CN203179572U - Conductive film and touch screen comprising conductive film - Google Patents

Abstract

The utility model relates to a conductive film comprising a substrate, a first substrate layer, a first conductive layer, a second substrate layer, a second conductive layer, a light-shielding layer, a first lead electrode, and a second lead electrode. A first mesh recess and a second mesh recess are respectively provided on the first substrate layer and the second substrate layer. A conductive material is filled in the first mesh recess and the second mesh recess, such that the first conductive layer and the second conductive layer are formed. Because the first conductive layer and the second conductive layer are respectively positioned in the first mesh recess and the second mesh recess, the first substrate layer and the second substrate layer respectively cover the first conductive layer and the second conductive layer. Therefore, the first conductive layer and the second conductive layer can be protected by the first substrate layer and the second substrate layer, such that scratches to the first conductive layer and the second conductive layer during touch screen manufacturing can be prevented, and product yield can be further improved. The utility model also provides a touch screen.

Description

Conducting film and the touch-screen that comprises this conducting film

Technical field

The utility model relates to electronic technology, the touch-screen that particularly relates to a kind of conducting film and comprise this conducting film.

Background technology

In daily life, capacitive touch screen has been widely used in various electronic products, brings great convenience for people's life.Along with the further raising that people experience the user, electronic product more and more develops to lightening direction.Touch-screen is to determine whether electronic equipment does thin key factor.Therefore, along with the lightening needs to electronic product, touch-screen is also progressively to lightening development.OGS (One Glass Solution, i.e. integrated touch-control) is that touch-screen is to the important channel of lightening development.The main thought of OGS directly forms ITO conducting film and transducer on cover glass, make a glass play the double action of cover glass and touch sensor simultaneously.

Need preparation conducting film earlier when producing touch-screen, will show that again module is attached on the conducting film to obtain touch-screen.In general OGS technology, be directly to form conductive layer (being generally the ITO layer) on the cover glass surface mostly, thereby obtain the conducting film for the preparation of touch-screen.So in the conducting film that traditional handicraft obtains, conductive layer protrudes from glass surface.And because electric conducting material is softer as the quality of ITO, be scratched easily so protrude from the conductive layer of glass surface.Therefore, when fit showing module, may scratch conductive layer and cause electrolemma to scrap tradition, and then make the product yield not high.

The utility model content

Based on this, be necessary to provide a kind of touch-screen that improves the conducting film of product yield and comprise this conducting film.

A kind of conducting film comprises:

Substrate comprises first surface and the second surface that is oppositely arranged with described first surface;

First hypothallus, be attached to described first surface, described first hypothallus is solidify to form by the jelly coating, and described first hypothallus offers the first grid groove away from a side of described substrate, filled conductive material in the described first grid groove forms first conductive layer;

Second hypothallus, be attached on described first hypothallus side away from described substrate, described second hypothallus is solidify to form by the jelly coating, the length of described second hypothallus is less than the length of described first hypothallus, so that an end of described first hypothallus forms the white space that is not adhered to by described second hypothallus, described second hypothallus offers the second grid groove away from a side of described first hypothallus, and filled conductive material in the described second grid groove forms second conductive layer; And

Light shield layer, be attached to edge and the described white space of described second hypothallus, the zone that described second hypothallus adheres to described light shield layer forms the second non-viewing area, the white space that adheres to described light shield layer forms the first non-viewing area, the described first grid groove extends to the described first non-viewing area, and the described second grid groove extends to the described second non-viewing area;

Offer first through hole on the described light shield layer, described first through hole run through described light shield layer and and is communicated with the described first grid groove, filled conductive material in described first through hole is to form first electrode that goes between that is electrically connected with described first conductive layer; Described light shield layer surface also has the second lead-in wire electrode, and the described second lead-in wire electrode is electrically connected with described second conductive layer.

Among embodiment, the described second lead-in wire electrode forms lead-in wire by etching mode, and described lead-in wire electric conducting material is electrically connected with the electric conducting material of described second conductive layer therein; Or offer second through hole at described light shield layer, and described second through hole runs through described light shield layer and is communicated with the described second grid groove, filled conductive material in described second through hole, and be electrically connected with the electric conducting material of described second conductive layer.

Among embodiment, the thickness of described first conductive layer is not more than the degree of depth of the described first grid groove therein, and the thickness of described second conductive layer is not more than the degree of depth of the described second grid groove.

Among embodiment, described electric conducting material is silver therein.

Therein among embodiment, the width of the described first grid groove and the described second grid groove is between 1～5 micron, and the degree of depth is between 2～6 microns, and depth-to-width ratio is greater than 1, and the transmitance of described first conductive layer and described second conductive layer is greater than 85%.

Among embodiment, the thickness of described light shield layer is 1～10 micron therein.

Among embodiment, be ink lay or black light resistance layer therein.

Among embodiment, described substrate is glass therein.

Among embodiment, the grid of the described first grid groove and the described second grid groove is random grid therein.

A kind of touch-screen comprises:

As each described conducting film in the above-mentioned preferred embodiment;

Show module, be attached at described second hypothallus away from a side of described first hypothallus by optical cement.

Compare with traditional conducting film, above-mentioned conducting film has following at least advantage:

1, because first conductive layer and second conductive layer lay respectively in the first grid groove and the second grid groove, first conductive layer and second conductive layer are coated by first hypothallus and second hypothallus respectively.Therefore, first hypothallus and second hypothallus can provide protection to first conductive layer and second conductive layer, thereby prevent from when making touch-screen first conductive layer and second conductive layer being caused scratch, and then can improve the yield of product;

2, the edge of substrate is provided with light shield layer, and the first lead-in wire electrode and the second lead-in wire electrode can be arranged in the first non-viewing area and the second non-viewing area that is formed by the light shield layer projection.Therefore, when being assembled into touch-screen, from the wiring of screen top view less than the first lead-in wire electrode and the second lead-in wire electrode, thereby can improve the outward appearance of product.

Description of drawings

Fig. 1 is the layer structure schematic diagram of touch-screen in the utility model preferred embodiment;

Vertical interface schematic diagram of conducting film in Fig. 2 touch-screen shown in Figure 1;

Fig. 3 is the transverse interface schematic diagram of conducting film shown in Figure 2;

Fig. 4 is conducting film three-dimensional structure diagram shown in Figure 2;

Fig. 5 is the mesh shape schematic diagram of first conductive layer and second conductive layer in the conducting film shown in Figure 2;

Fig. 6 is the mesh shape schematic diagram of first conductive layer and second conductive layer among another embodiment.

Embodiment

For the ease of understanding the utility model, with reference to relevant drawings the utility model is described more fully below.Provided preferred embodiment of the present utility model in the accompanying drawing.But the utility model can be realized with many different forms, be not limited to embodiment described herein.On the contrary, provide the purpose of these embodiment be make the understanding of disclosure of the present utility model comprehensively thorough more.

Need to prove that when element is called as " being fixed in " another element, can directly can there be element placed in the middle in it on another element or also.When an element is considered to " connection " another element, it can be to be directly connected to another element or may to have element placed in the middle simultaneously.

Unless otherwise defined, the employed all technology of this paper are identical with the implication that belongs to those skilled in the art's common sense of the present utility model with scientific terminology.Employed term is not intended to be restriction the utility model just in order to describe the purpose of specific embodiment in specification of the present utility model herein.Term as used herein " and/or " comprise one or more relevant Listed Items arbitrarily with all combinations.

See also Fig. 1, the touch-screen 10 in the utility model preferred embodiment comprises conducting film 100 and shows module 200.Wherein, show that module 200 is attached on the conducting film 100 by optical cement.

See also 2, reach Fig. 3 and Fig. 4, conducting film 100 comprises substrate 110, first hypothallus 120, first conductive layer 130, second hypothallus 140, second conductive layer 150, light shield layer 160, the first lead-in wire electrode 170, reaches the second lead-in wire electrode 180.

Substrate 110 is platy structure, comprises first surface (figure is mark not) and second surface (figure is mark not), and wherein first surface and second surface are oppositely arranged.In the present embodiment, substrate 110 is glass substrate, and passes through intensive treatment for the manufacture of the glass of substrate 110, so obtain substrate 110 intensity height, can well play a protective role.It is to be noted, in other embodiment, substrate 110 also can be the film of other materials, as polybutylene terephthalate (PBT), polymethyl methacrylate (PMMA), polycarbonate plastic (PC) and Polyethyleneglycol Terephthalate (PET) film etc.When conducting film 100 was applied to touch-screen and prepares, the material of preparation substrate 110 was preferably transparent insulation material.

First hypothallus 120 is attached to the first surface of substrate 110.First hypothallus 120 is solidify to form by the jelly that is coated on the substrate 110, and therefore, its thickness is less than the thickness of substrate 110.In addition, first hypothallus 120 is made by transparent insulation material, and this material differs from the material of substrate 110.

In addition, first hypothallus 120 offers the first grid groove 121 away from a side of substrate 110.Electric conducting material is filled in the first grid groove 121, to form first conductive layer 130.Because first conductive layer 130 is positioned at the first grid groove 121, so first hypothallus 120 can coat first conductive layer 130.Therefore, first hypothallus 120 can form protection to first conductive layer 130, thus prevent this first conductive layer 130 in follow-up applying program by scratch.

Concrete, electric conducting material is filled in the first grid groove 121 and intersects the conductive grid that constitutes to form first conductive layer, 130, the first conductive layers 130 conduction fine rule of serving as reasons.Because ITO resistance ratio when doing large-sized conducting film is bigger, so that traditional utilization comprises the sensitivity of the prepared touch-screen of the conducting film of ITO conductive layer is bad.And latticed structure can effectively reduce resistance, thereby makes the resistance of first conductive layer 130 less, and then the sensitivity that can improve product.

Second hypothallus 140 is attached on first hypothallus 120 side away from substrate 110.Second hypothallus 140 is solidify to form by the jelly that is coated on first hypothallus 120, and its thickness is less than the thickness of substrate 110.Wherein, the length of second hypothallus 140 is less than the length (a is the length of first hypothallus among Fig. 4, and b is the length of second hypothallus) of first hypothallus 120.And the end alignment of an end first hypothallus 120 of second hypothallus 140 is so that an end of first hypothallus 120 forms the white space 123 that is not adhered to by second hypothallus 140.Concrete, second hypothallus 140 is fitted with showing module 200 away from a side of first hypothallus 120, so that show that module 200 is attached on the conducting film 100.

In addition, second hypothallus 140 offers the second grid groove 141 away from a side of first hypothallus 120.Electric conducting material is filled in the second grid groove 141, to form second conductive layer 150.Because second conductive layer 150 is positioned at the second grid groove 141, so second hypothallus 140 can coat second conductive layer 150.Therefore, 140 pairs of second hypothalluses, second conductive layers 150 form protection, prevent this second conductive layer 150 in follow-up applying program by scratch.

Concrete, electric conducting material is filled in the second grid groove 141 and intersects the conductive grid that constitutes to form second conductive layer, 150, the second conductive layers 150 conduction fine rule of serving as reasons.Because ITO resistance ratio when doing large-sized conducting film is bigger, so the sensitivity of the prepared touch-screen of traditional conducting film that utilizes the ITO conductive layer is bad.And latticed structure can effectively reduce resistance, thereby makes the resistance of second conductive layer 150 less, and then improves the sensitivity of product.

Light shield layer 160 is attached to edge and the white space 123 of second hypothallus 140.Light shield layer 160 is formed by the light screening material that is coated on second hypothallus, 140 marginal surfaces and white space 123, and formed light shield layer 160 is annular layer structure.Light shield layer 160 is made by lighttight material, so can form shade at the edge of first hypothallus 120 and second hypothallus 140.The zone that second hypothallus 140 adheres to light shield layer 160 forms the second non-viewing area (figure is mark not), and white space 123 adheres to light shield layer 160, thereby forms the first non-viewing area (not shown).Wherein, the first grid groove 121 extends to the first non-viewing area, and the second grid groove 141 extends to the second non-viewing area.

In the present embodiment, light shield layer 160 is ink lay or black light resistance layer, and its thickness is between 1～10 micron.When light shield layer 160 was ink lay, the thickness of light shield layer 160 can be 6 microns, and light shield layer 160 is when being the black light resistance layer, and the thickness of light shield layer 160 can be 1 micron, thereby reaches thinner thickness.

Offer the first through hole (not shown) on the light shield layer 160.First through hole runs through light shield layer 160 and is communicated with the first grid groove 121.

Filled conductive material in first through hole forms the first lead-in wire electrode 170.Because first through hole is communicated with the first grid groove 131.Therefore, the first lead-in wire electrode 170 that forms in first through hole is electrically connected with first conductive layer 130.The first lead-in wire electrode 170 is guided to the surface of light shield layer 160 with first conductive layer 130, is electrically connected with the controller of electronic equipment thereby be convenient to first conductive layer 130.

The second lead-in wire electrode 180 is formed at the surface of light shield layer 160, and the second lead-in wire electrode 180 is electrically connected 150 with second conductive layer.

In the present embodiment, the second lead-in wire electrode 180 forms lead-in wire by etching mode, and this lead-in wire electric conducting material is electrically connected with the electric conducting material of second conductive layer 150.In addition, in other embodiments, also can offer the second through hole (not shown) at light shield layer, second through hole runs through light shield layer 160 and is communicated with the second grid groove 141.Filled conductive material in second through hole is to form the second lead-in wire electrode 180.Because second through hole is communicated with the second grid groove 141.Therefore, the second lead-in wire electrode 180 that forms in second through hole is electrically connected with second conductive layer 150.The second lead-in wire electrode that the described second conductive layer point is electrically connected.The second lead-in wire electrode 180 is guided to the surface of light shield layer 160 with second conductive layer 150, is electrically connected with the controller of electronic equipment thereby be convenient to second conductive layer 150.

Conducting film 100 is during for the preparation of the touch-screen of electronic equipment, and the first lead-in wire electrode 170 and the second lead-in wire electrode are used for first conductive layer 130 and second conductive layer 150 are electrically connected with the controller of electronic equipment, thereby makes controller sense operation on the touch-screen.Because the first lead-in wire electrode 170 and the second lead-in wire electrode 180 all are positioned at the surface of light shield layer 160.Therefore, do not observe the wiring of the first lead-in wire electrode 170 and the second lead-in wire electrode 180 at the electronic equipment of preparation, thereby help to promote product appearance.

In the present embodiment, form the electric conducting material of first conductive layer 130, second conductive layer 150, the first lead-in wire electrode 170 and the second lead-in wire electrode 180 for silver-colored.Silver is good conductor, and resistivity is little, thereby can further improve the sensitivity of product.It is pointed out that in other embodiments conductor material also can be macromolecule conducting material, Graphene, carbon nano-tube and tin indium oxide (ITO) etc.

See also Fig. 5, in the present embodiment, the grid of the first grid groove 121 and the second grid groove 141 is random grid.Therefore, the mesh shape of first conductive layer 130 of formation and second conductive layer 150 also is random grid.Because the center random distribution of random grid can not produce interference thereby make to win between conductive layer 130 and second conductive layer 150, and then avoid producing Moire fringe, promote the display effect of the display screen that comprises conducting film 100.It is to be noted, as shown in Figure 6, in other embodiments, the mesh shape of the first grid groove 121 and the second grid groove 141 also can be regular polygon, and the grid element center of first conductive layer 130 and second conductive layer 150 staggers, to avoid producing Moire fringe.

In the present embodiment, the thickness of first conductive layer 130 is not more than the degree of depth of the first grid groove 121, and the thickness of second conductive layer 150 is not more than the degree of depth of the second grid groove 141.Therefore, first conductive layer 130 and second conductive layer 150 can insulate by first hypothallus 120 and second hypothallus 140, thereby form capacitance structure between first conductive layer 130 and second conductive layer 150.It is pointed out that in other embodiments, also can make first conductive layer 130 and 150 insulation of second conductive layer by the mode at first hypothallus 120 and second hypothallus, 140 laying insulating barriers.

In the present embodiment, the width of the first grid groove 121 and the second grid groove 141 is between 1～5 micron, and height is between 2～6 microns, and depth-to-width ratio is greater than 1.Therefore, first conductive layer 130 of formation and the transmitance of second conductive layer 150 are greater than 85%, and light passes to make from conductive layer and do not have too many loss, thereby can make the display screen that comprises conducting film 100 have better display effect.

Compare with traditional conducting film, conducting film 100 has following at least advantage:

1, because first conductive layer 130 and second conductive layer 150 lay respectively in the first grid groove 121 and the second grid groove 141, first conductive layer 130 and second conductive layer 150 are coated by first hypothallus 120 and second hypothallus 140 respectively.Therefore, first hypothallus 120 and second hypothallus 140 can provide protection to first conductive layer 130 and second conductive layer 150, thereby prevent from when making touch-screen first conductive layer 130 and second conductive layer 150 being caused scratch, and then can improve the yield of product;

2, the edge of substrate 110 is provided with light shield layer 160, the first lead-in wire electrodes 170 and the second lead-in wire electrode 180 can be arranged in the first non-viewing area and the second non-viewing area that is formed by light shield layer 160 projections.Therefore, when being assembled into touch-screen 10, from the wiring of screen top view less than the first lead-in wire electrode 170 and the second lead-in wire electrode 180, thereby can improve the outward appearance of product.

The above embodiment has only expressed several execution mode of the present utility model, and it describes comparatively concrete and detailed, but can not therefore be interpreted as the restriction to the utility model claim.Should be pointed out that for the person of ordinary skill of the art under the prerequisite that does not break away from the utility model design, can also make some distortion and improvement, these all belong to protection range of the present utility model.Therefore, the protection range of the utility model patent should be as the criterion with claims.

Claims (10)

1. a conducting film is characterized in that, comprising:

Substrate comprises first surface and the second surface that is oppositely arranged with described first surface;

First hypothallus, be attached to described first surface, described first hypothallus is solidify to form by the jelly coating, and described first hypothallus offers the first grid groove away from a side of described substrate, filled conductive material in the described first grid groove forms first conductive layer;

Second hypothallus, be attached on described first hypothallus side away from described substrate, described second hypothallus is solidify to form by the jelly coating, the length of described second hypothallus is less than the length of described first hypothallus, so that an end of described first hypothallus forms the white space that is not adhered to by described second hypothallus, described second hypothallus offers the second grid groove away from a side of described first hypothallus, and filled conductive material in the described second grid groove forms second conductive layer; And

Light shield layer, be attached to edge and the described white space of described second hypothallus, the zone that described second hypothallus adheres to described light shield layer forms the second non-viewing area, the white space that adheres to described light shield layer forms the first non-viewing area, the described first grid groove extends to the described first non-viewing area, and the described second grid groove extends to the described second non-viewing area;

Offer first through hole on the described light shield layer, described first through hole run through described light shield layer and and is communicated with the described first grid groove, filled conductive material in described first through hole is to form first electrode that goes between that is electrically connected with described first conductive layer; Described light shield layer surface also has the second lead-in wire electrode, and the described second lead-in wire electrode is electrically connected with described second conductive layer.

2. conducting film according to claim 1 is characterized in that, the described second lead-in wire electrode forms lead-in wire by etching mode, and described lead-in wire electric conducting material is electrically connected with the electric conducting material of described second conductive layer; Or offer second through hole at described light shield layer, and described second through hole runs through described light shield layer and is communicated with the described second grid groove, filled conductive material in described second through hole, and be electrically connected with the electric conducting material of described second conductive layer.

3. conducting film according to claim 1 is characterized in that, the thickness of described first conductive layer is not more than the degree of depth of the described first grid groove, and the thickness of described second conductive layer is not more than the degree of depth of the described second grid groove.

4. conducting film according to claim 1 is characterized in that, described electric conducting material is silver.

5. according to the arbitrary described conducting film of claim 1～4, it is characterized in that the width of the described first grid groove and the described second grid groove is between 1～5 micron, the degree of depth is between 2～6 microns, and depth-to-width ratio is greater than 1, and the transmitance of described first conductive layer and described second conductive layer is greater than 85%.

6. conducting film according to claim 1 is characterized in that, the thickness of described light shield layer is 1～10 micron.

7. conducting film according to claim 6 is characterized in that, is ink lay or black light resistance layer.

8. conducting film according to claim 1 is characterized in that, described substrate is glass.

9. conducting film according to claim 1 is characterized in that, the grid of the described first grid groove and the described second grid groove is random grid.

10. a touch-screen is characterized in that, comprising:

As each described conducting film of above-mentioned claim 1～9;

Show module, be attached at described second hypothallus away from a side of described first hypothallus by optical cement.

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