KR101351797B1 - Slimming touch screen panel - Google Patents

Abstract

The present invention relates to an ultra-slim integrated touch screen panel in which a touch sensing substrate for sensing a touch signal in a capacitive manner is attached in close contact with a display substrate for displaying a screen image.
An ultra-slim integrated touch screen panel according to the present invention is a laminated body including a transparent touch plate capable of touching the front surface, a transparent electrode laminated on a rear surface of the touch plate and sensing whether or not the touch is performed in a capacitive manner, and the transparent A touch sensing substrate including a wire part connected to supply an electric current to an electrode, and a printed layer printed on a rear surface of the touch plate and covering the wire part; A display substrate including a top plate to which the touch sensing substrate is bonded; And a processing groove provided on a contact surface of the touch sensing substrate and the display substrate and on which the wire part and the print layer are seated.

Description

Ultra Slim Integrated Touch Screen Panel {SLIMMING TOUCH SCREEN PANEL}

The present invention relates to an ultra-slim integrated touch screen panel in which a touch sensing substrate for sensing a touch signal in a capacitive manner is attached in close contact with a display substrate for displaying a screen image.

In general, a touch screen panel may input a user's command by selecting an instruction displayed on a screen such as an image display device using a human hand or an object, and converts a contact position into an electrical signal, It is accepted as an input signal.

Such a touch screen panel has been expanded due to the rapid development of smart devices including smart phones, smart pads, and the like.

As a touch screen panel, various methods such as resistive, capacitive, ultrasonic (SAW), and infrared (IR) methods have been applied. It is widely applied.

The capacitive touch screen panel detects and drives static electricity generated by the human body. It is durable, has a short response time, has good permeability, and has a multi-touch function that recognizes more than one place. It is becoming.

At this time, the touch sensing substrate that serves to detect the position is provided with a laminated structure capable of sensing a touch on the rear surface of the glass shape, and the wires for supplying current to the transparent electrode of the laminated structure are connected to the external FPCB. In order to prevent the user from seeing such wires through the touch sensing substrate, a separate printed layer is provided on the touch sensing substrate.

The touch sensing substrate configured as described above is formed such that the thickness of the laminated structure is formed in nm units, whereas the thickness of the printed layer is formed in μm units so that the laminated structure and the printed layer are stepped.

Therefore, in the conventional integrated touch screen panel, when the stepped touch sensing substrate is bonded to the flat display substrate, it is difficult to provide a clear screen by lowering the transmittance because it occurs in the space between the touch sensing substrate and the display substrate. There is a problem that the thickness of the product becomes thick.

In addition, since the stepped portion of the touch sensing substrate is formed and the transparent electrode is pulled out so as to be connected to the wire part to pass through the stepped portion, the touch sensing substrate is damaged due to repetitive touch operation, or the touch sensing Noise or malfunction occurs due to the warpage of the substrate.

In addition, since the transparent electrode is drawn out through the stepped portion of the touch sensing substrate, there is a problem in that the drawn portion of the transparent electrode is disconnected due to repeated friction with the stepped portion during touch operation.

In addition, when the adhesive is applied to bond the touch-sensitive substrate and the display substrate thus manufactured, bubbles are generated because the stepped portion of the touch-sensitive substrate and the flat portion of the display substrate contact each other to form a predetermined space. There is a problem that a defect occurs in the bonding process.

The present invention has been made to solve the above problems of the prior art, an object of the present invention is to provide an ultra-slim integrated touch screen panel that can be in close contact with the touch sensing substrate and the display substrate.

In addition, an object of the present invention is to provide an ultra-slim integrated touch screen panel which can reduce the step of the printed layer or the wire portion on the touch sensing substrate side.

According to the present invention, a laminate including a transparent touch plate capable of touching the front surface, a transparent electrode stacked on a rear surface of the touch plate, and sensing a touch by a capacitive method is connected to supply current to the transparent electrode. A touch sensing substrate including a wire portion and a printed layer printed on a rear surface of the touch plate and covering the wire portion; A display substrate including a top plate to which the touch sensing substrate is bonded; And a processing groove provided on the contact surface of the touch sensing substrate and the display substrate, wherein the processing groove in which the wire part and the print layer are seated provides a super slim integrated touch screen panel.

Since the ultra-slim integrated touch screen panel according to the present invention is closely adhered so as not to have a step between the touch sensing substrate and the display substrate, the user can see the image more clearly, thereby improving the quality and reducing the thickness of the product. have.

In addition, the ultra-slim integrated touch screen panel according to the present invention seats the printed layer or the wire portion in a predetermined processing groove on the side of the touch sensing substrate, so that the wire portion is drawn out horizontally between the touch sensing substrate and the display substrate. Therefore, even if the user repeatedly touches, there is an advantage of preventing breakage of the touch sensing substrate and reducing noise and malfunction due to warpage of the touch sensing substrate.

In addition, the ultra-slim integrated touch screen panel according to the present invention not only reduces the disconnection of the transparent electrode drawn out between the touch sensing substrate and the gaseous substrate, but also reduces the defect rate due to bubble generation when the adhesive is applied, and furthermore, the use of the adhesive There is an advantage that can be significantly reduced.

1 is an exploded view showing a first embodiment of a super slim integrated touch screen panel according to the present invention;
FIG. 2 is an enlarged view of a portion A of FIG. 1; FIG.
FIG. 3 is a view illustrating the ultra-slim integrated touch screen panel of FIG. 1 assembled; FIG.
Figure 4 is an exploded view showing a second embodiment of the ultra-slim integrated touch screen panel according to the present invention.
FIG. 5 is a view illustrating the ultra-slim integrated touch screen panel of FIG. 4 assembled; FIG.

Hereinafter, the present embodiment will be described in detail with reference to the accompanying drawings. It should be understood, however, that the scope of the inventive concept of the present embodiment can be determined from the matters disclosed in the present embodiment, and the spirit of the present invention possessed by the present embodiment is not limited to the embodiments in which addition, Variations.

1 to 3 are diagrams illustrating a first embodiment of a super slim integrated touch screen panel according to the present invention.

The first embodiment of the ultra slim integrated touch screen panel according to the present invention may be configured such that the touch sensing substrate 100 and the display substrate 200 are in close contact with each other as shown in FIGS. 1 to 3.

The touch sensing substrate 100 may be configured to include a touch plate 110, a laminate 120, a printed layer 130, an electric wire unit 140, and a detection sensor unit 150. .

The touch plate 110 may be made of various materials such as plastic and glass as a transparent form, but may be limited to glass in the embodiment of the present invention. In this case, the user may touch the upper surface of the touch plate 110, and other components may be provided on the rear surface of the touch plate 110.

In particular, a predetermined processing groove 111 is provided in an area where the printing layer 130 is to be printed on the rear surface of the touch plate 110, and the printing layer 130 or an electric wire part ( 140 may be seated. At this time, the thickness of the processing groove 111 is set in consideration of the thickness of the laminate 120 and the printed layer 130 or the wire portion 140, preferably the thickness (h) of the processing groove 111 ) May be set to a value obtained by subtracting the thickness (c) of the laminate 120 from the value of the thickness (a) of the printed layer 130 and the thickness (b) of the wire part 140. Therefore, when viewed from the rear surface of the touch plate 110, the laminate 120 and the printed layer 130 or the wire portion 140 is formed to form the same plane, or only to allow a minute step.

The processing groove 111 may be a chemical etching method or a physical polishing method to be formed in the glass-shaped touch plate 110, but is not limited. For example, in the case of a chemical etching method, by masking and protecting the surface of the touch plate 110 except for the portion where the processing groove 111 is to be located, and then etching using a predetermined chemical, the processing groove of the desired thickness and shape (111) can be implemented. As another example, in the case of the physical polishing method, when the portion in which the processing groove 111 is to be worn is worn using a sand blaster, a processing groove having a desired thickness and shape may be realized. Of course, in the case of the physical polishing method, the processing groove 111 may be implemented using various equipment such as a polished stone, a laser, a water zet device, and the like.

The laminate 120 is formed by stacking a plurality of layers provided on the rear surface of the touch plate 110, and may be configured to detect a touch in a capacitive manner. Such a laminate 120 is an optical layer 121, the transparent electrode 122, the shielding layer 123, the transparent electrode 124, the adhesive layer 125, the shielding layer 126 in the embodiment of the present invention sequentially It is configured to be laminated, and is manufactured in a transparent form, but is not limited. Of course, the laminate 120, but a plurality of layers are stacked, the thickness is configured in a thin unit in nm.

However, the laminate 120 is configured to necessarily include transparent electrodes 122 and 124 in the form of ITO, etc., through which current can flow, and the transparent electrodes 122 and 124 include a wire portion 140 through which current can be transferred. Is connected, the wire unit 140 is configured to be connected to the touch sensor unit 150 of the control panel on the outside.

The print layer 130 may be provided at a rear edge of the touch plate 110 to be positioned around the laminate 120 and may be in a printed form. In this case, the printed layer 130 to cover the portion that the wire portion 140 is drawn out to prevent the wire portion 140 is visible through the transparent touch plate 110 and the laminate 120 to the user. Is printed. In this case, the printed layer 130 is thicker than the laminate 120 in a unit of μm, but is formed to form the same plane as the laminate 120 as it is seated in the processing groove 111. .

The display substrate 200 may be composed of upper and lower plates 210 and 220 maintaining a predetermined gap, and liquid crystal positioned between the upper and lower plates 210 and 220, and the upper and lower plates 210 and 220 may be plastic, Glass or the like. In this case, the rear surface of the touch sensing substrate 100 is mounted on the upper surface of the display substrate 200, and the laminate 120, the printed layer 130, and the wire unit 140 are connected to the upper plate 210. Close contact.

Thus, since the touch-sensitive substrate 100 and the display substrate 200 are in close contact with each other, the user may clearly see the screen displayed on the display substrate 200, and the overall thickness may be thin.

In addition, since the step between the touch sensing substrate 100 and the display substrate 200 may be eliminated, the touch sensing substrate 100 may be prevented from being damaged during repeated touch operations of the user, and the touch sensing substrate 100 may be used. Noise and malfunction caused by the warpage phenomenon of b) can be reduced.

In addition, since the step between the touch sensing substrate 100 and the display substrate 200 can be eliminated, the disconnection of the transparent electrode 124 due to the step can be reduced, and the defective rate due to the disconnection can be reduced.

In addition, since the touch-sensitive substrate 100 and the display substrate 200 are adhered to each other by applying an adhesive on a flat surface, the defective rate of the adhesion process due to bubble generation may be reduced.

4 to 5 are diagrams illustrating a second embodiment of the ultra slim integrated touch screen panel according to the present invention.

According to the second embodiment of the ultra-slim integrated touch screen panel according to the present invention, the laminate 120, the printed layer 130, and the wire part 140 are provided on the rear surface of the touch plate 110 in the same manner as the first embodiment. A touch sensing substrate 100 and a display substrate 200 having a liquid crystal 230 between upper and lower plates 210 and 220. The printed layer 130 or the wire part 140 is formed on the upper plate 210. ) Is provided with a processing groove 211 to be seated. In this case, the transparent electrode 124 included in the laminate 120 is drawn out to the stepped portion of the printed layer 130, and the drawn portion of the transparent electrode 124 is drawn out by the printed layer 130. It is connected to the covered wire part 140, which is to prevent the wire part 140 from being exposed to the stepped part of the printed layer 130 and visible to the user.

That is, the touch sensing substrate 100 has a predetermined step as the print layer 130 and the wire unit 140 protrude from the rear surface of the touch plate 110, whereas the display substrate 200 The processing groove 211 is formed on the upper surface of the upper plate 210. At this time, the top plate 210 may be made of various materials such as plastic, glass, etc., in the embodiment of the present invention is configured in the form of glass, the processing groove 211 is as described in the first embodiment A chemical etching method or a physical polishing method may be processed on the upper edge portion of the upper plate 211.

Therefore, when the touch sensing substrate 100 is adhered to the display substrate 200, the printed layer 130 and the wire unit 140 of the touch sensing substrate 100 are processed on the display substrate 200. It is seated in the groove 211, the stack 120 of the touch sensing substrate 100 is in close contact with the top plate 210 of the display substrate 200. In this case, as the contact between the touch sensing substrate 100 and the display substrate 200 is closely adhered, visibility may be increased, the product may be slimmed, and breakage / disconnection and malfunction may be prevented.

100: touch sensing substrate 110: touch plate
111: processing groove 120: laminated body
130: printed layer 140: wire portion
150: touch sensor unit 200: display substrate

Claims (5)

A laminated body including a transparent touch plate capable of touching the front surface, a transparent electrode stacked on a rear surface of the touch plate, the transparent electrode sensing whether or not the touch is capacitively connected, and a wire part connected to supply current to the transparent electrode; A touch sensing substrate printed on a rear surface of the touch plate and including a printed layer covering the wire part;
A display substrate including a top plate to which the touch sensing substrate is bonded; And
And a processing groove provided on the contact surface of the touch sensing substrate and the display substrate, wherein the processing groove is mounted on the wire part and the printing layer. The method of claim 1,
The super slim integrated touch screen panel is bonded such that the stack of the touch sensing substrate is in contact with the top plate of the display substrate. The method of claim 1,
The processing groove is an ultra-slim integrated touch screen panel provided on the touch plate or the upper plate of the display substrate. The method of claim 3,
The depth (h) of the processing groove is set to a value obtained by subtracting the thickness (c) of the laminate from the sum of the thickness (a) of the printed layer and the thickness (b) of the wire. 5. The method according to any one of claims 1 to 4,
The touch panel or the upper plate is a super slim integrated touch screen panel of plastic or glass (glass).

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