JP4000178B1 - Touch panel display device and touch panel unit manufacturing method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a structure of a touch panel display device capable of being thinned.
A touch panel unit 11 is provided on the front side of a display unit 1 that performs screen display, and information is input by contact. The touch panel unit 11 is bonded to the front surface of the display unit 1 with a transparent adhesive 17 applied on the entire surface. The touch panel unit 11 includes glass panels 12 and 13 that cover the display unit 1. The glass panels 12 and 13 have their surfaces mechanically polished by spraying the eluate L and spraying the eluate with an acceleration greater than the acceleration due to their own weight, and the thickness is 0.5 mm or less. It has flatness with a maximum surface roughness of 0.5 μm or less.
[Selection] Figure 1

Description

  The present invention relates to a touch panel display device that inputs information by bringing a human finger or a touch pen into contact with the touch panel display device.

  A touch panel display device that inputs information by touching a person's finger or touch pen, etc. should have a display function that also has an information input function. As a multifunctional human interface for machines, electronic notebooks, etc., it is widely used in various fields.

  The touch panel display device can be defined as inputting information by touching the surface while performing screen display, but there are several different types in principle. A typical touch panel is a resistive film type. A conventional touch panel display device will be described taking a resistive film type as an example. FIG. 12 is a schematic cross-sectional view of a conventional touch panel display device of a resistive film type.

  The touch panel display device shown in FIG. 12 includes a display unit 1 that performs screen display, and a touch panel unit 11 that is provided on the front side of the display unit 1 and that inputs information by being touched. The display unit 1 is often a liquid crystal display, but a CRT display or the like may be employed. The conventional example shown in FIG. 12 is a case of a liquid crystal display, and has a structure in which a liquid crystal 193 is sealed between a pair of liquid crystal substrates 191 and 192. The touch panel unit 11 has a structure in which a pair of transparent panels 194 and 195 are bonded together by a bonding portion 190, and a large number of spacers 196 are enclosed therein.

  In the touch panel unit 11, a panel (hereinafter referred to as a front panel) 194 located on the front side (side on which an operator is located) is thin with a thickness of about 0.2 mm. The front panel 194 may be made of glass, but may be formed of a transparent resin such as PET (polyethylene terephthalate). Since the front panel 194 is thin and soft, it may be appropriate to call it a film or a sheet.

A panel (hereinafter referred to as main panel) 195 facing the front panel 194 is a transparent glass plate having a thickness of about 1.1 mm in order to ensure strength. Electrode lattices 197 and 198 made of a transparent conductive film such as ITO (Indiun Tin Oxide) are provided on the opposing surfaces of the pair of panels 194 and 195. When the front panel 194 is touched and pressed, the electrode grids 197 and 198 of the pair of panels 194 and 195 come into contact with each other at the pressed position and a current flows. By detecting this current, the position where the front panel 194 is touched can be determined. Note that the touch panel unit 11 is fixed to the display unit 1 via a fixing portion 199 at the end.
Masayuki Kawamura's “Touch Panel That Can Be Understood” (published by Denpa Shimbun)

  The above-described touch panels have been improved in technology such as an improvement in light transmittance of the conductive film, and many of them are excellent in terms of visibility and operability. In connection with this, it is spreading as a human interface of various information devices. And although it is mounted also on small information equipment like a mobile phone, it has a problem in the point of thickness reduction.

  This problem will be described by taking the resistive film type touch panel display device as an example. In the above-described touch panel display device, a fairly thin front panel of about 0.2 mm is used, but the main panel is considerably thick as about 1.1 mm. The main reason is to ensure mechanical strength. Since the touch panel display device inputs information by pressing with a finger or the like, the touch panel unit needs to have a certain degree of rigidity and mechanical durability so as to withstand repeated pressing. For this reason, the main panel is made of glass and has a thickness of about 1.1 mm. Therefore, the thickness of the touch panel unit as a whole reaches about 1.6 mm.

As described above, in the conventional touch panel display device, since the thickness of the touch panel unit is not thinned, the overall thickness becomes thick even though electronic devices such as mobile phones are required to be thin. I'm stuck.
The invention of the present application has been made in order to solve such a problem, and provides a structure of a touch panel display device that can be thinned. An electronic device such as a mobile phone that is required to be thinned. The present invention has a significance of providing a touch panel display device that is suitably mounted on a device.

In order to solve the above problems, the invention described in claim 1 of the present application includes a display unit that performs screen display, and a touch panel unit that is provided on the front side of the display unit and that inputs information by being touched. A touch panel display device,
The touch panel unit is bonded to the front surface of the display unit with a layer of light-transmitting adhesive applied to the entire surface.
The touch panel unit has a glass panel covering the display unit, and this glass panel is pressed at the time of the contact, and the elution liquid is ejected at an acceleration larger than the acceleration due to its own weight. the sprayed be bombarded are mechanically polished surface, comprising a thickness of 0.1mm or more 0.5mm or less, the maximum roughness of the surface has a flatness is 0.5μm or less ,
The layer of the light-transmitting adhesive material has a configuration of a thickness of 30 μm or more and 100 μm or less .
Moreover, in order to solve the said subject, invention of Claim 2 is the structure of the said Claim 1, In addition to the said glass panel, another glass panel is provided,
These two glass panels are bonded together with the surfaces on which the electrode grids are formed facing each other.
Another glass panel is mechanically polished by spraying the eluate and spraying the eluate with an acceleration larger than the acceleration due to its own weight, and the thickness is 0.1 mm or more and 0.5 mm or less. The surface has a flatness with a maximum roughness of 0.5 μm or less .
In order to solve the above-mentioned problem, the invention according to claim 3 has a structure in which the light-transmitting adhesive layer has a thickness of 50 μm or more and 70 μm or less in the structure of claim 1 or 2. .
In order to solve the above problem, the invention according to claim 4 is the structure according to claim 1 or 2, wherein the light-transmitting adhesive layer has a thickness of 50 μm or more and 70 μm or less (excluding 50 μm). It has a configuration that is.
In order to solve the above-mentioned problem, the invention according to claim 5 is used in a touch panel display device in which information is input by being touched, and manufacturing a touch panel unit provided on the front side of a display unit that performs image display. A method,
The touch panel unit includes a pair of glass panels that cover the display unit and a tail sandwiched between the pair of glass panels.
An electrode forming step of forming an electrode grid on the surface of each of a pair of glass substrates having a size corresponding to a plurality of touch panel units;
A bonding step of bonding a pair of glass substrates on which the electrode grid is formed, with the surfaces on which the electrodes are formed facing each other;
After the bonding process, a reduction process for reducing the outer surfaces of the pair of glass substrates,
After the reduction step, it has a cutting step of cutting a pair of glass substrates to obtain individual glass panel units,
The bonding process is a process of bonding a pair of glass substrates while sandwiching the tail,
In the reduction process, the thickness of the glass substrate is reduced by mechanically polishing the outer surface of the glass substrate by spraying the elution solution toward the outer surface of the glass substrate and spraying the elution solution at an acceleration larger than the acceleration due to its own weight. This is a process of reducing the thickness to 0.1 mm or more and 0.5 mm or less and flattening so that the maximum surface roughness is 0.5 μm or less. In this reduction process, the tail is masked so that no eluate is applied. Have

  As described below, according to the invention described in each claim of the present application, it is possible to reduce the thickness and increase the surface flatness while sufficiently securing the strength of the glass panel. Therefore, a touch panel display device that is suitably mounted on an electronic device such as a mobile phone that is required to be thin is provided.

The best mode for carrying out the present invention (hereinafter referred to as an embodiment) will be described with reference to the drawings.
FIG. 1 is a schematic cross-sectional view of a touch panel display device according to an embodiment of the present invention. The touch panel display device shown in FIG. 1 includes a display unit 1 that performs screen display, and a touch panel unit 11 that is provided on the front side of the display unit 1 and that inputs information by being touched.

In the present embodiment, a liquid crystal display is assumed as the display unit 1 and has a structure in which a liquid crystal 193 is sealed between a pair of glass substrates 191 and 192. In the present embodiment, a thin liquid crystal display is particularly preferably used, but since it may be the same as that used in a mobile phone or the like, a detailed description is omitted. In addition to the liquid crystal display, an organic EL display or the like has been developed as a thin type, and such a display may be used.
The touch panel unit 11 has at least one glass panel that covers the display unit 1. In the present embodiment, the touch panel unit 11 is a resistive film type and has a pair of glass panels 12 and 13. On the opposing surfaces of the pair of glass panels 12 and 13, electrode grids 14 and 15 formed of a transparent conductive film such as ITO are provided.

  The electrode grids 14 and 15 are formed by forming a transparent conductive film by a film forming technique such as sputtering and then patterning it by photolithography. Since the material and structure of the electrode grids 14 and 15 may be the same as those of the conventional touch panel unit, a detailed description is omitted. Note that irregularities may be formed on the surfaces of the electrode grids 14 and 15. This is to make the electrode grids 14 and 15 easier to touch when touched.

  The pair of glass panels 12 and 13 are borosilicate glass or soda glass. The pair of glass panels 12 and 13 are bonded together by being bonded at the joint 10 while interposing an elastic spacer 16. Note that a transparent adhesive is used for bonding at the joint 10 as necessary, for example, when the display unit 1 overlaps the display area. Since the spacer 16 and the bonding may be the same as those of the conventional glass panel unit, a detailed description is omitted. Note that the spacer may be provided in the joint 10 in a mixed manner.

One of the major features of the touch panel unit 11 of the present embodiment is that the glass panels 12 and 13 have the required strength and the thickness (indicated by t1 and t2 in FIG. 1) is as thin as 0.5 mm or less. The surface roughness is such that the maximum roughness (indicated by Rmax in FIG. 1) is 0.5 μm or less. Hereinafter, this point will be described.
As described above, the strength of the glass plate is inevitably lowered when the thickness is reduced. In this embodiment, the thing which ensured required intensity | strength and surface flatness by reducing the thickness of a glass plate by a certain special process is employ | adopted.

FIG. 2 is a view schematically showing a processing method when manufacturing the glass panels 12 and 13 shown in FIG. The glass panels 12 and 13 in the present embodiment are mechanically polished by spraying the eluate and spraying the eluate at an acceleration larger than the acceleration due to its own weight. Further, in order to perform polishing more uniformly, the glass panels 12, 13 are mechanically moved relative to the injection holes of the nozzle 4 for injecting the eluate while the glass panel 12, Shock 13
Note that “mechanical polishing” has both the meaning of polishing utilizing the physical action of the eluate, called the spraying pressure, and the meaning that the glass panels 12 and 13 move mechanically during polishing. “Move mechanically” means “move using a machine”.

A strong acid such as hydrofluoric acid is used as the eluent. In the case of hydrofluoric acid, for example, it is diluted to about 10 to 50% (volume percentage) with respect to water 100 and used. Impact pressure is 0.5kg ^/ cm ² ~3.5kg ^/ cm 2 on the surface of the glass panel 12, 13 bonded.
The outer surface impacted by the eluate sprayed from the nozzle 4 is dissolved in the eluate and flows out due to the impact of the eluate. As a result, the surface is mechanically polished, and the thickness of the glass panels 12 and 13 is reduced.

Thus, according to the mechanical polishing using the eluent, it is possible to reduce the thickness and increase the surface flatness while sufficiently securing the strength of the glass panels 12 and 13. This point will be described with reference to FIG. FIG. 3 is a diagram showing the effect of mechanical polishing using the eluent.
Glass is generally vulnerable to breakage, one of which is due to microcracks present on the surface. As the glass plate manufacturing method, the float method is the mainstream, and the fusion method, the download method, etc. have been put into practical use, but in any case, the surface of the manufactured glass plate is as shown in FIG. Many small scratches (microcracks) 100 are formed. For this reason, when a thin product is manufactured, the strength is inevitably reduced.

  On the other hand, when the thickness is reduced by mechanical polishing using the eluent as described above, the surface layer on which the microcracks 100 are formed is melted and removed as shown in FIG. Therefore, the surfaces of the glass panels 12 and 13 after reduction are in a state free from microcracks. Therefore, sufficient strength is ensured even when the thickness is reduced. In addition, as a technique for reducing the thickness of the glass plate, there is a Reed low method (hot rolling method), but even with such a method, microcracks are still formed on the surface of the thinned glass plate, Sufficient strength cannot be secured.

  In other words, in the current glass plate manufacturing method and glass plate reduction processing method, unless mechanical polishing using the eluent as in the present embodiment is used, in a state where microcracks are not formed on the surface, It is impossible to obtain a glass plate having a thickness of 0.5 mm or less and a maximum roughness of 0.5 μm or less. Therefore, a glass plate having a thickness of 0.5 mm or less and a maximum roughness of 0.5 μm or less by a mechanical polishing method using an eluate, and a maximum roughness of 0.5 mm or less regardless of a mechanical polishing method using an eluate. The glass plate having a thickness of 0.5 μm or less can be clearly distinguished depending on whether or not microcracks are formed on the surface.

Further, the surface flatness is ensured by appropriately selecting the arrangement of the nozzles 4 and the jetting strength as will be described later. If the surface flatness is poor, the light is slightly refracted when the light passes through the glass panels 12 and 13, and this causes poor visibility. That is, it is felt that the screen is uneven for those who have seen the touch panel display device. According to this embodiment, since the maximum roughness Rmax is 0.5 μm or less, there is no such problem. The maximum roughness is more preferably 0.1 μm or less, and the maximum roughness of 0.1 μm or less can be realized by using a glass polishing machine described later.
Further, the glass panels 12 and 13 are preferably as thin as possible in response to a request for thinning the equipment to be mounted. However, there is a limit in terms of strength, and depending on the material, etc., the lower limit of the thickness is about 0.1 mm, and a thickness of 0.1 mm or more is preferable.

Another major feature of the present embodiment is that the touch panel unit 11 described above is fixed to the display unit 1 by whole surface adhesion. That is, as shown in FIG. 1, the touch panel unit 11 and the display unit 1 are bonded together with the adhesive 17 attached to the entire interface.
As this adhesive material 17, since it covers the front surface of the display unit 1, an adhesive material having sufficient light transmittance is adopted. For example, XVL-90 manufactured by Kyoritsu Chemical Industry Co., Ltd. can be used. The thickness of the layer of the adhesive 17 is about 30 μm to 100 μm. The layer of the adhesive 17 is preferably as thin as possible while ensuring the necessary adhesive strength, and more preferably in the range of 50 μm to 70 μm.

  As described above, since the entire surface of the touch panel unit 11 and the display unit 1 is bonded by the light transmissive adhesive material 17, the strength of the touch panel unit 11 is increased. As shown in FIG. 12, when the touch panel unit 11 is fixed to the display unit 1 at the end by a fixing portion 199 and a cavity is formed between the two, it can withstand the pressing force at the time of touch. Therefore, the main panel 195 must be considerably thickened. On the other hand, in the present embodiment, since the entire touch panel unit 11 is bonded to the display unit 1, a sufficient touch resistance is ensured even when the thickness of the main panel is reduced. That is, the pressing force at the time of touch is received by the display unit 1, and sufficient touch-proof strength is ensured by appropriately attaching the display unit 1 to the device.

  According to the touch panel display device of the above embodiment, since the glass panels 12 and 13 are very thin as 0.5 mm or less, the thickness of the entire touch panel unit 11 can be reduced, and as a result, the thickness of the entire device can also be reduced. Specifically, when the thickness of each glass panel 12 and 13 is 0.2 mm, the thickness of the touch panel unit 11 is about 0.5 mm. And if a thin liquid crystal display is employ | adopted as the display unit 1, the thickness of the whole touch panel display apparatus can be thinned to about 1.6 mm. For this reason, it can be suitably employed as a human interface for electronic devices that are required to be thin, such as mobile phones.

  At this time, since the glass panels 12 and 13 are reduced by a mechanical polishing method using an eluate, there are no microcracks on the surface, and sufficient strength is ensured even when the glass panels 12 and 13 are thinned. Furthermore, since the entire surface of the touch panel unit 11 and the display unit 1 is bonded by the transparent adhesive 17, the strength of the touch panel unit 11 is high in this respect as well. And since the maximum roughness of the glass panels 12 and 13 is as high as 0.5 micrometer or less, there is no display nonuniformity and a touch panel display device with high visibility is provided.

Next, an embodiment of a touch panel display device other than the resistance film type will be described. FIG. 4 is a schematic view showing an embodiment of a touch panel display device other than the resistive film type.
FIG. 4 (1) shows a schematic cross-sectional view of a capacitive touch panel unit. As shown in FIG. 4A, in the capacitive type, the touch panel unit includes a glass panel 101, a conductive film 102 formed on the surface of the glass panel 101, and a surface film formed on the conductive film 102. 103. The surface film 103 is an antireflection film or an antifouling film. A shielding conductive film may be formed on the back surface of the glass panel 101.

  In such a capacitive touch panel, a low electric field is applied along the glass panel 101, and information is obtained by capturing a weak charging current flowing in a capacitor formed between the touched human finger and the glass panel 101. Is entered. In the touch panel unit of this embodiment, the surface of the glass panel 101 is sprayed and sprayed with an elution liquid at an acceleration larger than the acceleration due to its own weight, as in the case of the resistive film main panel described above. It is mechanically polished and has a flatness with a thickness of 0.5 mm or less and a maximum surface roughness of 0.5 μm or less.

  4 (2a) shows a schematic plan view of a surface acoustic wave type touch panel unit, and FIG. 4 (2b) shows a schematic cross-sectional view of the surface acoustic wave type touch panel unit. As shown in FIG. 4 (2a), the surface acoustic wave type touch panel unit is provided with an X-direction oscillator 105 at a corner of a rectangular glass panel 104, and a Y-direction oscillator 106 at a corner opposite to this corner. Is provided. And the X direction receiver 107 and the Y direction receiver 108 are provided in another corner. Further, a reflection array 109 is formed along the periphery of the glass panel 104. The reflection array 109 has a large number of resonators arranged at 45 degrees with respect to the X direction or the Y direction. A surface film may be formed on the surface of the glass panel 104 for antireflection or antifouling.

  When an ultrasonic wave is emitted from each of the oscillators 105 and 106, while propagating through the reflection array 109, it is reflected by 90 degrees and propagates toward the inner side of the square, and spreads on the surface of the glass panel 104 as an elastic wave. When the glass panel 104 is touched with a finger (if a surface film is formed on the glass panel 104, the surface film is touched), the surface acoustic wave is absorbed by the finger and reaches the receiver. Will be weak. By measuring the time when the weak elastic wave arrives, it is possible to know where it was touched and to input information.

  Also in such a surface acoustic wave type touch panel unit, the glass panel 104 covers the display unit. As in the above embodiments, the surface of the glass panel 104 is mechanically polished by spraying the eluate and spraying the eluate with an acceleration larger than the acceleration due to its own weight, and the thickness is 0.5 mm. The flatness is such that the maximum roughness of the surface is 0.5 μm or less.

  FIG. 4 (3) shows a schematic cross-sectional view of an optical touch panel unit. The optical touch panel unit includes a light emitter (usually an LED) 111 on one side in the vertical direction and one side in the horizontal direction among the four vertical and horizontal sides of the glass panel 110, and a light receiver 112 on the other side in the vertical and horizontal directions. Provided. When the surface of the glass panel 110 is touched, light is blocked at the touched position. Therefore, it is possible to know where the light is touched from the incident state of the light to the light receiver 112 and thereby input information.

  Even in the optical touch panel unit of the present embodiment, the glass panel 110 covers the display unit. The glass panel 110 has a mechanically polished surface by spraying the eluate and spraying the eluate with an acceleration larger than the acceleration due to its own weight, as in the above embodiments. The flatness is 0.5 mm or less and the maximum roughness of the surface is 0.5 μm or less.

  In addition to the embodiments shown in FIG. 4, an electromagnetic induction type touch panel unit using a touch pen, an image recognition type touch panel unit that detects a touch position by capturing a touch image with a camera, and the like are known. These touch panel units also have at least one glass panel that covers the display unit. This glass panel is sprayed with the eluate and sprayed with the eluate at an acceleration greater than the acceleration due to its own weight. The surface is mechanically polished and has a flatness with a thickness of 0.5 mm or less and a maximum surface roughness of 0.5 μm or less.

Next, an embodiment of the touch panel unit manufacturing method and a glass polishing machine used in this method will be described. The following description includes a more specific description of the above-described mechanical polishing of the glass panel.
FIG. 5 is a schematic diagram of the touch panel unit manufacturing method according to the embodiment. In the method shown in FIG. 5, a touch unit master is manufactured using at least one large glass substrate. The touch unit master refers to a structure in which the structure of the touch panel unit 11 as a product is built in each region of the glass substrate, and a plurality of touch panel units 11 are formed by cutting into individual regions. pointing. In the following description, as an example, the resistive film type touch panel unit 11 is taken up as described above.

As shown in FIG. 5, the touch panel unit manufacturing method of the embodiment includes a touch unit master manufacturing process, a reduction process of reducing the thickness by mechanically polishing the outer surface of the touch unit master 120 using an eluent, And a dividing step of dividing the unit master 120 to obtain individual touch panel units 11.
The touch unit master manufacturing process includes an electrode forming process for forming electrode grids 14 and 15 on the surface of a pair of glass substrates 181 and 182 having a size corresponding to the touch unit master, and a pair of electrode grids 14 and 15 formed thereon. A bonding step of bonding the glass substrates 181 and 182 through the spacer 16.

  The electrode forming step is a step of forming a transparent conductive film such as ITO on the surfaces of the glass substrates 181 and 182 by a film forming technique such as sputtering, and forming electrode grids 14 and 15 having a predetermined pattern by photolithography. In the bonding process, the pair of glass substrates 181 and 182 are bonded with an adhesive with the surfaces on which the electrode grids 14 and 15 are formed facing each other. At the time of bonding, the electrode grids 14 and 15 facing each other are in a predetermined positional relationship so as to function as a functional layer when touched. These steps may be the same as the manufacturing of the conventional touch panel unit 11.

Next, the reduction process will be described.
As shown in FIG. 5, in the touch panel unit manufacturing method of the present embodiment, the glass panels 12 and 13 are reduced after the touch unit master 120 is assembled. Therefore, the object to be polished by spraying the eluent L is the outer surface (outer surface) in the touch unit master 120.

FIG. 6 is a schematic front sectional view of a glass polishing machine used in the method of the embodiment, and FIG. 7 is a schematic side sectional view of the apparatus shown in FIG. The glass polishing machine shown in FIGS. 6 and 7 includes a processing chamber 2 in which a mechanical polishing process is performed, a master holder 3 that holds the touch unit master 120 at a predetermined position in the processing chamber 2, and a master holder 3 The nozzle 4 is provided at a position for spraying the eluate L toward the outer surface of the touch unit master 120 held by the eluent, and the eluate supply system 5 for supplying the eluate L to the nozzle 4.

The processing chamber 2 includes a carry-in port 21 for carrying in the touch unit master 120 and a carry-out port 22 for carrying out the touch unit master 120 after the mechanical polishing process. The carry-in port 21 and the carry-out port 22 are opened and closed by a blocking gate 23. The opening / closing operation is performed by moving the blocking gate 23 in a horizontal direction (vertical direction in FIG. 6) perpendicular to the transport direction.
This apparatus includes a moving mechanism that mechanically moves the touch unit master 120 on which the eluate is ejected relative to the ejection hole of the nozzle 4. A transfer mechanism 30 that transfers the touch unit master 120 through the carry-in port 21 and the carry-out port 22 is also used as the moving mechanism. The master holder 3 is provided as a member constituting the transport mechanism 30. FIG. 8 is a schematic perspective view of the master holder 3 in the apparatus shown in FIGS. 6 and 7.

As shown in FIG. 8, the master holder 3 is a member that holds the touch unit master 120 in a substantially vertical position. The master holder 3 is mainly composed of a base plate 31 in a horizontal posture, a support column 32 erected on the base plate 31, and a shock absorber 33 attached to the support column 32.
The support columns 32 are respectively provided at the corners of the elongated rectangular base plate 31, and a total of four support columns 32 are provided. A beam member 34 extending along the long side direction of the base plate 31 is provided, and the upper end of each column 32 is connected to reinforce the master holder 3. Each column 32 is slightly higher than the standing touch unit master 120. The distance between the two support columns 32 on the short side of the base plate 31 is slightly larger than the thickness of the touch unit master 120. The distance between the two support columns 32 in the long side direction of the base plate 31 is slightly longer than the length of the touch unit master 120. The touch unit master 120 is held so as to be inserted into a space formed by these columns 32.

The shock absorber 33 is a member that directly contacts the touch unit master 120 and prevents the touch unit master 120 from wobbling. The buffer 33 is made of a material that does not corrode (equivalent to chemical resistance) against the eluent L, and is made of, for example, a fluororesin such as Teflon (registered trademark of DuPont).
As shown in FIG. 8, the shock absorber 33 connects the lower end of each support column 32 at both ends in the long side direction of the base plate 31 and also connects the upper end of the support column 32 at both ends in the long side direction. It consists of what is provided. Each corner portion of the held touch unit master 120 comes into contact with these shock absorbers 33. The lower shock absorber 33 in contact with the lower end corner of the touch unit master 120 has a concave cross-sectional shape in the short side direction and an L-shaped cross sectional shape in the long side direction. The shock absorber 33 that comes into contact with the upper end corner of the touch unit master 120 has a concave shape in which the cross-sectional shape in the short side direction is horizontal. As shown in FIG. 8, when the touch unit master 120 is mounted, the touch unit master 120 is inserted from above and dropped into the recesses of the respective shock absorbers 33.

The transport mechanism 30 is, for example, a rack and pinion mechanism. The transport mechanism 30 is configured by a pinion 301 that meshes with the base plate 31 as a rack. A number of pinions are provided at predetermined intervals along the transport line. The pinion 301 is disposed inside and outside the processing chamber 2. A guide member for guiding the moving master disk holder 3 as a whole is provided as appropriate.
As shown in FIG. 7, the nozzles 4 are provided on both sides of the touch unit master 120 held by the master holder 3, and the eluent L is simultaneously applied toward the outer surfaces on both sides of the touch unit master 120. It can be sprayed. FIG. 9 is a schematic perspective view showing the shape of the nozzle 4 shown in FIG.

  As shown in FIG. 9, the nozzle 4 is a tubular member having an injection hole 41. As shown in FIG. 9, the nozzles 4 are arranged so as to extend in a vertical direction, and a plurality of nozzles 4 are provided side by side at equal intervals in the length direction (conveying direction) of the touch unit master 120. The injection holes 41 are provided in a portion of the nozzle 4 that faces the touch unit master 120, and are provided at equal intervals in the tube extending direction (vertical direction). In addition, as a structure of the nozzle 4, there may be a case where a larger number (or a smaller number) than that shown in FIG. 9 is arranged, and a plurality of nozzles 4 may be arranged along the horizontal direction or the oblique direction. Moreover, the nozzle 4 does not need to be tubular, and may have a plate shape or other shapes.

The eluate supply system 5 includes a liquid reservoir 51 that stores the eluate L, a pipe 52 that connects the liquid reservoir 51 and each nozzle 4, a valve 53 and a liquid feed pump 54 that are provided on the pipe 52. ing. A filter for removing impurities, dust, and the like from the supplied eluate L, a pressure adjusting valve, and the like are provided as necessary.
The eluate L is sprayed from the respective injection holes 41 toward the outer surface of the touch unit master 120 held by the master holder 3 by the eluate supply system 5. The ejected elution liquid L is impacted on the outer surface and eluted, and the outer surface is polished.

As shown in FIG. 6, the bottom of the processing chamber 2 has a funnel shape, and a discharge hole 24 is provided at the bottom. A discharge pipe 25 for discharging the used eluate L is connected to the discharge hole 24. The eluent L in which the material of the touch unit master 120 is dissolved as described above falls to the bottom of the processing chamber 2 and is discharged through the discharge hole 24 and the discharge pipe 25.
Further, the inner wall surface of the processing chamber 2 and the surface of each member in the processing chamber 2 are configured to be chemically resistant to the eluate L. For example, when the eluent L is hydrofluoric acid, the inner wall surface and the surface of each member are covered with a fluororesin such as Teflon (registered trademark of DuPont). The blocking gate 23 that opens and closes the carry-in port 21 and the carry-out port 22 is sealed in a liquid-tight manner so that the eluate L does not leak.

In this apparatus , in order to further improve the flatness of the outer surface after mechanical polishing, a special device is devised in the configuration of the nozzle 4. Hereinafter, this point will be described with reference to FIGS. 9 and 10. FIG. 10 is a schematic view showing a point where the eluent L is uniformly ejected from the ejection holes 41 to the outer surface of the touch unit master 120.
As shown in FIG. 9, each injection hole 41 is elongated in a direction of 45 degrees oblique to the direction (vertical direction) in which the tube of the nozzle 4 extends. Accordingly, as shown in FIG. 9, the eluent L ejected from each ejection hole 41 spreads in a long cone shape (or trumpet shape) in this oblique direction. Note that the spread of the eluate L does not overlap on the outer surface of the touch unit master 120. When the spread of the eluate L overlaps on the outer surface of the touch unit master 120, the eluate L is scattered and an irregular flow such as turbulent flow is likely to occur, and as a result, polishing with good flatness is difficult. For this reason, avoid overlapping. In order not to overlap, the dimensions of the injection hole 41, the distance between the nozzle 4 and the touch unit master 120, the injection pressure, and the like may be appropriately selected. However, even if each spread of the eluate L overlaps on the outer surface, polishing with good flatness may be performed, and such a case may be performed.

  The middle part of FIG. 10 shows the eluent L ejected from each ejection hole 41 of one nozzle 4. The right side of FIG. 10 shows the distribution of the injection amount of the eluent L from each injection hole 41 as seen in the height direction of the touch unit master 120. When the touch unit master 120 passes between the nozzles 4 on both sides, each point on the outer surface of the touch unit master 120 receives supply of the eluent L ejected from any one of the ejection holes 41. At this time, the point P on the outer surface that passes so as to face an intermediate position between the two upper and lower injection holes 41 receives the supply of the eluent L from the two adjacent injection holes 41. In this case, since this point P is located at the end of the spread of the eluent L in the form of a guess, as shown on the right side of FIG. 10, the amount of the eluent L received from one injection hole 41 is the other point. The effluent L for one injection hole 41 is supplied by the injection holes 41 on both the upper and lower sides. Therefore, in the height direction of the touch unit master 120, the supply amount of the eluate L at each point on the outer surface is uniform. In addition, not only when the eluent L spreads in the cross-sectional shape as shown in FIG. It may spread.

Next, the operation of the glass polishing machine will be described.
The touch unit master 120 completed through the electrode forming process and the bonding process as described above is mounted on the master holder 3 outside the processing chamber 2. The mounting operation may be performed by a robot or may be performed by a worker's hand. Prior to mounting on the master holder 3, masking with a masking tape may be performed.

  The transport mechanism 30 operates, the sealing gate 23 of the carry-in entrance 21 is opened, and the master holder 3 moves into the processing chamber 2 through the carry-in entrance 21. The master disc holder 3 stops when the touch unit master disc 120 is located at a predetermined position between the nozzles 4 on both sides. The blocking gate 23 of the carry-in port 21 is closed. In this state, the valve 53 of the eluate supply system 5 is opened, and the liquid feed pump 54 sends the eluate L to each nozzle 4 at a predetermined pressure. As a result, the eluent L is ejected from each ejection hole 41 of each nozzle 4 and impacts the outer surface of the touch unit master 120 with a predetermined pressure. Thereby, the outer surface of the touch unit master 120 is saved. The eluate L in which the material on the outer surface is dissolved falls and is discharged from the discharge hole 24.

  After spraying the eluate L for a predetermined time, the liquid feed pump 54 is stopped and the valve 53 is closed. Then, the transport mechanism 30 operates to move the master holder 3, open the sealing gate 23 of the carry-out port 22, and carry the touch unit master 120 out of the processing chamber 2. The carried-out touch unit master 120 is subjected to operations such as cleaning with a cleaning liquid such as pure water and removal of the masking tape.

In the operation of the glass polishing machine, the touch unit master 120 may be displaced as necessary during the ejection of the eluent L. When the impact pressure becomes too high at the point at the shortest distance from each injection hole 41 of each nozzle 4 among the points on the outer surface of the touch unit master 120, the touch unit master 120 is moved during the elution of the eluent L. By moving back and forth, the impact pressure at each point averaged over time can be made uniform. Thereby, the flatness of the outer surface after mechanical polishing can be further improved. The movement of the touch unit master 120 may be performed in the vertical direction.
The glass polishing machine includes a control unit (not shown) that controls the whole. The control unit includes a function of performing sequence control on each unit, and control of the above-described operation and control of movement of the master holder 3 for equalizing the impact are achieved by sequence control performed by the control unit.

In the configuration of the glass polishing machine, liquid feed pressure due to the liquid feed pump 54 is set so that the impact pressure generated by the eluate L of the outer surface is in the range of 0.5kg ^/ cm ² ~3.5kg ^/ cm 2 The At this time, the distance (indicated by d in FIG. 7) between each injection hole 41 of each nozzle 4 and the outer surface is an important factor. If the distance d is too large, the outer surface cannot be impacted with a pressure within the above range unless the liquid feeding pressure by the liquid feeding pump 54 is made considerably high, which is practically difficult. Further, when the distance d is small, it is easy to keep the impact pressure at an optimum value, but the impact pressure at the shortest point to the injection hole 41 becomes too high, causing a problem in terms of uniformity. In order to achieve a practical configuration while ensuring uniformity of impact (that is, flatness of polishing), the distance d is preferably 5 mm or more and 100 mm or less. Note that the distance from the injection hole 41 to the outer surface is slightly longer in the process of polishing with the eluent L, but the distance from 5 mm to 100 mm is the distance at which polishing is started.

Also, if the impact pressure is less than 0.5 kg / cm ² , the supply of fresh eluate L is reduced, so that sufficient polishing cannot be performed and the physical action is not sufficient, so the glass composition and crystal state In addition, there is a problem that uneven portions cannot be sufficiently polished and flatness is lowered. On the other hand, if the impact pressure is larger than 3.5 kg / cm ² , only the shortest point is often polished from the injection hole 41 of the nozzle 4, and the flatness deteriorates at this point. ^Therefore, it is preferable that the impact pressure in the range of ^{0.5kg / cm 2 ~3.5kg / cm 2} .

Next, the dividing step will be described.
In the dividing step, the mechanically polished touch unit master 120 is cut using a dicing apparatus. As the dicing apparatus, an apparatus used for manufacturing a liquid crystal display or the like, that is, an apparatus used when manufacturing a plurality of liquid crystal displays from a single glass substrate can be diverted. After the cutting process, when a connector line called a tail is attached, the touch panel unit is completed.

  In addition, attachment of a tail may be performed in the case of a bonding process. That is, the tip of the tail is inserted between the pair of glass substrates at a predetermined position, and bonding is performed with the tip of the tail sandwiched. This point will be described with reference to FIG. FIG. 11 is a schematic view showing an example of manufacturing four touch panel units 11 from a pair of glass substrates. As shown in this example, when the pair of glass substrates 181 and 182 are bonded together, the tip of the tail 140 is sandwiched at a predetermined position as shown in FIG. In this case, since the reduction process is performed with the tail 140 attached, masking is performed so that the eluate is not applied to the tail 140. After that, through the dividing process, four touch panel units are completed.

  In the manufacturing method described above, for example, a glass substrate 181.182 having a thickness of about 1 mm is prepared, and the thickness of the glass substrates 181 and 182 is reduced to about 0.1 to 0.2 mm in a reduction process after bonding. The Therefore, the completed touch panel unit is thinner than conventional ones, and is suitably mounted on a thin electronic device such as a mobile phone. And even if it becomes thin, since a touch panel unit does not have a micro crack in the surface of a glass panel, sufficient intensity | strength is ensured.

  Further, in the above-described manufacturing method, the elution liquid L that elutes the material on the outer surface of the touch unit master 120 is sprayed toward the outer surface, thereby applying an acceleration larger than the acceleration due to its own weight and spraying the elution liquid L on the outer surface. Since the outer surface is mechanically polished using the physical action of impact by the eluent L, fresh eluate L is supplied one after another, and the eluate L in which the material of the outer surface is dissolved Since it flows out one after another, mechanical polishing can be performed efficiently and uniformly. Even if there is a non-uniform portion in the composition or crystal state of the glass on the outer surface, mechanical polishing can be performed sufficiently uniformly because the physical action is used in combination. For this reason, the flatness of the outer surface after mechanical polishing can be improved, and the visibility of the produced touch panel unit is also high.

Further, according to the glass polishing machine, the outer surface is polished by utilizing the physical action of impact in addition to the chemical action of the eluent L, so that the flatness of the touch unit master 120 can be obtained. Since the conveyance and mechanical polishing process are automated, productivity is high.
Moreover, since each injection hole 41 of the nozzle 4 is provided at equal intervals and the distance from each injection hole 41 to the outer surface is constant, it is easy to make the impact pressure due to the eluent L to be injected uniform. In this respect, it is possible to contribute to polishing processing with high flatness.

In addition, elution is performed while the touch unit master 120 is held vertically, which has an effect of promoting the replacement of the eluate L on the outer surface, and is a technology that allows the outer surface mechanical polishing to be performed sufficiently efficiently. Is meaningful.
Furthermore, since the nozzles 4 are provided on both sides of the touch unit master 120 and both outer surfaces can be mechanically polished at the same time, the touch unit master 120 can be made thinner and the productivity is high.
In some cases, the impact pressure by the eluent L is different on both sides of the touch unit master 120. That is, the injection pressure may be increased on one side and the injection pressure may be decreased on one side. This may occur when it is desired to increase the amount of reduction on one side of the outer surface of the touch unit master 120 and reduce the amount of reduction on the other side.
Further, the mechanical polishing using the eluent L described above can also be applied when manufacturing a flat panel display such as a liquid crystal display. That is, it can be similarly performed when the outer surface of the bonded glass panel for display is mechanically polished and reduced. In this case as well, the outer surfaces on both sides can be reduced by mechanical polishing at the same time, and the reduction can be performed with different spray pressures.

In the configuration of each of the embodiments described above, the polishing of the outer surface with the eluent L uses the physical action of the impact of the eluent, and is an etching that is simply immersed in the etchant or sprayed with the etchant. Are essentially different.
In the above apparatus , the transport mechanism 30 is also used as a moving mechanism, but a moving mechanism may be provided separately from the transport mechanism 30. For example, the master holder 3 may be provided as a part of the moving mechanism, and the touch unit master 120 transported by the transport mechanism 30 may be transferred to the master holder and moved. Note that “relatively moving” means that the positional relationship between the touch unit master 120 and the injection holes 41 of the nozzles 4 changes, and the injection holes 41 of the nozzles 4 that are stationary as in the above embodiment. In contrast, the touch unit master 120 may move, the injection hole 41 may move relative to the stationary touch unit master 120, or both may move.

  In the above embodiment, in the resistive touch panel unit, the panels 12 and 13 on both sides of the spacer 16 are both made of glass, but the front panel as described in the prior art is made of plastic such as PET. Even if only the main panel is made of glass, the same can be done. In this case, a functional layer is similarly formed using a single large plastic substrate and a glass substrate having the same size. And after bonding, only the glass substrate is mechanically polished. If there is a problem when the eluate is applied to the plastic substrate during mechanical polishing, masking is performed.

In the touch panel unit manufacturing method of the above-described embodiment, the dividing step is performed after the reducing step. However, the reducing step may be performed after the dividing step. In this case, a reduction process is performed for each divided touch panel unit. However, in comparison with this, the embodiment in which the reduction process is collectively performed on the touch unit master has higher productivity.
Moreover, in embodiment of the touchscreen unit manufacturing method mentioned above, although the reduction process was performed after bonding a pair of glass panel, you may perform a reduction process before bonding. In this case, the electrode substrate may be formed after the glass substrate is mechanically polished to reduce the thickness to a predetermined thickness, or the reduction step may be performed after the electrode lattice is formed. When the reduction process is performed after the electrode grid is formed, it is preferable that the formed electrode grid is masked so that no eluate is applied.

  Further, in the embodiment of the touch panel unit manufacturing method of the above embodiment, the resistive film type touch panel unit is manufactured. However, other types of touch panel units such as a capacitance type, a surface acoustic wave type, and an optical type are also displayed. As long as it has at least one glass panel covering the unit, it can be manufactured in the same manner. That is, the process of grind | polishing a glass panel using the glass grinder mentioned above can be included.

1 is a schematic cross-sectional view of a touch panel display device according to an embodiment of the present invention. It is the figure which showed roughly about the processing method at the time of manufacturing the glass panels 12 and 13 shown in FIG. It is the figure shown about the effect of mechanical polishing using an eluate. It is the schematic shown about embodiment of touchscreen display apparatuses other than a resistive film type. It is the schematic of the touchscreen unit manufacturing method which concerns on embodiment. It is a front section schematic diagram of the glass polisher used for the method of an embodiment. FIG. 7 is a schematic side sectional view of the glass polishing machine shown in FIG. 6. FIG. 8 is a schematic perspective view of the master holder 3 in the apparatus shown in FIGS. 6 and 7. It is the perspective schematic which showed the shape of the nozzle 4 shown in FIG. FIG. 6 is a schematic view showing a point where an eluent L is uniformly ejected from each ejection hole 41 to the outer surface of the touch unit master 120; It is the schematic shown about the example which manufactures four touch-panel units from a pair of glass substrate. It is a cross-sectional schematic diagram of a conventional touch panel display device that is a resistive film type.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Display unit 11 Touch panel unit 12 Glass panel 13 Glass panel 14 Electrode grating | lattice 15 Electrode grating | lattice 16 Spacer 17 Adhesive material 181 Glass substrate 182 Glass substrate 2 Processing chamber 3 Substrate holder 30 Transport mechanism 4 Nozzle 41 Injection hole 5 Eluate supply system L Eluent

Claims (5)

A touch panel display device including a display unit that performs screen display and a touch panel unit that is provided on the front side of the display unit and that inputs information by being touched,
The touch panel unit is bonded to the front surface of the display unit with a layer of light-transmitting adhesive applied to the entire surface.
The touch panel unit has a glass panel covering the display unit, and this glass panel is pressed at the time of the contact, and the elution liquid is ejected at an acceleration larger than the acceleration due to its own weight. the sprayed be bombarded are mechanically polished surface, comprising a thickness of 0.1mm or more 0.5mm or less, the maximum roughness of the surface has a flatness is 0.5μm or less ,
The touch-panel display device, wherein the light-transmitting adhesive layer has a thickness of 30 μm to 100 μm . In addition to the glass panel, another glass panel is provided,
  These two glass panels are bonded together with the surfaces on which the electrode grids are formed facing each other.
  Another glass panel is mechanically polished by spraying the eluate and spraying the eluate with an acceleration larger than the acceleration due to its own weight, and the thickness is 0.1 mm or more and 0.5 mm or less. The touch panel display device according to claim 1, wherein the touch panel display device has flatness with a maximum surface roughness of 0.5 μm or less.   The touch panel display device according to claim 1, wherein the light-transmitting adhesive layer has a thickness of 50 μm or more and 70 μm or less.   3. The touch panel display device according to claim 1, wherein the light-transmitting adhesive layer has a thickness of 50 μm or more and 70 μm or less (excluding 50 μm).   It is used in a touch panel display device in which information is input by being touched, and is a method of manufacturing a touch panel unit provided on the front side of a display unit that performs image display,
  The touch panel unit includes a pair of glass panels that cover the display unit, and a tail sandwiched between the pair of glass panels.
  An electrode forming step of forming an electrode grid on the surface of each of a pair of glass substrates having a size corresponding to a plurality of touch panel units;
  A bonding step of bonding a pair of glass substrates on which the electrode grid is formed, with the surfaces on which the electrodes are formed facing each other;
  After the bonding process, a reduction process for reducing the outer surfaces of the pair of glass substrates,
  After the reduction step, it has a cutting step of cutting a pair of glass substrates to obtain individual glass panel units,
  The bonding process is a process of bonding a pair of glass substrates while sandwiching the tail,
  In the reduction process, the thickness of the glass substrate is reduced by mechanically polishing the outer surface of the glass substrate by spraying the elution solution toward the outer surface of the glass substrate and spraying the elution solution at an acceleration larger than the acceleration due to its own weight. It is a process of reducing the thickness to 0.1 mm or more and 0.5 mm or less and flattening so that the maximum surface roughness is 0.5 μm or less. In this reduction process, the tail is masked so that the eluate is not applied. A featured touch panel unit manufacturing method.

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