CN205451011U - Touch control module - Google Patents

Abstract

The utility model provides a touch control module exposes here. Touch control module includes a base plate, at least two first touch -control electrodes, two at least second touch -control electrodes, an insulation layer piece, an at least electrode passageway and an at least bridging. First touch -control electrode is on the base plate. Second touch -control electrode is on the base plate. The embedding of insulation layer piece is in the base plate to be located between first touch -control electrode and the second touch -control electrode. The electrode passageway is for electric connection second touch -control electrode on the base plate. Build bridge and stride across this electrode passageway for the first touch -control electrode of electric connection. The insulation of first touch -control electrode electrical property is in second touch -control electrode. This is borrowed, etching mode patterning touch -control electrode can be avoided seeing through to avoid causing touch control module's optical index inhomogeneous, and influence the optics uniformity of touch control module outward appearance.

Description

Touch-control module

Technical field

This utility model relates to a kind of electronic installation.In particular to a kind of touch-control module.

Background technology

Along with the rapid progress of electronics technology, touch-control module has been widely used in various electronic installation, such as mobile phone, panel computer etc..

Typical touch-control module such as may be disposed on display screen, including multiple touch control electrode.Object (finger or touching pen etc.) close to or during touching display screen, corresponding touch control electrode produces the signal of telecommunication, reaches touch-control sensing whereby.

In the fabrication process, usually utilize etching mode to be removed by the conductive materials between touch control electrode, to pattern touch control electrode, and make between touch control electrode insulated from each other.But, the way that partially electronically conductive material is removed, and only remove the structure that partially electronically conductive material is formed, by uneven for the optical index causing touch-control module, and affect the optical homogeneity of touch-control module outward appearance.

Utility model content

Therefore the optical index for avoiding touch-control module is uneven, one side of the present utility model provides a kind of touch-control module.According to this utility model one embodiment, this touch-control module includes a substrate, at least two first touch control electrode, at least two second touch control electrode, an insulation block, at least one electrode channel and at least one bridge formation.Described first touch control electrode is formed on this substrate.Described second touch control electrode is formed on this substrate.This insulation block embeds and is formed in this substrate, and between this first touch control electrode and this second touch control electrode.This electrode channel is formed on this substrate, is for electrically connecting to described second touch control electrode.This bridge formation is arranged on this substrate, is for electrically connecting to described first touch control electrode.Described first touch control electrode is electrically insulated from described second touch control electrode.

According to this utility model one embodiment, described first touch control electrode, described second touch control electrode, this electrode channel and this insulation block are to be formed by same conductive material layer and have identical conductive materials, and this insulation block is to have the conductive materials of separation through the insulating process of a dispersed electro-conductive material.

According to this utility model one embodiment, this insulation block is more positioned at around described first touch control electrode and described second touch control electrode.

According to this utility model one embodiment, this insulation block orthographic projection on a surface of this substrate is in described first touch control electrode and described second touch control electrode between the orthographic projection on this surface of this substrate.

According to this utility model one embodiment, the most overlapping between described first touch control electrode, described second touch control electrode, this electrode channel with this insulation block orthographic projection on a surface of this substrate.

According to this utility model one embodiment, this touch-control module also includes multiple shade, is respectively arranged on described first touch control electrode, described second touch control electrode and this electrode channel.

According to this utility model one embodiment, described in be arranged in described first touch control electrode shade also include multiple contact hole.This bridge formation is electrically connected with described first touch control electrode through described contact hole.

According to this utility model one embodiment, described in be arranged in described first touch control electrode shade also include multiple electric-conductor, lay respectively in described contact hole.This bridge formation is electrically connected with described first touch control electrode through described electric-conductor.

According to this utility model one embodiment, this bridge formation is arranged at the shade on this electrode channel to be electrically insulated with this electrode channel by this.

According to this utility model one embodiment, this touch-control module also includes a plurality of wire, is electrically connected with this first touch control electrode and this second touch control electrode.

According to this utility model one embodiment, this touch-control module also includes a plurality of auxiliary conductor, lays respectively under described wire, and is electrically connected with described wire.

According to this utility model one embodiment, this touch-control module also includes multiple engagement pad and a plurality of wire.Described engagement pad is respectively arranged on this first touch control electrode of part and this second touch control electrode of part.Described wire is electrically connected with described engagement pad.

According to this utility model one embodiment, described first touch control electrode is to arrange along a first direction, and described second touch control electrode is to arrange along a second direction, and this first direction is different from this second direction.

In sum, through applying an above-mentioned embodiment, a kind of touch-control module can be realized.By forming insulation block in substrate, can make between touch control electrode insulated from each other.Consequently, it is possible to can avoid patterning touch control electrode through etching mode, and avoid the optical index causing touch-control module uneven, and affect the optical homogeneity of touch-control module outward appearance.

Accompanying drawing explanation

The schematic diagram of the manufacture method of a kind of touch-control module that Figure 1A, Fig. 2 A, Fig. 3 A, Fig. 4 A, Fig. 5 A respectively illustrates according to this utility model one embodiment；

Figure 1B, Fig. 2 B, Fig. 3 B, Fig. 4 B, Fig. 5 B is respectively the touch-control module in Figure 1A, Fig. 2 A, Fig. 3 A, Fig. 4 A, Fig. 5 A along the profile depicted in line segment A-a direction；

Fig. 6 is the profile according to the formation touch control electrode depicted in this utility model comparative example with insulation block；

The schematic diagram of the manufacture method of a kind of touch-control module that Fig. 7 A, Fig. 8 A, Fig. 9 A respectively illustrate according to this utility model one embodiment；

The touch-control module that Fig. 7 B, Fig. 8 B, Fig. 9 B are respectively in Fig. 7 A, Fig. 8 A, Fig. 9 A is along the profile depicted in line segment A-a direction；

The schematic diagram of the manufacture method of a kind of touch-control module that Figure 10 A, Figure 11 A, Figure 12 A, Figure 13 A, Figure 14 A respectively illustrate according to this utility model one embodiment；

The touch-control module that Figure 10 B, Figure 11 B, Figure 12 B, Figure 13 B, Figure 14 B are respectively in Figure 10 A, Figure 11 A, Figure 12 A, Figure 13 A, Figure 14 A is along the profile depicted in line segment A-a direction；

The schematic diagram of the manufacture method of a kind of touch-control module that Figure 15 A, Figure 16 A, Figure 17 A, Figure 18 A, Figure 19 A respectively illustrate according to this utility model one embodiment；

The touch-control module that Figure 15 B, Figure 16 B, Figure 17 B, Figure 18 B, Figure 19 B are respectively in Figure 15 A, Figure 16 A, Figure 17 A, Figure 18 A, Figure 19 A is along the profile depicted in line segment A-a direction；

Figure 20 A, Figure 21 A, Figure 22 A, Figure 23 A are respectively the schematic diagram of a step in the manufacture method of a kind of touch-control module that the embodiment according to this utility model one change illustrates；

The touch-control module that Figure 20 B, Figure 21 B, Figure 22 B, Figure 23 B are respectively in Figure 20 A, Figure 21 A, Figure 22 A, Figure 23 A is along the profile depicted in line segment A-a direction；

The schematic diagram of the manufacture method of a kind of touch-control module that Figure 24 A, Figure 25 A, Figure 26 A, Figure 27 A, Figure 28 A respectively illustrate according to this utility model one embodiment；

The touch-control module that Figure 24 B, Figure 25 B, Figure 26 B, Figure 27 B, Figure 28 B are respectively in Figure 24 A, Figure 25 A, Figure 26 A, Figure 27 A, Figure 28 A is along the profile depicted in line segment A-a direction；

The schematic diagram of the manufacture method of a kind of touch-control module that Figure 29 A, Figure 30 A, Figure 31 A, Figure 32 A respectively illustrate according to this utility model one embodiment；

The touch-control module that Figure 29 B, Figure 30 B, Figure 31 B, Figure 32 B are respectively in Figure 29 A, Figure 30 A, Figure 31 A, Figure 32 A is along the profile depicted in line segment A-a direction；

The schematic diagram of the manufacture method of a kind of touch-control module that Figure 33 A, Figure 34 A respectively illustrate according to this utility model one embodiment；

The touch-control module that Figure 33 B, Figure 34 B are respectively in Figure 33 A, Figure 34 A is along the profile depicted in line segment A-a direction；

The schematic diagram of the manufacture method of a kind of touch-control module that Figure 35 A, Figure 36 A, Figure 37 A, Figure 38 A, Figure 39 A respectively illustrate according to this utility model one embodiment；

The touch-control module that Figure 35 B, Figure 36 B, Figure 37 B, Figure 38 B, Figure 39 B are respectively in Figure 35 A, Figure 36 A, Figure 37 A, Figure 38 A, Figure 39 A is along the profile depicted in line segment A-a direction；

The schematic diagram of the manufacture method of a kind of touch-control module that Figure 40 A, Figure 41 A, Figure 42 A, Figure 43 A respectively illustrate according to this utility model one embodiment；

The touch-control module that Figure 40 B, Figure 41 B, Figure 42 B, Figure 43 B are respectively in Figure 40 A, Figure 41 A, Figure 42 A, Figure 43 A is along the profile depicted in line segment A-a direction；

The schematic diagram of the manufacture method of a kind of touch-control module that Figure 44 A, Figure 45 A, Figure 46 A, Figure 47 A respectively illustrate according to this utility model one embodiment；

The touch-control module that Figure 44 B, Figure 45 B, Figure 46 B, Figure 47 B are respectively in Figure 44 A, Figure 45 A, Figure 46 A, Figure 47 A is along the profile depicted in line segment A-a direction；

The schematic diagram of the manufacture method of a kind of touch-control module that Figure 48 A, Figure 49 A, Figure 50 A respectively illustrate according to this utility model one embodiment；

The touch-control module that Figure 48 B, Figure 49 B, Figure 50 B are respectively in Figure 48 A, Figure 49 A, Figure 50 A is along the profile depicted in line segment A-a direction；

The schematic diagram of the manufacture method of a kind of touch-control module that Figure 51 A, Figure 52 A, Figure 53 A, Figure 54 A respectively illustrate according to this utility model one embodiment；

The touch-control module that Figure 51 B, Figure 52 B, Figure 53 B, Figure 54 B are respectively in Figure 51 A, Figure 52 A, Figure 53 A, Figure 54 A is along the profile depicted in line segment A-a direction；

The schematic diagram of the manufacture method of a kind of touch-control module that Figure 55 A, Figure 56 A, Figure 57 A respectively illustrate according to this utility model one embodiment；

The touch-control module that Figure 55 B, Figure 56 B, Figure 57 B are respectively in Figure 56 A, Figure 57 A is along the profile depicted in line segment A-a direction；And

Figure 58 is the flow chart of the manufacture method of a kind of touch-control module illustrated according to this utility model one embodiment.

Detailed description of the invention

Hereinafter with accompanying drawing and narration in detail, spirit of the present utility model will be clearly described, any art has usually intellectual after understanding preferred embodiment of the present utility model, when the technology that can be taught by this utility model, being changed and modify, it is without departing from spirit and scope of the present utility model.

About " first " used herein, " second " ... etc., censure order or the meaning of cis-position the most especially, be also not used to limit this utility model, its element described with constructed term only for difference or operation.

About direction used herein term, such as: upper and lower, left and right, front or rear etc., it is only the direction with reference to attached drawings.Therefore, the direction term of use is used to illustrate not for limiting this creation.

About " comprising " used herein, " including ", " having ", " containing " etc., be the term of opening, i.e. mean including but not limited to.

About used herein " and/or ", be to include the arbitrary of described things or all combine.

About word used herein (terms), in addition to having and indicating especially, be generally of each word use in this area, in the content that discloses at this with the usual meaning in special content.Some is in order to describe the word of this exposure by lower or discuss in the other places of this description, to provide those skilled in the art about guiding extra in the description of this exposure.

An embodiment of the present utility model is the manufacture method of a kind of touch-control module.In the following paragraphs, this utility model will illustrate this utility model details as a example by following first embodiment to the 14th embodiment, but this utility model is not limited with the details in following embodiment, and other embodiment is also among this utility model scope.

First embodiment

The schematic diagram of the manufacture method of a kind of touch-control module 100 that Figure 1A, Fig. 2 A, Fig. 3 A, Fig. 4 A, Fig. 5 A respectively illustrates according to this utility model one embodiment.Figure 1B, Fig. 2 B, Fig. 3 B, Fig. 4 B, Fig. 5 B is respectively the touch-control module 100 in Figure 1A, Fig. 2 A, Fig. 3 A, Fig. 4 A, Fig. 5 A along the profile depicted in line segment A-A direction.

First, referring specifically to Figure 1A and Figure 1B, in a first step, it is provided that conductive material layer 120 is on the upper surface SF1 of substrate 110.Then, in a second step, it is provided that multiple first shade MSK1 and the second shade MSK2 are on conductive material layer 120.

In one embodiment, it is by providing the embedding liquid (embeddingsolvent) containing conductive additive (conductingadditive) on the upper surface SF1 of substrate 110, to make conductive additive be partially submerged in substrate 110, form conductive material layer 120.That is, conductive material layer 120 is to be partially submerged on the upper surface SF1 of substrate 110.

In one embodiment, substrate 110 is e.g. by polyacids methyl ester (polymethylmethacrylate, PMMA), Merlon (polycarbonate, PC), polyethylene terephthalate (polyethyleneterephthalate, PET), the suitably macromolecular material such as cyclic olefin monomers co-polymer (cycloolefinpolymer, COP) realizes.In one embodiment, embedding liquid containing conductive additive is e.g. realized by conductive additive being dissolved in specific solvent, the solubility parameter (solubilityparameter) of wherein said specific solvent is close to the solubility parameter of the material of substrate 110, so that the conductive additive being dissolved in described specific solvent penetrates among substrate 110, to reach the effect of embedding.In one embodiment, the suitably electrically conductive material such as above-mentioned conductive additive e.g. CNT, nano metal line, conducting resinl, conducting polymer, dilute, the nano metal of graphite.

By providing the embedding liquid containing conductive additive on the upper surface SF1 of the substrate 110 formed with macromolecular material, the demi-inflation of adjacent upper surface SF1 in substrate 110 can be made, so that partially electronically conductive additive penetrates among substrate 110, to reach the effect being partially submerged into.

For making narration clear, in the following paragraphs, aforesaid conductive additive will illustrate as a example by nano-silver thread, but this utility model is not limited.

In one embodiment, the first shade MSK1 is in order to the first touch control electrode E1 graphical in step then, and the second shade MSK2 is in order to the second touch control electrode E2 graphical in step then.

In one embodiment, it is to be initially formed a transparent material layer on conductive material layer 120, the most again to remove the part in this transparent material layer, to form the first shade MSK1 and the second shade MSK2.In one embodiment, this one remove program can with gold-tinted etching or dry-etching realize, right this utility model is not limited.

In one embodiment, the first shade MSK1 and the second shade MSK2 such as can be with photoresist or other transparent conduction, non-conducting material realization, and right this utility model is not limited.

In one embodiment, the first shade MSK1 exists multiple contact hole T, these contact holes T and expose partially electronically conductive material layer 120.

Then, referring specifically to Fig. 2 A and Fig. 2 B, in a third step, it is provided that multiple electrically conducting transparent part CD are in contact hole T and on conductive material layer 120.

In one embodiment, electrically conducting transparent part CD and contact hole T on vertical view face equivalently-sized.In one embodiment, electrically conducting transparent part CD size on vertical view face can be more than or less than contact hole T size on vertical view face.

In one embodiment, electrically conducting transparent part CD can be formed with transparent conductive material.

Then, referring specifically to Fig. 3 A and Fig. 3 B, in one the 4th step, it is provided that a plurality of plain conductor MT is on conductive material layer 120 and the first shade MSK1 and the second shade MSK2.

Now, the Part I P outside conductive material layer 120 includes being exposed to shade MSK1, MSK2 and plain conductor MT；It is positioned at the Part II Q under shade MSK1, MSK2 and electrically conducting transparent part CD；And be positioned under plain conductor MT and the Part III R of contacting metal wire MT.

Then, referring specifically to Fig. 4 A and Fig. 4 B, in one the 5th step, the Part I P of insulating conductive material layer 120, to form the first touch control electrode E1, the second touch control electrode E2, electrode channel C, auxiliary conductor X and insulation block I.

nullFurthermore，In the 5th step，It is that dispersing conductive material layer 120 is exposed to shade MSK1、MSK2、And electrically conducting transparent part CD、And the conductive materials (such as nano-silver thread) in the Part I P outside plain conductor MT，And make these conductive materials sink further and be dispersed among substrate 110 to form insulation block I，And make the Part II Q being positioned under the first shade MSK1 and electrically conducting transparent part CD and contacting the first shade MSK1 and electrically conducting transparent part CD in conductive material layer 120 form the first touch control electrode E1、Make in conductive material layer 120 under the second shade MSK2 and contact the Part II Q of the second shade MSK2 to form the second touch control electrode E2 and the electrode channel C between the second touch control electrode E2，And make conductive material layer 120 to be positioned under plain conductor MT and the Part III R formation auxiliary conductor X of contacting metal wire MT.

In one embodiment, it is by the Part I P outside providing the embedding liquid without conductive additive to be exposed to shade MSK1, MSK2 and plain conductor MT in conductive material layer 120, with the conductive materials in the Part I P in dispersing conductive material layer 120, and make these conductive materials sink further and be dispersed among substrate 110, to form the insulation block I of embedding in substrate 110.

For example, referring specifically to Fig. 6.As shown in Figure 6, multiple nano-silver thread SNW under the first shade MSK1 are to be connected to each other, to form the first touch control electrode E1 of tool electric conductivity, in addition, it is exposed to the nano-silver thread SNW outside electrically conducting transparent part CD and the plain conductor MT corresponding to the first shade MSK1, the first shade MSK1, because being disperseed by the embedding liquid without conductive additive, therefore it is not connected to each other, to form the insulation block I not having electric conductivity.In other words, touch control electrode E1, E2, electrode channel C and auxiliary conductor X have the conductive materials being electrically connected to each other, and insulation block I has the conductive materials disperseing each other and electrically isolating.

In one embodiment, the liquid that embeds without conductive additive is e.g. realized by the aforesaid specific solvent with specific solubility parameter.

In one embodiment, insulation block I is formed between touch control electrode E1, E2, so that touch control electrode E1, E2 are insulated from each other.In one embodiment, insulation block I is also formed in around touch control electrode E1, E2.In one embodiment, insulation block I is exposed to the upper surface SF1 of substrate 110.

Then, referring specifically to Fig. 5 A and Fig. 5 B, in one the 6th step, it is provided that at least one bridge formation BG, wherein bridge formation BG is across electrode channel C setting, to be electrically connected with two the first adjacent touch control electrode E1.In one embodiment, bridge formation BG is through contact hole T two adjacent electrically conducting transparent part CD in electrical contact, to be electrically connected with two the first adjacent touch control electrode E1.In one embodiment, bridge formation BG is electrically insulated with electrode channel C by the shade MSK2 being arranged on electrode channel C.

Through above-mentioned manufacture method, touch-control module 100 can be realized.In substrate 110, form insulation block I, touch control electrode E1 can be made to electrically isolate from touch control electrode E2 and electrode channel C.Consequently, it is possible to can avoid patterning touch control electrode E1, E2 through etching mode, and avoid the optical index causing touch-control module 100 uneven, and affect the optical homogeneity of touch-control module 100 outward appearance.

In other words, by the conductive materials of aforementioned dispersing conductive material layer 120 with the method forming insulation block I in substrate 110, can make the most do not have gap or the most overlapping between touch control electrode E1, E2, electrode channel C, auxiliary conductor X with insulation block I orthographic projection on the upper surface SF1 of substrate 110.That is, touch control electrode E1, E2, electrode channel C, auxiliary conductor X can form a complete plane with insulation block I orthographic projection on the upper surface SF1 of substrate 110.Consequently, it is possible to can avoid because refractive index is uneven, and affect the optical homogeneity of touch-control module 100 outward appearance.

When noticing, the term " substantially " in this utility model, be modify can the quantity of slight variations and the nearmis that caused because of manufacture process, but this slight variations and nearmis can't change its essence.For example, during forming insulation block I, it is possible to create error so that there is gap or slightly overlapping slightly between touch control electrode E1, E2, plain conductor MT and insulation block I orthographic projection on the upper surface SF1 of substrate 110.But, these nearmis caused because of manufacture process, also among this utility model scope.

In one embodiment, insulation block I orthographic projection on the upper surface SF1 of substrate 110 is between touch control electrode E1, E2 and electrode channel C orthographic projection on the upper surface SF1 of substrate 110.In one embodiment, insulation block I orthographic projection on the upper surface SF1 of substrate 110 is positioned at around touch control electrode E1, E2 and electrode channel C orthographic projection on the upper surface SF1 of substrate 110.

In the present embodiment, the first touch control electrode E1 e.g. x-axis direction setting along Fig. 5 A.It is to be electrically connected to each other through bridge formation BG between two adjacent the first touch control electrode E1.Bridge formation BG is across on electrode channel C.Bridge formation BG and electrode channel C is intercepted by shade MSK2, therefore the most in electrical contact.In one embodiment, the first touch control electrode E1 is positioned under shade MSK1, and bridge formation BG is positioned on shade MSK1.

Additionally, e.g. y-axis direction (the being perpendicular to x-axis direction) setting along Fig. 5 A of the second touch control electrode E2.It is to be electrically connected to each other through electrode channel C between two adjacent the second touch control electrode E2.In one embodiment, touch control electrode E2 and electrode channel C are all positioned under shade MSK2.

Furthermore, in the present embodiment, the first touch control electrode E1 and the second touch control electrode E2 are the most substantially diamond shaped.Illustrating it should be noted that above-described embodiment is only, other shapes of touch control electrode E1, E2 are also among this utility model category, therefore this utility model is not limited thereto.

In one embodiment, shade MSK1 e.g. x-axis direction setting along Fig. 5 A, and shade MSK2 e.g. y-axis direction setting along Fig. 5 A.In one embodiment, shade MSK1, MSK2 is the most substantially diamond shaped.Illustrating it should be noted that above-described embodiment is only, other shapes of shade MSK1, MSK2 are also among this utility model category, therefore this utility model is not limited thereto.

In one embodiment, shade MSK1, MSK2 is separated from one another.In one embodiment, do not overlap each other between shade MSK1, MSK2 orthographic projection on the upper surface SF1 of substrate 110.

In one embodiment, shade MSK1 and shade MSK2 can remove by selectivity at least partially after forming touch control electrode E1, E2, therefore this utility model is not limited with above-described embodiment.

In one embodiment, auxiliary conductor X is positioned under plain conductor MT.In one embodiment, auxiliary conductor X is electrically connected with plain conductor MT, and is electrically connected with touch control electrode E1, E2.In one embodiment, auxiliary conductor X can assist plain conductor MT to transmit touching signals.

In one embodiment, auxiliary conductor X, electrode channel C, insulation block I and touch control electrode E1, E2 have identical conductive materials.

It should be noted that, although in the above-described embodiments, touch control electrode E1, E2 are formed on same substrate 110, but in different embodiments, touch control electrode E1, E2 also can first be respectively formed on different substrate, the most again by these superimposed substrates, to form touch-control module 100.Therefore, this utility model is not limited with previous embodiment.

On the other hand, it is noted that in the embodiment of a change of the present utility model, substrate 110 can include active layer (not illustrating) and bottom (not illustrating).Active layer is arranged on bottom, and aforesaid touch control electrode E1, E2, electrode channel C and auxiliary conductor X are all partially submerged on the active layer of substrate 110, and aforesaid insulation block I is formed among the active layer of substrate 110.

In one embodiment, bottom can be rigidity or soft materials, and such as useable glass, polyethylene terephthalate (polyethyleneterephthalate, PET) and/or Merlon (polycarbonate, PC) are made.Active layer such as can use the suitably macromolecular material such as polyacids methyl ester, polrvinyl chloride (polyvinylchloride, PVC) and/or polystyrene (polystyrene) to realize.

In one embodiment, owing to the first touch control electrode E1, the second touch control electrode E2, electrode channel C and the block I that insulate are to be formed by same conductive material layer 120, therefore there is identical conductive materials.Insulation block I is that the insulating of the conductive materials in a dispersing conductive material layer 120 processes (the most aforesaid embedding process) and has isolated conductive materials from conductive material layer 120.

Second embodiment

Hereinafter will transmit through the second embodiment, it is provided that the manufacture method of another kind of touch-control module 100.This manufacture method is roughly the same with the manufacture method in first embodiment, is only replacing electrically conducting transparent part with metallic conduction part MD in place of difference, so that providing the step of metallic conduction part MD to be integrated with the step providing plain conductor MT.Therefore, in the following description, the part of repetition will not repeat.

The first step of the present embodiment, second step and the first step of first embodiment, second step roughly the same (can refer to Figure 1A, 1B), therefore be not repeated herein.

With reference to Fig. 7 A and Fig. 7 B, in a third step, it is possible to provide multiple metallic conduction part MD are in contact hole T and on conductive material layer 120, and provide plain conductor MT on shade MSK1, MSK2 with conductive material layer 120.In one embodiment, metallic conduction part MD can fill up contact hole T.

In one embodiment, it is provided that the step of metallic conduction part MD and plain conductor MT can be integrated into single processing procedure.In different embodiments, metallic conduction part MD and plain conductor MT is to provide in different processing procedures.

In one embodiment, metallic conduction part MD can realize with same metal material with plain conductor MT.In different embodiments, metallic conduction part MD can realize with different metal material with plain conductor MT.

Now, the Part I P outside conductive material layer 120 includes being exposed to shade MSK1, MSK2, metallic conduction part MD and plain conductor MT；It is positioned at the Part II Q under shade MSK1, MSK2, metallic conduction part MD；And be positioned under plain conductor MT and the Part III R of contacting metal wire MT.

Then, with reference to Fig. 8 A and Fig. 8 B, in one the 4th step, the Part I P of insulating conductive material layer 120, to form the first touch control electrode E1, the second touch control electrode E2, electrode channel C, auxiliary conductor X and insulation block I.

nullFurthermore，In the 4th step，It is that dispersing conductive material layer 120 is exposed to shade MSK1、MSK2、Metallic conduction part MD、And the conductive materials (such as nano-silver thread) in the Part I P outside plain conductor MT，And make these conductive materials sink further and be dispersed among substrate 110 to form insulation block I，And make the Part II Q being positioned under the first shade MSK1 and metallic conduction part MD and contacting the first shade MSK1 and metallic conduction part MD in conductive material layer 120 form the first touch control electrode E1、Make in conductive material layer 120 under the second shade MSK2 and contact the Part II Q of the second shade MSK2 to form the second touch control electrode E2 and the electrode channel C between the second touch control electrode E2，And make conductive material layer 120 to be positioned under plain conductor MT and the Part III R formation auxiliary conductor X of contacting metal wire MT.

In the present embodiment, the details of the conductive materials being exposed in dispersing conductive material layer 120 in the Part I P outside shade MSK1, MSK2, metallic conduction part MD and plain conductor MT can refer to aforementioned paragraphs, therefore is not repeated herein.

In one embodiment, being formed at least partially between touch control electrode E1, E2, so that touch control electrode E1, E2 are insulated from each other in insulation block I.In one embodiment, being formed at least partially around touch control electrode E1, E2 in insulation block I.In one embodiment, insulation block I is exposed to the upper surface SF1 of substrate 110.

Then, referring specifically to Fig. 9 A and Fig. 9 B, in one the 5th step, it is provided that at least one bridge formation BG, wherein bridge formation BG is across electrode channel C setting, to be electrically connected with two the first adjacent touch control electrode E1.In one embodiment, bridge formation BG is through contact hole T two adjacent metallic conduction part MD in electrical contact, to be electrically connected with two the first adjacent touch control electrode E1.

Through above-mentioned manufacture method, touch-control module 100 can be realized.In substrate 110, form insulation block I, touch control electrode E1 can be made to electrically isolate from touch control electrode E2 and electrode channel C.Consequently, it is possible to can avoid patterning touch control electrode E1, E2 through etching mode, and avoid the optical index causing touch-control module 100 uneven, and affect the optical homogeneity of touch-control module 100 outward appearance.

In other words, by the conductive materials of aforementioned dispersing conductive material layer 120 with the method forming insulation block I in substrate 110, can make the most do not have gap or the most overlapping between touch control electrode E1, E2, auxiliary conductor X with insulation block I orthographic projection on the upper surface SF1 of substrate 110.That is, touch control electrode E1, E2, auxiliary conductor X can form a complete plane with insulation block I orthographic projection on the upper surface SF1 of substrate 110.Consequently, it is possible to can avoid because refractive index is uneven, and affect the optical homogeneity of touch-control module 100 outward appearance.

In the present embodiment, substrate 110, insulation block I, touch control electrode E1, E2, electrode channel C, shade MSK1, MSK2, bridge formation BG, the details of auxiliary conductor X substantially can refer to previous embodiment with corresponding relation therebetween, therefore be not repeated herein.

3rd embodiment

Hereinafter will transmit through the 3rd embodiment, it is provided that the manufacture method of another kind of touch-control module 100.This manufacture method is roughly the same with the manufacture method in first embodiment, is only that the formation order of electrically conducting transparent part CD and shade MSK1, MSK2 in place of difference.Therefore in the following description, the part of repetition will not repeat.

The schematic diagram of the manufacture method of a kind of touch-control module 100 that Figure 10 A, Figure 11 A, Figure 12 A, Figure 13 A, Figure 14 A respectively illustrate according to this utility model one embodiment.The touch-control module 100 that Figure 10 B, Figure 11 B, Figure 12 B, Figure 13 B, Figure 14 B are respectively in Figure 10 A, Figure 11 A, Figure 12 A, Figure 13 A, Figure 14 A is along the profile depicted in line segment A-a direction.

Referring specifically to Figure 10 A and Figure 10 B, in a first step, it is provided that conductive material layer 120 is on the upper surface SF1 of substrate 110.Then, in a second step, it is provided that on multiple electrically conducting transparent part CD conductive material layers 120.

In the present embodiment, substrate 110, conductive material layer 120 can refer to aforementioned paragraphs with the details of electrically conducting transparent part CD, therefore be not repeated herein.

Then, referring specifically to Figure 11 A and Figure 11 B, in a third step, it is provided that multiple first shade MSK1 and the second shade MSK2 are on conductive material layer 120.

In the present embodiment, there is contact hole T in shade MSK1, MSK2, to expose electrically conducting transparent part CD.

In the present embodiment, the details of shade MSK1, MSK2 can refer to aforementioned paragraphs, therefore is not repeated herein.

Then, referring specifically to Figure 12 A and Figure 12 B, in one the 4th step, it is provided that a plurality of plain conductor MT is on conductive material layer 120 and the first shade MSK1 and the second shade MSK2.

Now, the Part I P outside conductive material layer 120 includes being exposed to shade MSK1, MSK2, electrically conducting transparent part CD and plain conductor MT；It is positioned at the Part II Q under shade MSK1, MSK2, electrically conducting transparent part CD；And be positioned under plain conductor MT and the Part III R of contacting metal wire MT.

Then, with reference to Figure 13 A and Figure 13 B, in one the 5th step, the Part I P of insulating conductive material layer 120, to form the first touch control electrode E1, the second touch control electrode E2, electrode channel C, auxiliary conductor X and insulation block I.

nullFurthermore，In the 5th step，It is that dispersing conductive material layer 120 is exposed to shade MSK1、MSK2、Electrically conducting transparent part CD、And the conductive materials (such as nano-silver thread) in the Part I P outside plain conductor MT，And make these conductive materials sink further and be dispersed among substrate 110 to form insulation block I，And make the Part II Q being positioned under the first shade MSK1 and electrically conducting transparent part CD and contacting the first shade MSK1 and electrically conducting transparent part CD in conductive material layer 120 form the first touch control electrode E1、Make in conductive material layer 120 under the second shade MSK2 and contact the Part II Q of the second shade MSK2 to form the second touch control electrode E2 and the electrode channel C between the second touch control electrode E2，And make conductive material layer 120 to be positioned under plain conductor MT and the Part III R formation auxiliary conductor X of contacting metal wire MT.

In the present embodiment, the details of the conductive materials being exposed in dispersing conductive material layer 120 in the Part I P outside shade MSK1, MSK2, electrically conducting transparent part CD and plain conductor MT can refer to aforementioned paragraphs, therefore is not repeated herein.

In one embodiment, at least some of system in insulation block I is formed between touch control electrode E1, E2, so that touch control electrode E1, E2 are insulated from each other.In one embodiment, being formed at least partially around touch control electrode E1, E2 in insulation block I.In one embodiment, insulation block I is exposed to the upper surface SF1 of substrate 110.

Then, referring specifically to Figure 14 A and Figure 14 B, in one the 6th step, it is provided that at least one bridge formation BG, wherein bridge formation BG is across electrode channel C setting, to be electrically connected with two the first adjacent touch control electrode E1.In one embodiment, bridge formation BG is through contact hole T two adjacent electrically conducting transparent part CD in electrical contact, to be electrically connected with two the first adjacent touch control electrode E1.

Through above-mentioned manufacture method, touch-control module 100 can be realized.In substrate 110, form insulation block I, touch control electrode E1 can be made to electrically isolate from touch control electrode E2 and electrode channel C.Consequently, it is possible to can avoid patterning touch control electrode E1, E2 through etching mode, and avoid the optical index causing touch-control module 100 uneven, and affect the optical homogeneity of touch-control module 100 outward appearance.

In other words, by the conductive materials of aforementioned dispersing conductive material layer 120 with the method forming insulation block I in substrate 110, can make the most do not have gap or the most overlapping between touch control electrode E1, E2, auxiliary conductor X with insulation block I orthographic projection on the upper surface SF1 of substrate 110.That is, touch control electrode E1, E2, auxiliary conductor X can form a complete plane with insulation block I orthographic projection on the upper surface SF1 of substrate 110.Consequently, it is possible to can avoid because refractive index is uneven, and affect the optical homogeneity of touch-control module 100 outward appearance.

In the present embodiment, substrate 110, insulation block I, touch control electrode E1, E2, electrode channel C, shade MSK1, MSK2, bridge formation BG, the details of auxiliary conductor X substantially can refer to previous embodiment with corresponding relation therebetween, therefore be not repeated herein.

4th embodiment

Hereinafter will transmit through the 4th embodiment, it is provided that the manufacture method of another kind of touch-control module 100.This manufacture method is roughly the same with the manufacture method in the 3rd embodiment, is only that the formation order of plain conductor MT and shade MSK1, MSK2 in place of difference.Therefore in the following description, the part of repetition will not repeat.

The schematic diagram of the manufacture method of a kind of touch-control module 100 that Figure 15 A, Figure 16 A, Figure 17 A, Figure 18 A, Figure 19 A respectively illustrate according to this utility model one embodiment.The touch-control module 100 that Figure 15 B, Figure 16 B, Figure 17 B, Figure 18 B, Figure 19 B are respectively in Figure 15 A, Figure 16 A, Figure 17 A, Figure 18 A, Figure 19 A is along the profile depicted in line segment A-a direction.

Referring specifically to Figure 15 A and Figure 15 B, in a first step, it is provided that conductive material layer 120 is on the upper surface SF1 of substrate 110.Then, in a second step, it is provided that multiple electrically conducting transparent part CD are on conductive material layer 120.

In the present embodiment, substrate 110, conductive material layer 120 can refer to aforementioned paragraphs with the details of electrically conducting transparent part CD, therefore be not repeated herein.

Then, referring specifically to Figure 16 A and Figure 16 B, in a third step, it is provided that a plurality of plain conductor MT is on conductive material layer 120.

Then, referring specifically to Figure 17 A and Figure 17 B, in one the 4th step, it is provided that multiple first shade MSK1 and the second shade MSK2 are on conductive material layer 120 with plain conductor MT.

In one embodiment, the first shade MSK1 exists multiple contact hole T, these contact holes T and expose electrically conducting transparent part CD.

In the present embodiment, the details of shade MSK1, MSK2 can refer to aforementioned paragraphs, therefore is not repeated herein.

Now, the Part I P outside conductive material layer 120 includes being exposed to shade MSK1, MSK2, electrically conducting transparent part CD and plain conductor MT；It is positioned at the Part II Q under shade MSK1, MSK2, electrically conducting transparent part CD；And be positioned under plain conductor MT and the Part III R of contacting metal wire MT.

Then, with reference to Figure 18 A and Figure 18 B, in one the 5th step, the Part I P of insulating conductive material layer 120, to form the first touch control electrode E1, the second touch control electrode E2, electrode channel C, auxiliary conductor X and insulation block I.

nullFurthermore，In the 5th step，It is that dispersing conductive material layer 120 is exposed to shade MSK1、MSK2、Electrically conducting transparent part CD、And the conductive materials (such as nano-silver thread) in the Part I P outside plain conductor MT，And make these conductive materials sink further and be dispersed among substrate 110 to form insulation block I，And make the Part II Q being positioned under the first shade MSK1 and electrically conducting transparent part CD and contacting the first shade MSK1 and electrically conducting transparent part CD in conductive material layer 120 form the first touch control electrode E1、Make in conductive material layer 120 under the second shade MSK2 and contact the Part II Q of the second shade MSK2 to form the second touch control electrode E2 and the electrode channel C between the second touch control electrode E2，And make conductive material layer 120 to be positioned under plain conductor MT and the Part III R formation auxiliary conductor X of contacting metal wire MT.

In the present embodiment, the details of the conductive materials being exposed in dispersing conductive material layer 120 in the Part I P outside shade MSK1, MSK2, electrically conducting transparent part CD and plain conductor MT can refer to aforementioned paragraphs, therefore is not repeated herein.

In one embodiment, being formed at least partially between touch control electrode E1, E2, so that touch control electrode E1, E2 are insulated from each other in insulation block I.In one embodiment, being formed at least partially around touch control electrode E1, E2 in insulation block I.In one embodiment, insulation block I is exposed to the upper surface SF1 of substrate 110.

Then, referring specifically to Figure 15 A and Figure 15 B, in one the 6th step, it is provided that at least one bridge formation BG, wherein bridge formation BG is across electrode channel C setting, to be electrically connected with two the first adjacent touch control electrode E1.In one embodiment, bridge formation BG is through contact hole T two adjacent electrically conducting transparent part CD in electrical contact, to be electrically connected with two the first adjacent touch control electrode E1.

Through above-mentioned manufacture method, touch-control module 100 can be realized.In substrate 110, form insulation block I, touch control electrode E1 can be made to electrically isolate from touch control electrode E2 and electrode channel C.Consequently, it is possible to can avoid patterning touch control electrode E1, E2 through etching mode, and avoid the optical index causing touch-control module 100 uneven, and affect the optical homogeneity of touch-control module 100 outward appearance.

In other words, by the conductive materials of aforementioned dispersing conductive material layer 120 with the method forming insulation block I in substrate 110, can make the most do not have gap or the most overlapping between touch control electrode E1, E2, auxiliary conductor X with insulation block I orthographic projection on the upper surface SF1 of substrate 110.That is, touch control electrode E1, E2, auxiliary conductor X can form a complete plane with insulation block I orthographic projection on the upper surface SF1 of substrate 110.Consequently, it is possible to can avoid because refractive index is uneven, and affect the optical homogeneity of touch-control module 100 outward appearance.

In the present embodiment, substrate 110, insulation block I, touch control electrode E1, E2, electrode channel C, shade MSK1, MSK2, bridge formation BG, the details of auxiliary conductor X substantially can refer to previous embodiment with corresponding relation therebetween, therefore be not repeated herein.

5th embodiment

Hereinafter will transmit through the 5th embodiment, it is provided that the manufacture method of another kind of touch-control module 100.This manufacture method is roughly the same with the manufacture method in the second embodiment, is only that the formation order of plain conductor MT and shade MSK1, MSK2 in place of difference.Therefore in the following description, the part of repetition will not repeat.

The schematic diagram of the manufacture method of a kind of touch-control module 100 that Figure 20 A, Figure 21 A, Figure 22 A, Figure 23 A respectively illustrate according to this utility model one embodiment.The touch-control module 100 that Figure 20 B, Figure 21 B, Figure 22 B, Figure 23 B are respectively in Figure 20 A, Figure 21 A, Figure 22 A, Figure 23 A is along the profile depicted in line segment A-a direction.

Referring specifically to Figure 20 A and Figure 20 B, in a first step, it is provided that conductive material layer 120 is on the upper surface SF1 of substrate 110.Then, in a second step, it is provided that a plurality of plain conductor MT and multiple metallic conduction part MD are on conductive material layer 120.

In one embodiment, it is provided that the step of metallic conduction part MD and plain conductor MT can be integrated into single processing procedure.In different embodiments, metallic conduction part MD and plain conductor MT is to provide in different processing procedures.

In the present embodiment, substrate 110, conductive material layer 120, metallic conduction part MD can refer to aforementioned paragraphs with the details of plain conductor MT, therefore are not repeated herein.

Then, referring specifically to Figure 21 A and Figure 21 B, in a third step, it is provided that multiple first shade MSK1 and the second shade MSK2 are on conductive material layer 120 with metallic conduction part MD.

In one embodiment, the first shade MSK1 exists multiple contact hole T, these contact holes T and expose metallic conduction part MD.

In the present embodiment, the details of shade MSK1, MSK2 can refer to aforementioned paragraphs, therefore is not repeated herein.

Now, the Part I P outside conductive material layer 120 includes being exposed to shade MSK1, MSK2, metallic conduction part MD and plain conductor MT；It is positioned at the Part II Q under shade MSK1, MSK2, metallic conduction part MD；And be positioned under plain conductor MT and the Part III R of contacting metal wire MT.

Then, referring specifically to Figure 22 A and Figure 22 B, in one the 4th step, the Part I P of insulating conductive material layer 120, to form the first touch control electrode E1, the second touch control electrode E2, electrode channel C, auxiliary conductor X and insulation block I.

nullFurthermore，In the 4th step，It is that dispersing conductive material layer 120 is exposed to shade MSK1、MSK2、Metallic conduction part MD、And the conductive materials (such as nano-silver thread) in the Part I P outside plain conductor MT，And make these conductive materials sink further and be dispersed among substrate 110 to form insulation block I，And make the Part II Q being positioned under the first shade MSK1 and metallic conduction part MD and contacting the first shade MSK1 and metallic conduction part MD in conductive material layer 120 form the first touch control electrode E1、Make in conductive material layer 120 under the second shade MSK2 and contact the Part II Q of the second shade MSK2 to form the second touch control electrode E2 and the electrode channel C between the second touch control electrode E2，And make conductive material layer 120 to be positioned under plain conductor MT and the Part III R formation auxiliary conductor X of contacting metal wire MT.

In the present embodiment, the details of the conductive materials being exposed in dispersing conductive material layer 120 in the Part I P outside shade MSK1, MSK2, metallic conduction part MD and plain conductor MT can refer to aforementioned paragraphs, therefore is not repeated herein.

In one embodiment, being formed at least partially between touch control electrode E1, E2, so that touch control electrode E1, E2 are insulated from each other in insulation block I.In one embodiment, being formed at least partially around touch control electrode E1, E2 in insulation block I.In one embodiment, insulation block I is exposed to the upper surface SF1 of substrate 110.

Then, referring specifically to Figure 23 A and Figure 23 B, in one the 5th step, it is provided that at least one bridge formation BG, wherein bridge formation BG is across electrode channel C setting, to be electrically connected with two the first adjacent touch control electrode E1.In one embodiment, bridge formation BG is through contact hole T two adjacent metallic conduction part MD in electrical contact, to be electrically connected with two the first adjacent touch control electrode E1.

Through above-mentioned manufacture method, touch-control module 100 can be realized.In substrate 110, form insulation block I, touch control electrode E1 can be made to electrically isolate from touch control electrode E2 and electrode channel C.Consequently, it is possible to can avoid patterning touch control electrode E1, E2 through etching mode, and avoid the optical index causing touch-control module 100 uneven, and affect the optical homogeneity of touch-control module 100 outward appearance.

In other words, by the conductive materials of aforementioned dispersing conductive material layer 120 with the method forming insulation block I in substrate 110, can make the most do not have gap or the most overlapping between touch control electrode E1, E2, auxiliary conductor X with insulation block I orthographic projection on the upper surface SF1 of substrate 110.That is, touch control electrode E1, E2, auxiliary conductor X can form a complete plane with insulation block I orthographic projection on the upper surface SF1 of substrate 110.Consequently, it is possible to can avoid because refractive index is uneven, and affect the optical homogeneity of touch-control module 100 outward appearance.

In the present embodiment, substrate 110, insulation block I, touch control electrode E1, E2, electrode channel C, shade MSK1, MSK2, bridge formation BG, the details of auxiliary conductor X substantially can refer to previous embodiment with corresponding relation therebetween, therefore be not repeated herein.

Sixth embodiment

Hereinafter will transmit through sixth embodiment, it is provided that the manufacture method of another kind of touch-control module 100.This manufacture method is roughly the same with the manufacture method in the 4th embodiment, is only that sixth embodiment increases transparent conductors TR in place of difference.Therefore in the following description, the part of repetition will not repeat.

The schematic diagram of the manufacture method of a kind of touch-control module 100 that Figure 24 A, Figure 25 A, Figure 26 A, Figure 27 A, Figure 28 A respectively illustrate according to this utility model one embodiment.The touch-control module 100 that Figure 24 B, Figure 25 B, Figure 26 B, Figure 27 B, Figure 28 B are respectively in Figure 24 A, Figure 25 A, Figure 26 A, Figure 27 A, Figure 28 A is along the profile depicted in line segment A-a direction.

Referring specifically to Figure 24 A and Figure 24 B, in a first step, it is provided that conductive material layer 120 is on the upper surface SF1 of substrate 110.Then, in a second step, it is provided that multiple electrically conducting transparent part CD and a plurality of transparent conductors TR is on conductive material layer 120.

In one embodiment, it is provided that the step of electrically conducting transparent part CD and transparent conductors TR can be integrated into single processing procedure.In different embodiments, electrically conducting transparent part CD and transparent conductors TR is to provide in different processing procedures.

In the present embodiment, substrate 110, conductive material layer 120 can refer to aforementioned paragraphs with the details of electrically conducting transparent part CD, therefore be not repeated herein.

In one embodiment, transparent conductors TR can realize with the transparent conductive material being same as electrically conducting transparent part CD.In different embodiments, transparent conductors TR can realize with the transparent conductive material being different from electrically conducting transparent part CD.

Then, referring specifically to Figure 25 A and Figure 25 B, in a third step, it is provided that a plurality of plain conductor MT is on transparent conductors TR.

Then, referring specifically to Figure 26 A and Figure 26 B, in one the 4th step, it is provided that multiple first shade MSK1 and the second shade MSK2 are on conductive material layer 120 with plain conductor MT.

In the present embodiment, the details of shade MSK1, MSK2 can refer to aforementioned paragraphs, therefore is not repeated herein.

Now, the Part I P outside conductive material layer 120 includes being exposed to shade MSK1, MSK2, electrically conducting transparent part CD, transparent conductors TR and plain conductor MT；It is positioned at the Part II Q under shade MSK1, MSK2, electrically conducting transparent part CD；And it is positioned under transparent conductors TR and contacts the Part III R of transparent conductors TR.

Then, with reference to Figure 27 A and Figure 27 B, in one the 5th step, the Part I P of insulating conductive material layer 120, to form the first touch control electrode E1, the second touch control electrode E2, electrode channel C, auxiliary conductor X and insulation block I.

nullFurthermore，In the 5th step，It is that dispersing conductive material layer 120 is exposed to shade MSK1、MSK2、Electrically conducting transparent part CD、Transparent conductors TR、And the conductive materials (such as nano-silver thread) in the Part I P outside plain conductor MT，And make these conductive materials sink further and be dispersed among substrate 110 to form insulation block I，And make the Part II Q being positioned under the first shade MSK1 and electrically conducting transparent part CD and contacting the first shade MSK1 and electrically conducting transparent part CD in conductive material layer 120 form the first touch control electrode E1、Make in conductive material layer 120 under the second shade MSK2 and contact the Part II Q of the second shade MSK2 to form the second touch control electrode E2 and the electrode channel C between the second touch control electrode E2，And make the Part III R being positioned under transparent conductors TR and contacting transparent conductors TR in conductive material layer 120 form auxiliary conductor X.

In the present embodiment, the details of the conductive materials being exposed in dispersing conductive material layer 120 in the Part I P outside shade MSK1, MSK2, electrically conducting transparent part CD, transparent conductors TR and plain conductor MT can refer to aforementioned paragraphs, therefore is not repeated herein.

In one embodiment, being formed at least partially between touch control electrode E1, E2, so that touch control electrode E1, E2 are insulated from each other in insulation block I.In one embodiment, being formed at least partially around touch control electrode E1, E2 in insulation block I.In one embodiment, insulation block I is exposed to the upper surface SF1 of substrate 110.

Then, referring specifically to Figure 28 A and Figure 28 B, in one the 6th step, it is provided that at least one bridge formation BG, wherein bridge formation BG is across electrode channel C setting, to be electrically connected with two the first adjacent touch control electrode E1.In one embodiment, bridge formation BG is through contact hole T two adjacent electrically conducting transparent part CD in electrical contact, to be electrically connected with two the first adjacent touch control electrode E1.

Through above-mentioned manufacture method, touch-control module 100 can be realized.In substrate 110, form insulation block I, touch control electrode E1 can be made to electrically isolate from touch control electrode E2 and electrode channel C.Consequently, it is possible to can avoid patterning touch control electrode E1, E2 through etching mode, and avoid the optical index causing touch-control module 100 uneven, and affect the optical homogeneity of touch-control module 100 outward appearance.

In other words, by the conductive materials of aforementioned dispersing conductive material layer 120 with the method forming insulation block I in substrate 110, can make the most do not have gap or the most overlapping between touch control electrode E1, E2, auxiliary conductor X with insulation block I orthographic projection on the upper surface SF1 of substrate 110.That is, touch control electrode E1, E2, auxiliary conductor X can form a complete plane with insulation block I orthographic projection on the upper surface SF1 of substrate 110.Consequently, it is possible to can avoid because refractive index is uneven, and affect the optical homogeneity of touch-control module 100 outward appearance.

In the present embodiment, transparent conductors TR is between auxiliary conductor X and plain conductor MT, and is electrically connected with touch control electrode E1, E2, auxiliary conductor X and plain conductor MT.In one embodiment, transparent conductors TR can assist plain conductor MT to transmit touching signals.

In the present embodiment, substrate 110, insulation block I, touch control electrode E1, E2, electrode channel C, shade MSK1, MSK2, bridge formation BG, the details of auxiliary conductor X substantially can refer to previous embodiment with corresponding relation therebetween, therefore be not repeated herein.

7th embodiment

Hereinafter will transmit through the 7th embodiment, it is provided that the manufacture method of another kind of touch-control module 100.This manufacture method is roughly the same with the manufacture method in sixth embodiment, is only that the formation order of plain conductor MT and shade MSK1, MSK2 in place of difference.Therefore, in the following description, the part of repetition will not repeat.

The first step of the present embodiment, second step and the first step of sixth embodiment, second step roughly the same (can refer to Figure 24 A, Figure 24 B), therefore be not repeated herein.

With reference to Figure 29 A and Figure 29 B, in a third step, it is provided that multiple first shade MSK1 and the second shade MSK2 are on conductive material layer 120.

In one embodiment, the first shade MSK1 exists multiple contact hole T, these contact holes T and expose electrically conducting transparent part CD.

In the present embodiment, the details of shade MSK1, MSK2 can refer to aforementioned paragraphs, therefore is not repeated herein.

Then, with reference to Figure 30 A and Figure 30 B, in one the 4th step, it is provided that a plurality of plain conductor MT is on transparent conductors TR and shade MSK1, MSK2.

Now, the Part I P outside conductive material layer 120 includes being exposed to shade MSK1, MSK2, electrically conducting transparent part CD, transparent conductors TR and plain conductor MT；It is positioned at the Part II Q under shade MSK1, MSK2, electrically conducting transparent part CD；And it is positioned under transparent conductors TR and contacts the Part III R of transparent conductors TR.

Then, referring specifically to Figure 31 A and Figure 31 B, in one the 5th step, the Part I P of insulating conductive material layer 120, to form the first touch control electrode E1, the second touch control electrode E2, electrode channel C, auxiliary conductor X and insulation block I.

nullFurthermore，In the 5th step，It is that dispersing conductive material layer 120 is exposed to shade MSK1、MSK2、Electrically conducting transparent part CD、Transparent conductors TR、And the conductive materials (such as nano-silver thread) in the Part I P outside plain conductor MT，And make these conductive materials sink further and be dispersed among substrate 110 to form insulation block I，And make the Part II Q being positioned under the first shade MSK1 and electrically conducting transparent part CD and contacting the first shade MSK1 and electrically conducting transparent part CD in conductive material layer 120 form the first touch control electrode E1、Make in conductive material layer 120 under the second shade MSK2 and contact the Part II Q of the second shade MSK2 to form the second touch control electrode E2 and the electrode channel C between the second touch control electrode E2，And make the Part III R being positioned under transparent conductors TR and contacting transparent conductors TR in conductive material layer 120 form auxiliary conductor X.

In the present embodiment, the details of the conductive materials being exposed in dispersing conductive material layer 120 in the Part I P outside shade MSK1, MSK2, electrically conducting transparent part CD, transparent conductors TR and plain conductor MT can refer to aforementioned paragraphs, therefore is not repeated herein.

In one embodiment, being formed at least partially between touch control electrode E1, E2, so that touch control electrode E1, E2 are insulated from each other in insulation block I.In one embodiment, being formed at least partially around touch control electrode E1, E2 in insulation block I.In one embodiment, insulation block I is exposed to the upper surface SF1 of substrate 110.

Then, referring specifically to Figure 32 A and Figure 32 B, in one the 6th step, it is provided that at least one bridge formation BG, wherein bridge formation BG is across electrode channel C setting, to be electrically connected with two the first adjacent touch control electrode E1.In one embodiment, bridge formation BG is through contact hole T two adjacent electrically conducting transparent part CD in electrical contact, to be electrically connected with two the first adjacent touch control electrode E1.

Through above-mentioned manufacture method, touch-control module 100 can be realized.In substrate 110, form insulation block I, touch control electrode E1 can be made to electrically isolate from touch control electrode E2 and electrode channel C.Consequently, it is possible to can avoid patterning touch control electrode E1, E2 through etching mode, and avoid the optical index causing touch-control module 100 uneven, and affect the optical homogeneity of touch-control module 100 outward appearance.

In other words, by the conductive materials of aforementioned dispersing conductive material layer 120 with the method forming insulation block I in substrate 110, can make the most do not have gap or the most overlapping between touch control electrode E1, E2, auxiliary conductor X with insulation block I orthographic projection on the upper surface SF1 of substrate 110.That is, touch control electrode E1, E2, auxiliary conductor X can form a complete plane with insulation block I orthographic projection on the upper surface SF1 of substrate 110.Consequently, it is possible to can avoid because refractive index is uneven, and affect the optical homogeneity of touch-control module 100 outward appearance.

In the present embodiment, the details of substrate 110, insulation block I, touch control electrode E1, E2, electrode channel C, shade MSK1, MSK2, bridge formation BG, auxiliary conductor X, plain conductor MT and transparent conductors TR substantially can refer to previous embodiment with corresponding relation therebetween, therefore is not repeated herein.

8th embodiment

Hereinafter will transmit through the 8th embodiment, it is provided that the manufacture method of another kind of touch-control module 100.This manufacture method is roughly the same with the manufacture method in the 7th embodiment, is only that the process sequence of plain conductor MT and insulating conductive material layer 120, therefore in the following description, the part of repetition will not repeat in place of difference.

The first step of the present embodiment, second step, third step and the first step of sixth embodiment, second step, third step roughly the same (can refer to Figure 24 A, Figure 24 B, Figure 29 A, Figure 29 B), therefore be not repeated herein.

With reference to Figure 33 A and Figure 33 B, in one the 4th step, the Part I P of insulating conductive material layer 120, to form the first touch control electrode E1, the second touch control electrode E2, electrode channel C, auxiliary conductor X and insulation block I.

nullFurthermore，In the 4th step，It is that dispersing conductive material layer 120 is exposed to shade MSK1、MSK2、Electrically conducting transparent part CD、Transparent conductors TR、And the conductive materials (such as nano-silver thread) in the Part I P outside plain conductor MT，And make these conductive materials sink further and be dispersed among substrate 110 to form insulation block I，And make the Part II Q being positioned under the first shade MSK1 and electrically conducting transparent part CD and contacting the first shade MSK1 and electrically conducting transparent part CD in conductive material layer 120 form the first touch control electrode E1、Make in conductive material layer 120 under the second shade MSK2 and contact the Part II Q of the second shade MSK2 to form the second touch control electrode E2 and the electrode channel C between the second touch control electrode E2，And make the Part III R being positioned under transparent conductors TR and contacting transparent conductors TR in conductive material layer 120 form auxiliary conductor X.

In the present embodiment, the details of the conductive materials being exposed in dispersing conductive material layer 120 in the Part I P outside shade MSK1, MSK2, electrically conducting transparent part CD and transparent conductors TR can refer to aforementioned paragraphs, therefore is not repeated herein.

In one embodiment, being formed at least partially between touch control electrode E1, E2, so that touch control electrode E1, E2 are insulated from each other in insulation block I.In one embodiment, being formed at least partially around touch control electrode E1, E2 in insulation block I.In one embodiment, insulation block I is exposed to the upper surface SF1 of substrate 110.

Then, referring specifically to Figure 34 A and Figure 34 B, in one the 6th step, it is provided that at least one bridge formation BG, wherein bridge formation BG is across electrode channel C setting, to be electrically connected with two the first adjacent touch control electrode E1.In one embodiment, bridge formation BG is through contact hole T two adjacent electrically conducting transparent part CD in electrical contact, to be electrically connected with two the first adjacent touch control electrode E1.

Additionally, in the 6th step, also provide a plurality of plain conductor MT on transparent conductors TR.

In one embodiment, it is provided that the step of bridge formation BG and plain conductor MT can be integrated into single processing procedure.In different embodiments, bridge formation BG and plain conductor MT is to provide in different processing procedures.

In one embodiment, bridge formation BG can realize with same metal material with plain conductor MT.In different embodiments, bridge formation BG can realize with different metal material with plain conductor MT.

Through above-mentioned manufacture method, touch-control module 100 can be realized.In substrate 110, form insulation block I, touch control electrode E1 can be made to electrically isolate from touch control electrode E2 and electrode channel C.Consequently, it is possible to can avoid patterning touch control electrode E1, E2 through etching mode, and avoid the optical index causing touch-control module 100 uneven, and affect the optical homogeneity of touch-control module 100 outward appearance.

In other words, by the conductive materials of aforementioned dispersing conductive material layer 120 with the method forming insulation block I in substrate 110, can make the most do not have gap or the most overlapping between touch control electrode E1, E2, auxiliary conductor X with insulation block I orthographic projection on the upper surface SF1 of substrate 110.That is, touch control electrode E1, E2, auxiliary conductor X can form a complete plane with insulation block I orthographic projection on the upper surface SF1 of substrate 110.Consequently, it is possible to can avoid because refractive index is uneven, and affect the optical homogeneity of touch-control module 100 outward appearance.

In the present embodiment, the details of substrate 110, insulation block I, touch control electrode E1, E2, electrode channel C, shade MSK1, MSK2, bridge formation BG, auxiliary conductor X, plain conductor MT and transparent conductors TR substantially can refer to previous embodiment with corresponding relation therebetween, therefore is not repeated herein.

9th embodiment

Hereinafter will transmit through the 9th embodiment, it is provided that the manufacture method of another kind of touch-control module 100.This manufacture method is roughly the same with the manufacture method in previous embodiment, therefore in the following description, the part of repetition will not repeat.

The schematic diagram of the manufacture method of a kind of touch-control module 100 that Figure 35 A, Figure 36 A, Figure 37 A, Figure 38 A respectively illustrate according to this utility model one embodiment.The touch-control module 100 that Figure 35 B, Figure 36 B, Figure 37 B, Figure 38 B are respectively in Figure 35 A, Figure 36 A, Figure 37 A, Figure 38 A is along the profile depicted in line segment A-a direction.

Referring specifically to Figure 35 A and Figure 35 B, in a first step, it is provided that conductive material layer 120 is on the upper surface SF1 of substrate 110.Then, in a second step, it is provided that a plurality of transparent conductors TR is on conductive material layer 120.

In the present embodiment, substrate 110, conductive material layer 120 can refer to aforementioned paragraphs with the details of transparent conductors TR, therefore be not repeated herein.

Then, referring specifically to Figure 36 A and Figure 36 B, in a third step, it is provided that multiple first shade MSK1 and the second shade MSK2 are on conductive material layer 120 with transparent conductors TR.

In one embodiment, the first shade MSK1 exists multiple contact hole T, these contact holes T and expose partially electronically conductive material layer 120.

In the present embodiment, the details of shade MSK1, MSK2 can refer to aforementioned paragraphs, therefore is not repeated herein.

Then, referring specifically to Figure 37 A and Figure 37 B, in one the 4th step, it is provided that multiple metallic conduction part MD are in the contact hole T of shade MSK1 and on conductive material layer 120.

Additionally, in the 4th step, also provide a plurality of plain conductor MT on transparent conductors TR and shade MSK1, MSK2.

In one embodiment, it is provided that the step of metallic conduction part MD and plain conductor MT can be integrated into single processing procedure.In different embodiments, metallic conduction part MD and plain conductor MT is to provide in different processing procedures.

In the present embodiment, the details of metallic conduction part MD and plain conductor MT can refer to aforementioned paragraphs, therefore is not repeated herein.

Now, the Part I P outside conductive material layer 120 includes being exposed to shade MSK1, MSK2, metallic conduction part MD, transparent conductors TR and plain conductor MT；It is positioned at the Part II Q under the electrically conducting transparent part CD of shade MSK1, MSK2 and correspondence thereof；And it is positioned under transparent conductors TR and contacts the Part III R of transparent conductors TR.

Then, with reference to Figure 38 A and Figure 38 B, in one the 5th step, the Part I P of insulating conductive material layer 120, to form the first touch control electrode E1, the second touch control electrode E2, electrode channel C, auxiliary conductor X and insulation block I.

nullFurthermore，In the 5th step，It is that dispersing conductive material layer 120 is exposed to shade MSK1、MSK2、Metallic conduction part MD、Transparent conductors TR、And the conductive materials (such as nano-silver thread) in the Part I P outside plain conductor MT，And make these conductive materials sink further and be dispersed among substrate 110 to form insulation block I，And make the Part II Q being positioned under the first shade MSK1 and metallic conduction part MD and contacting the first shade MSK1 and metallic conduction part MD in conductive material layer 120 form the first touch control electrode E1、Make in conductive material layer 120 under the second shade MSK2 and contact the Part II Q of the second shade MSK2 to form the second touch control electrode E2 and the electrode channel C between the second touch control electrode E2，And make the Part III R being positioned under transparent conductors TR and contacting transparent conductors TR in conductive material layer 120 form auxiliary conductor X.

In the present embodiment, the details of the conductive materials being exposed in dispersing conductive material layer 120 in the Part I P outside shade MSK1, MSK2, metallic conduction part MD, transparent conductors TR and plain conductor MT can refer to aforementioned paragraphs, therefore is not repeated herein.

In one embodiment, being formed at least partially between touch control electrode E1, E2, so that touch control electrode E1, E2 are insulated from each other in insulation block I.In one embodiment, being formed at least partially around touch control electrode E1, E2 in insulation block I.In one embodiment, insulation block I is exposed to the upper surface SF1 of substrate 110.

Then, referring specifically to Figure 39 A and Figure 39 B, in one the 6th step, it is provided that at least one bridge formation BG, wherein bridge formation BG is across electrode channel C setting, to be electrically connected with two the first adjacent touch control electrode E1.In one embodiment, bridge formation BG is through contact hole T two adjacent metallic conduction part MD in electrical contact, to be electrically connected with two the first adjacent touch control electrode E1.

Through above-mentioned manufacture method, touch-control module 100 can be realized.In substrate 110, form insulation block I, touch control electrode E1 can be made to electrically isolate from touch control electrode E2 and electrode channel C.Consequently, it is possible to can avoid patterning touch control electrode E1, E2 through etching mode, and avoid the optical index causing touch-control module 100 uneven, and affect the optical homogeneity of touch-control module 100 outward appearance.

In other words, by the conductive materials of aforementioned dispersing conductive material layer 120 with the method forming insulation block I in substrate 110, can make the most do not have gap or the most overlapping between touch control electrode E1, E2, auxiliary conductor X with insulation block I orthographic projection on the upper surface SF1 of substrate 110.That is, touch control electrode E1, E2, auxiliary conductor X can form a complete plane with insulation block I orthographic projection on the upper surface SF1 of substrate 110.Consequently, it is possible to can avoid because refractive index is uneven, and affect the optical homogeneity of touch-control module 100 outward appearance.

In the present embodiment, substrate 110, insulation block I, touch control electrode E1, E2, electrode channel C, shade MSK1, MSK2, bridge formation BG, auxiliary conductor X, plain conductor MT substantially can refer to previous embodiment with the details of transparent conductors TR with corresponding relation therebetween, therefore be not repeated herein.

Tenth embodiment

Hereinafter will transmit through the tenth embodiment, it is provided that the manufacture method of another kind of touch-control module 100.This manufacture method is roughly the same with the manufacture method in the 9th embodiment, is only that the formation order of shade MSK1, MSK2 and metallic conduction part MD and plain conductor MT, therefore in the following description, the part of repetition will not repeat in place of difference.

The first step of the present embodiment, second step and the first step of the 9th embodiment, second step roughly the same (can refer to Figure 35 A, Figure 35 B), therefore be not repeated herein.

With reference to Figure 40 A and Figure 40 B, in a third step, it is possible to provide multiple metallic conduction part MD are on conductive material layer 120.

Additionally, in third step, also can provide a plurality of plain conductor MT on transparent conductors TR.

In one embodiment, it is provided that the step of metallic conduction part MD and plain conductor MT can be integrated into single processing procedure.In different embodiments, metallic conduction part MD and plain conductor MT is to provide in different processing procedures.

In the present embodiment, the details of metallic conduction part MD and plain conductor MT can refer to aforementioned paragraphs, therefore is not repeated herein.

Then, with reference to Figure 41 A and Figure 41 B, in one the 4th step, it is provided that multiple first shade MSK1 and the second shade MSK2 are on conductive material layer 120 with plain conductor MT.

In one embodiment, the first shade MSK1 exists multiple contact hole T, these contact holes T and expose metallic conduction part MD.

In the present embodiment, the details of shade MSK1, MSK2 can refer to aforementioned paragraphs, therefore is not repeated herein.

Now, the Part I P outside conductive material layer 120 includes being exposed to shade MSK1, MSK2, metallic conduction part MD, transparent conductors TR and plain conductor MT；It is positioned at the Part II Q under shade MSK1, MSK2 and metallic conduction part MD；And it is positioned under transparent conductors TR and contacts the Part III R of transparent conductors TR.

Then, with reference to Figure 42 A and Figure 42 B, in one the 5th step, the Part I P of insulating conductive material layer 120, to form the first touch control electrode E1, the second touch control electrode E2, electrode channel C, auxiliary conductor X and insulation block I.

nullFurthermore，In the 5th step，It is that dispersing conductive material layer 120 is exposed to shade MSK1、MSK2、Metallic conduction part MD、Transparent conductors TR、And the conductive materials (such as nano-silver thread) in the Part I P outside plain conductor MT，And make these conductive materials sink further and be dispersed among substrate 110 to form insulation block I，And make the Part II Q being positioned under the first shade MSK1 and metallic conduction part MD and contacting the first shade MSK1 and metallic conduction part MD in conductive material layer 120 form the first touch control electrode E1、Make in conductive material layer 120 under the second shade MSK2 and contact the Part II Q of the second shade MSK2 to form the second touch control electrode E2 and the electrode channel C between the second touch control electrode E2，And make the Part III R being positioned under transparent conductors TR and contacting transparent conductors TR in conductive material layer 120 form auxiliary conductor X.

In the present embodiment, the details of the conductive materials being exposed in dispersing conductive material layer 120 in the Part I P outside shade MSK1, MSK2, metallic conduction part MD, transparent conductors TR and plain conductor MT can refer to aforementioned paragraphs, therefore is not repeated herein.

In one embodiment, being formed at least partially between touch control electrode E1, E2, so that touch control electrode E1, E2 are insulated from each other in insulation block I.In one embodiment, being formed at least partially around touch control electrode E1, E2 in insulation block I.In one embodiment, insulation block I is exposed to the upper surface SF1 of substrate 110.

Then, referring specifically to Figure 43 A and Figure 43 B, in one the 6th step, it is provided that at least one bridge formation BG, wherein bridge formation BG is across electrode channel C setting, to be electrically connected with two the first adjacent touch control electrode E1.In one embodiment, bridge formation BG is through contact hole T two adjacent metallic conduction part MD in electrical contact, to be electrically connected with two the first adjacent touch control electrode E1.

Through above-mentioned manufacture method, touch-control module 100 can be realized.In substrate 110, form insulation block I, touch control electrode E1 can be made to electrically isolate from touch control electrode E2 and electrode channel C.Consequently, it is possible to can avoid patterning touch control electrode E1, E2 through etching mode, and avoid the optical index causing touch-control module 100 uneven, and affect the optical homogeneity of touch-control module 100 outward appearance.

In other words, by the conductive materials of aforementioned dispersing conductive material layer 120 with the method forming insulation block I in substrate 110, can make the most do not have gap or the most overlapping between touch control electrode E1, E2, auxiliary conductor X with insulation block I orthographic projection on the upper surface SF1 of substrate 110.That is, touch control electrode E1, E2, auxiliary conductor X can form a complete plane with insulation block I orthographic projection on the upper surface SF1 of substrate 110.Consequently, it is possible to can avoid because refractive index is uneven, and affect the optical homogeneity of touch-control module 100 outward appearance.

In the present embodiment, the details of substrate 110, insulation block I, touch control electrode E1, E2, electrode channel C, shade MSK1, MSK2, bridge formation BG, auxiliary conductor X, plain conductor MT and transparent conductors TR substantially can refer to previous embodiment with corresponding relation therebetween, therefore is not repeated herein.

11st embodiment

Hereinafter will transmit through the 11st embodiment, it is provided that the manufacture method of another kind of touch-control module 100.This manufacture method is roughly the same with the manufacture method in previous embodiment, therefore in the following description, the part of repetition will not repeat.

The schematic diagram of the manufacture method of a kind of touch-control module 100 that Figure 44 A, Figure 45 A, Figure 46 A, Figure 47 A respectively illustrate according to this utility model one embodiment.The touch-control module 100 that Figure 44 B, Figure 45 B, Figure 46 B, Figure 47 B are respectively in Figure 44 A, Figure 45 A, Figure 46 A, Figure 47 A is along the profile depicted in line segment A-a direction.

Referring specifically to Figure 44 A and Figure 44 B, in a first step, it is provided that conductive material layer 120 is on the upper surface SF1 of substrate 110.Then, in a second step, it is provided that multiple electrically conducting transparent part CD are on conductive material layer 120.

Additionally, in the second step, also can provide multiple transparent touch pad PD on conductive material layer 120.

In one embodiment, it is provided that electrically conducting transparent part CD can be integrated into single processing procedure with the step of transparent touch pad PD.In different embodiments, electrically conducting transparent part CD is to provide in different processing procedures from transparent touch pad PD.

In the present embodiment, conductive material layer 120 can refer to aforementioned paragraphs with the details of electrically conducting transparent part CD, therefore is not repeated herein.

In one embodiment, transparent touch pad PD can realize with the transparent conductive material being same as electrically conducting transparent part CD.In different embodiments, transparent touch pad PD also can realize with the transparent conductive material being different from electrically conducting transparent part CD.

Then, referring specifically to Figure 45 A and Figure 45 B, in a third step, it is provided that multiple first shade MSK1 and the second shade MSK2 are on conductive material layer 120.

In one embodiment, the first shade MSK1 exists multiple contact hole T, these contact holes T and expose electrically conducting transparent part CD.

In the present embodiment, the details of shade MSK1, MSK2 can refer to aforementioned paragraphs, therefore is not repeated herein.

Now, the Part I P outside conductive material layer 120 includes being exposed to shade MSK1, MSK2, electrically conducting transparent part CD and transparent touch pad PD；And it is positioned at the electrically conducting transparent part CD and the Part II Q under transparent touch pad PD of shade MSK1, MSK2 and correspondence thereof.

Then, referring specifically to Figure 46 A and Figure 46 B, in one the 4th step, the Part I P of insulating conductive material layer 120, to form the first touch control electrode E1, the second touch control electrode E2, electrode channel C and insulation block I.

nullFurthermore，In the 4th step，It is that dispersing conductive material layer 120 is exposed to shade MSK1、MSK2、Electrically conducting transparent part CD、And the conductive materials (such as nano-silver thread) in the Part I P outside transparent touch pad PD，And make these conductive materials sink further and be dispersed among substrate 110 to form insulation block I，And make conductive material layer 120 is positioned at the first shade MSK1、Electrically conducting transparent part CD、And under transparent touch pad PD and contact the first shade MSK1、Electrically conducting transparent part CD、And the Part II Q of transparent touch pad PD forms the first touch control electrode E1、Make in conductive material layer 120 under the second shade MSK2 and contact the Part II Q of the second shade MSK2 to form the second touch control electrode E2 and the electrode channel C between the second touch control electrode E2.

In the present embodiment, the details of the conductive materials being exposed in dispersing conductive material layer 120 in the Part I P outside shade MSK1, MSK2, electrically conducting transparent part CD and transparent touch pad PD can refer to aforementioned paragraphs, therefore is not repeated herein.

In one embodiment, being formed at least partially between touch control electrode E1, E2, so that touch control electrode E1, E2 are insulated from each other in insulation block I.In one embodiment, being formed at least partially around touch control electrode E1, E2 in insulation block I.In one embodiment, insulation block I is exposed to the upper surface SF1 of substrate 110.

Then, referring specifically to Figure 47 A and Figure 47 B, in one the 5th step, it is provided that at least one bridge formation BG, wherein bridge formation BG is across electrode channel C setting, to be electrically connected with two the first adjacent touch control electrode E1.In one embodiment, bridge formation BG is through contact hole T two adjacent electrically conducting transparent part CD in electrical contact, to be electrically connected with two the first adjacent touch control electrode E1.

Additionally, in the 5th step, also provide a plurality of plain conductor MT in transparent touch pad PD and insulation block I.Consequently, it is possible to plain conductor MT can be avoided to cause short circuit because of the conductive materials in contact substrate 110.

In one embodiment, it is provided that the step of bridge formation BG and plain conductor MT can be integrated into single processing procedure.In different embodiments, bridge formation BG and plain conductor MT is to provide in different processing procedures.

In one embodiment, bridge formation BG can realize with same metal material with plain conductor MT.In different embodiments, bridge formation BG can realize with different metal material with plain conductor MT.

Through above-mentioned manufacture method, touch-control module 100 can be realized.In substrate 110, form insulation block I, touch control electrode E1 can be made to electrically isolate from touch control electrode E2 and electrode channel C.Consequently, it is possible to can avoid patterning touch control electrode E1, E2 through etching mode, and avoid the optical index causing touch-control module 100 uneven, and affect the optical homogeneity of touch-control module 100 outward appearance.

In other words, by the conductive materials of aforementioned dispersing conductive material layer 120 with the method forming insulation block I in substrate 110, can make the most do not have gap or the most overlapping between touch control electrode E1, E2 with insulation block I orthographic projection on the upper surface SF1 of substrate 110.That is, touch control electrode E1, E2 and insulation block I orthographic projection on the upper surface SF1 of substrate 110 can form a complete plane.Consequently, it is possible to can avoid because refractive index is uneven, and affect the optical homogeneity of touch-control module 100 outward appearance.

In the present embodiment, transparent touch pad PD is between plain conductor MT and the first touch control electrode E1, and is for electrically connecting to plain conductor MT and the first touch control electrode E1.

In the present embodiment, the details of substrate 110, insulation block I, touch control electrode E1, E2, electrode channel C, shade MSK1, MSK2, bridge formation BG and plain conductor MT substantially can refer to previous embodiment with corresponding relation therebetween, therefore is not repeated herein.

12nd embodiment

Hereinafter will transmit through the 12nd embodiment, it is provided that the manufacture method of another kind of touch-control module 100.This manufacture method is roughly the same with the manufacture method in the 11st embodiment, is only that the formation order of plain conductor MT, therefore in the following description, the part of repetition will not repeat in place of difference.

The first step of the present embodiment, second step, third step and the first step of the 11st embodiment, second step, third step roughly the same (can refer to Figure 44 A and 45A, Figure 44 B and 45B), therefore be not repeated herein.

With reference to Figure 48 A and Figure 48 B, in one the 4th step, it is possible to provide a plurality of plain conductor MT is in transparent touch pad PD with upper conductive material layer 120.

Now, Part I P outside conductive material layer 120 includes being exposed to shade MSK1, MSK2, electrically conducting transparent part CD, transparent touch pad PD and plain conductor MT, the Part II Q being positioned under the electrically conducting transparent part CD of shade MSK1, MSK2 and correspondence thereof and be positioned under plain conductor MT and the Part III R of contacting metal wire MT.

Then, with reference to Figure 49 A and Figure 49 B, in one the 5th step, the Part I P of insulating conductive material layer 120, to form the first touch control electrode E1, the second touch control electrode E2, electrode channel C, auxiliary conductor X and insulation block I.

nullFurthermore，In the 5th step，It is that dispersing conductive material layer 120 is exposed to shade MSK1、MSK2、Electrically conducting transparent part CD、The conductive materials (such as nano-silver thread) in a Part I P outside transparent touch pad PD and plain conductor MT，And make these conductive materials sink further and be dispersed among substrate 110 to form insulation block I，And make conductive material layer 120 is positioned at the first shade MSK1、Under electrically conducting transparent part CD and transparent touch pad PD and contact the first shade MSK1、The Part II Q of electrically conducting transparent part CD and transparent touch pad PD forms the first touch control electrode E1、Make in conductive material layer 120 under the second shade MSK2 and contact the Part II Q of the second shade MSK2 to form the second touch control electrode E2 and the electrode channel C between the second touch control electrode E2，And make conductive material layer 120 to be positioned under plain conductor MT and the Part III R formation auxiliary conductor X of contacting metal wire MT.

In the present embodiment, the details of the conductive materials being exposed in dispersing conductive material layer 120 in the Part I P outside shade MSK1, MSK2, electrically conducting transparent part CD, transparent touch pad PD and plain conductor MT can refer to aforementioned paragraphs, therefore is not repeated herein.

In one embodiment, being formed at least partially between touch control electrode E1, E2, so that touch control electrode E1, E2 are insulated from each other in insulation block I.In one embodiment, being formed at least partially around touch control electrode E1, E2 in insulation block I.In one embodiment, insulation block I is exposed to the upper surface SF1 of substrate 110.

Then, referring specifically to Figure 50 A and Figure 50 B, in one the 6th step, it is provided that at least one bridge formation BG, wherein bridge formation BG is across electrode channel C setting, to be electrically connected with two the first adjacent touch control electrode E1.In one embodiment, bridge formation BG is through contact hole T two adjacent electrically conducting transparent part CD in electrical contact, to be electrically connected with two the first adjacent touch control electrode E1.

Through above-mentioned manufacture method, touch-control module 100 can be realized.In substrate 110, form insulation block I, touch control electrode E1 can be made to electrically isolate from touch control electrode E2 and electrode channel C.Consequently, it is possible to can avoid patterning touch control electrode E1, E2 through etching mode, and avoid the optical index causing touch-control module 100 uneven, and affect the optical homogeneity of touch-control module 100 outward appearance.

In other words, by the conductive materials of aforementioned dispersing conductive material layer 120 with the method forming insulation block I in substrate 110, can make the most do not have gap or the most overlapping between touch control electrode E1, E2, auxiliary conductor X with insulation block I orthographic projection on the upper surface SF1 of substrate 110.That is, touch control electrode E1, E2, auxiliary conductor X can form a complete plane with insulation block I orthographic projection on the upper surface SF1 of substrate 110.Consequently, it is possible to can avoid because refractive index is uneven, and affect the optical homogeneity of touch-control module 100 outward appearance.

In the present embodiment, the details of substrate 110, insulation block I, touch control electrode E1, E2, electrode channel C, shade MSK1, MSK2, bridge formation BG, auxiliary conductor X, transparent touch pad PD and plain conductor MT substantially can refer to previous embodiment with corresponding relation therebetween, therefore is not repeated herein.

13rd embodiment

Hereinafter will transmit through the 13rd embodiment, it is provided that the manufacture method of another kind of touch-control module 100.This manufacture method is roughly the same with the manufacture method in the 11st embodiment, is only that shade MSK1, MSK2 and electrically conducting transparent part CD, the formation order of transparent touch pad PD, therefore in the following description, the part of repetition will not repeat in place of difference.

The schematic diagram of the manufacture method of a kind of touch-control module 100 that Figure 51 A, Figure 52 A, Figure 53 A, Figure 54 A respectively illustrate according to this utility model one embodiment.The touch-control module 100 that Figure 51 B, Figure 52 B, Figure 53 B, Figure 54 B are respectively in Figure 51 A, Figure 52 A, Figure 53 A, Figure 54 A is along the profile depicted in line segment A-a direction.

Referring specifically to Figure 51 A and Figure 51 B, in a first step, it is provided that conductive material layer 120 is on the upper surface SF1 of substrate 110.Then, in a second step, it is provided that multiple first shade MSK1 and the second shade MSK2 are on conductive material layer 120.

In one embodiment, the first shade MSK1 exists multiple contact hole T, these contact holes T and expose partially electronically conductive material layer 120.

In the present embodiment, substrate 110, conductive material layer 120, the details of shade MSK1, MSK2 can refer to aforementioned paragraphs, therefore be not repeated herein.

Then, referring specifically to Figure 52 A and Figure 52 B, in a third step, it is provided that multiple electrically conducting transparent part CD are in the contact hole T of shade MSK1.

Additionally, in third step, also can provide multiple transparent touch pad PD on conductive material layer 120.

In one embodiment, it is provided that electrically conducting transparent part CD can be integrated into single processing procedure with the step of transparent touch pad PD.In different embodiments, electrically conducting transparent part CD is to provide in different processing procedures from transparent touch pad PD.

In the present embodiment, electrically conducting transparent part CD can refer to aforementioned paragraphs with the details of transparent touch pad PD, therefore is not repeated herein.

Now, the Part I P outside conductive material layer 120 includes being exposed to shade MSK1, MSK2, electrically conducting transparent part CD and transparent touch pad PD；And it is positioned at the electrically conducting transparent part CD and the Part II Q under transparent touch pad PD of shade MSK1, MSK2 and correspondence thereof.

Then, referring specifically to Figure 53 A and Figure 53 B, in one the 4th step, the Part I P of insulating conductive material layer 120, to form the first touch control electrode E1, the second touch control electrode E2, electrode channel C and insulation block I.

nullFurthermore，In the 4th step，It is that dispersing conductive material layer 120 is exposed to shade MSK1、MSK2、Electrically conducting transparent part CD、And the conductive materials (such as nano-silver thread) in the Part I P outside transparent touch pad PD，And make these conductive materials sink further and be dispersed among substrate 110 to form insulation block I，And make conductive material layer 120 is positioned at the first shade MSK1、Electrically conducting transparent part CD、And under transparent touch pad PD and contact the first shade MSK1、Electrically conducting transparent part CD、And the Part II Q of transparent touch pad PD forms the first touch control electrode E1、Make in conductive material layer 120 under the second shade MSK2 and contact the Part II Q of the second shade MSK2 to form the second touch control electrode E2 and the electrode channel C between the second touch control electrode E2.

In the present embodiment, the details of the conductive materials being exposed in dispersing conductive material layer 120 in the Part I P outside shade MSK1, MSK2, electrically conducting transparent part CD and transparent touch pad PD can refer to aforementioned paragraphs, therefore is not repeated herein.

In one embodiment, being formed at least partially between touch control electrode E1, E2, so that touch control electrode E1, E2 are insulated from each other in insulation block I.In one embodiment, being formed at least partially around touch control electrode E1, E2 in insulation block I.In one embodiment, insulation block I is exposed to the upper surface SF1 of substrate 110.

Then, referring specifically to Figure 54 A and Figure 54 B, in one the 5th step, it is provided that at least one bridge formation BG, wherein bridge formation BG is across electrode channel C setting, to be electrically connected with two the first adjacent touch control electrode E1.In one embodiment, bridge formation BG is through contact hole T two adjacent electrically conducting transparent part CD in electrical contact, to be electrically connected with two the first adjacent touch control electrode E1.

Additionally, in the 5th step, also provide a plurality of plain conductor MT in transparent touch pad PD and insulation block I.Consequently, it is possible to plain conductor MT can be avoided to cause short circuit because of the conductive materials in contact substrate 110.

In one embodiment, it is provided that the step of bridge formation BG and plain conductor MT can be integrated into single processing procedure.In different embodiments, bridge formation BG and plain conductor MT is to provide in different processing procedures.

In one embodiment, bridge formation BG can realize with same metal material with plain conductor MT.In different embodiments, bridge formation BG can realize with different metal material with plain conductor MT.

Through above-mentioned manufacture method, touch-control module 100 can be realized.In substrate 110, form insulation block I, touch control electrode E1 can be made to electrically isolate from touch control electrode E2 and electrode channel C.Consequently, it is possible to can avoid patterning touch control electrode E1, E2 through etching mode, and avoid the optical index causing touch-control module 100 uneven, and affect the optical homogeneity of touch-control module 100 outward appearance.

In other words, by the conductive materials of aforementioned dispersing conductive material layer 120 with the method forming insulation block I in substrate 110, can make the most do not have gap or the most overlapping between touch control electrode E1, E2 and the insulation block I orthographic projection on the upper surface SF1 of substrate 110.That is, touch control electrode E1, E2 and insulation block I orthographic projection on the upper surface SF1 of substrate 110 can form a complete plane.Consequently, it is possible to can avoid because refractive index is uneven, and affect the optical homogeneity of touch-control module 100 outward appearance.

In the present embodiment, the details of substrate 110, insulation block I, touch control electrode E1, E2, electrode channel C, shade MSK1, MSK2, bridge formation BG, transparent touch pad PD and plain conductor MT substantially can refer to previous embodiment with corresponding relation therebetween, therefore is not repeated herein.

14th embodiment

Hereinafter will transmit through the 14th embodiment, it is provided that the manufacture method of another kind of touch-control module 100.This manufacture method is roughly the same with the manufacture method in the 13rd embodiment, is only that the formation order of plain conductor MT, therefore in the following description, the part of repetition will not repeat in place of difference.

The first step of the present embodiment, second step, third step and the first step of the 13rd embodiment, second step, third step roughly the same (can refer to Figure 51 A and 52A, Figure 51 B and 52B), therefore be not repeated herein.

With reference to Figure 55 A and Figure 55 B, in one the 4th step, it is possible to provide a plurality of plain conductor MT is in transparent touch pad PD with upper conductive material layer 120.

Now, the Part I P outside conductive material layer 120 includes being exposed to shade MSK1, MSK2, electrically conducting transparent part CD, transparent touch pad PD and plain conductor MT；It is positioned at the Part II Q under the electrically conducting transparent part CD of shade MSK1, MSK2 and correspondence thereof；And be positioned under plain conductor MT and the Part III R of contacting metal wire MT.

Then, with reference to Figure 56 A and Figure 56 B, in one the 5th step, the Part I P of insulating conductive material layer 120, to form the first touch control electrode E1, the second touch control electrode E2, electrode channel C, auxiliary conductor X and insulation block I.

nullFurthermore，In the 5th step，It is that dispersing conductive material layer 120 is exposed to shade MSK1、MSK2、Electrically conducting transparent part CD、The conductive materials (such as nano-silver thread) in a Part I P outside transparent touch pad PD and plain conductor MT，And make these conductive materials sink further and be dispersed among substrate 110 to form insulation block I，And make conductive material layer 120 is positioned at the first shade MSK1、Under electrically conducting transparent part CD and transparent touch pad PD and contact the first shade MSK1、The Part II Q of electrically conducting transparent part CD and transparent touch pad PD forms the first touch control electrode E1、Make in conductive material layer 120 under the second shade MSK2 and contact the Part II Q of the second shade MSK2 to form the second touch control electrode E2 and the electrode channel C between the second touch control electrode E2，And make conductive material layer 120 to be positioned under plain conductor MT and the Part III R formation auxiliary conductor X of contacting metal wire MT.

In the present embodiment, the details of the conductive materials being exposed in dispersing conductive material layer 120 in the Part I P outside shade MSK1, MSK2, electrically conducting transparent part CD, transparent touch pad PD and plain conductor MT can refer to aforementioned paragraphs, therefore is not repeated herein.

In one embodiment, being formed at least partially between touch control electrode E1, E2, so that touch control electrode E1, E2 are insulated from each other in insulation block I.In one embodiment, being formed at least partially around touch control electrode E1, E2 in insulation block I.In one embodiment, insulation block I is exposed to the upper surface SF1 of substrate 110.

Then, referring specifically to Figure 57 A and Figure 57 B, in one the 6th step, it is provided that at least one bridge formation BG, wherein bridge formation BG is across electrode channel C setting, to be electrically connected with two the first adjacent touch control electrode E1.In one embodiment, bridge formation BG is through contact hole T two adjacent electrically conducting transparent part CD in electrical contact, to be electrically connected with two the first adjacent touch control electrode E1.

Through above-mentioned manufacture method, touch-control module 100 can be realized.In substrate 110, form insulation block I, touch control electrode E1 can be made to electrically isolate from touch control electrode E2 and electrode channel C.Consequently, it is possible to can avoid patterning touch control electrode E1, E2 through etching mode, and avoid the optical index causing touch-control module 100 uneven, and affect the optical homogeneity of touch-control module 100 outward appearance.

In other words, by the conductive materials of aforementioned dispersing conductive material layer 120 with the method forming insulation block I in substrate 110, can make the most do not have gap or the most overlapping between touch control electrode E1, E2, auxiliary conductor X with insulation block I orthographic projection on the upper surface SF1 of substrate 110.That is, touch control electrode E1, E2, auxiliary conductor X can form a complete plane with insulation block I orthographic projection on the upper surface SF1 of substrate 110.Consequently, it is possible to can avoid because refractive index is uneven, and affect the optical homogeneity of touch-control module 100 outward appearance.

In the present embodiment, the details of substrate 110, insulation block I, touch control electrode E1, E2, electrode channel C, shade MSK1, MSK2, bridge formation BG, auxiliary conductor X, transparent touch pad PD and plain conductor MT substantially can refer to previous embodiment with corresponding relation therebetween, therefore is not repeated herein.

Figure 58 is the flow chart of the manufacture method 200 of a kind of touch-control module illustrated according to this utility model one embodiment.Manufacture method 200 may be used to make above-mentioned first embodiment to the touch-control module 100 in the 14th embodiment, is so not limited.In paragraphs below, will carry out the explanation of manufacture method 200 as a example by the touch-control module 100 in first embodiment, right this utility model is not limited.Manufacture method 200 comprises the following steps.

In step sl, form at least two first touch control electrode E1, at least two first touch control electrode E2 and at least one electrode channel C on a substrate 110, and synchronize embed formed one insulation block I in substrate 110, wherein insulation block I between the first touch control electrode E1 and the second touch control electrode E2, be for electrically connecting to the second touch control electrode E2.

In step s 2, at least one bridge formation BG is on substrate 110 in setting, and wherein bridge formation BG is for electrically connecting to the first touch control electrode E1.Wherein, the first touch control electrode E1 is electrically insulated from the second touch control electrode E2.

Through above-mentioned manufacture method, touch-control module 100 can be realized.In substrate 110, form insulation block I, can make between touch control electrode E1, E2 insulated from each other.Consequently, it is possible to can avoid patterning touch control electrode E1, E2 through etching mode, and avoid the optical index causing touch-control module 100 uneven, and affect the optical homogeneity of touch-control module 100 outward appearance.

In sum, an embodiment of the present utility model discloses a kind of touch-control module.Touch-control module includes a substrate, at least two first touch control electrode, at least two second touch control electrode, an insulation block, at least one electrode channel and at least one bridge formation.First touch control electrode is formed on substrate.Second touch control electrode is formed on substrate.Insulation block embeds and is formed in substrate, and between the first touch control electrode and the second touch control electrode.Electrode channel is formed on substrate and is for electrically connecting to the second touch control electrode.Bridge formation is arranged on substrate, is for electrically connecting to the first touch control electrode.First touch control electrode is electrically insulated from the second touch control electrode.

Another embodiment of the present utility model discloses the manufacture method of a kind of touch-control module.Manufacture method includes: form at least two first touch control electrode, at least two first touch control electrode and at least one electrode channel on substrate, and synchronize to embed formation insulation block in substrate, wherein insulation block is between the first touch control electrode and the second touch control electrode, and electrode channel is for electrically connecting to the second touch control electrode；And arrange and at least one build bridge on substrate, wherein building bridge is for electrically connecting to the first touch control electrode.First touch control electrode is electrically insulated from the second touch control electrode.

Although this utility model is disclosed above with embodiment; so it is not limited to this utility model; any it is familiar with this those skilled in the art; without departing from spirit and scope of the present utility model; when being used for a variety of modifications and variations, protection domain the most of the present utility model is when being defined in the range of standard depending on appending claims.

Claims (13)

1. a touch-control module, it is characterised in that including:

One substrate；

At least two first touch control electrode, are formed on this substrate；

At least two second touch control electrode, are formed on this substrate；

One insulation block, embeds and is formed in this substrate, and between this first touch control electrode and this second touch control electrode；

At least one electrode channel, is formed on this substrate, is for electrically connecting to described second touch control electrode；And

At least one builds bridge, and crosses over this electrode channel, is for electrically connecting to described first touch control electrode；

Wherein said first touch control electrode is electrically insulated from described second touch control electrode.

Touch-control module the most according to claim 1, it is characterized in that, described first touch control electrode, described second touch control electrode, this electrode channel and this insulation block are to be formed by same conductive material layer and have identical conductive materials, and this insulation block is to have the conductive materials of separation through the insulating process of a dispersed electro-conductive material.

Touch-control module the most according to claim 1, it is characterised in that this insulation block is more positioned at around described first touch control electrode and described second touch control electrode.

Touch-control module the most according to claim 1, it is characterised in that this insulation block orthographic projection on a surface of this substrate is in described first touch control electrode and described second touch control electrode between the orthographic projection on this surface of this substrate.

Touch-control module the most according to claim 1, it is characterised in that the most overlapping between described first touch control electrode, described second touch control electrode, this electrode channel with this insulation block orthographic projection on a surface of this substrate.

Touch-control module the most according to claim 1, it is characterised in that also include:

Multiple shades, are respectively arranged on described first touch control electrode, described second touch control electrode and this electrode channel.

Touch-control module the most according to claim 6, it is characterised in that the described shade being arranged in described first touch control electrode also includes:

Multiple contact holes；

Wherein this bridge formation is electrically connected with described first touch control electrode through described contact hole.

Touch-control module the most according to claim 7, it is characterised in that the described shade being arranged in described first touch control electrode also includes:

Multiple electric-conductors, lay respectively in described contact hole；

Wherein this bridge formation is electrically connected with described first touch control electrode through described electric-conductor.

Touch-control module the most according to claim 6, it is characterised in that this bridge formation is electrically insulated with this electrode channel by the described shade being arranged on this electrode channel.

Touch-control module the most according to claim 1, it is characterised in that also include:

A plurality of wire, is electrically connected with this first touch control electrode and this second touch control electrode.

11. touch-control modules according to claim 10, it is characterised in that also include:

A plurality of auxiliary conductor, lays respectively under described wire, and is electrically connected with described wire.

12. touch-control modules according to claim 1, it is characterised in that also include:

Multiple engagement pads, are respectively arranged on this first touch control electrode of part and this second touch control electrode of part；And

A plurality of wire, is electrically connected with described engagement pad.

13. touch-control modules according to claim 1, it is characterised in that described first touch control electrode is to arrange along a first direction, described second touch control electrode is to arrange along a second direction, and this first direction is different from this second direction.