CN203187549U - Vacuum glass with metallic edge sealing structure - Google Patents

Vacuum glass with metallic edge sealing structure Download PDF

Info

Publication number
CN203187549U
CN203187549U CN 201320087986 CN201320087986U CN203187549U CN 203187549 U CN203187549 U CN 203187549U CN 201320087986 CN201320087986 CN 201320087986 CN 201320087986 U CN201320087986 U CN 201320087986U CN 203187549 U CN203187549 U CN 203187549U
Authority
CN
China
Prior art keywords
glass
metal
vacuum glass
vacuum
edge sealing
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Expired - Lifetime
Application number
CN 201320087986
Other languages
Chinese (zh)
Inventor
刘小根
包亦望
许海凤
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
Beijing Synergy Vacuum Glazing Technology Co Ltd
China Building Material Test and Certification Group Co Ltd
Original Assignee
Beijing Synergy Vacuum Glazing Technology Co Ltd
China Building Material Test and Certification Group Co Ltd
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by Beijing Synergy Vacuum Glazing Technology Co Ltd, China Building Material Test and Certification Group Co Ltd filed Critical Beijing Synergy Vacuum Glazing Technology Co Ltd
Priority to CN 201320087986 priority Critical patent/CN203187549U/en
Application granted granted Critical
Publication of CN203187549U publication Critical patent/CN203187549U/en
Anticipated expiration legal-status Critical
Expired - Lifetime legal-status Critical Current

Links

Images

Landscapes

  • Joining Of Glass To Other Materials (AREA)

Abstract

The utility model relates to vacuum glass with a metallic edge sealing structure. The vacuum glass comprises two original plate glass pieces, a plurality of supports and a sealing layer, wherein two metallic transition layers are respectively cured on sealing faces of the two original plate glass pieces, a metallic layer formed by low-melting-point metal solder is sealed between the two metallic transition layers in a fusion manner, and the sealing layer is formed by the metallic transition layers and the metallic layer which are sealed in the fusion manner. The vacuum glass disclosed by the utility model uses the metallic edge sealing structure, so that the structure is novel, and the vacuum performance is good; and vacuum glass without exhaust holes and toughened vacuum glass can also be provided, so that the application range of the vacuum glass is broadened.

Description

The vacuum glass of tool metal edge sealing structure
Technical field
The utility model belongs to glass deep process technology field, relates to a kind of vacuum glass, refers to adopt metallic substance that glass edge is carried out the vacuum glass structure that hermetic seal forms especially.
Background technology
Vacuum glass is a kind of glasswork with good heat-insulation and heat-preservation, has obtained widespread use in fields such as building doors and windows, curtain wall and household electrical appliances.
Previously, polymer organic macromolecular material sealing glass such as people's structural silicone adhesive commonly used, PC, PVB, SGP.Though, this class material and glass have good adhesiveproperties and sealing property, but for the vacuum glass that requires to keep permanent high vacuum, this class material obviously can not be used for the vacuum glass hermetic seal, because this class organic materials has higher gas leak rate, itself also can in use discharge gas, thereby vacuum glass vacuum tightness is just sharply descended in a short time, can't reach permanent desirable energy-saving effect.
At present, the making of vacuum glass is to adopt two sheet glass peripheries use frit seal, the gap between two sheet glass is evacuated, and in establish a plurality of upholders, its vacuum tightness requirement reaches 10 -2More than the Pa.Have typical vacuum glass structure as shown in Figure 1, comprising two sheet glass 101, a plurality of upholder 102, frit seal layer 103, aspirating hole 104.
Low melting glass has the heat good with glass, power matching parameter, can realize excellent sealing performance.But be used for the low melting glass fusing point of vacuum glass edge sealing material generally between 420 ℃~450 ℃, so high sealing temperature causes great sealing-in energy consumption on the one hand, on the other hand, if use toughened glass as former, the toughened glass surface stress can be retreated basically fully under this sealing temperature, has greatly influenced the mechanical property of vacuum glass.
At present, also be not suitable for preparing the low-melting point sealing glass of toughened vacuum glass on the market, therefore, the preparation toughened vacuum glass has run into technical bottleneck.By present standard, conventional vacuum glass can not be as safety glass applications on building curtain wall, and this has just limited the commercial application of vacuum glass greatly.On the other hand, low melting glass all also has plumbous composition in the main product at present, and life-time service obviously can work the mischief to human body and environment, and obviously, the unleaded technology of preparing of vacuum glass is demanded development urgently.
The utility model content
At above-mentioned practical problems, the purpose of this utility model provides a kind of vacuum glass of novel tool metal edge sealing structure.
The utility model is achieved by following technical solution:
A kind of vacuum glass of tool metal edge sealing structure, comprise former of two sheet glass, a plurality of upholder and sealing layer, wherein: on the sealing surface of former of two sheet glass, be solidified with the layer of metal transition layer separately, fusion is sealed with the metal level that the low melting point metal scolder forms between two intermediate metals, and the intermediate metal and the metal level that are sealed by fusion form described sealing layer.
Described intermediate metal is metal paste sintering curing layer.
Described intermediate metal is the metal-plated rete.Described metal-plated rete is silverskin or copper film.
Described low melting point metal scolder is that fusing point is at the brazing metal of 130 ° of C~400 ° C.Described low melting point metal scolder is the soldering paste that has soldering flux, or weld tabs (itself is not with soldering flux, joins soldering flux when needing in addition).
Former of described sheet glass is a kind of in simple glass, half tempered glass or the toughened glass.
Described vacuum glass is provided with aspirating hole.
Do not establish aspirating hole on the described vacuum glass.
The vacuum glass of described tool metal edge sealing structure is toughened vacuum glass.
Adopt above technical scheme, the vacuum glass good airproof performance that the utility model provides, sealing strength height; Sealing-in at a lower temperature (about 130 ℃~400 ℃), and realized unleadedly in the vacuum glass manufacturing, therefore, the design of this vacuum glass is produced significant to reducing production costs, realize industrialization.Also have, the utility model can provide real no aspirating hole vacuum glass and toughened vacuum glass, has widened the vacuum glass range of application.
Description of drawings
Fig. 1 is existing vacuum glass structural representation;
Fig. 2 A is metal edge sealing platform sealing-in vacuum glass edge sealing of the present utility model position biopsy cavity marker devices synoptic diagram;
Fig. 2 B is metal edge sealing faulting of slab ends sealing-in vacuum glass edge sealing of the present utility model position biopsy cavity marker devices synoptic diagram;
Fig. 3 A has the vacuum glass limit portion low melting point metal scolder of soldering flux welding process to lay synoptic diagram;
Fig. 3 B forms one deck low-melting-point metal layer synoptic diagram for there being the soldering flux welding process to freeze at the metal transfer laminar surface;
Fig. 3 C has two sheet glass of the soldering flux welding process compound back of the low-melting-point metal layer portion biopsy cavity marker devices synoptic diagram that all freezed;
Fig. 3 D has the only sheet glass of the soldering flux welding compound back of the low-melting-point metal layer portion biopsy cavity marker devices synoptic diagram that freezed;
Fig. 4 lays limit portion biopsy cavity marker devices synoptic diagram for the vacuum glass limit portion low melting point metal weld tabs of no soldering flux welding;
Fig. 5 A is the metal edge sealing vacuum glass structural representation of band aspirating hole;
Fig. 5 B is not for the metal edge sealing vacuum glass structural representation of aspirating hole.
Embodiment
Below in conjunction with accompanying drawing embodiment of the present utility model is further described.
Fig. 2 A, Fig. 2 B are the metal edge sealing structure synoptic diagram of the utility model vacuum glass, and wherein Fig. 2 A is platform sealing structure exemplary plot, and Fig. 2 B is faulting of slab ends sealing structure exemplary plot.In these two kinds of structures, all be on the sealing-in surface of former 101 of two sheet glass, be solidified with layer of metal transition layer 201 earlier, between two intermediate metals 201, fuse welded seals with low melting point metal scolder 202 again, thereby form the sealed structure of vacuum glass.
Specifically, in platform sealing structure shown in Fig. 2 A, former 101 of two sheet glass are justified margin and place, sealing-in place in the edge of two glass, at the lower surface of upper flat plate original sheet glass 101 and the upper surface of former 101 of sheet glass down, all being solidified with layer of metal transition layer 201, two intermediate metals 201 is oppositely arranged; Owing between two intermediate metals 201, can have certain interval, so the sheet low-melting-point metal layer welded seal that is fused into by low melting point metal scolder 202 at gap location.
In the faulting of slab ends sealing structure shown in Fig. 2 B, be former 101 of two sheet glass to be edge dislocation place, in sealing-in place of two glass, at the upper surface of former 101 of a sheet glass, and the side elevation of former 101 of another sheet glass, all be solidified with layer of metal transition layer 201; Because two intermediate metals 201 are vertical setting, so the trilateral low-melting-point metal layer that fuses into low melting point metal scolder 202 between two intermediate metals 201 is with two intermediate metals, 201 welded seals.
It below only is the vacuum glass sealing structure that has exemplified platform and faulting of slab ends, in fact for the vacuum glass of any sealing-in shape, its aim all is to be solidified with layer of metal transition layer 201 respectively on the sealing surface of former 101 of two sheet glass, fuses into low-melting-point metal layer with two sheet glass welded seals by low melting point metal scolder 202 again between two intermediate metals 201.
Above-mentioned vacuum glass is except having the metal edge sealing structure, all the other structures are identical with existing vacuum glass, namely, can offer aspirating hole 104 or do not offer (aspirating hole 104 is sealed up) after glass vacuumizes on glass, and between two original sheet glasses, place a plurality of upholder 102(referring to Fig. 1 at interval).Especially, the utility model can really provide the vacuum glass of not offering aspirating hole.
The commercially available metal paste sintering of can selecting of above-mentioned intermediate metal 201 forms, and also can be metal coating.
Above-mentioned low melting point metal scolder 202 can be selected commercially available soldering paste (having soldering flux) or weld tabs (no soldering flux own can be bought rations soldering flux in addition).Low melting point metal scolder 202 fusing points are generally between 130 ° of C~400 ° C.
Former 101 of above-mentioned sheet glass can be simple glass, half tempered glass or toughened glass.Especially, the utility model can select toughened glass to prepare to be difficult in the prior art toughened vacuum glass that obtains for use.
Below describe in detail the curing mode of intermediate metal 201 and how with 202 fusions of low melting point metal scolder on intermediate metal 201, form good airtight welding, thereby obtain the vacuum glass of the utility model metal edge sealing structure.
One, the preparation of intermediate metal 201:
Adopt methods such as electroless plating, plating, vacuum plating to plate metallic membrane at first at the sealing-in surface of former 101 of sheet glass coated with metal slurry, or on the sealing-in surface of glass.
Glass for the matel coated slurry, as prepare tempering or half tempered vacuum glass (former 101 of sheet glass is tempering or half tempered glass), then put into the annealing furnace sintering, in the process that glass is sintered, metal paste also is sintered at glass surface, forms layer of metal transition layer 201 thus.As preparing conventional vacuum glass, metal paste then adopts local heating method sintering such as flame heating, LASER HEATING, induction heating on glass surface.This sintering process adopts common process.
For the glass of metal-coated membrane, do not need to carry out sintering and just can directly form the intermediate metal 201 that one deck and glass closely link to each other.This coating process adopts common process.
Two, the airtight welding of low melting point metal scolder 202 and intermediate metal 201:
In general, two sheet glass that prepare intermediate metal 201 are put on request, (putting position is decided on demand, such as putting by the position of Fig. 2 A or 2B), low melting point metal scolder 202 cloth are placed on the weld, low melting point metal scolder 202 is heated (the control Heating temperature is a little more than the fusing point of scolder) fusing, scolder and intermediate metal are welded together, thereby realize the hermetic seal all around of vacuum glass.
Whether have soldering flux according to employed low melting point metal scolder 202, the utility model provides the mode of two kinds of low melting point metal scolders 202 with the airtight welding of intermediate metal 201:
Mode one: Fig. 3 A~3D has shown the method that the low melting point metal of soldering flux scolder 202 and intermediate metal 201 airtight welding are arranged.
At first, place the low melting point metal scolder 202 that has soldering flux at the glass surface for preparing intermediate metal 201, low melting point metal scolder 202 can be soldering paste or weld tabs (must apply a certain amount of soldering flux at weld tabs when using weld tabs in advance, itself contain soldering flux in the soldering paste during with soldering paste), weld tabs directly is placed on the intermediate metal 201 of monolithic glass, soldering paste is paste, directly be coated on the intermediate metal 201 of glass (referring to Fig. 3 A) width that low melting point metal scolder 202 consumptions optionally weld and thickness and decide;
Then, the low melting point metal scolder 202 that places is heated until fusing, heating can be adopted stove medium wave peak weldering, or local heating methods such as induction heating, LASER HEATING, flame heating, electric stove wire heating carry out, and the control Heating temperature is a little more than the fusing point of scolder.Namely form one deck low-melting-point metal layer 301(referring to Fig. 3 B on intermediate metal 201 surfaces after 202 coolings of low melting point metal scolder), at this moment, low-melting-point metal layer 301 is combined closely with intermediate metal 201;
Can the soldering flux that not be evaporated completely be arranged at low-melting-point metal layer 301 remained on surface in the above-mentioned technological process, because residual soldering flux has a strong impact on the permanent vacuum tightness of vacuum glass, therefore, must carry out strictness to low-melting-point metal layer 301 remained on surface soldering fluxs this moment and clean, purging method can adopt washing or alcohol wash according to the soldering flux type;
In this mode, have at least intermediate metal 201 surfaces of a sheet glass to be formed with low-melting-point metal layer 301, a slice can have low-melting-point metal layer 301 or not have in addition, but intermediate metal 201 must be arranged;
Prepare vacuum glass with this mode, at first select certain a slice of this two sheet glass, the upholder that lays on request on glass, upholder adopt array way to lay, and spacing generally between 25mm~45mm, is docked compound with another sheet glass after upholder lays and finishes.Fig. 3 C is that intermediate metal 201 surfaces around two sheet glass all are formed with the compound back of one deck low-melting-point metal layer 301 portion biopsy cavity marker devices synoptic diagram; Fig. 3 D has only intermediate metal 201 surfaces around the sheet glass to be formed with the compound back of one deck low-melting-point metal layer 301 portion biopsy cavity marker devices synoptic diagram.Then, clamp glass with certain clamping force will be used around two sheet glass, then to the glass heats that clamping (the control Heating temperature is a little more than the fusing point of scolder), low-melting-point metal layer 301 refuses after the heating and under the clamping force effect with intermediate metal 201 tight solder bond, and can adapt to limit portion sealing-in thickness demand (upholder of this thickness and setting is identical), thereby make the hermetic seal all around of two sheet glass.Above-mentioned heating can be carried out in common High Temperature Furnaces Heating Apparatus, also can carry out in vacuum oven, or adopt local heating methods such as induction heating, LASER HEATING, flame heating, electric stove wire heating to carry out.
In this mode, owing to use the soldering flux in the low melting point metal scolder 202 sealing-in processes to be cleaned in advance totally, thereby satisfied the requirement that can not contain soldering flux in the vacuum glass vacuum chamber.
Mode two: Fig. 4 shows the another kind of low melting point metal scolder 202 of soldering flux and the method for intermediate metal 201 airtight welding of not adopting.
The low melting point metal scolder 202(weld tabs that will not have soldering flux by Fig. 4) be placed between the intermediate metal 201 of two sheet glass, weld tabs thickness can determine that width is identical with the intermediate metal width according to two sheet glass vacuum gap thickness.
To put two sheet glass of low melting point metal scolder 202 then well exerts pressure to glass with having certain clamping force clip all around, put into stove heating (the control temperature is a little more than low melting point metal scolder fusing point) and make 202 fusings of low melting point metal scolder, thereby make molten metal scolder and intermediate metal 201 fuse together the formation low-melting-point metal layer, realize vacuum glass hermetic seal all around.
Preparation is during vacuum glass, and region intermediate lays upholder on request between two sheet glass earlier, again weld tabs is laid in glass surrounding portion zone two sheet glass between, and then clamp, vacuum glass that heating is formed with the metal edge sealing.
Owing to adopt no soldering flux to weld, therefore, this welding process must in the atmosphere protection stove, weld or vacuum high temperature furnace in weld.
In sum, the utility model essence has been to propose a kind of vacuum glass of tool metal edge sealing structure, this metal edge sealing structure is: the sealing-in surface former of two sheet glass is solidified with the layer of metal transition layer separately, and fusion is sealed with the metal level that the low melting point metal scolder forms between two intermediate metals.
Above-mentioned intermediate metal can be to be formed by the metal paste sintering curing, also can be to be formed by metal coating.Described metal paste can be silver slurry, copper slurry or other metal pastes, or alloy pulp; Described metallic membrane can be silverskin or copper film etc.
The vacuum glass of this kind tool metal edge sealing structure also can be offered aspirating hole or not offer aspirating hole on glass.
The utility model essence also is to have proposed to make the method for this tool metal edge sealing structure vacuum glass, and concrete steps comprise:
1) get former of two sheet glass, the layer of metal transition layer is solidified on the sealing-in surface earlier around both.Here, according to the selected raw material difference of intermediate metal, divide into two kinds of curing process: if 1. select metal paste to be cured, then be earlier at glass surface coated with metal slurry, carry out sintering then: as the preparation toughened vacuum glass, then put into the annealing furnace sintering, as preparation conventional vacuum glass, then adopt local heating method sintering such as flame heating, LASER HEATING, induction heating.If 2. select metallic film to be cured, then directly adopt methods such as electroless plating, plating, vacuum plating to plate metallic membrane and get final product, do not need heat-agglomerating.
2) will be solidified with two sheet glass of intermediate metal, fusion low melting point metal scolder makes two sheet glass hermetic seals between two intermediate metals.The low melting point metal scolder can be the soldering paste that is added with soldering flux or the weld tabs that does not have soldering flux.
Here, have or not the interpolation soldering flux according to the low melting point metal scolder, also divide into the method for two kinds of hermetic seals: if 1. select to have the low melting point metal scolder of soldering flux, then at first place the low melting point metal scolder that has soldering flux at the intermediate metal upper surface of at least one sheet glass, the width that low melting point metal scolder consumption optionally welds and thickness and decide; Secondly, the glass that places the low melting point metal scolder heated (weld tabs directly is placed on glass metal transition layer surface and gets final product until fusing, soldering paste is coated in the metal transfer laminar surface and gets final product), form one deck low-melting-point metal layer, heating can be carried out in common High Temperature Furnaces Heating Apparatus, also can in vacuum high temperature furnace, carry out, or adopt local heating methods such as induction heating, LASER HEATING, flame heating, electric stove wire heating to carry out; The soldering flux of low-melting-point metal layer remained on surface to cooling cleans then, and purging method can adopt washing or alcohol or other clean-out system to clean according to the soldering flux type; At last, all have intermediate metal with two, and wherein a slice fuses two sheet glass that low-melting-point metal layer is arranged at least, place upholder on a slice of bottom surface on glass, the glass that another sheet glass and cloth is placed with upholder is compound, clamp glass with certain clamping force will be used then around two sheet glass, and the glass heats to clamping, heating can be carried out in common High Temperature Furnaces Heating Apparatus, also can in vacuum oven, carry out, or employing induction heating, LASER HEATING, flame heating, local heating methods such as electric stove wire heating are carried out, the low-melting-point metal layer of two sheet glass and metal transfer interlayer are closely fused (at a slice glass surface intermediate metal is arranged, there is the situation of low-melting-point metal layer on another sheet glass surface), or closely fusion (situation that low-melting-point metal layer is arranged at two sheet glass surfaces) between low-melting-point metal layer and the low-melting-point metal layer.
If 2. select the low melting point metal scolder of no soldering flux; then at first directly place the low melting point metal scolder of no soldering flux at the intermediate metal of a sheet glass of bottom; scolder is generally made flake shape; and directly be shelved on glass metal transition layer surface and get final product; secondly; place upholder on request; the glass that then another sheet glass and cloth is placed with upholder is compound; clamp glass with certain clamping force will be used at last around two sheet glass; and the glass heats to clamping, heating is carried out in the atmosphere protection stove or in the vacuum high temperature furnace.
The above-mentioned main metal edge sealing method of having introduced vacuum glass, the utility model vacuum glass also can be offered aspirating hole 104 or do not offer except having the metal edge sealing structure on glass.At the situation of offering aspirating hole 104, on the basis of above-mentioned steps, need to distinguish additional different technology again:
Fig. 5 A has provided the vacuum glass structure of band aspirating hole 104, for the situation of offering aspirating hole 104, need to reserve aspirating hole 104 at a slice original sheet glass at least earlier, taking above-mentioned steps 1 then), 2) metal edge sealing method implement around after the hermetic seal, at the aspirating hole place vacuum glass clearance layer is vacuumized again, aspirating hole is sealed get final product at last.
Fig. 5 B has provided not the vacuum glass structure with aspirating hole 104, for the situation of not offering aspirating hole 104, because the utility model vacuum glass has adopted metal edge sealing technology, when two sheet glass hermetic seals, because low-melting-point metal layer 301 can occur uneven not melting front surface, thereby the two sheet glass limit portions of giving stay many spaces, so can retain some gaps that communicate with the vacuum oven cavity by the cavity between two sheet glass.So in above-mentioned steps 2) in, before the low-melting-point metal layer heat fused, need put into vacuum oven earlier to compound two good sheet glass and carry out cold conditions and vacuumize, reach demand vacuum tightness after, again two sheet glass are carried out heat fused.After treating the metal freezing of melting welding, can make the vacuum glass clearance layer after coming out of the stove be vacuum state, thereby form no bleeding point vacuum glass product.
With an example vacuum glass metal edge sealing method of the present utility model and structure thereof are described below.
Select former of two identical simple glasses, length and width are of a size of 300mm * 300mm, and thickness is 5mm.Be coated with the last layer silver paste around two sheet glass, the width of slurry coating is 5mm, and thickness is 10um.The simple glass of coated silver paste is put into annealing furnace carry out tempering, the tempering temperature is 640 ° of C.Sinter one deck silverskin (intermediate metal) at glass surface behind the tempering, coat solder paster (containing soldering flux) on two sheet glass silverskin surfaces then, and put into process furnace and be heated to and be cooled to 50 ° of C behind 180 ° of C and come out of the stove, at this moment, just at the silverskin layer of metal tin (metal level) that freezed.The remaining soldering flux of clean metal tin surfaces, and after a slice glass surface cloth is put upholder well that another sheet glass is compound to putting, around clamp, put into vacuum oven.Cold conditions is evacuated down to 1 * 10 with the vacuum oven cavity -3Pa final vacuum stove is warming up to 150 ° of C insulation 1 hour, continues to be warming up to 200 ° of C then, be incubated cooling after 20 minutes, stops to vacuumize after being down to 150 ° of C, continues to be cooled to 50 ° of C and takes out samples, be i.e. the metal edge sealing vacuum glass of the no aspirating hole of acquisition.
Test to vacuum glass: vacuum glass is come out of the stove and is not seen fragmentation, and the final vacuum glass surface stress of coming out of the stove is 116MPa, is typical toughened vacuum glass, and thermal conductivity is 0.006W/ (m 2/ K), press the GB/T7106-1986 testing standard, the Wind-Pressure Resistance of Glass performance is 1 grade.
Above-described embodiment only is used for explanation the utility model, and wherein local structure and technology can change to some extent, and every equivalents and improvement of carrying out on the basis of technical solutions of the utility model all should do not got rid of outside protection domain of the present utility model.

Claims (10)

1. the vacuum glass of a tool metal edge sealing structure, comprise former of two sheet glass, a plurality of upholder and sealing layer, it is characterized in that: on the sealing surface of former of two sheet glass, be solidified with the layer of metal transition layer separately, fusion is sealed with the metal level that the low melting point metal scolder forms between two intermediate metals, and the intermediate metal and the metal level that are sealed by fusion form described sealing layer.
2. the vacuum glass of tool metal edge sealing structure according to claim 1, it is characterized in that: described intermediate metal is metal paste sintering curing layer or metal-plated rete.
3. the vacuum glass of tool metal edge sealing structure according to claim 2 is characterized in that: described metal paste is silver slurry or copper slurry or alloy pulp; Described metal-plated rete is silverskin or copper film.
4. according to the vacuum glass of claim 1 or 2 or 3 described tool metal edge sealing structures, it is characterized in that: described low melting point metal scolder is that fusing point is at the brazing metal of 130 ° of C~400 ° C.
5. the vacuum glass of tool metal edge sealing structure according to claim 4, it is characterized in that: described low melting point metal scolder is soldering paste or weld tabs.
6. according to the vacuum glass of claim 1 or 2 or 3 described tool metal edge sealing structures, it is characterized in that: a kind of in simple glass, half tempered glass or the toughened glass of former of described sheet glass.
7. the vacuum glass of tool metal edge sealing structure according to claim 4 is characterized in that: a kind of in simple glass, half tempered glass or the toughened glass of former of described sheet glass.
8. the vacuum glass of tool metal edge sealing structure according to claim 7 is characterized in that: former of described sheet glass is toughened glass.
9. according to the vacuum glass of claim 1 or 2 or 3 described tool metal edge sealing structures, it is characterized in that: described vacuum glass is provided with or does not establish aspirating hole.
10. the vacuum glass of tool metal edge sealing structure according to claim 5 is characterized in that: do not establish aspirating hole on the described vacuum glass.
CN 201320087986 2013-02-26 2013-02-26 Vacuum glass with metallic edge sealing structure Expired - Lifetime CN203187549U (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
CN 201320087986 CN203187549U (en) 2013-02-26 2013-02-26 Vacuum glass with metallic edge sealing structure

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
CN 201320087986 CN203187549U (en) 2013-02-26 2013-02-26 Vacuum glass with metallic edge sealing structure

Publications (1)

Publication Number Publication Date
CN203187549U true CN203187549U (en) 2013-09-11

Family

ID=49104423

Family Applications (1)

Application Number Title Priority Date Filing Date
CN 201320087986 Expired - Lifetime CN203187549U (en) 2013-02-26 2013-02-26 Vacuum glass with metallic edge sealing structure

Country Status (1)

Country Link
CN (1) CN203187549U (en)

Cited By (6)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN103904162A (en) * 2014-03-24 2014-07-02 无锡艾立德智能科技有限公司 Simple method for packaging and assembling non-refrigeration infrared detector TEC
CN104003628A (en) * 2013-02-26 2014-08-27 中国建材检验认证集团股份有限公司 Vacuum glass with metal edge-sealing structure and making method thereof
CN104478202A (en) * 2014-12-19 2015-04-01 洛阳兰迪玻璃机器股份有限公司 Vacuum glass sealing method and vacuum glass product
CN104973807A (en) * 2014-04-11 2015-10-14 青岛鑫泰青玻璃有限公司 Tempered vacuum glass and production method thereof
CN105621902A (en) * 2015-12-28 2016-06-01 太仓耀华玻璃有限公司 Packaging method for vacuum glass
CN109369036A (en) * 2018-11-20 2019-02-22 常州美索虹铭玻璃有限公司 Vacuum glass and preparation method thereof and vacuum glass production line

Cited By (7)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN104003628A (en) * 2013-02-26 2014-08-27 中国建材检验认证集团股份有限公司 Vacuum glass with metal edge-sealing structure and making method thereof
CN103904162A (en) * 2014-03-24 2014-07-02 无锡艾立德智能科技有限公司 Simple method for packaging and assembling non-refrigeration infrared detector TEC
CN104973807A (en) * 2014-04-11 2015-10-14 青岛鑫泰青玻璃有限公司 Tempered vacuum glass and production method thereof
CN104478202A (en) * 2014-12-19 2015-04-01 洛阳兰迪玻璃机器股份有限公司 Vacuum glass sealing method and vacuum glass product
CN105621902A (en) * 2015-12-28 2016-06-01 太仓耀华玻璃有限公司 Packaging method for vacuum glass
CN105621902B (en) * 2015-12-28 2018-05-29 太仓耀华玻璃有限公司 A kind of method for packing of vacuum glass
CN109369036A (en) * 2018-11-20 2019-02-22 常州美索虹铭玻璃有限公司 Vacuum glass and preparation method thereof and vacuum glass production line

Similar Documents

Publication Publication Date Title
CN104003628A (en) Vacuum glass with metal edge-sealing structure and making method thereof
CN203187549U (en) Vacuum glass with metallic edge sealing structure
CN103420593A (en) Convex double-vacuum-layer glass mounting holes with sealing strips and grooves and manufacturing method of convex double-vacuum-layer glass mounting holes
CN102531361B (en) Tempered vacuum glass edge-sealing method and tempered vacuum glass edge-sealing device
CN101337774B (en) Energy-conserving plate material and its making method
CN103420572B (en) There is open holes of the two vacuum layer glass of the plane of sealing groove and preparation method thereof
CN104291588A (en) Mounting holes of vacuum glass and manufacturing method thereof
CN104193189A (en) Energy transmission window seal structure and manufacturing method thereof
CN103420582B (en) There is the open holes of the two vacuum layer glass of the plane of pipe and sealing groove
CN103420569A (en) Mounting holes of convex vacuum glass with round tube and sealing groove and strip, and preparation method of same
CN201245558Y (en) Energy-saving plate
CN104291663A (en) Vacuumizing hole of vacuum glass and manufacturing method thereof
CN103420585B (en) There is open holes of the area vacuum glass of pipe and seal strip groove and preparation method thereof
CN104291593A (en) Air-exhaust port sealing structure and manufacturing method thereof
CN104291594A (en) Vacuum glass air-exhaust port sealing structure and manufacturing method thereof
CN104291598A (en) Sealing structure for extraction opening of vacuum glass and manufacturing method
CN104291654A (en) Mounting hole having circular tube and sealing groove of flat vacuum glass and manufacturing method thereof
CN104291636A (en) Mounting hole with circular tube and seal strips for plate vacuum glass and a manufacturing method thereof
CN103420588A (en) Convex double-vacuum-layer glass mounting holes with round tubes and sealing strips
CN104291587A (en) Vacuum glass air-exhaust port structure and manufacturing method thereof
CN104291622A (en) Structure of extraction opening and manufacturing method
CN103420583A (en) Convex vacuum glass mounting holes with round tubes and sealing strips and manufacturing method of mounting holes
CN104291644A (en) Mounting hole having circular tube and sealing groove of convex vacuum glass
CN104291664A (en) Mounting hole having circular tube and sealing groove of convex double-vacuum-layer glass
CN104291625A (en) Vacuum glass air-exhaust port sealing structure and preparation method thereof

Legal Events

Date Code Title Description
C14 Grant of patent or utility model
GR01 Patent grant
CX01 Expiry of patent term

Granted publication date: 20130911

CX01 Expiry of patent term