KR101206341B1 - touch screen panel with white coating layer - Google Patents

Abstract

PURPOSE: A touch screen panel which a white coating layer is formed is provided to thinly make thickness of the white coating layer by using a vacuum coating method. CONSTITUTION: A coating layer is successively formed in a back side of a glass plate(10) with a vacuum coating method. The coating layer is differently formed in a border unit and a central unit of the back side of the glass plate. A central unit coating layer is formed by successively laminating a SiO2 coating layer(50) and an indium tin oxide coating layer(60). A border coating layer is a white coating layer. The border coating layer is formed by successively laminating a MgO coating layer(20), a Ag coating layer(30), a TiO+SiO or SiO2+TiO2 coating layer(40), the SiO2 coating layer and the indium tin oxide coating layer in the glass plate with an uneven unit. The uneven unit is formed by sanding or etching.

Description

Touch screen panel with white coating layer

The present invention relates to a touch screen panel having a white coating layer, and more particularly to a touch screen panel having a white coating layer for forming a white coating layer by a vacuum coating method on the touch screen panel.

Recently, a touch screen panel (TSP) in which transparent electrodes are integrated into a display and tempered glass has been developed. As an example, as described in Patent Registration Publication No. 10-0974073 as a background art, The touch screen panel (TSP) is a flat panel display device that has various advantages such as an electronic organizer, a liquid crystal display device (LCD), a plasma display panel (PDP), an electroluminescense (EL), and a cathode ray tube (CRT). It is a tool that has the function of Flat-Panel-Display and is used to allow the user to select the desired information through the display. It is largely 1) resistive type and 2) capacitive type. And 3) resistive-multi-type.

1) Resistive type is formed by coating resistive material on glass or plastic plate and covering polyethylene film on it. Insulating rods are installed at regular intervals so that the two surfaces do not touch each other. The principle of operation is that if a constant current flows through both ends of the resistive film, the resistive film acts like a resistor having a resistive component, so that a voltage is applied at both ends. When contact is made with a finger, the upper surface of the polyester film is bent to connect. Therefore, the resistance component of the two surfaces leads to a parallel connection of the resistors, resulting in a change in the resistance value.

At this time, a change in voltage also occurs due to the current flowing through both ends, and the position of the touched finger can be known by the degree of change in the voltage. The resistive method has a high resolution and the fastest response time by operating by surface pressure, but has only one point and has a high risk of breakage.

 2) Capacitive type is made by coating transparent special conductive metal (TAO) on both sides of heat treated glass. When a voltage is applied to the four corners of the screen, the high frequency spreads in front of the sensor. When a finger touches the screen, the flow of electrons changes and the change is detected to find the coordinates. The fixed capacitance method can be executed by pressing several points at the same time, and has the advantages of high resolution and high durability, but has a disadvantage of low response speed and difficulty in mounting.

 3) The resistive-multi-touch type refers to an implementation that can be implemented in the same way as the fixed capacitance method by supplementing and improving the maximum shortcoming of the resistive film method that can be executed by only one point.

In addition, the touch screen panel (TSP), as well as the problem of signal amplification, the difference in resolution, the difficulty of design and processing technology, as well as the characteristic optical, electrical, mechanical, environmental resistance, input characteristics of each touch screen panel It is selected for individual electronic products in consideration of durability, economical efficiency, etc. In particular, resistive type and capacitive type are widely used in electronic notebooks, PDAs, portable PCs and mobile phones (cell phones). do.

The future direction in the touch screen manufacturing technology, it is necessary to manufacture a thinner thickness of the touch screen panel to have sufficient durability even if the conventional complex process as much as possible. The reason is that even if the display brightness is increased by lowering the light transmittance, the same performance as the existing product can be achieved, thereby reducing the power consumption and increasing the battery usage time.

A resistive type touch screen panel has been proposed.

Looking at the configuration of this technology, the first / first window film (or Overlay Film, 101) provided on one side of the liquid crystal display device, the first film is attached to the lower surface of the window film and provided to electrically input information to the liquid crystal display module 2 ITO film, the window film is provided to protect the first ITO film is made of a general PET (Poly Ethylen Terephthalate) film, the first ITO film is a window film (or OCA (Optical Clear Adhesive) Overlay Film). Each of the first and second ITO films is printed with first and second electrode layers using silver provided at edges, and a double-sided tape is attached between the first and second electrode layers for insulation. And it is spaced by a certain interval by the Dot Spacer is electrically connected to each other when the external pressure (touch) using a finger or a touch pen, so as to detect the correct touch position.

However, the lamination process using an optical clear adhesive (OCA) between the window film (or overlay film) and the first ITO film not only reduces the light transmittance, but also arranges the window film (or overlay film 1) and the OCA. There is a problem in that the process is complicated and the process cost increases because the separate process to be attached to the first ITO film to be performed by.

In addition, the technique patterning the ITO film on which the ITO film is formed through laser wet etching, thus cannot selectively coat ITO on a desired area on the window film (or PET film).

 Meanwhile, the touch panel of Korea Patent Publication No. 10-0893499 (2009. 04. 17) has been proposed.

The technique comprises a first conductive unit comprising a first substrate, a first ITO coating layer coated on the bottom surface of the first substrate, and a first electrode printed on the bottom edge of the first ITO coating layer; And a second conductive unit including a second substrate, a second ITO coating layer coated on the top surface of the second substrate, and a second electrode printed on the top edge of the second ITO coating layer, thereby improving light transmittance of the touch panel. In addition to being able to reduce the thickness of the touch panel, it is possible to reduce the cost and slim product design.

However, this technique can be applied to the first and second substrates (toughened glass) by coating the first 1/2 ITO (transparent electrode) to secure the strength to cope with the impact from the outside and to omit the overlay film (or window film). For example, tempered glass is an important component for manufacturing touch screen panels (TSP), but is mainly supplied by Chinese companies due to the problem of pollutant treatment, which causes low yield, frequent defects and scattering due to external impact. Therefore, in order to solve the scattering problem, the second / third embodiment has been disclosed to serve as a shatterproof film by providing a conductive unit protection part on the upper part of the first electrode (tempered glass) of the technology, but in the end, the touch panel becomes thinner. There is still a limit to this.

Therefore, in order to solve this problem, the prior art Patent Registration No. 10-0974073 is a method of manufacturing a window touch screen panel (Window Touch Screen Panel), the manufacturing method is an ITO film (Indium) having a sensing electrode function Manufacturing a window indium tin oxide film by a sputtering method by integrating a window film protecting the tin oxide film and the ITO film; Manufacturing an upper substrate by patterning an electrical wiring circuit on a lower surface of the manufactured window ITO film layer to form a first transparent printed layer for printing a first electrode layer and protecting a printed terminal of the first electrode layer. In addition, to prepare a double-sided tape having an insulating property to adhere to the first electrode layer of the upper substrate and the second electrode layer of the lower substrate, the double-sided tape is cut to suit the size of the upper and lower substrates, Perforating a 0.8mm diameter guide to meet the center reference point of the cut double-sided tape, half-cutting to perform half-cutting for peeling the visible area of the substrates, and half-cutting A step of preparing the upper and lower substrates to be laminated by removing and peeling off the unnecessary double-sided tape of the visible region, and further, the upper substrate and the lower substrate This prevents normal contact and energizes when a pressure is applied by a touch pen or finger, and when the pressure is released, the ITO-coated ITO Tempered Glass layer having a sensing electrode function to restore the upper substrate to elastic force. Forming a dot spacer on an upper surface thereof; Arranged at regular intervals from the upper substrate, and patterning the electrical wiring circuit on the upper surface of the ITO Tempered Glass layer (Patterning) to protect the second electrode layer printing and the printed terminal of the second electrode layer Forming a lower substrate by forming a transparent printed layer; Laminating a polycarbonate (PC) on the lower surface of the ITO Tempered Glass layer of the lower substrate, and after the lamination (Lamination), to match the cell size (Cell Size) of the film A method of manufacturing a slim window touch screen panel is disclosed which includes performing Computer Numerical Control (CNC) on cutting or cutting.

In addition, Patent Publication No. 10-0997712 discloses a window touch screen panel (Window Touch Screen Panel), the panel is disposed at regular intervals with the lower substrate, the window film to protect the ITO film, and a sensing electrode function Window ITO film layer manufactured by the sputtering method by integrating an ITO film having a film, a first electrode layer in which an electrical wiring circuit is patterned and printed on a lower surface of the window ITO film layer, and printing of the first electrode layer. An upper substrate having a first transparent printed layer for protecting the terminal; A second electrode layer disposed at regular intervals from the upper substrate, the ITO coated glass layer coated with ITO having a sensing electrode function on the tempered glass, and an electrical wiring circuit patterned and printed on the upper surface of the ITO tempered glass layer; A lower substrate having a second transparent printed layer for protecting the second electrode layer printed terminal; The adhesive member is cut to match the size of the upper and lower substrates, and a 0.8 mm diameter hole perforated to meet the center reference point of the cut adhesive member, and a half knife operation before peeling the visible region of the upper and lower substrates. a double-sided tape having an insulating property of attaching the first electrode layer of the upper substrate and the second electrode layer of the lower substrate after removing and peeling a half cut and an unnecessary member of the half cut visible region. ; A slim window touch screen comprising a dot spacer for preventing normal contact between the upper substrate and the lower substrate and energizing when a pressure is applied with a touch pen or a finger, and restoring the upper substrate to elastic force when the pressure is released. The panel is open.

In addition, Patent Publication No. 10-2010-0054673, ITO (Indium Tin Oxide) film deposited on the upper surface of the flexible plastic film; A first metal layer deposited on the ITO film; It includes a second metal layer plated on the first metal layer. According to an embodiment of the present invention, a touch screen capable of ensuring durability and excellent sensitivity and a method of manufacturing the same are disclosed.

In addition, Patent Registration No. 10-1011334 discloses that the transparent insulating film of the upper electrode member in the touch panel of the film / glass structure has an upwardly inclined cross section around the entire periphery, and the upper electrode member of the touch panel of the film / film composition. A touch panel is disclosed in which a transparent insulating film and a light insulating film of a lower electrode member have an upwardly inclined cross section around the whole.

     However, the touch screen products according to the related arts are bonded to the ITO coating film or the ITO coated glass on the back of the glass including the screen printing layer, the manufacturing cost is expensive, there is a disadvantage that the operation is complicated. In addition, the white coating layer formed on the touch screen simply paints the edge of the touch screen or is silk screen printed, so that the thickness becomes thicker than the center of the touch screen, and thus, the step difference between the edge and the center of the touch screen becomes large, resulting in product defects. This was easy to occur and was cumbersome and complicated.

Accordingly, the present invention has been made to solve the above problems, by providing a white coating layer on the touch screen panel by a vacuum coating method to provide a touch screen panel having a thin, durable and low-quality white coating layer is formed. It is.

The present invention relates to a touch screen panel in which a white coating layer is formed. In the touch screen panel in which a white coating layer is formed, the touch screen panel is sequentially formed with a coating layer by a vacuum coating method on the back of the glass plate (10). The coating layer is formed in the center portion and the edge portion of the back of the glass plate 10, respectively, the central portion coating layer is SiO ₂ coating layer 50 and the ITO coating layer 60 is sequentially formed, the edge portion coating layer is a white coating layer, sanding Alternatively, the MgO coating layer 20, the Ag coating layer 30, the TiO + SiO or SiO ₂ + TiO ₂ coating layer 40, the SiO ₂ coating layer 50 and the ITO coating layer 60 are sequentially formed on the glass plate having the uneven portion formed thereon. It is characterized by.

Therefore, the present invention has a remarkable effect that the white coating layer of the touch screen panel by the vacuum coating method is thin, durable, and product defects are small.

1 is a cross-sectional view of the touch screen panel manufactured by the present invention vacuum deposition coating method
2 is a flow chart of the present invention vacuum deposition coating method
3 is a layout view of the present invention vacuum deposition apparatus
Figure 4 is a schematic diagram showing the interior of the vacuum evaporation apparatus is installed Sputter module, linear ion source and Thermal evaporation source of the present invention
5 is a schematic diagram of a vacuum deposition apparatus installed with a sputte rmodule, a linear ion source, and a thermal evaporation source of the present invention.
6 is an exploded schematic view of a vacuum deposition apparatus in which a sputter module, a linear ion source, and a thermal evaporation source of the present invention are installed.
7 is a schematic plan view of a vacuum deposition apparatus in which a sputter module, a linear ion source, and a thermal evaporation source of the present invention are installed.
8 is an enlarged partial view of FIG.

The present invention relates to a touch screen panel in which a white coating layer is formed. In the touch screen panel in which a white coating layer is formed, the touch screen panel is sequentially formed by a vacuum coating method on the back of the glass plate 10, and the coating layer is The center portion and the edge portion of the rear surface of the glass plate 10 are formed differently, and the central portion coating layer is formed of SiO ₂ coating layer 50 and the ITO coating layer 60 sequentially, and the edge portion coating layer is a white coating layer, which is sanded or etched. MgO coating layer 20, Ag coating layer 30, TiO + SiO or SiO ₂ + TiO ₂ coating layer 40, SiO ₂ coating layer 50 and ITO coating layer 60 are sequentially formed on the glass plate on which the uneven portion is formed It features.

In addition, the SiO ₂ coating layer 50 and the ITO coating layer 60 is characterized in that it is formed over the entire center and the edge portion of the rear glass plate.

In addition, the coating layer of any one of the same white oxide CaO, TiO ₂ , SrO ₂ , Al ₂ O ₃ , Y ₂ O ₃ instead of the MgO coating layer 20 is formed.

In addition, an Al coating layer is formed in place of the Ag coating layer 30.

The present invention will be described in detail with reference to the accompanying drawings. 1 is a cross-sectional view of a touch screen panel manufactured by the present invention vacuum deposition coating method, Figure 2 is a flow chart of the present invention vacuum deposition coating method, Figure 3 is a layout diagram of the present invention vacuum deposition apparatus, Figure 4 is a sputter module, linear ion of the present invention Fig. 5 is a schematic diagram of a vacuum evaporation apparatus installed with a source and a thermal evaporation source, FIG. 5 is a schematic diagram illustrating a vacuum evaporation apparatus installed with a sputte rmodule, a linear ion source and a thermal evaporation source of the present invention, and FIG. 7 is an exploded schematic view of a vacuum deposition apparatus installed with a thermal evaporation source, FIG. 7 is a schematic plan view of a vacuum deposition apparatus installed with a sputter module, a linear ion source and a thermal evaporation source of the present invention, and FIG. 8 is a partially enlarged view of FIG.

     In the present invention, a touch screen panel in which a white coating layer is formed, the touch screen panel is a coating layer is sequentially formed by the vacuum coating method on the back of the glass plate 10, the coating layer is different from the center and the edge of the back of the glass plate 10, respectively It is formed.

The central portion coating layer is a SiO ₂ coating layer 50 and the ITO coating layer 60 is sequentially formed, the edge portion coating layer is a white coating layer MgO coating layer 20, Ag coating layer 30, TiO + SiO or SiO ₂ + The TiO ₂ coating layer 40, the SiO ₂ coating layer 50, and the ITO coating layer 60 are formed.

In addition, the SiO ₂ coating layer 50 and the ITO coating layer 60 is formed by the vacuum coating method over the entire center and the edge of the rear glass plate.

     The present invention first masks a part of the rear surface of the glass plate 10 for the touch screen panel. The masking uses a metal plate or silkscreen printing. The unmasked portion is then sanded or etched from the glass back surface to form an uneven portion. The reason for forming the uneven portion as described above is to allow the light to be scattered well by the uneven portion.

Next, the MgO coating layer 20 is formed by coating MgO on the back surface of the glass on which the uneven parts are sanded or etched by vacuum deposition or sputtering. MgO is combined with the scattered light of the uneven portion and expressed in white. On the other hand, the MgO may be used instead of white oxides, such as CaO, TiO ₂ , SrO ₂ , Al ₂ O ₃ , Y ₂ O ₃ .

Next, Ag coating layer 30 is formed on the MgO coating layer by sputtering Ag. The Ag coating layer 30 serves to prevent the backlight light from leaking through the fine gap of the TiO + SiO or SiO ₂ + TiO ₂ layer or the MgO coating layer to the upper glass surface.

     If the leaked light is left without the Ag coating layer 30, the white light by the uneven portion and the MgO coating layer may not be accurately interrupted by the leaking light. Meanwhile, instead of Ag, aluminum (Al) may be coated by a sputtering method to form an Al coating layer.

Next, the Ti coating layer 30 is coated with TiO + SiO or SiO ₂ + TiO ₂ by sputtering to form a TiO + SiO or SiO ₂ + TiO ₂ layer 40. The TiO + SiO or SiO ₂ + TiO ₂ layer is called a black coating to form a black non-conductive film. Next, masking is removed, and the entire surface of the glass plate 10 including the TiO + SiO or SiO ₂ + TiO ₂ layer is coated by sputtering to form an SiO ₂ coating layer 50.

Finally, the ITO coating layer 60 is formed by coating the entirety of the SiO ₂ coating layer 50 by the sputtering method.

     In the present invention, the glass plate 10 of the touch screen panel mainly used in a mobile phone has a rectangular shape, and in the masking step, the masking part is a rectangular part except for the edge of the glass plate 10.

On the other hand, the grain size of the uneven portion is sanded or etched smaller than the size of 500 mesh.

The production method of the present invention is described in detail as follows.

First, mask part of the back of the glass plate, which is either metal plated or silkscreen printed. When using a metal plate as a masking material, a magnet is attached to the front of the glass so that the metal plate is fixed without being detached from the front of the glass.

The unmasked glass front surface is then sanded or etched. Sanded or etched surfaces become diffuse reflections, making scattering easily occur. After that, coating is performed. Sanded or etched surfaces are smaller than 500 mesh.

After coating, MgO is first coated by vacuum deposition or sputtering, and then Ag is coated by sputtering.

Then, black coating is performed by coating by sputtering with TiO + SiO or SiO ₂ + TiO ₂ .

After that, the entire SiO ₂ coating is coated by a sputtering method. SiO ₂ coating is intended to have insulating effect and light transmittance.

The ITO conductive coating is then coated on the SiO ₂ coated portion by the sputtering method. ITO coatings are intended to have a conductive effect.

    The present invention is described with reference to the installation equipment as follows. In the present invention, it is desirable to implement a white coating using a composite deposition apparatus equipped with a linear ion source (LIS), a thermal source, and a sputter module.

      Of course, each of the equipment having the same function as the above function can be provided separately and implemented through a separate process, but it is efficient and economical to equip and work with the equipment in one vacuum chamber together.

      LIS is used for pretreatment. The sanded glass is first loaded into a vacuum chamber and then cleaned by the LIS.

After cleaning using LIS, MgO is coated by vacuum deposition or sputtering method using a centrally installed thermal source. After MgO coating, Ag is coated by sputtering method and black color coating layer TiO + SiO or SiO ₂ + TiO ₂ layer is coated by sputtering method.

In the case of the white coating according to the present invention, when the light is irradiated from the back of the glass, the light transmittance is 0% by the black layer. On the contrary, when irradiated from the front of the glass, the light is not transmitted by the Ag layer. 100% reflected. The reflected light is reflected by white light by the diffuse reflection effect by the MgO layer and the sanded glass surface, and appears white.

The thickness of the white coating layer is 4.5 μm or less, the resistance is 7 μs / cm 2 or more, and the average light transmittance is 0.3% or less.

     On the other hand, the vacuum coating apparatus used in the present invention can be efficiently implemented by mounting a resistance evaporation source (thermal evaporation source) in the center of the chamber in the conventional sputter vacuum coating method.

     A linear ion source is installed on the chamber wall to perform pre-treatment and cleaning of samples using Ar.

     The sputtering method used in the present invention refers to a conventional sputtering technique. Specifically, sputtering is a technique in which a positive ion formed in a plasma state is applied to an electric field applied to a cathode mounted on a sputter module The target is accelerated to the target located on the cathode and collides with the target, so that the atoms constituting the target protrude.

     Since sputtering does not have a heating process, it is possible to deposit even a solid solution metal such as tungsten. In general vacuum deposition, since the metal is heated to a high temperature to evaporate, in the case of an alloy, the vapor pressure of each of the component metals are different, causing problems. However, sputtering can easily make a thin film not only metal but also inorganic materials such as quartz.

     The sputtering apparatus is composed of a simple two-pole electrode and causes a glow discharge while flowing argon (Ar) gas. When the material to be deposited is made into a circular or rectangular target and a negative high voltage is applied thereto, a thin film is formed by stacking target atoms protruding by the collision of Ar + ions on the facing substrate.

     Sputtering has a high adhesion strength between the thin film and the substrate because the velocity of the flying target atoms is about 100 times faster than the evaporation method. In addition to the two-pole sputtering, there is a four-pole sputtering method for generating a plasma between the substrate and the target to the cathode and the anode, an RF method using a high frequency, and recently a magnetron sputtering method using a magnetic field in addition to an electric field.

     In addition, the basic principle of the sputtering method and the resistance heating method is described in the registration number 20-0185068, which is a pre-applied application, the basic principle of the sputtering method and the resistance heating method. To quote the configuration, the sputtered target is clamped to the cathode of the sputter module.

     Here, the evaporator is coated by melting and evaporating the coating material by resistance heating or electron beam method, and the sputtering target sputters and scatters the coating material to deposit the deposit.

     The resistance heating method uses a heating method using a current to flow through the resistor to generate Joule heat. In this case, both a direct method of heating a current directly through an object and an indirect method of transferring heat from a heating element to a heated object by radiative convection conduction can be adopted.

     In the plasma or glow discharge, the plasma or glow discharge zone is formed by the spark of high pressure voltage supplied from the inert injection gas and the power supply device between the above discharge means. In this state, the inner cylinder is rotated and the etching is performed while the discharge zone is applied to the coated portion of the coated body seated on the jig, and at the same time, the coating material melted by the sputtering target and the evaporator is scattered or sputtered. As a result, a multilayer thin film is formed on the deposit.

Summarizing the deposition process of the deposit, after mounting the substrate (deposit) to be deposited on the jig of the inner cylinder, the vacuum deposition chamber is evacuated through the vacuum exhaust device, and when the inside of the chamber reaches a constant vacuum state, the jig is It is a common method that the deposition material in which the portion to be deposited to be deposited is melted or sputtered from the sputtering target or evaporator is uniformly deposited on the surface of the deposit.

     Therefore, the present invention has a remarkable effect that the white coating layer of the touch screen panel by the vacuum coating method is thin, durable, and product defects are small.

400: chamber
500: linear ion source
100: sputter 110: resistance heating type evaporation source
10: glass plate 20: MgO coating layer
30 Ag coating layer 40 TiO + SiO or SiO ₂ + TiO ₂ layer
50: SiO ₂ coating layer 60: ITO coating layer

Claims (4)

In the touch screen panel formed with a white coating layer, the touch screen panel is formed on the back of the glass plate 10, the coating layer is sequentially formed by a vacuum coating method, the coating layer is formed in the center and the edge portion of the back of the glass plate 10, respectively, SiO ₂ coating layer 50 and ITO coating layer 60 is sequentially formed in the central portion coating layer, the edge portion coating layer is a white coating layer, MgO coating layer 20, Ag coating layer ( 30), the TiO + SiO or SiO ₂ + TiO ₂ coating layer 40, the SiO ₂ coating layer 50 and the ITO coating layer 60 is a touch screen panel with a white coating layer, characterized in that formed sequentially The touch screen panel according to claim 1, wherein the SiO ₂ coating layer 50 and the ITO coating layer 60 are formed over the center portion and the edge portion of the rear surface of the glass plate. According to claim 1, wherein the coating layer of any one of the same white oxide CaO, TiO ₂ , SrO ₂ , Al ₂ O ₃ , Y ₂ O ₃ instead of the MgO coating layer 20 is formed Touch screen panel The touch screen panel having a white coating layer according to claim 1, wherein an Al coating layer is formed instead of the Ag coating layer 30.

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