of a plurality of column lines, a plurality of scan lines, a light emitting pixel is formed at the intersection of the column line and the scan line, the column line and the scan line A drive circuit of a passive organic EL in which light is emitted from pixels formed at intersections thereof by an applied power source, comprising: a scan electrode driver for sequentially outputting signals to a plurality of scan lines; and a parasitic capacitor present in a column electrode line. And a column electrode driver for recovering the charged charges, storing and outputting the charged charges, and a capacitor having a large capacitance formed outside the IC for accumulating the charges output from the column electrode drivers.

Description

Energy saving circuit of organic EL element

The present invention relates to an organic EL, and more particularly, to a power saving circuit of a passive matrix organic EL device.

In recent years, the development of the flat panel display is due to its own advantages.

Among such flat panel displays, an organic EL display device is attracting attention as a next-generation flat panel display technology capable of displaying high-quality video due to its low voltage driving, high luminous efficiency, fast response speed, and wide viewing angle.

The organic EL display device can be divided into a passive matrix and an active matrix according to the driving method. The biggest difference in the driving method is in the light emission time difference of the organic EL element.

The passive matrix organic EL display is a driving method that emits light only during a selected time period, whereas the active matrix organic EL display is a driving method that keeps emitting light in addition to the selected time.

In addition, the passive matrix organic EL display has an advantage that the manufacturing process is simpler than the active matrix organic EL display, but it emits light only for a selected time, and thus requires a large amount of current because it emits light at a high luminance instantaneously to obtain a desired brightness. There is a growing disadvantage.

In addition, the passive matrix organic EL display has a disadvantage in that the parasitic capacitor becomes large due to the structural cause of the display panel, so that unnecessary power consumption is very large in addition to the power required for actual light emission. Therefore, in order for a passive matrix organic EL display to be used in a portable device, it is necessary to develop a method for reducing power consumption.

1 is a diagram showing a passive matrix organic EL display having conventional M column electrode lines and N scan electrode lines, and FIG. 2 is a diagram showing a column electrode driving circuit of a conventional passive matrix organic EL display.

1 and 2, a passive matrix organic EL display is a scan driver of a scan electrode circuit that sequentially selects and outputs a scan line signal of an organic EL display, supplies a constant current to the column electrode line, and supplies the column electrode line. It is composed of a column driver to reset and a light emitting display unit.

The column electrode driving circuit includes a current source for supplying a constant current to the organic EL display and a sink switch for resetting the column electrode line of the organic EL display as shown in FIG. 2. When 'off', the current supply supplies a constant current to the organic EL; when the sink switch is 'on', the current supply no longer supplies current to the organic EL, and the charge charged in the column electrode line sinks All discharge through the switch.

The driving of a passive matrix organic EL display having M column electrode lines and N scan electrode lines configured as described above is as follows.

First, when the first scan line S_1 is selected, the column driving circuit connected to the column electrode line supplies a certain amount of current to the organic EL element through the column electrode line according to the predetermined luminance.

At this time, the current supplied from the column driving circuit first charges the parasitic capacitor C_data present in the column electrode, and then, when the parasitic capacitor is charged, the current is supplied to the organic EL and the organic EL emits light.

At this time, the electric charge charged in the parasitic capacitor present in the column electrode line is discharged through the sink switch of the column driving circuit before the second scan line S_2 is selected.

When the second scan line S_2 is selected, the column driving circuit connected to the column electrode line supplies a predetermined amount of current to the organic EL element through the column electrode line according to the predetermined luminance.

At this time, the current supplied from the column driving circuit first charges the parasitic capacitor C_data present in the column electrode, and then supplies a certain amount of current to the organic EL when the parasitic capacitor is charged, and then the organic EL emits light. At this time, the electric charges charged in the parasitic capacitor existing in the column electrode line are all discharged through the sink switch of the column driving circuit before the third scan line S_3 is selected. When the third scan line is selected, the same as when the first and second scan lines are selected, the current is supplied from the column driving circuit and then the charged charge is discharged through the sink switch of the column driving circuit. Similarly, when the line is selected, the organic EL display device is driven.

As described above, the passive matrix organic EL display device has a disadvantage in that power consumption is very large because charging and discharging are continuously repeated periodically to the parasitic capacitor present in the column electrode line every scan line is selected.

Accordingly, an object of the present invention is to provide a power saving circuit for an organic EL device which reduces the power consumption by recycling electric charges.

According to an aspect of the present invention for achieving the above object, it is composed of a plurality of column lines, consisting of a plurality of scan lines, a light emitting pixel is formed at the intersection of the column line and the scan line, In a driving circuit of a passive organic EL in which light is emitted from pixels formed at intersections thereof by a power source applied to a scan line, a scan electrode driver for sequentially outputting signals to a plurality of scan lines and a column in a column electrode line. And a column electrode driver for collecting and storing the charges charged in the parasitic capacitor, and a capacitor having a large capacitance formed outside the IC for accumulating the charges output from the column electrode driver.

The parasitic capacitor of claim 1, wherein the column electrode driver comprises: a current supply unit, a separate switch unit for recovering charges charged in the parasitic capacitor present in the column electrode line, and the parasitic capacitor present in the column electrode line. And a sink portion for discharging the charge charged in the and a tank capacitor formed outside the IC for accumulating the charge recovered by the separate switch.

In addition, the separate switches are all dependent on the column electrodes, and each tank capacitor is connected to every switch, and the separate switches are all dependent on the column electrodes, and all the switches are connected to one tank capacitor. All of the charge recovered from the column electrode line is stored in one capacitor.

In addition, the switch is connected to the column line in parallel to the sink in parallel with the switch, and the charges recovered from the column electrodes of each of the R / G / B use separate capacitors between the respective column electrodes of the R / G / B. And the charges recovered from the column electrodes of the respective R / G / Bs are stored in the switch by using a separate tank capacitor.

And, in the switch for recovering the parasitic capacitor present in the column line, the charge recovered from the column electrode of each of the R / G / B is stored by using a separate tank capacitor between each column electrode line of the R / G / B In order to maintain a constant voltage accumulated in each of the tank capacitors of the R / G / B and to set the voltage of each of the R / G / B differently, a Zener diode is used for each tank capacitor of the R / G / B. Maintain constant voltage different for each R / G / B.

In addition, the charge accumulated in the tank capacitor is used as the input power of the DC-DC converter to reduce the power of the entire system.

Hereinafter, a configuration and an operation according to an exemplary embodiment of the present invention will be described with reference to the accompanying drawings.

3 is a power saving circuit of the organic EL device according to the present invention.

Referring to FIG. 3, the power saving circuit of the organic EL device according to the present invention includes a sink 12 for resetting charges charged in the current supply unit 11 and the parasitic capacitor 15 present in the column electrode line. And a tank capacitor 13 for recovering and storing the electric charges charged by the sink 12, a switch 14 and an organic EL 16 for controlling the electric charges stored in the tank capacitor.

The operation of the peak circuit of the organic EL element configured as described above is as follows.

First, when the scan line is selected, the sink 12 is 'off' and the switch 14 is 'on'. At this time, the electric charge stored in the parasitic capacitor 15 is supplied to the column electrode line.

Then, when a current is supplied from the current supply unit 11 to emit light at a desired luminance, the sink unit 12 is 'off' and the switch 14 is 'off'.

Thereafter, after the current supply is cut off from the current supply unit 11, the switch 14 is turned 'on' to recover the charge charged in the parasitic capacitor 15 present in the column electrode line to the tank capacitor 13.

After the charge is recovered, the switch 14 is 'off', and then the sink 12 is 'on' to discharge all the charge remaining in the column electrode line.

Subsequently, when the next scan line is selected, the same operation as when the first scan line is selected is performed.

FIG. 4 is a first embodiment using a power saving circuit of an organic EL device according to the present invention. In order to recover charges charged in parasitic capacitors existing in column electrode lines, separate switches and capacitors are used for each column electrode line. Thus, the electric charge discharged from the column electrode line is recovered, and the electric charge recovered at the next scan line driving is supplied to the next color electrode line again.

FIG. 5 is a second embodiment using a power saving circuit of an organic EL device according to the present invention. In order to recover charges charged in a parasitic capacitor present in a column electrode line, a separate switch is used for every column electrode line electrode. The recovered charges are stored together in one capacitor, and then the supplied charges are re-supplied to the next color electrode line when the next scan line is driven.

6 is a third embodiment using the power saving circuit of the organic EL element according to the present invention, and FIG. 7 is a fourth embodiment using the power saving circuit of the organic EL element according to the present invention.

6 to 7, a separate switch is used for every column electrode line to recover the charges charged in the parasitic capacitor present in the column electrode line, and the recovered charges are R / G / B for each column electrode line. After storing together in one capacitor, the charge is recovered to the desired voltage level using a Zener diode, and the recovered charge is supplied to each column electrode line of R / G / B during the next scan line driving. Example 4 uses a separate switch for every column electrode line to recover the charge charged in the parasitic capacitor present in the column electrode line, and the recovered charge is one capacitor for each column electrode line of R / G / B. After the storage, the charge recovered during the next scan line driving is re-supplied to each column electrode line of the R / G / B.

FIG. 8 is a fifth embodiment using the power saving circuit of the organic EL device according to the present invention. In the circuit of FIG. 5, charge stored in a parasitic capacitor present in the column electrode line is stored in a tank capacitor outside the column IC. Then, the stored charge is used as the input power of the DC-DC converter, and the scheme of reducing the power of the entire system by reducing the charge from the battery used as the input power of the first designed DC-DC converter is reduced. I use it.

As described above, the present invention can recover the charge stored in the parasitic capacitor in the passive matrix organic EL display device and reuse it, thereby reducing the power consumption of the passive matrix organic EL display.

Those skilled in the art will appreciate that various changes and modifications can be made without departing from the spirit of the present invention.

Therefore, the technical scope of the present invention should not be limited to the contents described in the examples, but should be defined by the claims.

1 is a view showing a passive matrix organic EL display having a conventional M column electrode lines and N scan electrode lines,

Fig. 2 shows a column electrode driving circuit of a conventional passive matrix organic EL display.

3 is a circuit diagram showing a power saving circuit of an organic EL device according to the present invention;

4 is a first embodiment using a power saving circuit of an organic EL element according to the present invention;

5 is a second embodiment using a power saving circuit of an organic EL element according to the present invention;

6 is a third embodiment using a power saving circuit of an organic EL element according to the present invention;

7 is a fourth embodiment using a power saving circuit of an organic EL element according to the present invention.

Fig. 8 is a fifth embodiment of the power saving circuit of the organic EL device according to the present invention.

* Description of the symbols for the main parts of the drawings *

11 current supply unit 12 sink unit

13: tank capacitor 14: switch

15: parasitic capacitor 16: organic EL

Claims (8)

Comprised of a plurality of column lines, consisting of a plurality of scan lines, a light emitting pixel is formed at the intersection of the column line and the scan line, the light emission from the pixel formed at the intersection point by the power applied to the column line and the scan line In the drive circuit of the passive organic EL which is formed, A scan electrode driver for sequentially outputting scan signals to the plurality of scan lines; A column electrode driver for recovering and storing the charges charged in the parasitic capacitor existing in the column electrode line and outputting them to the column electrode line in which the next scan line is selected and operated; And a capacitor having a large capacitance formed outside the IC that accumulates the charge recovered by the column electrode driver. The method of claim 1, wherein the column electrode driver, A current supply unit for applying electric charge to the color electrode driver; A sink unit for discharging a charge charged in a parasitic capacitor present in the column electrode line; A separate switch unit for recovering the electric charge charged in the parasitic capacitor before switching to the next scan line and before operating the sink switch; And a tank capacitor formed outside the IC for accumulating the charge recovered by the separate switch. The method of claim 2, The separate switch is dependent on each of the column electrodes, the power saving circuit of the organic EL device, characterized in that for each switch connects each tank capacitor. The method of claim 2, The separate switch is all dependent on the column electrode, A power saving circuit for an organic EL element, wherein all the switches are connected to one tank capacitor so that all of the charges recovered from the column electrode lines are stored in one capacitor. The method of claim 4, wherein The switch is connected to the column line in parallel with the sink in parallel to the switch, and the charges recovered from the column electrodes of each of R / G / B are stored using separate capacitors. A power saving circuit of an organic EL device, characterized in that. The method of claim 2, A power saving circuit of an organic EL device, characterized in that the switch stores the charge recovered from the column electrodes of each of the R / G / B columns using separate tank capacitors. The method of claim 6, In the switch for recovering the parasitic capacitor present in the column line, the organic solvent for storing the charge recovered from the column electrode of each of the R / G / B by using a separate tank capacitor between each column electrode line of the R / G / B In the driving section of the EL circuit, A Zener diode is used in each of the R / G / B tank capacitors to maintain a constant voltage accumulated in each of the R / G / B tank capacitors and to set a different voltage of each of the R / G / B tanks. To maintain a constant voltage different for each R / G / B. The method of claim 4, wherein A power saving circuit of an organic EL device, characterized in that to reduce the power of the entire system by using the charge accumulated in the tank capacitor as an input power supply of the DC-DC converter.