KR20040105958A - Organic electroluminescent device - Google Patents

Abstract

PURPOSE: An organic electroluminescence device is provided to achieve improved uniformity of luminance by arranging a plurality of voltage supply lines around a light emitting region constituted by pixels in plural columns. CONSTITUTION: An organic electroluminescence device comprises a substrate; a plurality of anode electrodes and a single cathode electrode arranged on the substrate; an organic material layer formed between the anode electrodes and the cathode electrode; a plurality of sub lines(23) for connecting pixels of each column in a light emitting region(24) constituted by pixels in plural columns; and a plurality of voltage supply lines(22A) arranged in the peripheral portion of the light emitting region and connected to a pad(21) so as to supply voltage of uniform value to pixels. The sub lines connected with pixels in columns are connected to the voltage supply lines.

Description

Organic electroluminescent device

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to organic electroluminescent devices, and more particularly, to an active driven organic electroluminescent device in which a plurality of voltage supply lines are arranged to obtain a uniform light emission effect in a plurality of light emitting regions.

In organic electroluminescence, electrons and holes injected through a cathode and an anode are recombined to form an exciton in an organic (low molecular or polymer) thin film, and light having a specific wavelength is generated by energy from the excitons formed. This is a phenomenon that occurs. The organic EL device using this phenomenon is classified into a passive driving device and an active driving device according to its driving method.

FIG. 1A is a diagram illustrating a part of a panel employing a general active driving method, in which an organic material layer 4 is positioned between a plurality of anode electrodes 2 formed on a substrate 1 and a single cathode electrode 3. It is shown. The biggest feature of the device using the active driving method is that it forms a thin film transistor (TFT) (hereinafter referred to as "transistor") capable of injecting a signal into each pixel. It is advantageous in terms of power and lifetime.

FIG. 1B is a circuit diagram showing the components of one pixel and shows one pixel having a driving TFT and a switching TFT as described above. On one side of the active driving light emitting region (representing a plurality of pixels as one single region), a voltage supply line VDD is provided to supply voltages to each pixel, and the voltage supplied to the voltage supply line is It is supplied to a drive transistor.

FIG. 2 is a schematic diagram showing the position of a voltage supply line in a panel employing a general active driving method, and is illustrated as a single light emitting region 14 without distinguishing a plurality of pixels for convenience. As described above, a voltage supply line 12 to which a voltage (for example, VO) is supplied from the pad 11 is disposed at one side of the light emitting region 14 of the panel 10. In addition, the voltage supply line 12 is connected to a plurality of sub lines 13 (sub line (only one sub line is illustrated in FIG. 2 for convenience)) in which pixels of each column are connected in parallel. Thus, when voltage is supplied to the plurality of sub lines 13 through the voltage supply line 12, each sub line 13 supplies a voltage to the pixels of the corresponding column.

However, the voltage supply line 12 and each sub line 13 formed of the metallic material have a resistance, so that as the voltage flows through the voltage supply line 12 and the sub line 13, the voltage drop due to the resistance is reduced. Occurs. That is, even though a voltage having a constant magnitude is supplied to the voltage supply line 12 through the pad 11, the voltage drops due to the resistance while passing through the voltage supply line 12 and the sub line 13. In particular, at the end of the voltage supply line 12 and the sub line 13, a voltage (i.e., V0-ΔV) as small as the final voltage drop ΔV is measured.

This voltage drop causes a difference in the current value (i.e., the current value applied to the transistor) at each pixel supplied with the voltage through the voltage supply line 12 and the sub line 13, thereby causing a difference in each diode. The difference is also in the luminance value of. As a result, even in the same panel 10, the luminance uniformity of the panel is seriously lowered because the luminous luminance of pixels far away from the voltage supply pad 11, the voltage supply line 12, and each sub line 13 is relatively low. Will fall out.

The present invention is to solve the above-mentioned problems generated in the organic EL device of the active driving method due to the voltage difference by the resistance of the voltage supply line, to provide an organic EL device that can improve the uniformity of light emission of the panel. The purpose is.

In the organic electroluminescent device of the active driving method according to the present invention for achieving the above object, a plurality of voltage supply lines in a state connected to the voltage supply pad in the outer portion of the light emitting area in order to supply a uniform voltage to all pixels And each sub line to which pixels in each column are connected to a plurality of voltage supply lines.

More specifically, in the organic EL device according to the present invention, two voltage supply lines are disposed on both sides of the emission area, and both ends of each sub line connecting pixels of each column in the emission area are respectively connected to each voltage supply line. It has a structure.

As another structure, the plurality of voltage supply lines are disposed on one side of the light emitting area, and are connected to a first voltage supply line connected to one end of each sub line for supplying voltage to the pixels of each column, and is arranged on the top of the light emitting area. And a second voltage supply line connected to another end of the sub line for supplying a voltage to the pixels of each column through.

Hereinafter, with reference to the accompanying drawings of the present invention will be described in detail.

1A and 1B are some structural and circuit diagrams of a panel employing a general active driving scheme.

2 is a schematic diagram showing the position of a voltage supply line in a panel employing a general active driving scheme.

3 is a view showing a structure in which two voltage supply lines connected to pads in a panel are disposed on both sides of the light emitting area, respectively.

FIG. 4 is a diagram illustrating a structure in which two voltage supply lines connected to pads are disposed on upper and one sides of a light emitting area, respectively.

5 illustrates a structure in which a light emitting area is divided into a plurality of blocks, and a plurality of horizontal voltage supply lines connected to a vertical voltage supply line connected to a pad and an outermost vertical voltage supply line are arranged in a space around each block. One drawing.

The most characteristic feature of the present invention is to arrange a plurality of voltage supply lines at the periphery of a region (light emitting region) in which a plurality of columns of pixels are formed in order to supply a uniform voltage to a plurality of pixels constituting the device. The voltage is supplied to each pixel through.

Each embodiment will be described in detail as follows. In the following description and drawings, a plurality of pixels are integrally divided and described as one light emitting area.

3 illustrates a structure in which two voltage supply lines connected to pads are disposed on both sides of a light emitting area, respectively. Each voltage supply line 22A and 22B disposed on both sides of the light emitting region 24 is supplied with a constant voltage (for example, VO) from the pad 21, and pixels of each column in the light emitting region 24 are provided. A plurality of sublines 23 (only one subline is shown in FIG. 3 for convenience) connected in parallel are connected at both ends to respective voltage supply lines 22A and 22B, respectively.

The pixels of each column are supplied with voltages from the voltage supply lines 22A and 22B on both sides through the corresponding subline 23, and therefore, the pixels of the same magnitude are supplied to the pixels located at both ends of each column. Although the pixel located at the center of each column is supplied with a lower voltage (V0-ΔV) due to the voltage drop (ΔV), only one end of the sub line 13 is connected to the voltage supply line 12 as shown in FIG. The drop in voltage is negligibly low compared to the pixels of, and as a result, the uniformity of the horizontal luminance of the entire light emitting region 24 is remarkably improved.

4 illustrates a structure in which two voltage supply lines connected to a pad are disposed on an upper portion and a side portion of a light emitting region, respectively. A first voltage supply line 32A, to which a voltage (for example, VO) is supplied from the pad 31, is disposed at one side of the emission region 34 of the panel 30, and each of the first voltage supply line 32A is disposed at the first voltage supply line 32A. One end of a plurality of sublines 33 (only one subline is shown) for supplying voltage to the pixels of a column is connected. Accordingly, voltage is supplied to the plurality of sub lines 33 through the first voltage supply line 32A, and each sub line 33 supplies a voltage to the pixels in the corresponding columns.

On the other hand, the second voltage supply line 32B disposed above the light emitting region 34 is connected to another end of the sub line 33 for supplying voltage to the pixels in each column through the auxiliary line 35. Therefore, since the voltage is supplied from the first voltage supply line 32A to the sub line 33 connecting the pixels of each column, the voltage is supplied through the second voltage supply line 32B and the auxiliary line 35 at the same time. Pixels at both ends of each column are supplied with the same voltage.

Therefore, in the structure of the present embodiment, although the pixel located at the center of each column is supplied with a lowered voltage due to the voltage drop, only one end of the sub line is lowered as compared with the pixels of the structure connected to the voltage supply line as shown in FIG. Chi appears negligibly low.

5 illustrates a structure in which a light emitting area is divided into a plurality of blocks, and a plurality of horizontal voltage supply lines connected to a vertical voltage supply line connected to a pad and an outermost vertical voltage supply line are arranged in a space around each block. do.

Here, a plurality of pixels are located in each block 44A, 44B, 44C ..., and the pixels in each column of each block 44A, 44B, 44C ... are placed on a subline (not shown) in parallel. It is connected. Each sub-line is connected to the vertical and horizontal voltage supply lines 42A1, 42A2, 42A3 and 42B1, 42B2, 42B3, 42B4 arranged in the space outside the respective blocks 44A, 44B, 44C ... Each pixel of 44A, 44B, 44C ... is supplied with voltages through the vertical and horizontal voltage supply lines 42A1, 42A2, 42A3 and 42B1, 42B2, 42B3, 42B4 and sub-lines. Each pixel column in each block 44A, 44B, 44C ... is selectively connected to each voltage supply line through each subline according to the distance between the power supply pads 41. That is, the sub-lines of the pixel columns in the blocks 44A, 44B, 44C ... corresponding to the portions of the vertical and horizontal voltage supply lines where the voltage drop does not occur adjacent to the pad 41 are limited to only one voltage supply line. On the contrary, the sub-line of the pixel column in the blocks 44A, 44B, 44C ... corresponding to the vertical and horizontal voltage supply line portions that are far away from the pad 41 to generate the voltage drop has a large number of located in the surrounding space. Is connected to the voltage supply line.

Thus, a plurality of voltages are supplied to the sublines of each pixel column to compensate for the voltage drop in each of the voltage supply lines 42A1, 42A2, 42A3 and 42B1, 42B2, 42B3, 42B4 generated according to the distance from the pad 41. By connecting the lines, a uniform voltage can be supplied to all the pixels, thereby improving the luminance uniformity of the panel.

In the structure shown in FIG. 5, the light emitting area is divided into a plurality of blocks 44A, 44B, 44C ..., so that an unlighted area is formed in the space between the blocks 44A, 44B, 44C .... Therefore, this structure is suitable for large panels rather than small panels.

In the organic electroluminescent device, the voltage supply line is mainly made of aluminum (Al), but the voltage supply line is made of a metal having a lower resistance value than aluminum, such as copper (Cu), silver (Ag), or gold (Au). And when forming the sub-line can greatly reduce the pressure drop in each line.

In the present invention as described above, by arranging a plurality of voltage supply lines around a light emitting region composed of a plurality of pixels, the luminance uniformity of the device is improved by compensating a voltage drop in the voltage supply line and applying a voltage having a uniform value to all pixels. You can.

Claims (5)

The organic material layer is positioned between a plurality of anode electrodes formed on the substrate and a single cathode electrode, and voltages from a plurality of sub lines and pads connecting the pixels of each column in parallel with each other in a light emitting area composed of a plurality of pixels. In an active driving organic electroluminescent device comprising a voltage supply line for supplying to each sub line, In order to supply a uniform voltage to all the pixels, a plurality of voltage supply lines are arranged in a state connected to a voltage supply pad at an outer portion of the light emitting area, and each of the sub lines to which pixels in each column are connected is provided in a plurality of voltage supply lines. An organic electroluminescent device characterized in that connected to. The method of claim 1, wherein the plurality of voltage supply lines are two voltage supply lines respectively disposed on both sides of the light emitting area, and both ends of each sub line connecting pixels of each column in the light emitting area are respectively connected to each voltage supply line. Organic electroluminescent element. The light emitting device of claim 1, wherein the plurality of voltage supply lines are disposed on one side of the light emitting area and connected to one end of each sub line for supplying voltage to the pixels of each column, and is disposed on the top of the light emitting area. An organic electroluminescent element, which is a second voltage supply line connected to another end of a sub line for supplying voltage to pixels in each column through a line. The display device of claim 1, wherein the light emitting area is divided into a plurality of blocks, and the plurality of voltage supply lines are vertical voltage supply lines connected to pads and a plurality of horizontal voltage supply lines connected to outermost vertical voltage supply lines. Vertical and horizontal voltage supply lines are arranged in the space around each block, and sub-lines in which pixels in each column of each block are connected in parallel are selectively connected to each voltage supply line in accordance with the distance from the power supply pads. The sublines of the pixel columns in the block corresponding to the vertical and horizontal voltage supply line portions in which no drop has occurred are connected to only one voltage supply line, and in the block corresponding to the vertical and horizontal voltage supply line portions in which the voltage drop has occurred. Sublines of the pixel column are organically connected to a number of voltage supply lines located in EL device. The organic electroluminescent device according to any one of claims 1 to 4, wherein the voltage supply line and the sub line are formed of any one of copper (Cu), silver (Ag), and gold (Au).