CN201741139U

CN201741139U - Touch circuit pattern structure, touch panel and touch display screen

Info

Publication number: CN201741139U
Application number: CN2010202311568U
Authority: CN
Inventors: 何宽鑫; 黄萍萍; 严建斌; 张�浩; 蔡志雄; 肖铁飞
Original assignee: TPK Touch Solutions Xiamen Inc
Current assignee: TPK Touch Solutions Xiamen Inc
Priority date: 2010-06-12
Filing date: 2010-06-12
Publication date: 2011-02-09
Anticipated expiration: 2020-06-12

Abstract

The utility model discloses a capacitance type touch circuit pattern structure which is formed on a substrate and used for a touch display screen. The touch circuit pattern structure comprises a transparent conductive layer with the thickness of 100-500 angstroms, a conductive layer with the thickness of 1000-5000 angstroms, and an insulating layer with the thickness of 1-5 micrometers and arranged between the transparent conductive layer and the conductive layer. The capacitance type touch circuit pattern structure only comprises a capacitance induction layer, thus being capable of effectively reducing the thickness of the whole touch panel, lowering resistance and improving the sensitivity of signal transmission. The utility model also discloses a touch panel and a touch screen with the pattern structure.

Description

Touch control circuit pattern structure, contact panel and touch-control display screen

Technical field

The utility model relates to touch-control display screen field, particularly relates to a kind of contact panel and touch-control display screen that is used for the touch control circuit pattern structure of capacitance type touch-control panel and adopts this touch control circuit pattern structure.

Background technology

The application of contact panel in electronic equipment at present more and more widely.They replace or the input equipment of additional common keyboard and mouse is used for controlling electronic equipment and realizes various functions as a kind of.

The existing touch-control input mode that is used for the contact panel (Touch Panel) of touch-control display screen comprises resistance-type, condenser type, optical profile type, induction and sound wave induction type etc.Wherein, capacitive principle of work is: the user touches with the surface of finger or induction pen counter plate, the variation that is subjected to the inside of the panel of touch position to produce voltage and electric current is accepted the position of touching to detect panel surface, to reach the purpose of touch-control input.

As shown in Figure 1, general capacitance type touch-control panel can etch the conductive coating on the base material different conductive modules, forms the electrode axis of X (X0-X7) direction and Y (Y0-Y4) direction.When the user with finger or during other ground connection conductive body touch panel (shown in dash area among the figure), X-axis that touches and Y-axis just can produce capacitance variations respectively, controller will be judged the position that finger touches according to the position of the X-axis and the Y-axis of this capacitance variations on touch surface.

A kind of traditional capacitance type touch control circuit pattern structure 201 includes two the

capacitive sensing layers

202 and 203 that are arranged on the substrate 205, separates with an intermediate insulating layer 204 therebetween, to form capacity effect.Each capacitive sensing layer comprises a plurality of conducting elements that essence is arranged in parallel, and the conducting element in two capacitive sensing layers is perpendicular to one another in fact.(for example tin indium oxide Indium Tin Oxide ITO) makes these electrodes conduct elements by transparent conductive material.

Above-mentioned traditional capacitance type touch control circuit pattern structure is provided with two-layer capacitive sensing layer, and one-piece construction is thicker, and because conducting element is made by ITO, and its impedance is bigger, causes the signal transmission sensitivity of touch control circuit pattern structure to be difficult to promote.

Therefore, need a kind of new capacitance type touch control circuit pattern structure to solve above-mentioned traditional existing problem of capacitance type touch control circuit pattern structure and defective.

The utility model content

A purpose of the present utility model is to provide a kind of capacitance type touch control circuit pattern structure that is used for the touch-control display screen, to overcome big and low problem and the defective of signal transmission sensitivity of touch control circuit pattern structural entity structural thickness in the above-mentioned prior art.

Another purpose of the present utility model is to provide a kind of contact panel that is provided with capacitance type touch control circuit pattern structure of the present invention.

Another purpose of the present utility model is to provide a kind of touch-control display screen with above-mentioned contact panel.

For realizing above-mentioned purpose, the utility model provides a kind of capacitance type touch control circuit pattern structure that is used for the contact panel in the touch-control display screen that is formed on the substrate, and comprising: a transparency conducting layer, its thickness is

One conductive layer, its thickness is And an insulation course that is arranged between described transparency conducting layer and the described conductive layer, its thickness is 1 μ m-5 μ m.

For realizing above-mentioned purpose, the utility model also provides a kind of contact panel that is used for the touch-control display screen, and it comprises a substrate, and one is arranged on first perimeter circuit and second perimeter circuit that is used for conducting above-mentioned touch sensible signal on the substrate; An and controller that is used for receiving and handling described touch sensible signal.

For realizing above-mentioned purpose, the utility model also provides a kind of touch-control display screen, and it comprises foregoing contact panel.

Advantage of the present utility model is, capacitance type touch control circuit pattern structure of the present utility model has included only a capacitive sensing layer, can effectively hang down the thickness of whole contact panel, and second lead of making by metal material, can lower the impedance of respectively organizing between the second electrode block and corresponding second perimeter circuit, the sensitivity of transmitting with the signal that promotes between each electrode block and perimeter circuit.And first and second electrode block can be laid formation in time processing, and peripheral circuit can form simultaneously with second lead, lays the required manufacturing procedure of touch control circuit pattern structure thereby reduced, and has improved production efficiency.

Description of drawings

Below in conjunction with accompanying drawing and detailed embodiment the utility model is elaborated, wherein:

Fig. 1 is capacitance type touch-control panel principle of induction figure.

Fig. 2 is the synoptic diagram of traditional capacitance type touch control circuit pattern structure.

Fig. 3 is the synoptic diagram according to graphic structure first embodiment of touch-control circuit of the present utility model.

Fig. 4 to Fig. 6 is the implementation step synoptic diagram of touch control circuit pattern structure in the construction drawing 3.

Fig. 7 is the synoptic diagram of touch control circuit pattern structure second embodiment of the present utility model.

Fig. 8 is the side structure synoptic diagram of first and second embodiment of touch control circuit pattern structure of the present utility model.

Fig. 9 is the structural representation with contact panel of the utility model first embodiment.

Figure 10 is the structural representation with contact panel of the utility model second embodiment.

Figure 11 to Figure 13 is for making the implementation step synoptic diagram of the 3rd embodiment of the present utility model.

Figure 14 is the side structure synoptic diagram of touch control circuit pattern the 3rd embodiment of the present utility model.

Figure 15 is the structural representation with contact panel of the utility model the 3rd embodiment.

Figure 16 is the side structure synoptic diagram of contact panel with first and second embodiment of touch control circuit pattern structure of the present utility model.

Figure 17 is the side structure synoptic diagram of contact panel with the 3rd embodiment of touch control circuit pattern structure of the present utility model.

Figure 18 is the structural representation of the touch-control display screen of the contact panel of employing touch control circuit pattern structure of the present utility model.

[primary clustering symbol description]

1,1a the

first region piece

10,10a first conducting

element

11,11a first lead

100,100a touch control circuit pattern 101,101a transparent insulating layer 102,102a transparency conducting layer

103,103a insulation course 104,104a conductive layer

2, the 2a

second electrode block

20,20a

second conducting element

21,21a second lead

201 traditional touch control circuit pattern structure 202 capacitive sensing layers 203 capacitive sensing layer

204 insulation courses, 205 substrates

3,3a substrate 301,301a transparent insulating layer 302,302a transparency conducting layer

303,303a insulation course 304,304a conductive layer 305,305a screen layer

306, protective seam 303 behind the 306a, protective seam 308 before the 307a, 308a tack coat

309,309a glass cover-plate 310,310a flexible circuit board (FPC)

4, the 4a dot interlace 51 that insulate, 51a

first perimeter circuit

52,52a second perimeter circuit

6,6a controller 60 touch-control display screens 61 contact panels

62 display device, 63 tack coats, 64 processors

Embodiment

Below in conjunction with accompanying drawing, be described in more detail with other technical characterictic and advantage the utility model is above-mentioned by exemplary embodiment.Yet should be appreciated that under the situation that is not having further narration element, structure and feature in embodiment also can be attached in other embodiment valuably.

As shown in Figure 3, be planar structure synoptic diagram according to first embodiment of capacitance type touch control circuit pattern structure of the present utility model.This touch control circuit pattern structure is formed on the substrate 3, and in fact this substrate 3 can be made of glass, plastic cement or other transparent insulating material.Described touch control circuit pattern structure 100 comprises a plurality of first conducting elements 10 and a plurality of second conducting element 20.Each first conducting element 10 comprises and a plurality ofly is electrically connected first lead 11 between the two adjacent the first region pieces 1 along first axial (as directions X) the spaced apart the first region piece 1 and a plurality of.Each second conducting element 20 comprises a plurality of along second axial (as the Y direction) the spaced apart second electrode block 2 be connected electrically in second lead 21 between the second adjacent electrode block 2.Wherein, first direction is vertical mutually with second direction.Certainly, first axially axially also can become the angle that is fit to arbitrarily with second.Adjacent two second electrode blocks 2 are corresponding to the both sides that place the first corresponding lead 11 along the interval between first axially adjacent two the first region pieces respectively in second conducting element 20, and second lead 21 is across this first lead 11.Between first and

second lead

11,21 of crossing over mutually, also be provided with insulation dot interlace 4, thereby between first and

second lead

11,21, form electrical isolation as insulation course.

In the foregoing description, the first region piece 1, the second electrode block 2 and first lead 11 are preferably made by transparent conductive material, as tin indium oxide (ITO), indium zinc oxide or aluminum zinc oxide etc.And second lead 21 is preferably made by opaque conductive material (as metal material, silver, copper, aluminium etc.).Insulation dot interlace 4 can be made as epoxy resin, polyimide or methyl methacrylate etc. by transparent insulation material, also can be made as printing ink by opaque insulating material.The first region piece 1 and the second electrode block 2 are polygon-shaped, as rectangle, rhombus, triangle, hexagon, octagon.

Method for making below in conjunction with capacitance type touch control circuit pattern structure in Fig. 4-6 key diagram 3.Present embodiment can utilize gold-tinted processing to be put into practice, yet should be appreciated that the method for making of capacitance type touch control circuit pattern structure of the present utility model also can realize by other suitable processing technologys.Described method for making comprises the following steps:

At first, as shown in Figure 4, at the surface of substrate 3 degree of a spattering transparency conducting layer, and be processed to form the second electrode block 2 that plural groups axially is provided with along the first the first region piece 1 that axially is provided with, plural groups first lead 11 and plural groups second through operations such as overexposure, development, etchings.Wherein, every group of the first region piece comprises a plurality of the first region pieces of arranging along described first axially spaced-apart, and every group second electrode block comprises a plurality of second electrode blocks of arranging along described second axially spaced-apart.Every group first lead comprises a plurality of first leads 11, is laid between two adjacent in same the first region piece group the first region pieces 1, to be electrically connected the first region piece 1 in same group.Adjacent two second electrode blocks 2 are corresponding to the both sides of first lead 11 that is placed in along the interval between first axially adjacent two the first region pieces 1 in same group.First, second electrode block 1,2 and first lead 11 can be made by transparent conductive material, and described transparent conductive material can be to select tin indium oxide (ITO), indium zinc oxide or aluminum zinc oxide etc. for use.

Then, as shown in Figure 5, according to the position of established first, second electrode block 1,2 and first lead 11, degree of a spattering insulation course, and lay a plurality of insulation dot interlaces 4 as insulation course on described substrate 3 surfaces through operations such as overexposure, development, etchings, cover the part of first lead 11.Insulation dot interlace 4 preferably is made by transparent insulating material, and for example epoxy resin, polyimide or methyl methacrylate or other possess the equivalent material of insulating capacity, thus the effective transparency of the touch control circuit pattern that obtained of raising.

At last, as shown in Figure 6, degree of a spattering conductive layer again on the figure that Fig. 5 forms, and by operations such as exposure, development, etchings, according to the position of established insulation dot interlace 4, form many group second leads 21 on described substrate 3 surfaces, every group comprises a plurality of second leads, be laid between the adjacent second electrode block 2 in the same second electrode block group, be used for being connected electrically in same group the two adjacent second electrode blocks 2.Wherein, second lead 21 is across on the insulation dot interlace 4, thus make its with corresponding first lead 11 between form electrical isolation.So just formed the structure of first embodiment of the present utility model.

According to first embodiment of the present utility model, a plurality of first conducting elements 10 parallel to each other and a plurality of second conducting element 20 parallel to each other can be set on substrate 3, and make a plurality of the first region pieces 1 be matrix to be spaced, and a plurality of second electrode block 2 is also that matrix is spaced and is staggered with described a plurality of the first region pieces 1.First lead 11, insulation dot interlace 4 and second lead 21 respectively can be with many groups of enforcements, and are matrix respectively and are spaced.And a plurality of insulation dot interlaces 4 of these one-tenth arranged have constituted the insulation course between first and second leads, insulation dot interlace 4 and the first and second electrode blocks 1 and 2 all do not have overlapping, therefore compared to the design of whole traditional insulation course, the utlity model has the advantage that improves light penetration.

As shown in Figure 7, be the structural representation of two embodiment of the present utility model.We can see among the figure, second embodiment and first example structure are basic identical, its difference is that second lead 22 of second embodiment extends on the implementation and links into an integrated entity, thereby with contact a plurality of second electrode blocks 2 in same group of stacked mode.The method for making of the method for making of second embodiment of the present utility model and first embodiment is basic identical, and different is, when making second lead 22, second lead 22 is with contact a plurality of second electrode blocks 2 in same group of stacked mode.Its method for making, operation and selection are all identical with first embodiment, are not just giving unnecessary details at this.

As shown in Figure 8, be the side structure synoptic diagram of first embodiment of the present utility model and second embodiment.Touch control circuit pattern structure 100 of the present utility model comprises that a transparent insulating layer 101 is used for forming substrate 3, one transparency conducting layer 102 is used for forming a plurality of first conducting elements 10 and a plurality of second electrode block, 2, one insulation courses 103 are used for forming insulation dot interlace 4 and a conductive layer 104 is used for forming second lead 21.In the said structure, transparent insulating layer 101 is made by glass usually, and its thickness is approximately 0.2mm-1mm, preferably 0.55mm; Transparency conducting layer 102 is made of transparent conductive material usually, and as tin indium oxide (ITO), indium zinc oxide or aluminum zinc oxide etc., its thickness is approximately

Preferably

Insulation course 103 is made by transparent insulation material usually, possesses the equivalent material of insulating capacity as epoxy resin, polyimide or methyl methacrylate or other, and its thickness is approximately 1 μ m-5 μ m, preferably 2 μ m; Conductive layer 104 preferably is made of the opaque metal material of better conductivity, as metal material, and silver, copper, aluminium etc., its thickness is approximately

Preferably

As shown in Figure 9, be the structural representation of contact panel with the utility model first embodiment.This contact panel is except the touch control circuit pattern structure that comprises the utility model first embodiment, also include a plurality of first perimeter circuits 51 and a plurality of second perimeter circuits 52 of being arranged on substrate 3 end limits (as two abutting end limits), and a controller 6 that is used for receiving and handle the signal that touch control circuit pattern produces.Each first perimeter circuit 51 is electrically connected to one group of the first region piece 1, and the respectively one group of second electrode block 2 of second perimeter circuit, 52 electrical connections, and first perimeter circuit 51 and second perimeter circuit all are connected to controller 6.So, the every group of the first region piece 1 and first lead 11 that is connected have therebetween constituted first conducting element 10; And the every group second electrode block 2 and second lead 21 that is connected therebetween constitute second conducting element 20, and wherein each first conducting element 10 is electrically connected to one first perimeter circuit 51, and each second conducting element 20 is electrically connected to one second perimeter circuit 52.

First perimeter circuit 51 and second perimeter circuit 52 can form in same operation with the first region piece 1, first lead 11 and the second electrode block 2 in the first embodiment manufacturing process of the present utility model, this moment, first and

second perimeter circuit

51,52 preferably can utilize transparent conductive material to make, as tin indium oxide (ITO), indium zinc oxide or aluminum zinc oxide etc., and this moment the thickness of first and second perimeter circuit 51, the 52 and consistency of thickness of transparency conducting layer 102.First and

second perimeter circuit

51,52 can also form in same operation with second lead 21, this moment, they can select for use opaque conductive material (as conducting electricity metal materials such as good gold, silver, copper, aluminium) to make, and the consistency of thickness of their thickness and conductive layer 104.Perhaps, first and

second perimeter circuit

51,52 also can form in independent manufacturing procedure.

Figure 10 is the structural representation with contact panel of the utility model second embodiment.This contact panel is except the touch control circuit pattern structure that comprises the utility model second embodiment, also include a plurality of first perimeter circuits 51 and a plurality of second perimeter circuits 52 of being arranged on substrate 3 end limits (as two abutting end limits), and a controller 6 that is used for receiving and handle the signal that touch control circuit pattern produces.Each first perimeter circuit 51 is electrically connected to one group of the first region piece 1, and the respectively one group of second electrode block 2 of second perimeter circuit, 52 electrical connections, and first perimeter circuit 51 and second perimeter circuit all are connected to controller 6.So, the every group of the first region piece 1 and first lead 11 that is connected have therebetween constituted first conducting element 10; And the every group second electrode block 2 and second lead 21 that is connected therebetween constitute second conducting element 20, and wherein each first conducting element 10 is electrically connected to one first perimeter circuit 51, and each second conducting element 20 is electrically connected to one second perimeter circuit 52.

Identical with contact panel with the utility model first embodiment, having first perimeter circuit 51 of contact panel of the utility model second embodiment and second perimeter circuit 52 can be in the first embodiment manufacturing process of the present utility model and the first region piece 10, first lead 11 and the second electrode block 20 form in same operation, this moment first and

second perimeter circuit

51,52 preferably can utilize transparent conductive material to make, as tin indium oxide (ITO), indium zinc oxide or aluminum zinc oxide etc., and this moment first and second perimeter circuit 51, the consistency of thickness of 52 thickness and transparency conducting layer 102.First and

second perimeter circuit

51,52 also can form in independent manufacturing procedure.

The method for making of the 3rd embodiment of the present utility model is described below in conjunction with Figure 11 to Figure 13.

At first, as shown in figure 11, at substrate 3a surface degree of a spattering conductive layer, to form many groups by operations such as exposure, development, etchings along the second second lead 21a that axially is provided with, every group comprises many second lead 21a.When the second lead 21a of group more than being laid with, it can be set as array by cloth.

Then, as shown in figure 12, according to the position of the established second lead 21a, degree of a spattering insulation course, and lay on described substrate 3a surface by operations such as exposure, development, etchings and to form a plurality of insulation dot interlace 4a as insulation course, be covered on the part of the second lead 21a.

At last, on the formed pattern of Figure 12, degree of a spattering transparency conducting layer, and form the plural groups second electrode block 2a, plural groups the first region piece 1a and the plural groups first lead 11a on substrate 3a surface by operations such as exposure, development, etchings.Every group second electrode block 2a comprises a plurality of second electrode block 2a that arrange along second axially spaced-apart, make every group second lead 21a be laid between the interior adjacent second electrode block 2a of the same second electrode block group, thereby the second electrode block in same group is electrically connected by the second lead 21a.Every group of the first region piece comprises a plurality of the first region piece 1a that arrange along first axially spaced-apart, and corresponding to the interval between two the second adjacent electrode block 2a, two adjacent the first region piece 1a are laid in the both sides of the described second lead 21a respectively.Every group first lead 11a is laid between the interior adjacent the first region piece 1a of same the first region piece group, the described the first region piece 1a in being used to be electrically connected same group.Form electrical isolation by described insulation course between described first lead and described second lead.Specifically, the first lead 11a crosses over insulation dot interlace 4a and is electrically connected two adjacent same group the first region piece 1a from the top, form electrical isolation thereby make to win between the lead 11a and the second lead 21a.Through above-mentioned steps, the touch control circuit pattern structure 100a that finally forms the utility model the 3rd embodiment as shown in figure 13.

The first and

second electrode block

1a, 2a also can be set to many groups in the present embodiment respectively.The first region piece 1a and the second electrode block 2a are polygon-shaped, as rectangle, rhombus, triangle, hexagon, octagon.All the other member compositions and embodiment in the present embodiment are identical with the embodiment of Fig. 4 to Fig. 6.

Compare with first embodiment of the present utility model, structural form and Fig. 3 of the 3rd embodiment of the present utility model are similar, and the difference place only is to lay the order that is formed up to substrate surface.

Consult Figure 14, be the side structure synoptic diagram of the 3rd embodiment of the present utility model.The touch control circuit pattern structure 100a of the utility model the 3rd embodiment comprises that a transparent insulating layer 101a is used for forming substrate 3a, one transparency conducting layer 102a is used for forming a plurality of first conducting element 10a and a plurality of second electrode block 2a, and an insulation course 103 is used for forming insulation dot interlace 4a and a conductive layer 104a is used for forming the second lead 21a.In the said structure, transparent insulating layer 101a is made by glass usually, and its thickness is approximately 0.2mm-1mm, preferably 0.55mm; Transparency conducting layer 102a is made of transparent conductive material usually, and as tin indium oxide (ITO), indium zinc oxide or aluminum zinc oxide etc., its thickness is approximately

Preferably

Insulation course 103a is made by transparent insulation material usually, possesses the equivalent material of insulating capacity as epoxy resin, polyimide or methyl methacrylate or other, and its thickness is approximately 1 μ m-5 μ m, preferably 2 μ m; Conductive layer 104a preferably is made of the opaque metal material of better conductivity, as metal material, and silver, copper, aluminium etc., its thickness is approximately

Preferably

As shown in figure 15, be the structural representation of contact panel with the utility model the 3rd embodiment.This contact panel is except the touch control circuit pattern structure that comprises the utility model the 3rd embodiment, also include a plurality of the first perimeter circuits 51a and a plurality of the second perimeter circuits 52a that are arranged on substrate 3a end limit (as two abutting end limits), and a controller 6a who is used for receiving and handle the signal that touch control circuit pattern produces.Each first perimeter circuit 51a is electrically connected to one group of the first region piece 1a, and each second perimeter circuit 52a is electrically connected one group of second electrode block 2a, and the first perimeter circuit 5a1 and second perimeter circuit all are connected to controller 6a.So, the every group of the first region piece 1a and the first lead 11a that is connected have therebetween constituted first conducting element 10; And the every group second electrode block 2a and the second lead 21a that is connected therebetween constitute the second conducting element 20a, wherein each first conducting element 10a is electrically connected to one first perimeter circuit 51a, and each second conducting element 20a is electrically connected to one second perimeter circuit 52a.

The first perimeter circuit 51a and the second perimeter circuit 52a can form in same operation with the first region piece 10a, the first lead 11a and the second electrode block 20a in the 3rd embodiment manufacturing process of the present utility model, first and

second perimeter circuit

51a, 52a preferably can utilize transparent conductive material to make at this moment, as tin indium oxide (ITO), indium zinc oxide or aluminum zinc oxide etc., and this moment the thickness of first and second perimeter circuit 51, the 52 and consistency of thickness of transparency conducting layer 102a.First and

second perimeter circuit

51a, 52a can also form in same operation with the second lead 21a, this moment, they can select for use opaque conductive material (as conducting electricity metal materials such as good gold, silver, copper, aluminium) to make, and the consistency of thickness of their thickness and conductive layer 104a.Perhaps, first and

second perimeter circuit

51a, 52a also can form in independent manufacturing procedure.

Touch control circuit pattern structure of the present utility model can be embodied in the contact panel that is used for the touch-control display screen.Described contact panel comprises a substrate, is formed with foregoing according to touch control circuit pattern structure of the present utility model on this substrate.

See also Figure 16, be the side structure synoptic diagram of contact panel with first and second embodiment of touch control circuit pattern of the present utility model.Contact panel comprises a substrate 301; one is arranged on the transparency conducting layer 302 that is used for forming first conducting element 10 and the second electrode block 2 on the substrate 301; one insulation course 303 and that is used for forming insulation dot interlace 4 is used for forming the conductive layer 304 of second lead 21; one is positioned at the screen layer 305 that is used for shielding electric signal of substrate 301 opposite sides; one is positioned at the back protective seam 306 that is used for protecting contact panel of screen layer 305 belows; one is positioned at the preceding protective seam 307 that is used for protecting the touch control circuit pattern structure of conductive layer 304 tops; one tack coat 308; one glass cover-plate 309 and a flexible circuit board 310 (FPC).Tack coat 308 is used for connecting glass cover-plate 309 and preceding protective seam 307, and glass cover-plate 309 is positioned at the top of whole contact panel.

In the said structure, substrate 301, transparency conducting layer 302, insulation course 303 and conductive layer 304, corresponding with Fig. 8, promptly constituted the touch control circuit pattern structure of the utility model first and second embodiment.Flexible circuit board 310 (FPC) promptly is equivalent to Fig. 9 and Figure 10 middle controller 6.The size of each layer of touch control circuit pattern structure has been described among Fig. 8, has not just described at this.Introduce the size of other each layers below, the thickness of screen layer 305 is approximately

The thickness of back protective seam 306 is approximately

The thickness of preceding protective seam 307 is approximately 2 μ m, and the thickness of tack coat 308 is approximately 0.175mm, and the thickness of glass cover-plate 309 is approximately 0.55mm.

Figure 17 is the side structure synoptic diagram with contact panel of touch control circuit pattern the 3rd embodiment of the present utility model.Contact panel comprises a substrate 301a; one is arranged on the conductive layer 304a that is used for forming the second lead 21a on the substrate 301a; one is used for forming the insulation course 303a of insulation dot interlace 4a; one is used for forming the transparency conducting layer 302a of the first conducting element 10a and the second electrode block 2a; one is positioned at the screen layer 305a that substrate 301a opposite side is used for shielding electric signal; one is positioned at the back protective seam 306a that is used for protecting contact panel of screen layer 305a below; one is positioned at the preceding protective seam 307a that is used for protecting the touch-control circuit structure of transparency conducting layer 302a top; one tack coat 308a; an one glass cover-plate 309a and a flexible circuit board 310a (FPC).Tack coat 308a is used for connecting glass cover-plate 309a and preceding protective seam 307a, and glass cover-plate 309a is positioned at the top of whole contact panel.

In the said structure, substrate 301a, transparency conducting layer 302a, insulation course 303a and conductive layer 304a, corresponding with Figure 14, promptly constituted the touch control circuit pattern structure of the utility model the 3rd embodiment.Flexible circuit board 310a (FPC) promptly is equivalent to Figure 15 middle controller 6a.The size of each layer of touch control circuit pattern structure has been described among Figure 14, has not just described at this.Introduce the size of other each layers below, the thickness of screen layer 305a is approximately

The thickness of back protective seam 306a is approximately

The thickness of preceding protective seam 307a is approximately 2 μ m, and the thickness of tack coat 308a is approximately 0.175mm, and the thickness of glass cover-plate 309a is approximately 0.55mm.

Above-mentioned contact panel can combine with display and constitute a touch-control display screen.See also Figure 18, be the structural representation of the touch-control display screen of the contact panel that adopts touch control circuit pattern of the present utility model.Touch-control display screen 60 comprises that a contact panel 61, one displays 62, are arranged at the tack coat 63 between contact panel 61 and the display 62, and a processor 64 that all is connected with contact panel 61 and display 62.Tack coat 63 is used for bonding contact panel 61 and display 62, contact panel 61 is used for responding to a touch action and produces a touch-control sensing signal and corresponding touch-control sensing signal is sent to processor 64, after processor 64 receives the touch-control sensing signal of contact panel 61 transmission, handle, produce corresponding demonstration indicator signal and also transmit the corresponding indicator signal that shows, thereby display 62 shows the pairing image information of corresponding touch action after receiving the demonstration indicator signal on display 62 to display 62.Aforementioned display device can be a LCD.

Contact panel 61 can be stacked and placed on the display 62 of touch-control display screen 60, and described display comprises upper substrate, infrabasal plate and is arranged on the pixel cell between the upper and lower base plate and is used for the black matrix (Black Matrix) of shading.Preferably, second lead of being made by opaque conductive material in the touch control circuit pattern structure is set to align with the black matrix of display, to improve the transmitance of display panel emitted light.

Touch control circuit pattern structure of the present utility model can also be implemented in the display of touch-control display screen, for example, the touch control circuit pattern structure is arranged under the upper substrate of display or on the infrabasal plate.At this moment, can utilize the upper substrate of display or infrabasal plate substrate as contact panel.Preferably, second lead can be set to display in the shading that constitutes by black matrix overlapped with shielding layer.When second lead is made by opaque conductive material, as selection, can omit the shielding layer that constitutes by black matrix, and with the shading element of second lead as display.Preferably, can make second lead, thereby can lower the impedance of respectively organizing between the second electrode block and corresponding second perimeter circuit, the sensitivity of transmitting with the signal that promotes between each electrode block and perimeter circuit by metal material.

According to as can be known above-mentioned, first and second electrode block of the present utility model can be laid formation in time processing, first and second perimeter circuits also can be laid formation in time processing simultaneously, thereby can finish the laying of touch control circuit pattern with three manufacturing procedures, process number of times, reduced processing cost, improved production efficiency thereby reduced required gold-tinted.

More than explanation is just illustrative for the utility model; and it is nonrestrictive; those of ordinary skills understand; under the situation of the spirit and scope that do not break away from following claims and limited; can make multiple modification, variation or equivalent, but these will fall in the protection domain of the utility model claims all.

Claims

1. touch control circuit pattern structure comprises:

One transparency conducting layer, its thickness is

One conductive layer, its thickness is

And an insulation course that is arranged between described transparency conducting layer and the described conductive layer, its thickness is 1 μ m-5 μ m.

2. touch control circuit pattern structure as claimed in claim 1 is characterized in that described transparency conducting layer is made by transparent conductive material.

3. touch control circuit pattern structure as claimed in claim 2 is characterized in that, described transparent conductive material is tin indium oxide, indium zinc oxide or aluminum zinc oxide.

4. touch control circuit pattern structure as claimed in claim 1 or 2 is characterized in that the thickness of described transparency conducting layer is

5. described touch control circuit pattern structure as claimed in claim 1 is characterized in that described insulation course is made by transparent insulation material.

6. described touch control circuit pattern structure as claimed in claim 5 is characterized in that described transparent insulation material is epoxy resin, polyimide or methyl methacrylate.

7. as claim 1 or 5 described touch control circuit pattern structures, it is characterized in that the thickness of described insulation course is 2 μ m.

8. described touch control circuit pattern structure as claimed in claim 1 is characterized in that described conductive layer is made of metal material.

9. described touch control circuit pattern structure as claimed in claim 8 is characterized in that described metal material is silver, copper, aluminium.

10. as claim 1 or 8 described touch control circuit pattern structures, it is characterized in that the thickness of described conductive layer is

11. the method for the touch control circuit pattern structure of manufacturing touch-control display screen as claimed in claim 1, it is characterized in that, described transparency conducting layer comprises at least one group first conducting element and at least one group the one the second electrode blocks, and described first conducting element and the described second electrode block do not have and be electrically connected and each interval is arranged.

12. method as the touch control circuit pattern structure of claim 1 or 11 described manufacturing touch-control display screens, it is characterized in that, insulation course comprises the insulation dot interlace of one or more each intervals, and each dot interlace that insulate covers at least a portion of described each first conducting element.

13. method as the touch control circuit pattern structure of claim 1 or 11 described manufacturing touch-control display screens, it is characterized in that, described conductive layer comprises at least one group of second lead that is used to be electrically connected the same group of interior two adjacent second electrode blocks, forms electrical isolation by described insulation course between described first guiding element and described second lead.

14. touch control circuit pattern structure as claimed in claim 1 is characterized in that, described transparency conducting layer comprises at least one group of the first region piece, and every group of the first region piece comprises at least two the first region pieces arranging along first axially spaced-apart; At least one group first lead, every group first lead is laid between the interior adjacent the first region piece of same the first region piece group, the described the first region piece in being used to be electrically connected same group; And at least one group second electrode block, every group comprises at least two the second electrode blocks of arranging along second axially spaced-apart, corresponding to the interval between two adjacent the first region pieces, two second adjacent electrode blocks are laid in the both sides of described first lead respectively; Described insulation course comprises the insulation dot interlace of one or more each intervals, and each dot interlace that insulate covers at least a portion of described each first lead; Described conductive layer comprises at least one group of second lead of being made by opaque conductive material, wherein every group second lead is laid between the interior adjacent second electrode block of the same second electrode block group, the described second electrode block in being used to be electrically connected same group forms electrical isolation by described insulation course between described first lead and described second lead.

15. described touch control circuit pattern structure as claimed in claim 14 is characterized in that, the described same group of second interior lead extends into one.

16. touch control circuit pattern structure as claimed in claim 14 is characterized in that, described the first region piece and the described second electrode block are rectangle, rhombus, triangle, hexagon or octagon.

17. a contact panel that is used for the touch-control display screen comprises:

One substrate;

One is formed on touch control circuit pattern structure as claimed in claim 1 on this substrate, is used for adopting the touch sensible signal; One is arranged on first perimeter circuit and second perimeter circuit that is used for conducting above-mentioned touch sensible signal on the substrate; An and controller that is used for receiving and handling described touch sensible signal.

18. contact panel as claimed in claim 17; it is characterized in that, described contact panel also comprise one be positioned at screen layer, that substrate one side is used for shielding electric signal be positioned at being used under the screen layer protect the back protective seam, of contact panel be positioned at the structural preceding protective seam that is used for protecting the touch control circuit pattern structure of touch control circuit pattern, a glass cover-plate, with one be used for connecting glass cover-plate and described before the tack coat of protective seam.

19. a touch-control display screen comprises:

One as claimed in claim 17ly is used for sensing touch-control action and produce the contact panel of corresponding touch-control sensing signal;

One is used for receiving the above-mentioned touch-control sensing signal of processing and producing corresponding Signal Processing device to be shown; And one be used for receiving described signal to be shown and show the display of corresponding pattern.

20. touch-control display screen as claimed in claim 19 is characterized in that, described touch-control display screen comprises that further one is arranged on the tack coat between described contact panel and the described display.

21. touch-control display screen as claimed in claim 19 is characterized in that, described display is a LCD.