KR20170074615A - Flexible Display - Google Patents

Abstract

The flexible display according to the present invention may include a display panel, a touch transmission line and a touch reception line, a touch IC, and a pressure sensing layer. The display panel may include a display area and a non-display area, and a pressure sensing layer may be stacked on the touch transmission line of the non-display area. In the case of the conventional flexible display, a rolling or folding angle of the flexible display can be determined by providing a piezoelectric sensor and a strain gauge sensor and a separate processing circuit. However, in the flexible display according to the present invention, the pressure sensing layer formed of QTC (Quantum Tunneling Composite) is laminated on the transmission line in the non-display area, and the resistance change when the flexible display is rolled or folded is sensed using the touch IC . Therefore, unlike the conventional flexible display, since the resistance change is sensed by using the touch IC, the rolling or folding angle of the flexible display can be recognized without any additional processing circuit.

Description

[0001] Flexible Display [

The present invention relates to a flexible display.

2. Description of the Related Art [0002] As a demand for a small-sized display device required for various portable electronic devices such as a mobile phone, a PDA (Personal Digital Assistants), and a notebook computer is required, Display Device) is increasing. Examples of such flat panel display devices include a liquid crystal display, an organic light emitting display, a plasma display panel (PDP), a field emission display (FED), and a vacuum fluorescent display (VFD) .

Recently, as demand for products requiring portability such as electronic sheets (Electro Sheet), arm band, and e-book has increased, development of flexible display devices has progressed . Therefore, a flexible display manufactured by using a substrate of a flexible material such as plastic instead of a silicon substrate or a glass substrate having no flexibility is emerging as a next generation display device.

In the case of such a flexible display, it is necessary to detect the deformation of the display device to change the contents displayed on the display, or to change the tactile and auditory feedback. There may also be various feedbacks, such as changing the execution mode to suit the shape change of the device, changing the UI (user interface) structure, adjusting the scroll speed, or executing the associated menu. Such a feedback senses the deformation of the display device using a sensor included in the flexible display. Examples of such sensors include a strain gauge sensor, a piezoelectric sensor, and the like.

In the conventional display device, a dedicated sensor such as a strain gauge sensor and a dedicated processing circuit must be used in order to detect deformation, resulting in an increase in manufacturing cost.

It is an object of the present invention to provide a flexible display capable of measuring deformation without a separate processing circuit.

According to an aspect of the present invention, there is provided a flexible display comprising: a plurality of touch transmission lines for providing touch detection signals; a plurality of touch reception lines for outputting touch detection signals; Receiving a signal through the display panel including the pressure sensing layer on the touch transmission line of the display panel, the plurality of touch transmission lines and the plurality of touch reception lines, and determining whether the touch panel of the display panel and the display panel are folded or rolled And a touch IC for detecting the touch.

In the flexible display according to the present invention, a pressure sensing layer is laminated on a touch transmission line in a non-display area, and the change is sensed in the touch IC according to the resistance change, thereby detecting deformation of the flexible display without a separate processing circuit It is possible to have an effect that can be achieved.

1 is a view illustrating a display panel according to a first embodiment of the present invention.
2 is an enlarged cross-sectional view taken along the line A-A 'in Fig.
3 is a diagram illustrating an operation circuit of a soft display device according to an embodiment of the present invention.
4A to 4C are diagrams illustrating changes in an output signal according to a resistance change of the pressure sensing layer according to an embodiment of the present invention.
5 is a view illustrating folding of a flexible display according to an embodiment of the present invention.
6 is a diagram illustrating rolling of a flexible display according to an embodiment of the present invention.

BRIEF DESCRIPTION OF THE DRAWINGS The above and other features and advantages of the present invention will become more apparent from the following detailed description taken in conjunction with the accompanying drawings, in which: FIG. In the description of the embodiments, it is to be understood that each layer (film), region, pattern or structure may be referred to as being "on" or "under" a substrate, each layer It is to be understood that the terms " on "and " under" include both " directly "or" indirectly " do. In addition, the criteria for the top / bottom or bottom / bottom of each layer are described with reference to the drawings.

Furthermore, terms including ordinals such as first, second, etc. used in this specification may be used to describe various components, but since the terms are used only for the purpose of distinguishing one component from another, The elements are not limited to these terms.

It will be understood that when an element or layer is referred to as being another element or "on" or "on ", it includes both intervening layers or other elements in the middle, do. On the other hand, when a device is referred to as "directly on" or "directly above ", it does not intervene another device or layer in the middle.

Unless otherwise defined, all terms used herein, including technical or scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. Terms such as those defined in commonly used dictionaries are to be interpreted as having a meaning consistent with the contextual meaning of the related art and are to be interpreted as either ideal or overly formal in the sense of the present application Do not.

The terminology used herein is for the purpose of describing embodiments only and is not intended to be limiting of the invention. In the present specification, the singular form includes plural forms unless otherwise specified in the specification. &Quot; comprise "and / or" comprising ", as used in the specification, means that the presence of stated elements, Or additions.

1 is a plan view of a flexible display according to an embodiment of the present invention.

1, a flexible display 100 according to an exemplary embodiment of the present invention includes a touch IC 20, a pressure sensing layer 30, a plurality of touch transmitters 40, a plurality of touch receivers 50, A touch transmission electrode 41, a plurality of touch receiving electrodes 51, and a touch line. The touch line may include a plurality of touch transmission lines TX ₁ to TX _x and a plurality of touch reception lines RX ₁ to RX _y . The plurality of touch transmission lines TX1 to TXx and the plurality of touch reception lines RX1 to RXy may connect a plurality of touch transmission electrodes 41 and a plurality of touch reception electrodes 51, respectively.

The display panel 10 may include a display area A / A and a non-display area N / A. A plurality of touch transmission electrodes 41, a plurality of touch reception electrodes 51, a plurality of first touch transmission lines (TX ₁ to TX _x ), a plurality of touch transmission electrodes 1 touch reception lines RX ₁ to RX _y may be arranged. A touch IC 20, a plurality of second touch transmission lines TX ₁ to TX _x and a plurality of second touch reception lines RX ₁ to RX _{y are} provided in a non-display area N / A of the display panel 10, , And a pressure sensing layer (30). The display panel 10 may include a touch panel.

The touch panel may be a member for detecting the coordinates of the position where the touch input is generated by the user or the object, that is, the X-axis coordinate and the Y-axis coordinate. For example, various methods such as Resistive Overlay, Capacitive Overlay, Surface Acoustic Wave, Infrared, and Surface Acoustic Wave can be applied to the touch panel. In the present invention, a touch panel using a capacitive method will be described. The electrostatic capacitive method is a method in which a transparent film or a transparent electrode layer is coated on a touch panel and a certain amount of electric current is applied to the touch panel, and then a change in capacitance caused when a finger or a stylus pen touches the surface of the touch screen is detected, Or the like. The capacitance type may include a ground capacitance type (Self capacitance) and a mutual capacitance type (mutual capacitance type). In the ground capacitance method, a touch is recognized by touch recognition, and one electrode is used for each basic pixel to read a capacitance change of the electrode to realize a touch. The mutual capacitance type is a method of using the capacitance between the electrodes. One electrode is arranged in the horizontal axis and the other electrode is arranged in the vertical axis to form a lattice structure, and then the capacitance formed at the intersection between the two axes is sequentially measured You can detect the capacitance change at a specific point. The electrode may be formed in the display area of the display. Accordingly, the electrode may be formed of a transparent conductive material (Indium Tin Oxide).

The mutual capacitance type can be divided into an add-on type, a cover window integral type, and a display integral type. Among them, the display integrated type may be a system in which a transmitting electrode and a receiving electrode are built in a display. In the case of a display-integrated type, there may be an on-cell type in which a transparent electrode is patterned on a display panel, and an in-cell in which a transparent electrode is patterned in a display to form a sensor . Unlike an add-on type touch panel using a touch electrode provided on a separate touch panel, a common electrode can be used as a touch electrode for touch recognition in a touch panel using an in-cell type structure.

The display panel 10 may include a plurality of touch transmitters 40 and a plurality of touch receivers 50. The plurality of touch transmitters 40 may include a plurality of touch transmit electrodes 41 and a plurality of first touch transmit lines TX ₁ to TX _x . The plurality of touch transmitting electrodes 41 may have a rhombus shape. However, the shapes of the plurality of touch transmitting electrodes 41 are not limited thereto. The plurality of touch transmitting electrodes 41 may be disposed within the display panel 10 at a distance from each other.

The plurality of first touch transmission lines TX ₁ to TX _x may connect the plurality of touch transmission electrodes 41. The plurality of touch transmission electrodes 41 may be connected to the touch IC 20 by a plurality of first touch transmission lines TX ₁ to TX _x and a plurality of second touch reception lines TX ₁ to TX _x .

The plurality of touch receiving units 50 may include a plurality of touch receiving electrodes 51 and a plurality of first touch receiving lines RX ₁ to RX _y .

The plurality of touch receiving electrodes 51 may have a rhombic shape. However, the shape of the plurality of touch receiving electrodes 51 is not limited thereto. The plurality of touch receiving electrodes 51 may be disposed within the display panel 10 at a distance from each other.

The plurality of first touch receiving lines RX ₁ to RX _y may connect each of the plurality of touch receiving electrodes 51. The plurality of touch receiving electrodes 51 may be connected to the touch IC 20 by a plurality of first touch receiving lines RX ₁ to RX _y and a plurality of second touch receiving lines RX ₁ to RX _y .

The plurality of first touch transmission lines TX ₁ to TX _x and the plurality of first touch reception lines RX ₁ to RX _y may be arranged orthogonally to each other. When the display area A / A is touched by a user's hand or an object, the electrostatic capacity between the plurality of touch transmitting electrodes 41 and the plurality of touch receiving electrodes 51 changes, TX ₁ ~ TX _x) and a plurality of touch reception line (RX ₁ ~ RX _y) is to transmit the changed capacitance with the touch IC (20), the touch-IC (20) in the plurality of touch receiving electrode (41) and a plurality of The touch can be recognized by measuring the capacitance change between the touch transmitting electrodes 51. [

The pressure sensing layer 30 may be disposed on the touch line. The pressure sensing layer 30 may be disposed on a plurality of touch transmission lines TX1 to TXx and a plurality of touch reception lines RX1 to RXy. The pressure sensing layer 30 may be disposed on the plurality of second touch transmission lines (TX ₁ to TX _x ) in the non-display area. The pressure sensing layer 30 may be stacked on a plurality of second touch transmission lines TX ₁ to TX _x by ink jet printing, sputtering, or the like.

The pressure sensing layer 30 may be formed of a Quantum Tunneling Composite (QTC). The pressure sensing layer 30 may be made of a conductive material such as nickel (Ni). The pressure sensing layer 30 can be formed by mixing a conductive particle with a polymer material such as rubber as a base material at an appropriate ratio. The pressure sensing layer 30 may be a conductive rubber using carbon black as a conductive particle or a force sensing resistor (FSR). QTC can vary greatly in resistance depending on the applied force. For example, the resistance of the QTC can be 10 ¹² ohms when not subjected to force. For example, the resistance when applying a force to the QTC can be less than 1 ohm. The pressure sensing layer 30 may be stacked on the plurality of touch second transmission lines TX ₁ to TX _x formed on the side surface of the non-display area. The pressure sensing layer 30 may be subjected to a force when the display panel 10 is rolled or folded. Therefore, the resistance of the pressure sensing layer 30 greatly varies, and the current flowing along the plurality of second touch transmission lines TX ₁ to TX _x may change. The touch IC 20 senses this change and can recognize the rolling or folding state of the display panel 10. [

In the case of conventional flexible displays, piezoelectric sensors and strain gauge sensors were used to determine the rolling or folding state of the flexible display. A separate processing circuit has to be added in order to know the rolling or folding state by using the existing sensor, so that the manufacturing cost is increased. However, in the case of the flexible display according to the embodiment of the present invention, the pressure sensing layer 30 is stacked on the plurality of second touch transmission lines (TX ₁ to TX _x ) in which the non-display region of the display panel is formed By measuring the change in resistance due to the pressure sensing layer 30 with the touch IC 20, the degree of rolling or the folding angle can be known without addition of a separate processing circuit, thereby reducing the manufacturing cost.

2 is a cross-sectional view taken along line A-A 'in Fig.

Referring to FIG. 2, the pressure sensing layer 30 may be formed on a plurality of second touch transmission lines TX ₁ to TX _x . When the display area is touched by a user's hand or an object, a capacitance change may occur between the plurality of touch transmitting electrodes 41 and the plurality of touch transmitting electrodes 51. [ The touch IC 20 changes the capacitance between the plurality of touch transmission electrodes 41 and the plurality of touch transmission electrodes 51 to a plurality of first transmission lines TX ₁ to TX _x and a plurality of second touch transmission lines 51. [ A touch of the display panel 10 is sensed by sensing signals through the plurality of first reception lines TX ₁ to TX _x , the plurality of first reception lines RX ₁ to RX _y and the plurality of second reception lines RX ₁ to RX _y , can do. When the pressure sensing layer 30 is not stacked on the plurality of second touch transmission lines TX ₁ to TX _x of the non-display area N / A, even if the flexible display is rolled or folded, There may be no resistance change of the transmission lines (TX ₁ to TX _x ). Therefore, even if the flexible display is rolled or folded, there is no change in the signal flowing along the plurality of second touch transmission lines (TX ₁ to TX _x ) in the non-display area N / A. However, when the pressure sensing layer 30 is stacked on the plurality of second touch transmission lines (TX ₁ to TX _x ) in the non-display area N / A, when the flexible display is rolled or folded, A force may be applied to the pressure sensing layer 30 stacked on the plurality of second touch transmission lines TX ₁ to TX _x on the area N / A. Accordingly, as the force is applied to the pressure sensing layer 30, the resistance of the pressure sensing layer 30 may vary. As the resistance of the pressure sensing layer 30 changes, a signal flowing along the plurality of touch transmission lines TX ₁ to TX _x may change. Accordingly, the touch IC 20 senses a signal to be measured on the touch IC 20 according to the resistance change of the pressure sensing layer 30, thereby detecting the rolling or folding of the flexible display of the present invention.

When the display panel 10 is not rolled or folded, there is no force applied to the pressure sensing layer 30. At this time, the resistance of the pressure sensing layer 30 may be 10 ¹² ohm, for example. The resistance of the pressure sensing layer 30 may be higher than the resistance of the plurality of second touch transmission lines TX ₁ to TX _x . Therefore, there may be no change in the current flowing along the plurality of second touch transmission lines (TX ₁ to TX _x ). The touch IC 20 can not sense the resistance change of the pressure sensing layer 30 because there is no change in the current flowing along the plurality of second touch transmission lines TX ₁ to TX _x .

When the display panel 10 is rolled or folded, the pressure sensitive layer 30 may be subjected to a force. Thus, the resistance of the pressure sensing layer 30 including the QTC can vary. At this time, the resistance of the pressure sensing layer 30 may be less than 1 ohm, for example. The resistance of the pressure sensing layer 30 may be lower than the resistance of the plurality of second touch transmission lines TX ₁ to TX _x . Therefore, a change may occur in the current flowing along the plurality of second touch transmission lines (TX ₁ to TX _x ). The touch IC 20 can sense the resistance change of the pressure sensing layer 30 by changing the current flowing along the plurality of second transmission lines TX ₁ to TX _x . If the touch IC 20 senses the change in resistance of the pressure sensing layer 30, it can be determined whether the flexible display according to the present invention is rolled or folded.

3 is a diagram illustrating an operation circuit of a soft display device according to an embodiment of the present invention.

 4A to 4C are diagrams illustrating changes in an output signal according to a resistance change of the pressure sensing layer according to an embodiment of the present invention.

Referring to FIG. 3 and FIGS. 4A to 4C, C13 may indicate a capacitance between the touch transmitting electrode 41 and the touch receiving electrode 51. FIG. R2 may be the resistance of the touch transmission line (TX ₁ TX ~ _x) in the non-display area. C11 may be the parasitic capacitance of the display panel. At this time, the time constants of the second touch transmission lines (TX ₁ to TX _x ) vary depending on the resistance (R _Tx ) of the second touch transmission lines (TX ₁ to TX _x ) in the non-display area. If there is a circuit in which the resistor (R) and the capacitor (C) are connected in series, if the constant voltage DC is applied at the time 0, the voltage across the capacitor does not suddenly rise and exponential And an applied DC voltage can be reached if a certain amount of time is passed. At this time, the time at which approximately 63% of the applied DC voltage is reached can be considered as a time constant. Second touch the time constant of the transmission line (TX ₁ TX ~ _x) may vary according to the resistance (R2) of the second touch transmission line (TX ₁ TX ~ _x). The second touch pressure laminated to the transmission line (TX ₁ ~ TX _x) of the resistance (R2) of the second touch transmission line (TX ₁ ~ TX _x) which is formed on the non-display region is the non-display area detection layer ( 30). ≪ / RTI > The pressure sensing layer 30 laminated to the second touch transmission lines (TX ₁ to TX _x ) of the non-display area may cause a change in resistance when the flexible display is rolled or folded. Therefore, when the flexible display according to the embodiment of the present invention is rolled, the resistance of the second touch transmission lines (TX ₁ to TX _x ) in the non-display area changes, so that the second touch transmission lines (TX ₁ to TX _x ) The time constant of the voltage Vc can also be changed. Since the voltage outputted to the ADC changes as the time constant of the second touch transmission lines (TX ₁ to TX _x ) changes, the touch IC 20 senses this change and recognizes the rolling degree or the folding angle of the flexible display device have.

For example, the resistance R _tx when the second touch transmission lines TX ₁ to TX _x is rolled or folded is 1 Kohm and the capacitance C _tx of the second touch transmission lines TX ₁ to TX _x ) May be 100 pF. At this time, the time constant is 0.1us and the voltage output to the ADC may be 2.8V. For example, the resistance R _tx when the second touch transmission lines TX ₁ to TX _x is rolled or folded is 10 kohm and the capacitance C _tx of the second touch transmission lines TX ₁ to TX _x ) May be 100 pF. At this time, the time constant is 1us and the voltage output to the ADC may be 2.4V. For example, the resistance R _tx when the second touch transmission lines TX ₁ to TX _x are not rolled or folded is 20 kohm and the capacitance C _tx of the second touch transmission lines TX ₁ to TX _x ) May be 100 pF. At this time, the time constant of the second touch transmission lines (TX ₁ to TX _x ) is 2us and the voltage output to the ADC may be 1.6V. Therefore, it can be seen that the time constant changes when the flexible display device according to the present invention is rolled or folded, when the rolling degree and the folding angle, when the resistance of the pressure sensing layer 30 is changed when the flexible display device is not rolled or folded, (20) senses this change and detects whether the flexible display device is rolling or folding.

5 is a view illustrating folding of a flexible display according to an embodiment of the present invention.

Referring to FIG. 5, in the flexible display according to the present invention, the pressure sensing layer 30 may be formed only in a predetermined folding region. However, the region where the pressure sensing layer 30 is formed is not limited thereto.

When the flexible display according to the present invention is folded, the plurality of second touch transmission lines (TX ₁ to TX _x ) in the non-display area can also be folded. Thereby, a force can be applied to the plurality of second touch transmission lines (TX ₁ to TX _x ) in the non-display area, and the pressure formed on the plurality of second touch transmission lines (TX ₁ to TX _x ) Force may also be applied to the sensing layer 30. The magnitude of the force applied to the pressure sensing layer 30 may vary depending on the angle at which the flexible display is folded. As shown in Fig. 5, the angle at which the flexible display is folded may be R1 < R2 < R3. The magnitude of the force applied to the pressure sensing layer 30 may vary depending on the angle at which the flexible display is folded. Therefore, the resistance of the pressure sensing layer 30 can also be varied. The resistance of the pressure sensing layer 30 may be R1>R2> R3.

As the folding angle of the flexible display according to the present invention changes, the magnitude of the force applied to the pressure sensing layer 30 may be varied, and thus the resistance change of the pressure sensing layer 30 may be varied. The greater the folding angle of the flexible display is, the lower the resistance can be. The touch IC 20 senses the change in resistance of the pressure sensing layer 30 depending on the angle at which the flexible display according to the present invention is folded. Therefore, the folding angle of the flexible display according to the resistance change of the pressure sensing layer 30 .

6 is a diagram illustrating rolling of a flexible display according to an embodiment of the present invention.

Referring to FIG. 6, the pressure sensing layer 30 of the flexible display according to the present invention may be formed in all areas of the second touch transmission lines TX ₁ to TX _x .

When the flexible display according to the present invention is rolled, a plurality of second touch transmission lines (TX ₁ to TX _x ) in the non-display area can also be rolled. Pressure sensing layer 30 is formed on the plurality of second touch transmission line (TX ₁ ~ TX _x) as the plurality of second touch transmission lines of the non-display region (TX ₁ ~ TX _x) The rolling may also be a rolling . Accordingly, as the flexible display is rolled, a plurality of second transmission lines TX ₁ to TX _x will be subjected to a force, and the pressure sensing layer 30 formed on the plurality of second touch transmission lines TX ₁ to TX _x , It is also possible to apply force. As the pressure is applied to the pressure sensing layer 30, the resistance of the pressure sensing layer 30 may change. The linear resistance of the pressure sensing layer 30 may vary depending on the section in which the flexible display is rolled. The section where the flexible display is rolled may be R1 > R2 > R3. Therefore, the force applied to the pressure sensing layer 30 of the flexible display may be R1 <R2 <R3. Therefore, the linear resistance of the pressure sensing layer 30 of the flexible display may be R1>R2> R3. In the touch IC 20, the line resistance of the pressure sensing layer 30 can be sensed according to the section in which the flexible display according to the present invention is rolled. Since the line resistance changes according to the rolled section, Can be sensed by the touch IC (20).

As described above, the flexible display according to the embodiment of the present invention can know the degree of folding or rolling of the flexible display by stacking the pressure sensing layer on the second touch transmission line in the non-display area. In the case of the conventional flexible display, it is possible to know the degree of rolling or folding of the flexible display by providing a piezoelectric sensor and a strain gauge sensor and constituting a separate processing circuit. However, in the case of the flexible display according to an embodiment of the present invention The pressure sensing layer including the QTC is stacked on the second touch transmission line of the non-display area, and the change in resistance of the QTC is sensed by using the touch IC, thereby indicating the rolling or folding of the flexible display. Therefore, even if a separate processing circuit is not provided, the degree of rolling or folding angle of the flexible display according to the present invention can be known by using the touch IC, so that the manufacturing cost can be reduced.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, It will be understood that various modifications and applications are possible. For example, each component specifically shown in the embodiments can be modified and implemented. It is to be understood that all changes and modifications that come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein.

10: display panel 20: touch IC 30: pressure sensing layer
TX ₁ to TX _x : a plurality of touch transmission lines RX ₁ to RX _y : a plurality of touch reception lines

Claims (9)

Touch IC;
A display panel having a display area and a non-display area;
A plurality of touch transmitting electrodes and a plurality of touch receiving electrodes in the display area;
A touch line connecting the plurality of touch transmitting electrodes or the plurality of touch receiving electrodes; And
And a pressure sensing layer having a Quantum Tunneling Composite (QTC) on the touch line.
The method according to claim 1,
And the pressure sensing layer is disposed on the touch line of the non-display area.
The method according to claim 1,
Wherein the pressure sensing layer has a resistance varying according to applied pressure.
The flexible display according to claim 1, wherein the QTC comprises any one of conductive rubber or FSR (Force Sensing Resistor) using carbon black as a conductive particle.
The method according to claim 1,
Wherein the pressure sensing layer has a resistance varying according to a folding angle of the display panel.
3. The method of claim 2,
Wherein the pressure sensing layer is provided in a region where the display panel is folded.
3. The method of claim 2,
Wherein the pressure sensing layer extends along a rolling direction of the display panel.
3. The method of claim 2,
Wherein the pressure sensing layer has a resistance varying according to a degree to which the display panel is rolled.
The method according to claim 6,
Wherein the pressure sensing layer is provided only in a part of a non-display area of a predetermined folding area of the display panel.

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