An ITO conductive film glass

By setting a positioning structure and positioning blocks on the lower edge of the ITO conductive glass, the accuracy and stability issues when connecting the ITO conductive glass to electronic components are solved, achieving high-precision docking and a firm connection, thus improving the practicality of the ITO conductive glass.

CN224417499UActive Publication Date: 2026-06-26PUTIAN DEXIN ELECTRONICS LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
PUTIAN DEXIN ELECTRONICS LTD
Filing Date
2025-05-26
Publication Date
2026-06-26

AI Technical Summary

Technical Problem

The existing ITO conductive glass has a square shape, which makes the bonding position inaccurate when connected to related components. It requires manual adjustment, prolongs the bonding time, and reduces its practicality.

Method used

A positioning structure is set at the lower edge of the glass body, and the adhesive layer of the frame is bonded with optical adhesive. The positioning block is embedded and positioned with the inner edge of the electronic component to ensure center alignment and improve connection accuracy and firmness.

Benefits of technology

Through the design of the positioning structure and positioning blocks, precise docking and firm connection between ITO conductive glass and electronic components are achieved, improving the stability and practicality of the bonding and avoiding problems such as center point deviation and unstable shaking.

✦ Generated by Eureka AI based on patent content.

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Abstract

The utility model discloses a kind of ITO conductive film glass, its structure includes: positioning structure, glass main body, sputtering layer, ITO conductive film, positioning structure is adhered to the lower edge position of glass main body by optical cement and glass main body is covered by upper end sputtering layer to let ITO conductive film;The utility model is based on the positioning structure being set in the lower end edge of glass main body, using the frame of positioning structure combines optical cement to let bonding layer be fixed in the lower edge of glass main body, then cavity according to the normal light transmission use of permeability state without affecting glass main body, subsequently when being connected with electronic component, positioning block can be embedded first and be clamped in the inside of electronic component, ensure that glass main body center point can be coincident with electronic component center point, replaced original direct placement and then the center point of optical cement generation is constantly displaced and reduced the practicality of ITO conductive glass, further improve the bonding accuracy of ITO conductive glass.
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Description

Technical Field

[0001] This utility model relates to the field of ITO conductive glass technology, specifically an ITO conductive film glass. Background Technology

[0002] ITO conductive film glass refers to ordinary glass with an ITO thin film sputtered on it to make it conductive. It is commonly used in components such as LCD screens, touch panels, and solar cells. Due to its high transparency, conductivity, good chemical stability and corrosion resistance, it can effectively improve the quality and service strength of related components and equipment.

[0003] However, existing ITO conductive glass still has the following drawbacks: Since the current ITO conductive glass is square in shape, it can only be bonded to the edges using suitable optical adhesive when connected to related components. As a result, the center of the glass and the component needs to be constantly adjusted manually during bonding, which can easily lead to inaccurate bonding position and prolong bonding time, thus reducing the practicality of ITO conductive film glass. Utility Model Content

[0004] To address the above problems, this utility model provides an ITO conductive film glass.

[0005] To achieve the above objectives, this utility model is implemented through the following technical solution: an ITO conductive film glass, the structure of which includes: a positioning structure, a glass body, a sputtering layer, and an ITO conductive film. The positioning structure is bonded to the lower edge of the glass body by optical adhesive, and the glass body is covered by the ITO conductive film through the upper sputtering layer.

[0006] Furthermore, the positioning structure has a cavity that extends through the central area of ​​the frame and communicates with the center of the glass body. An adhesive layer is provided on the surface of the frame, and a positioning block is provided in the opposite direction of the adhesive layer. The frame is connected to the lower edge of the glass body using optical adhesive through the adhesive layer.

[0007] Furthermore, the frame's adhesive layer is bonded using optical adhesive through the positioning structure at the lower end of the glass body. Then, the cavity of the frame is aligned with the center of the glass body, and the positioning blocks on the back are vertically embedded into the inner edge of the relevant components for positioning.

[0008] Furthermore, the positioning structure is located at the lower edge of the glass body, and the sputtered layer of the glass body is covered by an ITO conductive film.

[0009] Furthermore, the cavity is rectangular in shape and matches the central shape of the glass body. The frame covers and bonds the lower edge of the glass body with an adhesive layer and optical glue. There are two sets of positioning blocks in the edge area of ​​the frame, which are set in a vertical direction.

[0010] Furthermore, the positioning block is also provided with an insert block, which is embedded in the center of the overlapping layer and the bottom of the vertical block. The other end of the vertical block is provided with an adsorption block, and a positioning rail is also opened in the side area to match the protruding part on the inner edge of the component.

[0011] Furthermore, the insertion block aligns with the center of the vertical block through the center of the overlapping layer, and the positioning rail on the side of the vertical block also penetrates the side of the adsorption block to form a vertical opening. Beneficial effects

[0012] Compared with the prior art, the present invention has the following beneficial effects:

[0013] 1. This utility model uses a positioning structure set at the lower edge of the glass body as a basis. The frame of the positioning structure combined with optical adhesive fixes the adhesive layer to the lower edge of the glass body. Then, the cavity will not affect the normal light transmission of the glass body according to the transparency state. Subsequently, when connecting with electronic components, the positioning block can be embedded and engaged with the inside of the electronic component to ensure that the center point of the glass body coincides with the center point of the electronic component. This replaces the original method of directly placing the glass body and applying optical adhesive, which caused the center point to shift continuously and reduced the practicality of ITO conductive glass. This further improves the bonding accuracy of ITO conductive glass.

[0014] 2. After further improvement by the positioning block, this utility model can improve the vertical accuracy of the connection with the frame surface by relying on the overlapping layer and the insertion block at the lower end of the vertical block. Then, the positioning rail on the side can be used to embed the inner protruding area of ​​the electronic component to achieve the limiting effect. At the same time, the adsorption block is used again to adsorb and fix the inner metal parts of the electronic component, which can improve the firmness of the ITO conductive glass after the positioning and prevent the shaking and instability caused by the gap of the engagement. Attached Figure Description

[0015] Figure 1 This is a schematic diagram of the structure of an ITO conductive film glass according to the present invention.

[0016] Figure 2 This is a three-dimensional structural diagram of an improved positioning structure according to the present invention.

[0017] Figure 3 This is a three-dimensional structural diagram of an improved positioning card block according to the present invention.

[0018] In the diagram: Positioning structure-1, glass body-2, sputtering layer-3, ITO conductive film-4;

[0019] Cavity-11, Frame-12, Adhesive Layer-13, Positioning Block-14;

[0020] Insert block-141, overlapping layer-142, vertical block-143, adsorption block-144, positioning rail-145. Detailed Implementation

[0021] The technical solution of this utility model will be clearly and completely described below with reference to the accompanying drawings. Obviously, the described embodiments are only some embodiments of this utility model, not all embodiments. All other embodiments obtained by those skilled in the art based on the embodiments of this utility model without creative effort are within the protection scope of this utility model.

[0022] In the description of this utility model, it should be noted that the terms "center," "upper," "lower," "left," "right," "vertical," "horizontal," "inner," and "outer," etc., indicating the orientation or positional relationship, are based on the orientation or positional relationship shown in the accompanying drawings and are only for the convenience of describing this utility model and simplifying the description, and do not indicate or imply that the device or element referred to must have a specific orientation, or be constructed and operated in a specific orientation, and therefore should not be construed as a limitation of this utility model. Furthermore, the terms "first," "second," and "third" are used for descriptive purposes only and should not be construed as indicating or implying relative importance. Example

[0023] like Figures 1-3 As shown, this utility model provides an ITO conductive film glass.

[0024] Its structure includes: a positioning structure 1, a glass body 2, a sputtering layer 3, and an ITO conductive film 4. The positioning structure 1 is bonded to the lower edge of the glass body 2 with optical adhesive, and the glass body 2 is covered by the ITO conductive film 4 through the upper sputtering layer 3.

[0025] The positioning structure 1 has a cavity 11 that runs through the central area of ​​the frame 12 and communicates with the center of the glass body 2. The surface of the frame 12 is provided with an adhesive layer 13 and a positioning block 14 is provided in the opposite direction of the adhesive layer 13. The frame 12 is connected to the lower edge of the glass body 2 by optical adhesive through the adhesive layer 13.

[0026] In this process, the adhesive layer 13 of the frame 12 is bonded together by the positioning structure 1 at the lower end of the glass body 2 using optical adhesive. Then, the cavity 11 of the frame 12 is aligned with the center of the glass body 2. Subsequently, the positioning block 14 on the back is vertically embedded into the inner edge of the relevant component for positioning.

[0027] The positioning structure 1 is located at the lower edge of the glass body 2, and the sputtered layer 3 of the glass body 2 is covered by the ITO conductive film 4.

[0028] The cavity 11 is rectangular and matches the center shape of the glass body 2. The frame 12 covers and binds the lower edge of the glass body 2 through the adhesive layer 13 and optical glue. The positioning blocks 14 are provided in two sets in the edge area of ​​the frame 12 and are set in a vertical direction.

[0029] The positioning block 14 is further provided with an insert block 141, which is embedded in the center of the overlapping layer 142 and the bottom of the vertical block 143. The other end of the vertical block 143 is provided with an adsorption block 144 and a positioning rail 145 is opened in the side area to match the protruding part on the inner edge of the component.

[0030] The insertion block 141 is aligned with the center of the vertical block 143 through the center of the overlapping layer 142, and the positioning rail 145 on the side of the vertical block 143 also penetrates the side of the adsorption block 144 to form a vertical opening.

[0031] The working principle of this utility model is explained below: The glass body 2 of the ITO conductive film glass can be formed by sputtering the ITO conductive film 4 through the upper sputtering layer 3. Then, when the ITO conductive glass is optically bonded to the electronic device, the bottom positioning structure 1 can be used for auxiliary positioning to ensure that the center point of the ITO conductive glass can be accurately superimposed on the center point of the electronic device, thereby improving the connection accuracy between the two. Subsequently, the frame 12 of the positioning structure 1 can be superimposed on the bottom edge of the glass body 2 through the adhesive layer 13, and then connected by optical adhesive, so that the cavity 11 can be aligned with the center area of ​​the glass body 2, preventing positional obstruction from affecting the use of the center of the ITO conductive glass, thereby enabling the ITO conductive film to conduct. When the glass is connected to the electronic device, the positioning block 14 can be embedded in the inner edge area of ​​the electronic device to form a snap-fit ​​connection, so that the entire ITO conductive glass can be positioned, replacing the original direct bonding which requires constant adjustment of the center point and causes center point deviation. Finally, the vertical block 143 of the positioning block 14 can be vertically connected to the frame 12 through the overlapping layer 142 and the insert block 141. Then, the adsorption block 144 of the vertical block 143 can be adsorbed into the internal metal parts of the electronic device. At the same time, the side positioning rail 145 can restrain the position of the protruding parts on the inner edge of the electronic device, which can improve the firmness of the positioning and further improve the stability and accuracy of the optical adhesive application, thus improving the practicality of the ITO conductive glass.

[0032] The technical features of the above embodiments can be combined in any way. For the sake of brevity, not all possible combinations of the technical features in the above embodiments are described. However, as long as there is no contradiction in the combination of these technical features, they should be considered to be within the scope of this specification.

[0033] Therefore, the embodiments should be considered exemplary and non-limiting in all respects, and the scope of this invention is defined by the appended claims rather than the foregoing description. Thus, it is intended that all variations falling within the meaning and scope of equivalents of the claims be included within this invention. No reference numerals in the claims should be construed as limiting the scope of the claims.

Claims

1. An ITO conductive film glass, the structure of which includes: The system comprises a positioning structure (1), a glass body (2), a sputtering layer (3), and an ITO conductive film (4). The positioning structure (1) is bonded to the lower edge of the glass body (2) with optical adhesive, and the glass body (2) is covered by the ITO conductive film (4) through the upper sputtering layer (3). The system is characterized by: The positioning structure (1) has a cavity (11) that runs through the central area of ​​the frame (12) and communicates with the center of the glass body (2). The surface of the frame (12) is provided with an adhesive layer (13) and a positioning block (14) is provided in the opposite direction of the adhesive layer (13). The frame (12) is connected to the lower edge of the glass body (2) by optical adhesive through the adhesive layer (13).

2. The ITO conductive film glass according to claim 1, characterized in that: The adhesive layer (13) of the frame (12) is bonded by the positioning structure (1) at the lower end of the glass body (2) using optical adhesive. Then the cavity (11) of the frame (12) is aligned with the center of the glass body (2). Subsequently, the positioning block (14) on the back is vertically embedded into the inner edge of the relevant component for positioning.

3. The ITO conductive film glass according to claim 1, characterized in that: The positioning structure (1) is located at the lower edge of the glass body (2) and the sputtered layer (3) of the glass body (2) is covered by an ITO conductive film (4).

4. The ITO conductive film glass according to claim 1, characterized in that: The cavity (11) is rectangular and matches the center shape of the glass body (2). The frame (12) covers and combines the lower edge of the glass body (2) with the adhesive layer (13) and optical glue. The positioning blocks (14) are provided in two sets in the edge area of ​​the frame (12) and set in the vertical direction.

5. The ITO conductive film glass according to claim 1, characterized in that: The positioning block (14) is also provided with an insert (141), which is embedded in the center of the overlapping layer (142) and the bottom position of the vertical block (143). The other end of the vertical block (143) is provided with an adsorption block (144), and a positioning rail (145) is also opened in the side area to match the protruding part on the inner edge of the component.

6. The ITO conductive film glass according to claim 5, characterized in that: The insertion block (141) is aligned with the center of the vertical block (143) through the center of the overlapping layer (142), and the positioning rail (145) on the side of the vertical block (143) also penetrates the side of the adsorption block (144) to form a vertical opening.