CN203054781U - Touch panel with photoelectric conversion - Google Patents

Abstract

A touch panel with photoelectric conversion comprises a touch area and a non-touch area adjacent to the touch area, wherein the touch area is provided with a first transparent substrate, a photoelectric conversion layer, a touch electrode layer and a second transparent substrate; through the utility model discloses a touch panel's design must effectively promote photoelectric conversion layer absorption optical area to improve the effect of conversion current volume.

Description

The contact panel of tool opto-electronic conversion

Technical field

The utility model relates to a kind of contact panel, refers to especially a kind ofly absorb light area with reaching photoelectric conversion layer, and improving the effect of switching current amount, and then the contact panel of the tool opto-electronic conversion of more effective lifting standby and the effect of service time.

Background technology

Pressing existing general portable electronic equipment head heavily is the supply of electric power, so as to standby and the use of keeping electronic installation, it still need be dependent on built-in battery supplied electric power running the supply of portable electronic equipment electric power, since existing portable electronic equipment more since big screen and the use that combines contactor control device to make that it consumes electric power more acute, then significantly reduce the time of standby and use.

Consume the very big problem of electric power for solving known portable electronic equipment, be with a solar modules and its combination at present, and carry out the conversion of photoelectricity by solar modules, and then the electrical power storage that the order conversion produces is in the built-in cell device of this portable electronic equipment, increase use and the stand-by time of portable electronic equipment, described solar modules mainly is arranged in the housing of the non-Touch Zone of portable electronic equipment or this portable electronic equipment, carry out opto-electronic conversion for making solar modules can absorb the light irradiation, then this housing must be made as transparent material, or with protruding this outside of exposing of solar modules, and then produce the shortcoming that makes this product thickness be difficult for reduction.

Therefore, how to solve above-mentioned public problem and disappearance, the inventor who is this case desires most ardently the direction place that research improves with the relevant manufacturer that is engaged in the industry.

The utility model content

For this reason, for effectively solving the above problems, fundamental purpose of the present utility model has standby and the service time that promotes contact panel providing a kind of, and effectively promotes photoelectric conversion layer and absorb light area, with the contact panel of the tool opto-electronic conversion that improves the switching current amount.

Another purpose of the present utility model is that a kind of contact panel with tool opto-electronic conversion of the effect that reduces the contact panel integral thickness is being provided.

For reaching above-mentioned purpose, the utility model provides a kind of contact panel of tool opto-electronic conversion, this contact panel comprises a Touch Zone and a non-Touch Zone, adjacent this Touch Zone, this non-Touch Zone, and have one first transparency carrier, a photoelectric conversion layer, a touch control electrode layer and one second transparency carrier in this Touch Zone, this photoelectric conversion layer one side is attached on the side of this first transparency carrier, this touch control electrode layer then is formed on the side of this second transparency carrier, and is sticked mutually with the opposite side of relative this photoelectric conversion layer; Be located at first transparency carrier of this Touch Zone and the design between second transparency carrier by this photoelectric conversion layer, get and effectively promote photoelectric conversion layer absorption light area, with the effect of raising switching current amount, and then also effectively promote the standby of contact panel and the effect of service time.

Particularly, the utility model provides a kind of contact panel of tool opto-electronic conversion, this contact panel comprises: a Touch Zone and a non-Touch Zone, adjacent this Touch Zone, this non-Touch Zone, has one first transparency carrier in this Touch Zone, one photoelectric conversion layer, one touch control electrode layer and one second transparency carrier, this photoelectric conversion layer one side is attached on the side of this first transparency carrier, this touch control electrode layer is formed on the side of this second transparency carrier, and be sticked mutually with the opposite side of relative this photoelectric conversion layer, be provided with one first anti-reflecting layer between described first transparency carrier and the photoelectric conversion layer.

Preferably, the contact panel of described tool opto-electronic conversion, described photoelectric conversion layer has one first transparent electrode layer, a light absorbing zone and one second transparent electrode layer, this light absorbing zone is arranged between this first and second transparent electrode layer, and this first transparent electrode layer is sticked on aforementioned relatively first transparency carrier, one side, and this second transparent electrode layer is then with relative this second transparency carrier and go up this touch control electrode layer and be sticked mutually.

Preferably, the contact panel of described tool opto-electronic conversion, this first anti-reflecting layer, one side is fitted on the side of this first transparency carrier, and its opposite side then is fitted on this first transparent electrode layer.

Preferably, the contact panel of described tool opto-electronic conversion more is provided with one second anti-reflecting layer on described first transparency carrier, and this second anti-reflecting layer is formed on the opposite side of this first transparency carrier.

Preferably, the contact panel of described tool opto-electronic conversion, be provided with one first optics glue-line between aforementioned second transparency carrier and the photoelectric conversion layer, this first optics glue-line is in order to this second transparency carrier and go up this touch control electrode layer and second transparent electrode layer fits.

Preferably, the contact panel of described tool opto-electronic conversion, described touch control electrode layer is provided with one first induction electrode and one second induction electrode, and this first and second electrode is crisscross arranged and is formed on the side of this second transparency carrier, and this first and second induction electrode has an insulation course each other.

Preferably, the contact panel of described tool opto-electronic conversion, described touch control electrode layer are provided with one first induction electrode, and this first induction electrode is formed on the side of this second transparency carrier, and one second induction electrode then is formed on the opposite side of this second transparency carrier.

Preferably, the contact panel of described tool opto-electronic conversion, has a flexible circuit board in the aforementioned non-Touch Zone, one conductive adhesive layer, one electrode routing layer, one second optics glue-line and a shielding layer, this shielding layer is attached on the side of this first transparency carrier, this second optics glue-line is located between this shielding layer and relative this flexible circuit board and the electrode routing layer, and with adjacent this first optics glue-line phase gluing, this conducting resinl is positioned on this electrode routing layer one side, and be sticked mutually with relative this flexible circuit board, and the opposite side of this electrode routing layer is sticked on second transparency carrier, one side of correspondence.

Preferably, the contact panel of described tool opto-electronic conversion more is provided with a cementing layer between described first anti-reflecting layer and first transparency carrier, and this cementing layer is in order to fit this first transparency carrier and first anti-reflecting layer.

Preferably; the contact panel of described tool opto-electronic conversion; be provided with a protective seam between described photoelectric conversion layer and second transparency carrier, this protective seam one side is sticked on this second transparent electrode layer, and its opposite side then is sticked mutually with relative this second transparency carrier and last this touch control electrode layer thereof.

Preferably, the contact panel of described tool opto-electronic conversion, described photoelectric conversion layer is made of a thin-film type solar cell.

Preferably, the contact panel of described tool opto-electronic conversion, described first and second transparency carrier may be selected to be wherein arbitrary material of polyethylene terephthalate, polycarbonate, tygon, Polyvinylchloride, polypropylene, polystyrene, polymethylmethacrylate, cyclic olefine copolymer and glass.

Description of drawings

Fig. 1 is the schematic perspective view of contact panel of the present utility model;

Fig. 2 is the diagrammatic cross-section of first preferred embodiment of the present utility model;

Fig. 3 is another diagrammatic cross-section of first preferred embodiment of the present utility model;

Fig. 4 is the diagrammatic cross-section of second preferred embodiment of the present utility model;

Fig. 5 is another diagrammatic cross-section of second preferred embodiment of the present utility model;

Fig. 6 is the diagrammatic cross-section of the 3rd preferred embodiment of the present utility model;

Fig. 7 is another diagrammatic cross-section of the 3rd preferred embodiment of the present utility model.

The main element symbol description

Contact panel ... 1

The Touch Zone ... 11

First transparency carrier ... 111

Photoelectric conversion layer ... 112

First transparent electrode layer ... 1121

Light absorbing zone ... 1122

Second transparent electrode layer ... 1123

Touch control electrode layer ... 113

First induction electrode ... 1131

Second induction electrode ... 1132

Insulation course ... 114

First anti-reflecting layer ... 115

Second anti-reflecting layer ... 116

Second transparency carrier ... 117

The first optics glue-line ... 1181

Cementing layer ... 1182

Protective seam ... 119

Non-Touch Zone ... 13

Flexible circuit board ... 131

Conductive adhesive layer ... 132,133

The second optics glue-line ... 134

The electrode routing layer ... 135,136

Shielding layer ... 137

Embodiment

Characteristic on above-mentioned purpose of the present utility model and structure thereof and the function will be illustrated according to appended graphic preferred embodiment.

The utility model provides a kind of contact panel of tool opto-electronic conversion, sees also Fig. 1, Fig. 2 shows, shows solid and the diagrammatic cross-section of first preferred embodiment of the present utility model; This contact panel 1 comprises a non-Touch Zone 13 and a Touch Zone 11, have one first transparency carrier 111, a photoelectric conversion layer 112, a touch control electrode layer 113 and one second transparency carrier 117 in this Touch Zone 11, wherein said first and second transparency carrier 111,117 is constituted with glass material in this preferred embodiment to be explained, but be not limited thereto, also may be selected to be wherein arbitrary material of polyethylene terephthalate, polycarbonate, tygon, Polyvinylchloride, polypropylene, polystyrene, polymethylmethacrylate and cyclic olefine copolymer.

In addition the aforementioned photoelectric conversion layer 112 of person be chosen as amorphous silicon (a-Si), gallium arsenide (GaAs), cadmium telluride (CdTe), copper plug with molten metal gallium selenium (CIGS) or dye-sensitized cell (Dssc) wherein any thin-film solar cell constitute.And a side of this photoelectric conversion layer 112 is attached on the side of this first transparency carrier 111, its opposite side then is sticked mutually with relative touch control electrode layer 113, and described photoelectric conversion layer 112 has one first transparent electrode layer 1121, a light absorbing zone 1122 and one second transparent electrode layer 1123.

Moreover described first transparent electrode layer 1121 is a transparent conductive oxide (Transparent Conductive Oxide, TCO), and it has the characteristic of high-penetration degree and high conduction, and this first transparent electrode layer 1121 is sticked relatively on these first transparency carrier, 111 1 sides; This second transparent electrode layer 1123 is a metal level, and explains with metal level (be metals such as silver, aluminium, chromium as metal level) in this preferred embodiment, but is not limited thereto.

Continuous consult Fig. 1, Fig. 2 shows, aforementioned lights absorption layer 1122 is arranged between this first and second transparent electrode layer 1121,1123, it will be in order to will receive the light injected from this first transparency carrier 111 after opto-electronic conversion, in this first and second transparent electrode layer 1121,1123 generation electric energy, this electric energy can offer this contact panel 1 and use, so as to the standby of lifting contact panel 1 and the effect of service time.

So be located at first transparency carrier 111 of aforementioned Touch Zone 11 and the design between second transparency carrier 117 by photoelectric conversion layer 112 of the present utility model, make that promoting photoelectric conversion layer 112 absorbs light area, to improve the effect of switching current amount.Be located at non-Touch Zone and cause that to absorb light area limited so obviously improve known solar modules, and the problem that can't improve the switching current amount.

Be provided with one first optics glue-line 1181 between aforementioned second transparency carrier 117 of person and the photoelectric conversion layer 112 in addition, this first optics glue-line 1181 is an optical lens gelatin, an optical cement fat or a liquid optical cement (LAL), its in order to this second transparency carrier 117 and on touch control electrode layer 113 and relative second transparent electrode layer 1123 be sticked mutually (or fitting).

Moreover aforementioned touch control electrode layer 113 is formed on the side of this second transparency carrier 117, and be formed in the mode of sputter in the touch control electrode layer 113 of this preferred embodiment on the side of described second transparency carrier 117 and explain, but be not limited thereto, when the actual enforcement of the utility model, the mode that also can select to be coated with gel, plating or evaporation is formed on second transparency carrier, 117 1 sides.

See also Fig. 1, Fig. 2 shows, aforementioned touch control electrode layer 113 is provided with one first induction electrode 1131 and one second induction electrode 1132, this first and second induction electrode 1131,1132 material are indium tin oxide (Indium Tin Oxide, ITO) or the antimony tin oxide film (Antimony Tin Oxide, ATO); This first and second induction electrode 1131,1132 is crisscross arranged and is formed on the side of this second transparency carrier 117, in other words, first and second induction electrode 1131,1132 on described second transparency carrier, 117 1 sides arranges with level (being X-direction) and vertical (being Y direction) mode respectively exactly, and this second induction electrode 1132 is positioned at described first induction electrode 1131 tops and interlaced; And aforementioned first and second induction electrode 1131,1132 has an insulation course 114 each other.

And constitute a single layer structure (SITO) in this preferred embodiment with aforementioned touch control electrode layer 113 and second transparency carrier 117 and explain, but be not limited thereto, when concrete enforcement, the user can be according to penetrability, demands such as stability, change and be designed to pair of lamina structure (DITO), that is show as Fig. 3, this touch control electrode layer 113 changes design only one first induction electrode 1131, this first induction electrode 1131 is formed on these second transparency carrier, 117 1 sides, 1132 of one second induction electrodes are formed on the opposite side of this second transparency carrier 117, to constitute described double-decker with this first induction electrode 1131 and second transparency carrier 117.

The continuous Fig. 1 that consults, Fig. 2 shows, 13 adjacent these Touch Zones 11, aforementioned non-Touch Zone, that is described non-Touch Zone 13 is arranged on all sides of adjacent this Touch Zone 11, and has a flexible circuit board 131 in it, one conductive adhesive layer 132, one electrode routing layer 135, one second optics glue-line 134 and a shielding layer 137, wherein this shielding layer 137 is attached on the side of this first transparency carrier 111, and this second optics glue-line 134 is an optical cement, one optical cement fat or a liquid optical cement (LAL), it is located between shielding layer 137 and relative this flexible circuit board 131 and the electrode routing layer 135, and this second optics glue-line 134 and adjacent these first optics glue-line, 1181 phase gluings.

The described conductive adhesive layer 132 of person is positioned on the side of this electrode routing layer 135 in addition, and is sticked mutually with relative flexible circuit board 131, and this conductive adhesive layer 132, flexible circuit board 131 and electrode routing layer 135 electrically connect jointly; These electrode routing layer 135 opposite sides then are sticked on second transparency carrier, 117 1 sides of correspondence.

In addition, when concrete enforcement, if change when being designed to aforementioned double-decker, as the 3rd diagram, a wherein conductive adhesive layer 132 of aforementioned non-Touch Zone 13 is positioned on the side of this electrode routing layer 135, and fit with aforementioned flexible circuit board 131 1 ends, and this conductive adhesive layer 132 electrically connects jointly with an end of electrode routing layer 135 and this flexible circuit board 131 respectively, these electrode routing layer 135 1 sides are sticked mutually with corresponding conductive adhesive layer 132 and the second optics glue-line 134, and its opposite side then is sticked on described second transparency carrier of correspondence 117 1 sides; And another electrode routing layer 136 1 sides are sticked on the opposite side of second transparency carrier 117, its opposite side then is sticked mutually with another conductive adhesive layer 133, and this another conductive adhesive layer 133 is between the other end and another electrode routing layer 136 of this flexible circuit board 131, and it electrically connects the other end of this another electrode routing layer 136 and flexible circuit board 131 respectively.

So the design by this contact panel 1 of the utility model gets and effectively promotes photoelectric conversion layer 112 and absorb light areas, improving the effect of switching current amount, and then can also promote standby and the effect person of service time of contact panel 1.

See also Fig. 4, Fig. 5 shows, shows the diagrammatic cross-section of second preferred embodiment of the present utility model, and be aided with and consult Fig. 1 and show; The structure of this preferred embodiment and connection relationship and effect thereof are roughly identical with aforementioned first preferred embodiment, so do not give unnecessary details again at this, its both differences be in: be provided with one first anti-reflecting layer 115 between aforementioned first transparency carrier 111 and the photoelectric conversion layer 112, these first anti-reflecting layer, 115 1 sides are fitted on the side of this first transparency carrier 111, its opposite side then is fitted on first transparent electrode layer 1121 of this photoelectric conversion layer 112, and this first anti-reflecting layer 115 has the effect that reduces reflection of light and increase transmitted intensity.

More be provided with one second anti-reflecting layer 116 on described first transparency carrier 111 of person in addition, this second anti-reflecting layer 116 is formed on the opposite side of this first transparency carrier 111, and itself and first anti-reflecting layer, the 115 identical effects that all have the minimizing reflection of light and increase transmitted intensity.Wherein said first and second anti-reflecting layer 115,116 is constituted by monox, silicon nitride or titania material.

And be respectively formed at sputtering way on a side of aforementioned first transparency carrier 111 and the opposite side thereof in first and second anti-reflecting layer 115,116 of this preferred embodiment and explain, but be not limited thereto, when concrete enforcement, also can select to be coated with the gel mode and be formed on the side and opposite side thereof of this first transparency carrier 111, close first Chen Ming.

So be respectively formed at a side of described first transparency carrier 111 and the design on the opposite side thereof by this first and second anti-reflecting layer 115,116, get effectively to reach and reduce the effect that incident ray suffers 111 reflections of first transparency carrier, and then effectively reach the effect person who increases light content.

See also Fig. 6 and show, show the diagrammatic cross-section of the 3rd preferred embodiment of the present utility model, and be aided with and consult Fig. 1 and show; The structure of this preferred embodiment and connection relationship and effect thereof are roughly identical with aforementioned first preferred embodiment; so do not give unnecessary details again at this; this this preferred embodiment mainly is that the first optics glue-line 1181 with aforementioned first preferred embodiment changes and is designed to a protective seam 119; and between this first transparency carrier 111 and photoelectric conversion layer 112, more be provided with a cementing layer 1182 and one first anti-reflecting layer 115; that is aforementioned cementing layer 1182 is located between this first anti-reflecting layer 115 and first transparency carrier 111, and it is in order to fit this first transparency carrier 111 and first anti-reflecting layer 115.Wherein said cementing layer 1182 is identical with the first optics glue-line 1181 all to be to be an optical lens gelatin, an optical cement fat or a liquid optical cement (LAL).

Aforementioned first anti-reflecting layer 115 of person has the effect that reduces reflection of light and increase transmitted intensity in addition, and the one side is fitted on described first transparency carrier, 111 1 sides by this cementing layer 1182, its opposite side then is fitted on first transparent electrode layer 1121 of this photoelectric conversion layer 112, so must effectively reach the effect that the reduction incident ray suffers 111 reflections of first transparency carrier by this first anti-reflecting layer 115, and then effectively reach the effect person who increases light content.

Moreover described protective seam 119 is located between this photoelectric conversion layer 112 and second transparency carrier 117; the one side is sticked on this second transparent electrode layer 1123; its opposite side then is sticked mutually with relative this second transparency carrier 117 and last this touch control electrode layer 113 thereof, and this protective seam 119 avoids the scratch damage in order to protect this touch control electrode layer 113.Wherein said protective seam 119 (Over Coat) is a megohmite insulant, as silicon dioxide, but is not limited to this, when concrete enforcement, also can be materials such as silicon nitride, class photoresistance.

In addition, when concrete enforcement, if change when being designed to aforementioned double-decker, show as Fig. 7, a wherein conductive adhesive layer 132 of aforementioned non-Touch Zone 13 is positioned on the side of this electrode routing layer 135, and fit with aforementioned flexible circuit board 131 1 ends, and this conductive adhesive layer 132 electrically connects jointly with an end of electrode routing layer 135 and this flexible circuit board 131 respectively, these electrode routing layer 135 1 sides are sticked mutually with corresponding conductive adhesive layer 132 and the second optics glue-line 134, and its opposite side then is sticked on described second transparency carrier of correspondence 117 1 sides; Another conductive adhesive layer 133 is then between the opposite side of the other end of this flexible circuit board 131 and corresponding second transparency carrier 117, and its adjacent another electrode routing layer 136, the other end of this flexible circuit board 131 and another electrode routing layer 136 and another conductive adhesive layer 133 electrically connect jointly, and the opposite side of this second transparency carrier 117 is sticked mutually with relative this another conductive adhesive layer 133 and another electrode routing layer 136.

The above, the utility model has following advantage compared to known technology:

1. have to reach and promote photoelectric conversion layer and absorb light area, to improve the effect of switching current amount;

2. have the standby of lifting contact panel and the effect of service time.

Only the above only is preferable feasible embodiment of the present utility model, and the variation that utilizes the above-mentioned method of the utility model, shape, structure, device to do such as all should be contained in the claim scope of this case.

Claims (12)

1. A touch panel with photoelectric conversion, characterized in that the touch panel comprises: a touch area and a non-touch area, the non-touch area is adjacent to the touch area, and in the touch area It has a first transparent substrate, a photoelectric conversion layer, a touch electrode layer and a second transparent substrate, one side of the photoelectric conversion layer is attached to one side of the first transparent substrate, and the touch electrode layer is formed on One side of the second transparent substrate is attached to the other side opposite to the photoelectric conversion layer, and a first anti-reflection layer is arranged between the first transparent substrate and the photoelectric conversion layer. the 2. The touch panel with photoelectric conversion according to claim 1, wherein the photoelectric conversion layer has a first transparent electrode layer, a light absorbing layer and a second transparent electrode layer, and the light absorbing layer is set Between the first and second transparent electrode layers, and the first transparent electrode layer is attached on the side opposite to the first transparent substrate, and the second transparent electrode layer is opposite to the second transparent substrate and the contactor on it. The control electrode layer is attached to each other. the 3. The touch panel with photoelectric conversion according to claim 2, wherein one side of the first anti-reflection layer is attached to one side of the first transparent substrate, and the other side is attached to the first transparent substrate. on the first transparent electrode layer. the 4. The touch panel with photoelectric conversion according to claim 3, wherein a second anti-reflection layer is further provided on the first transparent substrate, and the second anti-reflection layer is formed on the first transparent substrate on the other side. the 5. The touch panel with photoelectric conversion according to claim 2 or 4, wherein a first optical adhesive layer is provided between the second transparent substrate and the photoelectric conversion layer, and the first optical adhesive layer is used to The second transparent substrate and the touch electrode layer on it are attached to the second transparent electrode layer. the 6. The touch panel with photoelectric conversion according to claim 5, wherein the touch electrode layer is provided with a first sensing electrode and a second sensing electrode, and the first and second electrodes are alternately arranged and formed on the There is an insulating layer on one side of the second transparent substrate and between the first and second sensing electrodes. the 7. The touch panel with photoelectric conversion according to claim 5, wherein the touch electrode layer is provided with a first sensing electrode, and the first sensing electrode is formed on one side of the second transparent substrate, A second sensing electrode is formed on the other side of the second transparent substrate. the 8. The touch panel with photoelectric conversion as claimed in claim 5, characterized in that, there is a flexible circuit board, a conductive adhesive layer, an electrode wiring layer, and a second optical adhesive layer in the aforementioned non-touch area and a shielding layer, the shielding layer is pasted on one side of the first transparent substrate, the second optical adhesive layer is arranged between the shielding layer and the corresponding flexible circuit board and electrode wiring layer, and is connected to the corresponding Adjacent to the first optical adhesive layer, the conductive adhesive is located on one side of the electrode wiring layer, and is attached to the opposite flexible circuit board, and the other side of the electrode wiring layer is attached to the corresponding on the side of the second transparent substrate. the 9. The touch panel with photoelectric conversion as claimed in claim 3, wherein a glue layer is further provided between the first anti-reflection layer and the first transparent substrate, and the glue layer is used to make the first transparent substrate The substrate is attached to the first anti-reflection layer. the 10. The touch panel with photoelectric conversion according to claim 9, wherein a protective layer is provided between the photoelectric conversion layer and the second transparent substrate, and one side of the protective layer is attached to the second transparent electrode layer, and the other side is attached to the second transparent substrate and the touch electrode layer thereon. the 11. The touch panel with photoelectric conversion as claimed in claim 2, wherein the photoelectric conversion layer is composed of a thin-film solar cell. the 12. The touch panel with photoelectric conversion according to claim 2, wherein the first and second transparent substrates can be selected from polyethylene terephthalate, polycarbonate, polyethylene, polyvinyl chloride , polypropylene, polystyrene, polymethyl methacrylate, cycloolefin copolymer and glass, any one of the materials. the

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