KR20180078480A - Power Line Sharing Display Device - Google Patents

Abstract

According to one embodiment of the present invention, a display device comprises: a plurality of pixels disposed in a display region; a dummy pixel disposed outside the display region; a plurality of pixel power wirings supplying drive power to the plurality of pixels; a power sharing wiring overlapping the dummy pixel and connected to the plurality of pixel power wirings; and a power supply wiring supplying the drive power to the power sharing wiring from the outside. The display device connects the plurality of pixel power wirings to the power sharing wiring to share the drive power. Moreover, the power sharing wiring can be overlapped with the dummy pixel to reduce an area.

Description

[0001] Power Line Sharing Display Device [0002]

The present invention relates to a power supply wiring of a display device of the present invention, and is a display device having a structure in which driving power supply wiring is shared so as to reduce the decrease in drive power supply voltage and the occurrence of a deviation.

1 is a view showing a conventional display device. The pixels P are arranged in a matrix form in the display area A / A of the display device. Each pixel P emits light of a predetermined color to display a desired image in the display area. Dummy pixels D are arranged in the non-display area N / A of the display area. As shown in the drawing, adjacent to the outermost pixels P of the display area, they may be arranged in one line or arranged in plural lines. The power source for driving each pixel P and the wirings for transmitting the gradation data are connected to the pixel P. [ The driving power supply line (EVDD) supplies the driving power for the foot of the pixel (P) and the device. The driving power supply line may be arranged in the column direction of the pixels P in the display area A / A and connected to the pixels P in one column or may be shared in the columns P of the pixels as shown in the figure. Further, a data line DATA and a reference power supply line REF for transferring a data voltage in accordance with the gray scale data are arranged and connected to the pixel P. Although not shown, scan wirings for selecting row-direction pixel rows in the pixel (P) array are included.

Since the driving power supply line (EVDD) supplies driving power for a plurality of pixels (P), a large amount of current flows. Each of the driving power supply lines EVDD is separated from each other, and when a high-gradation image is displayed on a pixel P in a specific region, a large amount of current flows in the specific driving power supply line EVDD, and the voltage of the driving power supply drops. When the voltage of the driving power source is lowered, the pixel P can not express the desired gradation, and the voltage of the driving power source is varied between the driving power source lines EVDD, so that the image of the entire display device becomes uneven and the image quality is deteriorated.

And aims to reduce variations in the driving power supply voltage of the driving power supply wiring of the display device and to display a uniform image.

The present invention shares the driving power by connecting the pixel power wiring to the power sharing wiring. In addition, the power sharing wiring can be overlapped with the dummy pixels to reduce the area.

In the display device according to the embodiment of the present invention, a plurality of pixels are arranged in the display region, and dummy pixels are arranged outside the display region. A plurality of pixel power supply wirings for supplying driving power to the plurality of pixels, power supply sharing wirings overlapping the dummy pixels and connected to the plurality of pixel power supply wirings, and power supply wiring for supplying driving power to the power sharing wirings from the outside.

The power sharing wiring can be formed by connecting conductive layers of adjacent dummy pixels.

Each of the plurality of pixel power supply wirings may be connected to other pixels in the display area to supply driving power.

And a dummy pattern of dummy pixels connected to the conductive layer.

The conductive layer or the dummy pattern of the dummy pixel may have a shape similar to the light emitting element or the driving circuit of the pixel.

The dummy pattern may be located in the same layer as the pixel power supply wiring.

And an insulating film between the power sharing wiring and the plurality of pixel power supply wirings, wherein the plurality of pixel power supply wirings can be connected to the power sharing wiring through the contact holes of the insulating film.

And may further include a data line which is located on the insulating film and which is insulated from and crosses the power sharing line.

The number of pixel power supply wirings may be less than or equal to the number of data wirings and may be larger than the number of power supply wirings.

A display device according to another embodiment of the present invention includes a power sharing wiring, an insulating film on the power sharing wiring, a plurality of pixel power supply wirings and a data wiring on the insulating film, and a plurality of pixel power wiring is connected to the first contact hole It is connected to the power sharing wiring, and the data wiring is insulated from the power sharing wiring.

And a dummy pattern located on the insulating film and connected to the power sharing wiring via the second contact hole of the insulating film.

And a power supply wiring connected to the power sharing wiring to supply driving power from the outside.

The pixel power supply line and the data line are connected to the pixels arranged in the display area, and the power sharing line can overlap with the dummy pixel arranged in the display area.

The power sharing wiring can be formed by connecting conductive layers of adjacent dummy pixels.

A display device according to another embodiment of the present invention includes a plurality of pixels each having a light emitting element and a driving circuit, each pixel having a plurality of pixels, a dummy element and a dummy circuit for displaying an image, a dummy pixel not displaying an image, A plurality of pixel power supply wirings for supplying a plurality of pixel power supply wirings, power supply wirings for supplying driving power from the outside, and power supply sharing wirings for sharing driving power supplied from the power supply wirings through the conductive layers of the dummy elements or dummy circuits, .

The display device of the present invention can reduce the drivability of the driving power supply voltage by distributing the current supply path when current is concentrated in a specific region by connecting the driving power supply wirings in parallel and reduce the deviation of the driving power supply voltage between the driving power supply wirings .

It is possible to reduce the area of the pad by reducing the power supply wiring for supplying the driving power from the outside by connecting the pixel power supply wiring that supplies the driving power to the pixels through the power sharing wiring.

The power supply sharing wiring can be formed by connecting the conductive layers or the dummy patterns of the dummy pixels to share the driving power supply wiring without increasing the area of the non-display area.

1 is a view showing a conventional display device.
2 is a diagram showing a display device of the present invention.
3A and 3B are diagrams showing driving power supply wiring of the present invention.
4 is a diagram showing a power sharing line and a dummy pixel in the embodiment of the present invention.
5 is a cross-sectional view of a power sharing wiring of an embodiment of the present invention.
6 is a diagram showing power supply sharing lines and dummy pixels in another embodiment of the present invention.
7 is a cross-sectional view of a power sharing wiring of another embodiment of the present invention.

2 is a diagram showing a display device of the present invention. Pixels P for displaying an image in a display area A / A of the display device are arranged in a matrix form. Dummy pixels D that do not display an image in the non-display area N / A of the display area outer angle are arranged. The dummy pixel D is formed in the display area A / A in a form similar to the pixel P in order to prevent the problem that the first or last pixel P of the display area A / As shown in Fig. The pixel P includes a light emitting element or a driving circuit, and the dummy pixel D includes a dummy element or a dummy circuit. The dummy element or the dummy circuit has a shape similar to that of the light emitting element or the driving circuit and does not actually operate even if it is not connected to the signal wiring or connected. Although only one row of dummy pixels D are shown, multiple rows may be arranged as needed.

The driving power supply line (EVDD) supplies the driving power for the foot of the pixel (P) and the device. A driving power supply is externally supplied through the power supply wiring 110 and the pixel power supply wiring 130 is arranged in the column direction of the pixel P in the display area A / The pixel power supply wiring 130 may be connected to the pixels P in one row or may be shared with the pixels P in a plurality of rows in order to reduce the number of wirings as shown in the figure.

A large amount of current flows because the pixel power supply wiring 130 supplies driving power for a plurality of pixels P. [ Each pixel power supply line 130 is connected to a number of other pixels P in the display area A / A. In the display area A / A, the other pixel power supply wiring 130 is connected to the same pixel P or not connected to each other. When a high-gradation image is displayed on a pixel P in a specific region, a large amount of current flows in the specific pixel power supply wiring 130, so that the voltage of the driving power supply may drop.

The display device of the present invention connects several pixel power supply wirings 130 to the power supply wirings 120 to prevent the driving power supply voltage from being lowered and to reduce the deviation of the driving power supply voltage between the pixel power supply wirings 130. Since a large amount of current flows through the pixel power supply wiring 130, a large amount of current may flow through the power supply sharing wiring 120 connecting the same. Therefore, the power sharing wiring 120 needs to have a small resistance so that the wiring width must be wide. In order to connect the pixel power supply wirings 130 to each other in the display area A / A, wirings are added to reduce the area of the pixels P or the opening area. Even if they are connected to each other in the non-display area N / A, the area is increased by the added wiring.

The power sharing wiring 120 is arranged overlapping with the dummy pixel D. [ By using the area of the dummy pixel D, the wiring width can be increased and the resistance can be reduced. The power sharing wiring 120 may be formed by a separate wiring. However, when the constituent elements of the dummy pixel D are used, additional wiring is not required, so that a required space can be reduced and the role of the dummy pixel D And the power sharing wiring 120 can be performed simultaneously. It is possible to share the driving power without connecting the pixel power supply lines 130 in the display area A / A and even if the pixel power supply lines 130 are connected to each other in the display area A / A, Lt; RTI ID = 0.0 > 120 < / RTI >

The data line DATA or the reference power supply line REF is arranged in parallel with the pixel power supply line 130. The data line DATA or the reference power line REF crosses the power sharing line 120 but is insulated from each other to minimize the influence. Although not shown, scan wirings for selecting row-direction pixel rows in the pixel (P) array are included.

In the display device of the present invention, when a plurality of pixel power supply wirings 130 are connected to the power supply wirings 120 and a current is concentrated in a specific region, the current supply path is dispersed to adjust the driving power supply voltage of the pixel power supply wirings 130 And the deviation of the driving power supply voltage between the pixel power supply wirings 130 can be reduced.

3A and 3B are diagrams showing driving power supply wiring of the present invention. A plurality of pixel power supply wirings 130 are connected to the power supply wirings 120 to supply driving power to the plurality of pixel power supply wirings 120. The power supply wirings 110 are connected to the power supply sharing wirings 120 to supply driving power, Share. Therefore, it is not necessary to connect the power supply wiring 110 to every pixel power supply wiring 130 and even if one power supply wiring 110 is connected to each pixel power supply wiring 130, Can be supplied.

3A shows a structure in which the pixel power supply line 130 and the power supply line 110 are connected in a 2: 1 ratio and FIG. 3B shows a structure in which the pixel power supply line 130 and the power supply line 110 are connected in a 4: . The present invention is not limited to this, and the number of the power supply lines 110 may be less than or equal to the number of the pixel power lines 130.

As the number of the power supply wiring lines 110 is reduced, the number of pads to which driving power is supplied from the outside can be reduced, and the area of the link wiring can be reduced, thereby reducing the area of the non-display area N / A. At least one power supply wiring 110 may be provided, but if the power supply wiring 110 is too small, it may be difficult to uniformly supply driving power.

4 is a plan view showing a dummy pixel D and a power sharing wiring 120 in a part of a display device of the embodiment of the present invention. The power sharing lines 120 are arranged so as to overlap with the plurality of dummy pixels D. [ The dummy pixel D includes a dummy element or a dummy circuit. The dummy element or the dummy circuit has a shape similar to that of the light emitting element or the driving circuit of the pixel P, but does not actually operate. The dummy element or the dummy circuit includes a conductive layer and the conductive layers of the adjacent dummy pixels D are connected to each other to constitute the power sharing wiring 120. [ The conductive layer of the power sharing wiring 120 may form a dummy element or a dummy circuit in the dummy pixel D to serve as the dummy pixel D. [ The dummy element or the dummy circuit may be different from the light emitting element or the driving circuit or may be different in the area of the conductive layer in order to configure the power sharing wiring 120. In order to serve as the dummy pixel D, And maintains a similar form to that of the < / RTI >

The power supply wiring 110 and the pixel power wiring 130 are connected to the power sharing wiring 120 through the first contact hole 140. [ The power supply wiring 110 and the pixel power supply wiring 130 may be integrally formed as shown in FIG. Only the pixel power supply wiring 130 can be connected in a portion where the power supply wiring 110 is not provided. The power supply wiring 110 may be disposed on a different layer from the pixel power supply wiring 130. [ In this case, it is electrically connected to the power sharing wiring 120 through another layer or another contact hole to supply driving power.

A signal line such as the data line 150 or the reference voltage line 160 may be disposed between the dummy pixels D. [ The data wiring 150 or the reference voltage wiring 160 is insulated from and crosses the power sharing wiring 120. [ In order to reduce the interference with the signal wiring, a slit is added to the power sharing wiring 120 at the intersection to reduce the overlapping area. Further, when the crossing wiring is short-circuited, the power-sharing wiring 120 of the short-circuited part is cut off, and repair can be performed to prevent defects.

Although only a part is shown in FIG. 4, the dummy pixels D are repeatedly arranged left and right, and wirings are arranged therebetween. As shown in FIG. 2, a plurality of pixel power supply wirings 130 are connected to the power supply common wiring 120.

As described above, the display device of another embodiment of the present invention includes the power sharing wiring 120 in a superimposed manner on the dummy pixel D, and is formed of the dummy element of the dummy pixel D or the conductive layer of the dummy circuit. Thus, the driving power between the pixel power supply lines 130 can be shared through the dummy pixels D. Therefore, the current supply path of the driving power source is distributed without increasing the area of the non-display area, thereby preventing the driving power source voltage from lowering and reducing the deviation of the driving power source voltage between the pixel power source wiring lines 130. [

Figure 5 is a cross-sectional view of the embodiment of Figure 4; A power sharing wiring 120 is disposed on the substrate 100. Another layer such as a buffer layer may be disposed on the substrate 100 and the power sharing wiring 120 may be disposed thereon. The power sharing wiring 120 may be a separate wiring or a conductive layer of the dummy pixel D. [ The dummy element or the dummy circuit includes a configuration similar to that of the light emitting element or the driving circuit. For example, a layer similar to a thin film transistor, a capacitor, an electrode, a signal line or a light emitting diode, etc., and its configuration is not perfect or does not work and does not actually work. A conductive layer such as a light blocking layer, a gate layer, a source / drain layer, or an electrode layer may be connected to each other to form the power sharing wiring 120 in the structure of the dummy element or the dummy circuit. Since the power sharing wiring 120 should be insulated from and crossed with other signal wiring such as data wiring, it is preferable to use a light blocking layer which is distant from the signal wiring and in the thickness direction, or to use a gate layer to reduce the resistance.

An insulating film 170 is disposed on the power sharing wiring 120. The insulating film 170 may be formed by using one of a buffer layer, a gate insulating film, and an interlayer insulating film among the dummy pixel or pixel structures, or by stacking two or more thereof. The insulating film 170 has a first contact hole 140 along the power supply wiring 110 or the pixel power wiring 130. [

The pixel power supply wiring 130 and the data wiring 150 are disposed on the insulating film 170. The pixel power line 130 is connected to the power sharing line 120 through the first contact hole 140 of the insulating layer 170. The power supply wiring 110 may be connected to the power sharing wiring 120 through the same first contact hole 140 or may be connected to each other through the different first contact hole 140. The data wiring 150 or the reference power wiring 160 is insulated from and crosses the power sharing wiring 120. [ Even if the driving power source is shared with the right and left pixel power supply wirings 130 through the power supply sharing wirings 120, the data wiring 150 is insulated with the insulating film 170 interposed therebetween.

A protective film 180 is disposed on the pixel power supply wiring 130, the data wiring 150, and the reference power supply wiring 160. A dummy element (not shown) or the like may be disposed on the protective film 180. The pixel power supply line 130 is connected to the insulating film 170 and the power supply common line 120 is disposed under the insulating film 170 and the pixel power supply line 130 is disposed on the insulating film 170. However, And the power sharing wiring 120 is disposed on the insulating film 170. [

6 is a plan view showing a dummy pixel D and a power sharing wiring 120 in a part of a display device of another embodiment of the present invention. Most of the embodiment of Fig. The common parts are omitted and the explanation is given mainly of the added components. The display device of this embodiment further includes a dummy pattern 220. [ The dummy pattern 220 may be a separate structure in the dummy pixel D, or a structure included in the dummy element or the dummy circuit. A dummy pattern 220 having a conductivity other than the conductive layer of the dummy pixel D is connected to the power sharing wiring 120. [ The dummy pattern 220 may serve as a dummy element or a dummy circuit, or may serve as a double layer with the power sharing wiring 120 to reduce the resistance. The dummy patterns 220 are connected to the power supply wiring 110 or the pixel power supply wiring 130 through the power sharing wiring 120 and may be directly connected or integrally formed.

Figure 7 is a cross-sectional view of the embodiment of Figure 6; The dummy pattern 220 is connected to the power sharing wiring 120 through the second contact hole 240 of the insulating film 170. And is connected through a plurality of second contact holes 240 to reduce the resistance and disperse the current supply path. The dummy pattern 220 may be formed as a layer such as the pixel power supply wiring 130 or the data wiring 150 as shown in FIG. The dummy pattern 220 is spaced apart from the data line 150 and may be directly connected to the pixel power line 130 or may be integrally formed. The dummy pattern 220 may be a layer different from the pixel power supply wiring 130 or may be disposed below the power supply sharing wiring 120. [

As described above, the display device of another embodiment of the present invention includes the power sharing wiring 120 in a superimposed manner on the dummy pixel D, and is formed of the dummy element of the dummy pixel D or the conductive layer of the dummy circuit. The dummy patterns 220 of the dummy elements or the dummy circuits are connected in a double layer structure. Thus, the driving power between the pixel power supply lines 130 can be shared through the dummy pixels D. Therefore, the current supply path of the driving power source is distributed without increasing the area of the non-display area, thereby preventing the driving power source voltage from lowering and reducing the deviation of the driving power source voltage between the pixel power source wiring lines 130. [

110: Power supply wiring
120: Power shared wiring
130: pixel power supply wiring

Claims (15)

A plurality of pixels arranged in a display area;
A dummy pixel disposed outside the display area;
A plurality of pixel power supply lines for supplying driving power to the plurality of pixels;
A power sharing wiring overlapped with the dummy pixel and connected to the plurality of pixel power wiring lines; And
And a power supply wiring for supplying driving power to the power sharing wiring from the outside. The method of claim 1,
And the power sharing wiring lines are connected to the conductive layers of adjacent dummy pixels. The method of claim 1,
And each of the plurality of pixel power supply wirings is connected to the other plurality of pixels in the display area to supply driving power. 3. The method of claim 2,
And the conductive layer is connected to the dummy pattern of the dummy pixel. 3. The method according to claim 2 or 4,
Wherein the conductive layer or the dummy pattern is similar to the light emitting element or the driving circuit of the pixel. 5. The method of claim 4,
Wherein the dummy pattern is located in the same layer as the pixel power supply wiring. The method of claim 1,
Further comprising an insulating film between the power sharing wiring and the plurality of pixel power supply wirings, wherein the plurality of pixel power supply wirings are connected to the power sharing wirings through contact holes of the insulating film. 8. The method of claim 7,
And a data wiring disposed on the insulating film and being insulated from and crossing the power sharing wiring. 9. The method of claim 8,
Wherein the number of the pixel power supply wirings is smaller than or equal to the number of the data wirings and larger than the number of the power supply wirings. Power sharing wiring;
An insulating film on the power sharing wiring; And
And a plurality of pixel power supply wirings and data wirings on the insulating film,
Wherein the plurality of pixel power supply wirings are connected to the power sharing wirings through the first contact holes of the insulating film, and the data wirings are insulated from and intersect the power sharing wirings. 11. The method of claim 10,
And a dummy pattern located on the insulating film and connected to the power sharing wiring via a second contact hole of the insulating film. 11. The method of claim 10,
And a power supply wiring connected to the power sharing wiring to supply driving power from the outside. 12. The method of claim 11,
Wherein the pixel power supply line and the data line are connected to pixels arranged in a display area, and the power sharing line overlaps a dummy pixel arranged in an outer area of the display area. The method of claim 13,
And the power sharing wiring lines are connected to the conductive layers of adjacent dummy pixels. A plurality of pixels having a light emitting element and a driving circuit and displaying an image;
A dummy pixel having a dummy element and a dummy circuit and not displaying an image;
A plurality of pixel power supply lines for supplying driving power to the plurality of pixels;
A power supply wiring to which driving power is supplied from the outside; And
And a power sharing wiring for sharing the driving power supplied from the power supply wiring through the conductive layer of the dummy element or the dummy circuit by the plurality of pixel power supply wirings.

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