阅读说明：本技术 一种金属化玻璃及其制备方法 (Metallized glass and preparation method thereof ) 是由 张峰 刘风雷 于 2021-08-16 设计创作，主要内容包括：本申请提供一种金属化玻璃及其制备方法,涉及玻璃转接板技术领域,包括玻璃基体,所述玻璃基体上沿厚度方向设有多个贯通的导光孔,所述导光孔内填充有导电介质。玻璃基体沿厚度方向具备导电功能,又有光学效果,能够将光束和电极沿玻璃基体厚度方向的一面传导到另一面。通过填充的方式,能在导光孔内密实地填满导电介质,以使导电介质和玻璃基体的结合力更好,这样得到的金属化玻璃更稳定；且在导光孔内填实导电介质,能使形成的金属化玻璃的气密性更好,能避免在电镀铜产生的空心问题,避免漏气现象,也能提高金属化玻璃的导电率,金属化玻璃的整体性能得到提升；填充的方式加工流程简单,效率高,成本低,对环境污染小,符合环保要求。(The application provides a metallized glass and a preparation method thereof, relates to the technical field of glass adapter plates, and comprises a glass substrate, wherein a plurality of through light guide holes are formed in the glass substrate along the thickness direction, and conductive media are filled in the light guide holes. The glass substrate has a conductive function along the thickness direction, has an optical effect and can conduct light beams and electrodes to the other surface along one surface of the glass substrate in the thickness direction. By the filling mode, the conductive medium can be densely filled in the light guide hole, so that the bonding force between the conductive medium and the glass substrate is better, and the obtained metallized glass is more stable; the conductive medium is filled in the light guide hole, so that the formed metalized glass has better air tightness, the hollow problem caused by copper electroplating can be avoided, the air leakage phenomenon is avoided, the electric conductivity of the metalized glass can be improved, and the overall performance of the metalized glass is improved; the filling mode has simple processing flow, high efficiency, low cost and little environmental pollution, and meets the requirement of environmental protection.)

1. A metallized glass, comprising: the glass substrate is provided with a plurality of through light guide holes along the thickness direction, and the light guide holes are filled with conductive media.

2. The metallized glass of claim 1, wherein a conductive electrode is disposed on a surface of said conductive medium along said thickness direction, said conductive electrode being in electrical communication with said conductive medium.

3. The metallized glass of claim 1, wherein the end face of the conductive medium is flush with the surface of the glass substrate.

4. The metallized glass of claim 2, wherein the conductive medium and the conductive electrode are the same material.

5. The metallized glass of claim 4, wherein said conductive medium and said conductive electrode are silver paste.

6. A method of making a metallized glass, comprising:

a plurality of through holes are formed in the thickness direction of the glass substrate;

filling a conductive medium in the through hole;

and sintering the glass substrate filled with the conductive medium according to a preset time.

7. The method of claim 6, wherein after the sintering the glass substrate filled with the conductive medium for a predetermined time, the method further comprises:

and printing a conductive electrode on the surface of the conductive medium in the thickness direction to conduct the conductive electrode and the conductive medium.

8. The method according to claim 6, wherein the filling of the conductive medium in the via hole comprises:

placing the glass substrate on a ceramic platform;

placing filter paper between the glass substrate and the ceramic platform;

and filling a conductive medium in the through hole by adopting a screen printing mode, and providing a negative pressure space for the surface of the glass substrate on one side of the ceramic platform far away from the glass substrate.

9. The method according to claim 6, wherein the conductive medium is silver paste, and the sintering the glass substrate filled with the conductive medium for a predetermined time comprises:

sintering at 350-650 ℃ for 1-2 h.

10. The method for producing a metallized glass according to claim 7, wherein said method further comprises, before printing a conductive electrode on a thickness-direction surface of said conductive medium:

and grinding and polishing along the thickness direction of the glass substrate to enable the end face of the conductive medium to be flush with the surface of the glass substrate.

Technical Field

The application relates to the technical field of glass adapter plates, in particular to metallized glass and a preparation method thereof.

Background

The glass with the through holes is metallized, so that the functions of conducting electricity and guiding light can be achieved. The glass produced is commonly used in mobile phone type electronic devices.

In the current industry, through hole glass metallization mainly adopts electrolytic copper plating, wherein the electrolytic copper plating adopts a mode of firstly sputtering a seed layer in a glass through hole and then growing copper on the seed layer. This approach has the following problems: the firmness is unstable, and the falling-off phenomenon is easy to occur; the air tightness is poor, and the situation that the through holes are not completely filled after electroplating often exists, so that the air leakage exists on the front side and the back side of the glass; the seed layer is needed to be used as a connecting layer of glass and copper, so that the conductivity is reduced; the glass is a poor conductor, so a seed layer needs to be sputtered on the glass by adopting a sputtering process before electroplating, and the processing flow is complicated; but also has great pollution to the electroplating environment and is greatly limited by regions.

Disclosure of Invention

The embodiment of the application aims to provide the metallized glass and the preparation method thereof, which can improve the overall performance of the metallized glass, and have the advantages of simple preparation process and small pollution.

An aspect of the embodiment of the application provides a metalized glass, including the glass base member, be equipped with a plurality of leaded light holes that link up along the thickness direction on the glass base member, the leaded light downthehole packing has the conductive medium.

The glass substrate has a conductive function along the thickness direction and an optical effect, can conduct light beams and electrodes to the other surface along one surface of the glass substrate in the thickness direction, and can conduct light and electricity between the top surface and the bottom surface of the glass substrate.

Optionally, a conductive electrode is disposed on a surface of the conductive medium along the thickness direction, and the conductive electrode is in conduction with the conductive medium.

The conductive medium can conduct electricity, and electrode connection can be conveniently formed through the conductive electrode, so that the metallized glass is electrically connected with other electric devices.

Optionally, the end face of the conductive medium is flush with the surface of the glass substrate, so that the surface of the glass substrate is flat, and the conductive medium is convenient to match with other electric devices.

Optionally, the conductive medium and the conductive electrode are made of the same material, so that the conductive medium and the conductive electrode can be matched, and the conductivity is high.

Optionally, the conductive medium and the conductive electrode are both silver paste. The silver colloid combines the conductive particles together through the bonding action of the matrix resin to form a conductive path, thereby realizing the conductive connection between the conductive medium and the conductive electrode.

In another aspect of the embodiments of the present application, there is provided a method for preparing a metallized glass, including: a plurality of through holes are formed in the thickness direction of the glass substrate; filling a conductive medium in the through hole; and sintering the glass substrate filled with the conductive medium according to a preset time.

The mode of filling the conductive medium, the processing flow is simple, and the mode of filling makes the compactness of conductive medium in the light guiding hole good, and the cohesion of conductive medium and glass substrate is good to the firmness of the metallized glass who forms is stable, and the gas tightness is good, and the conductivity is high, can improve metallized glass's wholeness ability. Moreover, the filling mode has little pollution to the environment, can effectively play a role in environmental protection and meet the requirement of environmental protection.

Optionally, after the sintering the glass substrate filled with the conductive medium for the preset time, the method further includes: and printing a conductive electrode on the surface of the conductive medium in the thickness direction to conduct the conductive electrode and the conductive medium.

The conductive electrode is used for conveniently and electrically connecting other electric devices, so that the metalized glass forms electrode connection with other electric devices through the conductive electrode to transmit electric signals.

Optionally, the filling of the conductive medium in the through hole includes: placing the glass substrate on a ceramic platform; placing filter paper between the glass substrate and the ceramic platform; and filling a conductive medium in the through hole by adopting a screen printing mode, and providing a negative pressure space for the surface of the glass substrate on one side of the ceramic platform far away from the glass substrate.

The filter paper and the ceramic platform are breathable, air in the light guide hole is pumped away in a vacuum mode through the filter paper and the ceramic platform, the silver colloid can be pumped to one side, away from the glass substrate, of the ceramic platform, and the silver colloid is dense in the light guide hole, so that the silver colloid can be filled in the light guide hole.

Optionally, the conductive medium is silver paste, and sintering the glass substrate filled with the conductive medium according to a preset time includes: sintering at 350-650 ℃ for 1-2 h.

Through high-temperature sintering, the silver colloid and the glass substrate are integrated, so that the binding force is improved, and the combination of the silver colloid and the glass substrate is more stable.

Optionally, before the printing the conductive electrode on the surface of the conductive medium in the thickness direction, the method further includes: and grinding and polishing along the thickness direction of the glass substrate to enable the end face of the conductive medium to be flush with the surface of the glass substrate.

After the conductive medium is filled and sintered, grinding and polishing treatment are needed to make the surface of the glass substrate smooth.

The metalized glass and the preparation method thereof provided by the embodiment of the application have the advantages that the plurality of light guide holes are formed in the glass substrate, the light guide holes are formed in the thickness direction of the glass substrate and are communicated, and light can be guided to the glass substrate along the thickness direction through the light guide holes; the light guide holes are filled with conductive media which are used for enabling the glass substrate to conduct electricity along the thickness direction; the glass substrate has a conductive function along the thickness direction, has an optical effect and can conduct light beams and electrodes to the other surface along one surface of the glass substrate in the thickness direction. By the filling mode, the conductive medium can be densely filled in the light guide hole, so that the bonding force between the conductive medium and the glass substrate is better, and the obtained metallized glass is more stable; the conductive medium is filled in the light guide hole, so that the formed metalized glass has better air tightness, the hollow problem caused by copper electroplating can be avoided, the air leakage phenomenon is avoided, the electric conductivity of the metalized glass can be improved, and the overall performance of the metalized glass is improved; meanwhile, the filling mode has the advantages of simple processing flow, high efficiency, low cost and small environmental pollution, and meets the requirement of environmental protection.

Furthermore, the preparation method of the metallized glass comprises the steps of forming a plurality of through holes in the thickness direction of the glass substrate; filling a conductive medium in the through hole; and sintering the glass substrate filled with the conductive medium according to a preset time. The filling mode enables the conductive medium to be directly sintered and melted with the glass substrate into a whole under high-temperature sintering, the formed metallized glass has good air tightness, is filled in a solid mode, avoids air leakage at the joint of the conductive medium and the glass substrate, and is simple in processing flow, high in efficiency and small in pollution.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present application, the drawings that are required to be used in the embodiments of the present application will be briefly described below, it should be understood that the following drawings only illustrate some embodiments of the present application and therefore should not be considered as limiting the scope, and that those skilled in the art can also obtain other related drawings based on the drawings without inventive efforts.

FIG. 1 is a schematic structural view of a prior art glass metallization;

FIG. 2 is a schematic view of the structure of the metallized glass provided in the present embodiment;

FIG. 3 is a flow chart of a method for making a metallized glass as provided in the present example;

FIG. 4 is a process diagram of a method for preparing a metallized glass provided in this example.

Icon: 10-glass; 11-voids; 12-a seed layer; 13-electroplating layer; 101-a glass substrate; 102-a conductive medium; 201-a ceramic platform; 202-filter paper; 203-a screen; 204-scraper.

Detailed Description

The technical solutions in the embodiments of the present application will be clearly and completely described below with reference to the drawings in the embodiments of the present application.

In the description of the present application, it should be noted that the terms "inside", "outside", and the like indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings or orientations or positional relationships that the products of the application usually place when using, and are only used for convenience in describing the present application and simplifying the description, but do not indicate or imply that the devices or elements that are referred to must have a specific orientation, be constructed in a specific orientation, and operate, and thus, should not be construed as limiting the present application. Furthermore, the terms "first," "second," and the like are used merely to distinguish one description from another, and are not to be construed as indicating or implying relative importance.

It should also be noted that, unless expressly stated or limited otherwise, the terms "disposed" and "connected" are to be construed broadly, e.g., as meaning fixedly connected, detachably connected, or integrally connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meaning of the above terms in the present application can be understood in a specific case by those of ordinary skill in the art.

In a three-dimensional stacked chip structure, a glass interposer is increasingly a hot point of research due to its excellent electrical insulation, low manufacturing cost and good process compatibility, but the reliable metal filling on the glass 10 is a challenge, and at present, there are mainly processes such as electroplating copper, etc., as shown in fig. 1, the manufacturing method is to sputter a seed layer 12 on the glass 10, then electroplate copper on the seed layer 12 by an electroplating process to form an electroplated layer 13, then planarize the bump by a cold working process, sputter the seed layer 12 again in the area where the electrode needs to be grown, and then perform secondary electroplating copper.

The method has complex processing flow, and the seed layer 12 needs to be sputtered on the glass 10 by adopting a sputtering process before electroplating because the glass 10 is a poor conductor; the firmness is unstable, the problem of reliability commonly exists in the current industry for electroplating glass 10, and the glass is easy to fall off after being subjected to acid and alkali resistance treatment; the airtightness is poor, the electroplating copper adopts a mode of growing copper on the seed layer 12, and the situation that the gap 11 exists in the middle (the gap is not completely filled) is often existed after the electroplating, so that the air leakage exists on the front side and the back side of the glass 10; since the seed layer 12 is required to be used as a connection layer between the glass 10 and the plating layer 13, the seed layer 12 is likely to be present between the copper in the hole of the glass 10 and the copper electrode on the surface, and the seed layer 12 would separate the connection between the two, resulting in a decrease in conductivity.

On this basis, this application embodiment provides a metallized glass, adopts the direct packing of silver colloid, and the electrode adopts screen printing's mode directly to print the silver colloid on glass base member 101, and the silver colloid of electrode is done with the surface to the silver colloid lug connection of filling in the through-hole, avoids the problem that the resistivity reduces.

Specifically, referring to fig. 2, an embodiment of the present application provides a metalized glass, which includes a glass substrate 101, wherein a plurality of light guide holes are formed in the glass substrate 101 along a thickness direction, and conductive media 102 are filled in the light guide holes.

The glass substrate 101 is provided with a plurality of light guide holes, the light guide holes are arranged in the thickness direction and are communicated, and the conductive medium 102 is filled in the light guide holes, so that the glass substrate 101 has the light guide and conductive characteristics, and the glass substrate 101 can guide and conduct light between the top surface and the bottom surface of the glass substrate 101 in the thickness direction.

Compared with the prior art, the method for filling the conductive medium 102 is adopted, the processing flow is simple, the conductive medium 102 is enabled to be good in compactness in the light guide hole in the filling mode, the bonding force between the conductive medium 102 and the glass substrate 101 is good, the formed metallized glass is stable in firmness, good in air tightness and high in conductivity, and the overall performance of the metallized glass can be improved. Moreover, with the increasingly strong demand on environmental protection, the production process is required to have less environmental pollution as much as possible, and compared with the electroplating process, the method for filling the conductive medium 102 is adopted, so that the method has less environmental pollution, can effectively play a role in environmental protection, and meets the requirement on environmental protection.

According to the metalized glass provided by the embodiment of the application, the glass substrate 101 is provided with the plurality of light guide holes, the light guide holes are arranged along the thickness direction of the glass substrate 101 and are communicated, and light can be guided along the thickness direction of the glass substrate 101 through the light guide holes; the light guide holes are filled with conductive media 102 for enabling the glass substrate 101 to conduct electricity along the thickness direction; the glass substrate 101 has a conductive function in the thickness direction and an optical effect, and can conduct a light beam and an electrode to one surface of the glass substrate 101 in the thickness direction to the other surface. By the filling mode, the conductive medium 102 can be densely filled in the light guide hole, so that the bonding force between the conductive medium 102 and the glass substrate 101 is better, and the obtained metallized glass is more stable; the conductive medium 102 is filled in the light guide hole, so that the formed metalized glass has better air tightness, the hollow problem caused by copper electroplating can be avoided, the air leakage phenomenon is avoided, the conductivity of the metalized glass can be improved, and the overall performance of the metalized glass is improved; meanwhile, the filling mode has the advantages of simple processing flow, high efficiency, low cost and small environmental pollution, and meets the requirement of environmental protection.

Further, in order to facilitate electrical connection between the metallized glass and other electrical devices, a conductive electrode (not shown in fig. 2) is provided on a surface of the conductive medium 102 in the thickness direction, and the conductive electrode is in electrical conduction with the conductive medium 102.

The conductive medium 102 is itself capable of conducting electricity, but electrode connections can be conveniently formed through the conductive electrodes to electrically connect the metallized glass to other electrical devices.

The end face of the conductive medium 102 is flush with the surface of the glass substrate 101, and after the conductive medium 102 is filled in the light guide hole of the glass substrate 101, the end face of the conductive medium 102 in the thickness direction needs to be flush with the surface of the glass substrate 101, so that the surface of the glass substrate 101 is flat, and the conductive medium can be conveniently matched with other electric devices.

The conductive medium 102 is further provided with a conductive electrode which is higher than the surface of the glass substrate 101, but the height of the conductive electrode is extremely small and can be ignored.

In order to match the conductive medium 102 and the conductive electrode, the conductive medium 102 and the conductive electrode are made of the same material to increase the conductivity. In particular, the conductive medium 102 and the conductive electrode may both be silver paste. The silver adhesive combines the conductive particles together through the bonding action of the matrix resin to form a conductive path, so that the conductive connection of the bonded material is realized.

The matrix resin of the silver colloid is an adhesive, can select proper curing temperature for filling and bonding, and can avoid material deformation, thermal damage of electronic devices and formation of internal stress which are possibly caused by an electroplating mode. Furthermore, due to the rapid development of miniaturization and miniaturization of electronic components and high density and high integration of printed circuit boards, conductive silver paste can be made into paste, realizing very high line resolution. The silver colloid filling process is simple and easy to operate, can improve the production efficiency and also avoids the environmental pollution caused by the electroplating mode.

The metalized glass provided by the embodiment of the application can be used as a glass adapter plate, and is applied to a mobile phone screen as an example, the metalized glass is arranged below the screen of a mobile phone, light is guided through the light guide hole, so that the metalized glass has an optical effect, and light beams can be transmitted from one side of the glass substrate 101 to the other side of the glass substrate to enable a display picture to be seen from the screen; meanwhile, the conductive medium 102 is metallized glass, which has a conductive effect, and can form electrode connection on electric devices on two sides of the metallized glass, so that electric signal transmission is performed, and transmission with a communication function is achieved.

In summary, in the metalized glass provided in the embodiment of the present application, the glass substrate 101 is provided with the light guide hole along the thickness direction, and the conductive medium 102 is filled in the light guide hole, so that the glass substrate 101 has a conductive function and an optical effect; the current and the light beam can be conducted from one side to the other side of the glass substrate 101 in the thickness direction. Furthermore, a conductive electrode may be disposed on the conductive medium 102 to form an electrical connection with other electrical devices, and the conductive medium 102 and the conductive electrode may both be made of silver paste. The formed metallized glass has simple processing flow, and can finish the processing of products only by a small amount of equipment; the glass substrate 101 is stable in firmness and good in binding force, can be filled with sintered silver colloid, is filled with filler similar to glass powder, and is directly sintered and melted with the glass substrate 101 into a whole under high-temperature sintering; the air tightness is good, the sintered silver colloid is adopted for metallization filling, on one hand, the sintered silver colloid can be sintered with the glass substrate 101 into a whole, air leakage at the joint of the sintered silver colloid and the glass substrate 101 is avoided, and meanwhile, the sintered silver colloid is filled in a full solid state, so that the problem of middle hollow generated in the process of similar copper electroplating is avoided; the conductivity is high, the sintered silver paste is directly filled, the conductive electrode is directly printed on the conductive medium 102 of the glass substrate 101 in a screen printing mode, the sintered silver paste filled in the light guide hole is directly connected with the sintered silver paste on the surface of the conductive electrode, and the problem of resistivity reduction is avoided.

On the other hand, referring to fig. 3, an embodiment of the present application further provides a method for preparing a metallized glass, which includes:

s100: a plurality of through holes are formed in the glass base 101 in the thickness direction.

The glass drilling mainly comprises a laser ablation method, a dry etching method, CNC drilling, a wet etching method, laser-assisted wet etching method and the like, the metalized glass provided by the embodiment of the application is very little affected by the drilling mode, and any drilling mode can be used for the glass substrate 101 in the embodiment of the application; the aperture after punching can be 50um-1000um, and the thickness of the glass substrate 101 is consistent with that of the through hole, and can be 0.1mm-10 mm.

The through hole is a light guide hole, and can be used for guiding light, so that the light beam is transmitted from one side of the glass substrate 101 to the other side through the through hole along the thickness direction.

S110: the via is filled with a conductive medium 102.

The mode of filling the conductive medium 102 enables the metallized glass to have a conductive function, the process is simple, the light guide hole can be effectively compacted, and the phenomenon that gaps are generated after the conductive medium 102 is filled in the light guide hole is avoided, so that the air tightness of the metallized glass is affected. Meanwhile, toxic and harmful substances are not generated in the filling process, and are not discharged into the atmosphere, so that the environment pollution is small, the environment-friendly effect can be effectively achieved, and the environment-friendly requirement is met.

Filling the conductive medium 102 is performed by the following steps:

as shown in fig. 4, S111: the glass substrate 101 is placed on the ceramic stage 201.

The ceramic material has a honeycomb structure inside, so the ceramic material is breathable, and when the through hole is filled with the conductive medium 102, the glass substrate 101 is placed on the ceramic platform 201.

S112: filter paper 202 is placed between the glass substrate 101 and the ceramic platform 201.

A layer of filter paper 202 is arranged between the glass substrate 101 and the ceramic platform 201.

S113: and filling the through hole with the conductive medium 102 by adopting a screen printing mode, and providing a negative pressure space for the surface of the glass base body 101 at the side of the ceramic platform 201 far away from the glass base body 101.

The screen printing adopts a CCD (charge coupled device) alignment mode, the silver paste is filled in the area needing to be filled, namely the through hole, through the scraper 204, and the area on the glass substrate 101 which is not filled is shielded by the screen 203; in the screen printing process, one side of the ceramic platform 201, which is far away from the glass substrate 101, is vacuumized, and the filter paper 202 and the ceramic platform 201 are breathable, so that air in the through hole is vacuumized away through the filter paper 202 and the ceramic platform 201, the silver colloid can be pumped to one side of the ceramic platform 201, which is far away from the glass substrate 101, and is dense in the through hole, and the silver colloid is favorably filled in the through hole.

S120: the glass substrate 101 filled with the conductive medium 102 is sintered for a predetermined time.

After the silver colloid fills the through hole, the glass substrate 101 is placed in a sintering furnace at 350-650 ℃ to be sintered for 1-2 h, so that the silver colloid and the glass substrate 101 are integrated. Through high-temperature sintering, the bonding force between the silver colloid and the glass substrate 101 is improved, and the bonding between the silver colloid and the glass substrate is firmer and more stable.

The specific sintering temperature and time are determined according to the characteristics of the silver paste and the melting point of the glass substrate 101, and when other materials are used for the conductive medium 102, the sintering temperature and time may be set according to the specific materials, which is not particularly limited in the embodiments of the present application.

After the conductive medium 102 is formed on the glass substrate 101, the glass substrate 101 has a conductive function, and an electric current or an electric signal is transmitted from one side to the other side in the thickness direction of the glass substrate 101 through the conductive medium 102 to be electrically transmitted.

S130: and grinding and polishing are performed in the thickness direction of the glass base 101 so that the end face of the conductive medium 102 is flush with the surface of the glass base 101.

After sintering, slight bulges or depressions are formed on the surface of the glass substrate 101, the surface of the redundant silver colloid and the surface of the glass substrate 101 are subjected to planarization treatment by adopting grinding and polishing processes, and the bulges or depressions on the surface are smaller than 3um after treatment.

S140: a conductive electrode is printed on the surface of the conductive medium 102 in the thickness direction, and the conductive electrode and the conductive medium 102 are electrically connected.

The conducting electrode can be conveniently and electrically connected with other electric devices, so that the metalized glass forms electrode connection with other electric devices through the conducting electrode to transmit electric signals.

The conductive electrode is on the end face of the conductive medium 102, and its height is small, in the order of micrometers, and therefore its height is negligible.

And (3) performing silver paste printing on the end face of the conductive medium 102 by adopting a screen printing process to manufacture a corresponding conductive level, wherein the conductive level can be made of the same silver paste material as the conductive medium 102 or other conductive materials similar to the silver paste.

In summary, according to the preparation method of the metalized glass provided by the embodiment of the present application, a hole is punched in the glass substrate 101 to form a light guide hole, then, sintered silver paste is filled in the light guide hole of the glass substrate 101 in a screen printing manner, the basic operation manner is that the glass substrate 101 with the light guide hole is placed on the air-permeable ceramic platform 201, a layer of filter paper 202 is arranged between the glass substrate 101 and the ceramic platform 201, a CCD alignment manner is adopted, the silver paste is placed in an area where the silver paste needs to be filled, and an unfilled area is shielded by the screen 203; in the screen printing process, air in the light guide hole is pumped away in a vacuum mode, and the silver colloid is filled in the light guide hole; after the silver colloid is filled, the glass substrate 101 is placed in a sintering furnace at 350-650 ℃ for sintering, so that the silver colloid and the glass substrate 101 are integrated into a whole; after sintering, slight bulges or depressions are formed on the surface of the glass substrate 101, and the surface of the redundant silver colloid and the glass substrate 101 are flattened through grinding and polishing; finally, a screen printing process is adopted, silver paste printing is carried out on the surface of the conductive medium 102 to form a corresponding conductive level, and the conductive electrode is conducted with the conductive medium 102 and used for enabling the metalized glass and other electric devices to form electrode connection for electric transmission.

The above description is only an example of the present application and is not intended to limit the scope of the present application, and various modifications and changes may be made by those skilled in the art. Any modification, equivalent replacement, improvement and the like made within the spirit and principle of the present application shall be included in the protection scope of the present application.