JP4814811B2 - Electronics - Google Patents

Description

  The present invention relates to an electronic device capable of input operation, and more particularly to an electronic device used with a display device.

  Conventionally, as this type of electronic apparatus, for example, there is a coordinate input device shown in Patent Document 1 below.

In this coordinate input device, a resist layer having a thickness equivalent to that of the X electrode is filled in a recess formed on the substrate and between adjacent X electrodes (the same applies to the Y electrode) without any gap. As a result, the surface of the substrate having electrodes is formed on a substantially flat surface with almost no unevenness, and a protective sheet is placed on such a substantially flat surface and bonded to form a bubble between the substrate and the protective sheet. Is prevented.
JP-A-9-305289

  In Patent Document 1, in order to prevent the formation of bubbles, it is necessary to prevent irregularities from being formed on the surface of the substrate, that is, to make the flatness of the resist layer formed on the substrate surface highly accurate. .

  However, there is a limit to increasing the flatness of the surface of the substrate, and it is difficult to completely prevent the formation of bubbles where the flatness is increased.

  A plurality of wiring patterns extending to the external circuit are formed at the ends of the X electrode and the Y electrode. These wiring patterns are wired along the outer peripheral edge portion of the insulating substrate on which the X electrode and the Y electrode are formed.

  The X electrode is formed by means such as sputtering or vapor deposition using a transparent electrode such as ITO, and has a thickness of about several hundreds of mm. On the other hand, the wiring pattern is formed by screen-printing a material such as Ag (silver), and the thickness dimension is about several μm. Therefore, a large step is formed between the X electrode and the wiring pattern. For this reason, when a protective sheet is placed on the sensor electrode, a large number of indeterminate bubbles accumulate in this stepped portion, resulting in a problem that the capacitance value varies greatly.

  In addition, when the protective sheet is used as a display part of a liquid crystal display device formed of a transparent panel, a large number of irregular bubbles appear around the display part, and visibility decreases when viewed from the outside. There was a problem to do.

  The present invention is for solving the above-described conventional problems, and it is possible to form a stable capacitance by forming bubbles at a predetermined position, and to make the bubbles difficult to see from the outside. The purpose is to provide equipment.

The present invention provides an electronic apparatus having a transparent protective plate provided on the surface, a coordinate input device disposed opposite to the back side of the protective plate, and a display device disposed opposite to the lower position of the coordinate input device. In
The coordinate input device includes a base material, a plurality of detection electrodes provided in a visible region on the base material that is visible from the outside through the protective plate, and an invisible region on the base material that is not visible from the outside through the protective plate. An auxiliary pattern line, an insulating layer covering the detection electrode, a protective layer covering the auxiliary pattern line, and a groove formed between the insulating layer and the protective layer. Is provided in the invisible region.

  In the electronic device of the present invention, by preparing a groove in which bubbles are formed in advance in the device, bubbles generated during assembly can be collected in the groove. In addition, since the groove is formed in a non-visible region that cannot be seen from the outside, no bubbles can be seen even if the interior of the electronic device is looked into from the outside through the protective plate after assembly. For this reason, it can be set as the electronic device excellent in visibility.

  In addition, since it is possible to avoid the formation of a large number of bubbles in a region other than the groove, the capacitance value formed between the electrodes of the coordinate input device can be stabilized. Therefore, an electronic apparatus with little detection error and excellent stability can be obtained.

For example, the coordinate input device includes a plurality of X detection electrodes and wiring pattern lines on a first base material, and an upper panel on which an insulating layer and a protective layer are formed so as to cover them, and the X base material on a second base material. A plurality of Y detection electrodes disposed opposite to the detection electrodes and the auxiliary pattern lines, and a lower panel on which an insulating layer and a protective layer covering these are formed;
The insulating layer and the protective layer on the upper panel side and the insulating layer and the protective layer on the lower panel side are joined by an adhesive member.

  Alternatively, the coordinate input device includes a plurality of X detection electrodes and wiring pattern lines on one surface of the base material and has an insulating layer and a protective layer covering the X detection electrodes and wiring pattern lines, and the X surface on the other surface of the base material. A plurality of Y detection electrodes and auxiliary pattern lines arranged orthogonal to the detection electrodes and having an insulating layer and a protective layer covering these, and a plurality of X detection electrodes formed on the one surface A plurality of Y detection electrodes formed on the other surface are arranged to face each other with the base material interposed therebetween.

That is, the coordinate input device may be a coordinate input device in which two panels each having electrodes formed on only one surface of a base material are prepared and the two sheets are bonded together. It may be a configuration using a coordinate input device in which electrodes are formed on both sides,
In the above, it is preferable that the protective plate and the coordinate input device are joined by an adhesive member. In this case, the adhesive member is preferably a transparent double-sided tape.

  In addition, it is preferable that the detection electrode is formed of a transparent electrode, and it is preferable that an insulating layer covering the electrode provided in the visible region is formed of a transparent resist material.

  With the above means, an electronic device having a transparent input unit can be provided. For this reason, the character information and the image displayed on the display device can be viewed from the outside through the coordinate input device and the protective plate which are arranged to face each other on the upper portion of the display device.

  In the present invention, it is possible to prevent a large number of irregularly shaped bubbles from being formed around the display portion, and it is possible to make the bubbles difficult to see from the outside. Thus, an electronic device with excellent visibility can be obtained.

  Furthermore, it can be set as the electronic device provided with the coordinate input device which can reduce the dispersion | variation in the electrostatic capacitance value between each electrode, and can form the stable electrostatic capacitance.

  1A is a cross-sectional view of an electronic apparatus provided with a coordinate input device showing an embodiment of the present invention, FIG. 1B is an enlarged cross-sectional view showing a portion B surrounded by a circle in FIG. 1A, and FIG. 2 shows a protective plate FIG. 3 is a plan view showing an upper panel constituting the coordinate input device, and FIG. 4 is a plan view showing a lower panel constituting the coordinate input device.

  The electronic device 10 shown below functions as a tablet device that can input characters, figures, and the like to an internal coordinate input device, for example. Alternatively, the electronic device functions as an electronic device having a switch function for receiving an input operation performed on the coordinate input device while viewing an image displayed on a display device provided on a lower layer side. This type of electronic apparatus 10 can be mounted on, for example, a mobile phone, a portable audio player, a portable video player, a portable terminal such as an electronic notebook or an electronic dictionary, or a remote control device.

  As shown in FIG. 1A, an electronic device 10 shown in this embodiment has a configuration in which a protective plate 21 is provided in the uppermost layer, a coordinate input device 20 is provided in an intermediate layer, and a display device 50 is provided in a lower layer side. is there. The display device 50 includes a thin display device such as a liquid crystal display or an organic EL display that can display characters and images (still images and moving images).

  The protective plate 21 is formed of a transparent glass substrate or a transparent resin substrate such as acrylic or polycarbonate. As shown in FIG. 2, when the protection plate 21 is shown in a plan view, a transmission part 22 that transmits light provided in the central part and a non-transmission part 23 (part indicated by oblique lines) provided in the periphery thereof are provided. Have. The non-transmissive portion 23 is formed of two layers, a first light shielding layer 23a and a second light shielding layer 23b. The first light shielding layer 23 a is formed in a region on the lower surface side of the protective plate 21 and on the outer peripheral side of the protective plate 21 excluding the transmission portion 22. The second light shielding layer 23b is formed so as to overlap the first light shielding layer 23a after the first light shielding layer 23a is formed.

  Both the first light shielding layer 23a and the second light shielding layer 23b are formed by applying or printing black ink that does not transmit light. The light is transmitted through the transmission part 22 in the plate thickness direction, but cannot be transmitted through the non-transmission part 23 in the plate thickness direction. The thickness of the first light shielding layer is preferably 1 to 3 μm, and the thickness of the second light shielding layer is preferably 3 to 10 μm.

  On the other hand, a transparent resist layer 24 is formed on the lower surface side of the protective plate 21 and on the transmission part. The transparent resist layer 24 is formed by printing a transparent resist material that transmits light. The film thickness dimension of the transparent resist layer 24 is formed with the same dimension as the total film thickness dimension in which the first light shielding layer 23a and the second light shielding layer 23b are overlapped. That is, the second light shielding layer 23b and the transparent resist layer 24 are formed on substantially the same plane.

  As shown in FIGS. 1B and 2, a first groove 25 is formed between the second light shielding layer 23 b and the transparent resist layer 24 adjacent to each other in the X direction and the Y direction. In this embodiment, the first groove 25 is formed on the surface of the first light shielding layer 23 a as a groove that is continuous over the entire circumference so as to surround the transmission portion 22. That is, the first groove 25 is formed in the non-transmissive portion 23 that avoids the transmissive portion 22. However, the first groove 25 is not necessarily continuous, and may be formed intermittently.

  In addition, as shown in FIG. 2, the transmission part 22 which permeate | transmits light forms the visible region (viewing area). In FIG. 1B, at both ends in the X direction and the Y direction, a region sandwiched between one inner edge portion and the other inner edge portion of the first light shielding portion 23a forming the non-transmissive portion 23 is a visible region (viewing area). ). A portion other than the visible region, that is, a portion where the non-transmissive portion 23 is formed is a non-visible region.

  A coordinate input device 20 shown in FIGS. 1A and 1B has a two-layer structure including an upper panel 30 and a lower panel 40. As will be described later, a single-layer structure in which electrodes are respectively disposed on both surfaces of a base material may be used.

  As shown in FIG. 3, the upper panel 30 has a transparent first base 31 made of a resin made of, for example, PET. A plurality of Y detection electrodes 32 extending in the X direction are formed on the surface of the first base material 31 at regular intervals along the Y direction. Most of the Y detection electrodes 32 are arranged in the transmission part 22, but both ends in the X direction reach the non-transmission part 23. The Y detection electrode 32 is formed on the surface of the first base 31 by depositing, for example, ITO (Indium Tin Oxide) or by sputtering. The thickness of the Y detection electrode 32 is about 50 to 300 mm.

  A plurality of auxiliary pattern lines 33 extending in the Y direction are formed at both edges in the width direction (X direction) of the transparent substrate 31. The auxiliary pattern line 33 is made of a conductive material containing silver and has a thickness dimension of about 3 to 20 μm. One end of each auxiliary pattern line 33 and one end in the width direction of each Y detection electrode 32 are connected in a one-to-one relationship. The other end portion of the auxiliary pattern line 33 is collected in a connection portion 35 provided on the transparent substrate 31, and is connected to an external circuit (not shown) through a flexible cable (not shown) from the connection portion 35. ing.

  As shown in FIG. 4, similarly to the upper panel 30, the lower panel 40 also has a transparent second base material 41 made of resin such as PET, and the surface of the second base material 41 is in the Y direction. A plurality of X detection electrodes 42 extending in the same direction and auxiliary electrodes 43 extending in the Y direction are alternately formed at regular intervals along the X direction.

  The X detection electrode 42 and the auxiliary electrode 43 are formed with branch electrodes composed of a plurality of twigs protruding in the X direction. By providing such a branch electrode, it is possible to suppress the variation of the capacitance formed between the adjacent X detection electrode 42 and the auxiliary electrode 43 for each combination. That is, the capacitance formed between the adjacent X detection electrode 42 and auxiliary electrode 43 can be made uniform in any combination. The X detection electrode 42, the auxiliary electrode 43, and the branch electrode are all made of ITO that forms a transparent electrode, and each electrode has a thickness of about 50 to 300 mm.

  A plurality of auxiliary pattern lines 44 extending in the X direction are formed on the Y2 side edge of the second base material 41 in the drawing. One end of each auxiliary pattern line 44 is connected to the end of each X detection electrode 42.

  An auxiliary pattern line (ground line) 45 is provided around the second base material 41 so as to surround the X detection electrode 42 and the auxiliary electrode 43. One end of each auxiliary electrode 43 is connected to the auxiliary pattern line 45 at the edge on the Y1 side in the drawing. The auxiliary pattern line 45 is made of a conductive material containing silver and has a thickness dimension of about 3 to 20 μm.

  The other end of each auxiliary pattern line 44 and the end of the auxiliary pattern line 45 are gathered at a connection portion 46 provided on the second base material 41, and the connection portion 46 is connected to the outside via a flexible cable (not shown). Connected to the circuit.

  As shown in FIGS. 1A and 1B, in the upper panel 30, an upper insulating layer 37 made of a transparent resist material is printed on the surface of the Y detection electrode 32 with a flat surface, and the plurality of Y detection electrodes 32 are covered. ing. Similarly, in the lower panel 40, a lower insulating layer 47 made of a transparent resist material is printed on a flat surface on the surfaces of the X detection electrode 42 and the auxiliary electrode 43, and the plurality of X detection electrodes 42 and the auxiliary electrodes 43 are covered. Has been.

  As a resist material for forming the upper insulating layer 37 and the lower insulating layer 47, a resist material having high light transmittance, low haze and good adhesion to ITO is preferable.

  An upper protective layer 38 is stacked on the auxiliary pattern line 33 provided on the outer peripheral portion of the upper panel 30, and a lower protective layer 48 is stacked on the auxiliary pattern line 45 provided on the outer peripheral portion of the lower panel 40. Has been. The upper protective layer 38 and the lower protective layer 48 are formed by applying a resist material to the surfaces of the auxiliary pattern lines 33 and the auxiliary pattern lines 45. The resist material in this case may be a transparent resist material having light translucency or an opaque resist material not having light translucency.

  As described above, by laminating the upper protective layer 38 and the lower protective layer 48, migration of silver contained in the conductive material forming the auxiliary pattern line 33 and the auxiliary pattern line 45 can be prevented. For this reason, it is preferable that the upper protective layer 38 and the lower protective layer 48 are made of a resist material excellent in suppressing the progress of migration.

  In addition, each thickness dimension with respect to the 1st, 2nd base materials 31 and 41 of the upper insulating layer 37 which consists of a transparent resist material located inside, and the lower insulating layer 47 is the upper protective layer 38 located outside these, The thickness of the lower protective layer 48 is preferably equal to or greater than the thickness of the first and second 31 and 41. In this way, bubbles escape from the transmissive part 22 (visible region) side having the upper insulating layer 37 and the lower insulating layer 47 to the non-transmissive part (nonvisible region) 23 side having the upper protective layer 38 and the lower protective layer 48. It can be made easier.

  A second groove 39 is formed in the upper panel 30 at a position outside the upper insulating layer 37 and a position inside the upper protective layer 38. That is, as shown in FIG. 3, the second groove 39 is formed over the circumference of the upper insulating layer 37 provided in the center. More specifically, the second groove 39 is outside the transmissive portion 22 (visible region), that is, in a non-visible region facing the non-transmissive portion 23, and inside the auxiliary pattern line 33 in the X direction. It is provided in the position.

  Similarly, a third groove 49 is formed in the lower panel 40 at a position outside the lower insulating layer 47 and at a position inside the lower protective layer 48. The third groove 49 is also provided outside the transmitting portion 22 (visible region), that is, a region facing the non-transmitting portion 23 and at a position inside the auxiliary pattern line 45 in the X direction. .

  3 and 4, the inner upper insulating layer 37 and the lower insulating layer 47 are indicated by thick diagonal lines with a downward slope. Further, the outer upper protective layer 38 and the lower protective layer 48 are indicated by thin diagonal lines with a downward shoulder. Then, the second groove 39 and the third groove 49 provided between the upper insulating layer 37 and the upper protective layer 38 and between the lower protective layer 48 and the lower insulating layer 47 are divided into two thin parallel lines. Is shown.

  The upper panel 30 and the lower panel 40 are joined together with the surfaces having electrodes facing each other. That is, a double-sided tape 61 as a transparent adhesive member is provided on the surface where the upper panel 30 and the lower panel 40 face each other, and between the upper insulating layer 37 and the lower insulating layer 47 via the transparent double-sided tape 61. And the upper protective layer 38 and the lower protective layer 48 are bonded together. In this state, the upper insulating layer 37 and the lower insulating layer 47 face each other, the upper protective layer 38 and the lower protective layer 48 face each other, and the second groove 39 and the third groove 49 face each other. In this state, the Y detection electrode 32, the X detection electrode 42, and the auxiliary electrode 43 are opposed to each other (orthogonal arrangement) in a matrix with the double-sided tape 61 sandwiched therebetween.

  In the upper panel 30, a second groove 39 is formed between the upper insulating layer 37 and the upper protective layer 38, and in the lower panel 40, a third groove 49 is formed between the lower insulating layer 47 and the lower protective layer 48. Has been. Further, the surface of the upper insulating layer 37 and the surface of the lower insulating layer 47 are in a state of high flatness.

  Therefore, the bubbles 1 are generated in the second groove 39 and the third groove 49 when the double-sided tape 61 and the upper insulating layer 37 are bonded together and when the double-sided tape 61 and the lower insulating layer 47 are bonded together. It is difficult to form between the upper surface of the double-sided tape 61 and the surface (lower surface) of the upper insulating layer 37 and between the lower surface of the double-sided tape 61 and the surface (upper surface) of the lower insulating layer 47. can do.

  In addition, the second groove 39 and the third groove 49 are formed in a non-visible region facing the non-transmissive portion 23. For this reason, the bubble 1 formed in the 2nd groove | channel 39 or the 3rd groove | channel 49 is not visually recognized from the exterior (upper part of the protection board 21). Therefore, it is possible to obtain an electronic device 10 that is difficult to see the bubbles 1 and has excellent visibility.

  The coordinate input device 20 in a state where the upper panel 30 and the lower panel 40 are bonded together is fixed to the lower surface side of the protective plate 21. At this time, the coordinate input device 20 and the protective plate 21 are fixed by a transparent adhesive member, for example, a double-sided tape 62. That is, the transparent resist layer 24 and the second light shielding layer 23 b provided on the lower surface of the protective plate 21 and the surface of the first base 31 of the upper panel 30 are fixed by the transparent double-sided tape 62.

  Here, since the surfaces of the transparent resist layer 24 and the first base material 31 are both flat, it is difficult for the bubbles 1 to be formed during this time. On the other hand, an air gap is formed between the first groove 25 and the surface of the double-sided tape 62 by the first groove 25, and the bubbles 1 can easily enter this portion.

For this reason, when the coordinate input device 20 is fixed to the lower surface of the protective plate 21, the bubble 1 can be confined in the first groove 25 formed in the non-visible region, and the bubble 1 is visible in other regions, particularly visible. It can prevent forming in a field (transmission part 22).
Therefore, in this case as well, the electronic device 10 in which the bubbles 1 are difficult to see from the outside can be obtained.

  As described above, in the present invention, assuming that the bubble 1 is formed, first to third grooves 25, 39, 49 for forming bubbles are prepared in advance, and the first to third grooves 25, The formation positions 39 and 49 are defined as non-visible regions (non-light transmitting portions 23) that are difficult to see from the outside.

  For this reason, when the coordinate input device 20 is fixed to the lower surface of the protective plate 21, the bubbles 1 can be confined in the first to third grooves 25, 39, 49, and a large number of irregular bubbles 1 are formed. Formation in the visible region (transmission part 22) can be prevented.

  Further, the volumes of the first to third grooves 25, 39 and 49 are constant, and the volume of the bubble 1 formed therebetween is also substantially constant. For this reason, the malfunction that the electrostatic capacitance value in the coordinate input device 20 varies for every product can be prevented. For this reason, it can be set as the electronic device 10 provided with the coordinate input device 20 with high detection accuracy.

  In the above embodiment, the coordinate input device 20 is described in which the upper panel 30 including the Y detection electrode 32 and the lower panel 40 including the X detection electrode 42 and the auxiliary electrode 43 are bonded together. However, the present invention is not limited to this.

  For example, in the case of using a coordinate input device in which an X detection electrode formed on one surface of a transparent substrate and a Y detection electrode formed on the other surface are arranged to face each other in a matrix. There may be. Even in such a coordinate input device, by adopting a configuration for confining bubbles by forming a groove in a position close to the visible region in the non-visible region between the protective plate and one surface of the substrate, Similarly to the above, it is possible to make it difficult to see bubbles from the outside, and it is possible to prevent variations in capacitance values.

1A is a cross-sectional view of an electronic apparatus provided with a coordinate input device according to an embodiment of the present invention, Sectional drawing which expands and shows the part B enclosed with (circle) in FIG. 1A, A plan view showing a protective plate, A plan view showing an upper panel constituting the coordinate input device, The top view which shows the lower panel which comprises a coordinate input device,

Explanation of symbols

DESCRIPTION OF SYMBOLS 10 Electronic device 20 Coordinate input device 21 Protection board 22 Transmission part (visible region)
23 Non-transparent part (non-visible region)
23a 1st light shielding layer 23b 2nd light shielding layer 24 Transparent resist layer 25 1st groove | channel 30 Upper panel 31 1st base material 32 Y detection electrode (transparent electrode)
33 Auxiliary pattern line 35 Connection portion 37 Upper insulating layer 38 Upper protective layer 39 Second groove 40 Lower panel 41 Second base material 42 X detection electrode (transparent electrode)
43 Auxiliary electrode (transparent electrode)
44 Auxiliary pattern line 45 Auxiliary pattern line (ground line)
46 connecting portion 47 lower insulating layer 48 lower protective layer 49 third groove 50 display device 61, 62 double-sided tape (adhesive member)

Claims (7)

In an electronic device having a transparent protective plate provided on the surface, a coordinate input device disposed opposite to the back side of the protective plate, and a display device disposed opposed to a lower position of the coordinate input device,
The coordinate input device includes a base material, a plurality of detection electrodes provided in a visible region on the base material that is visible from the outside through the protective plate, and an invisible region on the base material that is not visible from the outside through the protective plate. An auxiliary pattern line, an insulating layer covering the detection electrode, a protective layer covering the auxiliary pattern line, and a groove formed between the insulating layer and the protective layer. Is provided in the invisible region. The coordinate input device includes a plurality of X detection electrodes and wiring pattern lines on a first base material, an upper panel on which an insulating layer and a protective layer are formed to cover them, and the X detection electrode on a second base material And a plurality of Y detection electrodes and auxiliary pattern lines arranged opposite to each other, and a lower panel on which an insulating layer and a protective layer covering these are formed,
The electronic device according to claim 1, wherein the insulating layer and the protective layer on the upper panel side and the insulating layer and the protective layer on the lower panel side are joined by an adhesive member.   The coordinate input device includes a plurality of X detection electrodes and wiring pattern lines on one surface of the base material, and has an insulating layer and a protective layer covering the same, and the X detection electrode on the other surface of the base material A plurality of Y detection electrodes and auxiliary pattern lines arranged orthogonal to each other, and having an insulating layer and a protective layer covering these, and a plurality of X detection electrodes formed on the one surface and the other The electronic device according to claim 1, wherein a plurality of Y detection electrodes formed on a surface are arranged to face each other with the base material interposed therebetween.   The electronic device according to claim 1, wherein the protective plate and the coordinate input device are joined by an adhesive member.   The electronic apparatus according to claim 2, wherein the adhesive member is a transparent double-sided tape.   The electronic device according to claim 1, wherein the detection electrode is formed of a transparent electrode.   The electronic device according to claim 1, wherein an insulating layer that covers the electrode provided in the visible region is formed of a transparent resist material.

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