CN111302668B

CN111302668B - Double-glue sealing groove edge support buckling interlayer regulation and control vacuum tempered glass plate

Info

Publication number: CN111302668B
Application number: CN201911255714.6A
Authority: CN
Inventors: 徐宝安
Original assignee: Zibo Environmental Protection Technology Co ltd
Current assignee: Zibo Environmental Protection Technology Co ltd
Priority date: 2018-12-11
Filing date: 2019-12-10
Publication date: 2024-06-11
Anticipated expiration: 2039-12-10
Also published as: CN111302668A; WO2020118670A1

Abstract

According to the invention, the double-adhesive sealing is adopted, or high-humidity air is introduced into the vacuum furnace, and then the air suction is realized on the middle interlayer, so that the double-adhesive sealing glass can be rapidly cured, and the rapid sealing and curing of the edge of the vacuum glass can be realized. And the vacuum toughened glass plate is provided with communicated sealing pipe fittings communicated with two sides. The invention realizes good airtight sealing bonding and structural bonding quality of the glass, solves the problem of tempering failure of the vacuum glass, and solves the safety problem of the vacuum glass. The functional vacuum glass has the advantages of simple manufacturing process, wide application of common toughened glass on materials, great reduction in manufacturing cost, great improvement in safety and yield, and diversification in structural form. The toughened glass plate has the characteristics of thinness, light weight, high strength, safety, long service life, large size, high yield, strong functionality, low energy consumption, high efficiency, light transmission, safety, low manufacturing cost, dew prevention, convenience for mass production and the like.

Description

Double-glue sealing groove edge support buckling interlayer regulation and control vacuum tempered glass plate

Technical Field

The invention relates to a tempered glass plate with a vacuum heat preservation regulation function, which is manufactured by using an adhesive sealing technology to carry out adhesive sealing on glass. Belonging to the field of glass building materials.

Background

Currently, the main stream of functional glass is hollow glass and vacuum glass.

The insulating performance of the hollow glass is not ideal, and two layers of glass are not mutually supported and can not mutually borrow force, so that the glass has weak wind pressure resistance and is easy to break due to glass resonance. In addition, there is a problem that condensation occurs in glass after the adhesive leaks.

The vacuum glass is made up by using two layers of glass plates as sandwich layer, and making them pass through the processes of sealing adhesive, bonding, vacuumizing and sealing. The vacuum glass is transparent vacuum glass with the best energy-saving effect at present, has a series of advantages of light weight, thin thickness, small heat transfer coefficient, good sound insulation effect and the like, and is an ideal energy-saving building material. However, the high-rise building has not been applied on a large scale at present because of the expensive production cost and the fact that the safety requirements of the toughened glass required by the high-rise building cannot be met. Because the sealing adhesive on the periphery of the vacuum glass is bonded into low-temperature glass fusion seal, the manufacturing process, cost, yield, mechanical performance and dimension specification of the vacuum glass are greatly limited, and the tempering treatment of the glass plate is difficult to realize, so that the strength and safety performance of the glass are influenced. Once the glass-melt edge seal damages vacuum leakage due to stress and the like, the whole vacuum glass loses good sound insulation and heat preservation performance.

The above-mentioned disadvantages of the existing vacuum glass are caused by the design structure and the production process thereof. The prior vacuum glass is characterized in that two glass raw sheets are separated by a tiny support point array, the periphery of the glass raw sheets is sealed by a low-melting-point glass material in a melting way, and the vacuum glass is sealed after being exhausted by a glass exhaust tube, so that a vacuum layer with the thickness of only 0.1-0.2mm and the air pressure lower than 0.1Pa is formed. The production of vacuum glass must therefore be accomplished through a number of processes, including: 1) drilling a suction hole, 2) arranging a support, 3) coating glass brazing material, 4) glass lamination, 5) high-temperature edge sealing/suction hole brazing, 6) high-temperature air suction/sealing and 7) getter deblocking.

Applicant [ Liu Weijie ] applies for a low-cost tempered vacuum glass and a manufacturing method thereof, application number CN200910188347.2

The application provides vacuum glass and a manufacturing method thereof, which replace the existing stainless steel support laying process with a micro-convex point support integrated with a glass raw sheet, seal edges by using a low-temperature metal tin brazing technology which does not cause annealing of the tempered glass raw sheet, and integrate the traditional vacuum layer air extraction process and the sealing process into an air extraction and sealing integrated process.

Compared with the existing vacuum glass and the manufacturing process thereof, the application completes vacuumizing and braze welding sealing once, and the safety reaches the use standard of high-rise buildings. However, due to the need of coating sintered gold water, low tin soldering temperature, low heating temperature of a vacuum soldering furnace, insufficient air release of glass and tin soldering materials, poor vacuumizing effect, low vacuum degree of a glass vacuum interlayer and the like, the heat preservation and sound insulation performance of the vacuum glass are unsatisfactory.

According to the technical scheme of application number CN200910234678.5 of Nanjing industrial university, the surface of the glass is subjected to electroless copper plating metal surface treatment on the basis of the original process. After the heating system is started, the workpiece is heated to 550 ℃ along with the furnace, the temperature is kept until the vacuum degree in the furnace is 4 multiplied by 10 < -2 > Pa, the temperature of each part of the workpiece is uniform, the brazing furnace is continuously heated to the brazing temperature, the heating is stopped after the brazing furnace is kept for 10 to 30 minutes, the workpiece is slowly cooled along with the furnace, and the furnace discharging temperature of the vacuum glass is below 50 ℃.

The high-temperature edge sealing process is a main reason for the fact that the existing vacuum glass cannot reach the national safety standard of high-rise buildings. National standards require that high-rise building glass components must be manufactured using tempered glass. However, because the melting temperature of the existing high-temperature edge sealing glass brazing material exceeds 550 ℃ and is greatly higher than the annealing temperature 388 ℃ of the conventional tempered glass, even if the tempered glass is used for manufacturing vacuum glass, the vacuum glass can be annealed into common glass in the edge sealing process.

The other regulation vacuum glass is formed by arranging a support on the middle interlayer of two layers of glass plates, bonding and forming the periphery of the glass plates through a sealing adhesive, and carrying out intermittent or continuous vacuumizing through a vacuum pump to regulate and preserve heat on the vacuum of the glass interlayers. The method is that the applicant applies for patent in advance, the patent number of the laminated plate glass curtain wall for regulating and controlling the vacuum degree of the cavity is: 2010103000382.

The prior application patent realizes vacuum insulation of the glass interlayer through intermittent or continuous vacuumizing of a vacuum pump. However, in practice, it has been found that it is difficult to achieve a high vacuum due to the unreasonable design and poor reliability of the device. Meanwhile, when the adhesive is a single-layer silicone structure sealant, although the adhesive strength can be ensured, the air tightness is poor; when the single-layer airtight sealant is used for bonding, the mechanical strength of the adhesive cannot be ensured although the airtight performance can be maintained; this makes it difficult to combine the strength of the glass-bonded structure with the air-tight properties and weather-resistant properties. In both of these bonding methods, there is a problem that a large amount of bubbles are present in the bonding layer. There is also a problem that the vacuum glass is broken due to the collision of glass corners in the transportation and installation process because the periphery of the vacuum glass is not provided with a protective frame.

Due to the problems, the vacuum interlayer which can be pumped by the vacuum pump is rough vacuum, and the problem of serious vacuum leakage exists. And when the vacuum interlayer thickness is smaller, the vacuum glass has poorer heat preservation performance. Therefore, it is required to improve the heat-insulating effect of the vacuum layer by increasing the thickness of the hollow interlayer. But doing so makes the vacuum pump very energy consuming.

Disclosure of Invention

The invention is under the background of the conventional process technology, through researching the basic theory and generating inspiration from practice, the quality of the welded surface of glass and metal is improved by utilizing the vacuum electric heating brazing process, and the performance of the tempered glass in the stainless steel protective frame is ensured to be unchanged.

In order to solve the problems, a brand new design scheme is adopted for the technology, and the two glasses are provided with a protection frame, an isolation support and a closed-loop sealing support frame, and are sealed by a temperature-resistant airtight sealing agent and a structural sealing agent; and arranging an airtight air inlet and exhaust pipe fitting, a vacuum gauge, a vacuum valve and a vacuum pump to manufacture the glass spacing cavity vacuum regulation and control heat preservation glass plate, and realizing heat preservation of the functional vacuum glass plate by regulating and controlling the vacuum degree of the glass spacing interlayer.

The process method for manufacturing the vacuum glass has the characteristics of simple operation, high glass strength, safety, large size, low manufacturing cost, high yield, good heat preservation performance, strong functionality, low energy consumption, good perspective effect, convenience for mass production and the like, and solves the problems of the existing functional vacuum glass. The invention can obtain good metal glass brazing quality, solves the technical problem that the vacuum glass cannot be tempered for a long time, and obtains good economic benefit, environmental benefit and social benefit.

The technical scheme of the invention is realized as follows: the double-glue sealing groove edge support buckling interlayer regulation and control vacuum toughened glass plate comprises a toughened glass plate, bonding sealant and a stainless steel frame. The method is characterized in that: and one of the two toughened glass plates is provided with two communicated sides, and the communicated sealing pipe fitting is adhered and sealed through airtight sealant and structural sealant. Or one of the two toughened glass plates is provided with two communicated sealing pipe fittings which are tightly screwed and locked by the bonding of the connecting fastener and the airtight sealing glue. Or one of the two toughened glass plates is provided with a communicating sealing pipe fitting which is communicated with two sides and is sealed by brazing with low-melting-point metal brazing flux. Or one of the two toughened glass plates is provided with two communicating sealing pipe fittings which are communicated with two sides and are sealed, screwed and locked by the brazing of the connecting fastener and the low-melting-point metal brazing flux.

(A) The two toughened glass plates forming the interlayer cavity are mutually corresponding in outline shape and size, and embossed glass integrated with the toughened glass plates and uniformly distributed with lattice convex points or convex lines is arranged on one of the at least two toughened glass plates.

The edges of the two toughened glass plates are provided with annular closed toughened glass plates with the same height as the protruding points and are bent and supported frames in parallel. Or the edges of the two toughened glass plates are provided with annular closed toughened glass plate bending support frames with the same height as the protruding points. Or the edges of the two toughened glass plates are provided with annular closed toughened glass plate four-edge bending support frames with the same height as the protruding points. Or the edges of the two toughened glass plates are provided with annular closed toughened glass plates with the same total height as the total height of the annular closed toughened glass plates which are supported and overlapped by the raised points in a parallel bending mode. Or the edges of the two toughened glass plates are provided with annular closed toughened glass plate bending support frames which are opposite to the raised points and are stacked to have the same height. Or the edges of the two toughened glass plates are provided with annular closed toughened glass plate four-edge bending supporting frames with the same total height as the total height of the raised points which are supported and overlapped relatively.

The two pieces of embossed glass and flat glass with corresponding outline shapes and sizes, at least one of which is provided with convex points or convex lines, or the embossed glass and the embossed glass are adhered and sealed by bending and supporting frames at the edges of the toughened glass plates.

Or a layer of metal thin strip with good plasticity is arranged on the periphery of the double-layer toughened glass plate bonded and sealed by the two toughened glass plates in an airtight sealing way and is used as an airtight sealing ring of the isolation sealing layer.

(B) Or two toughened glass plates forming the interlayer cavity are mutually corresponding in outline shape and size, and at least one of the two toughened glass plates is provided with a lattice convex hull toughened glass plate formed by die pressing and stretching, or a corrugated toughened glass plate formed by die pressing and stretching.

And a processing forming annular closed toughened glass plate parallel bending support frame with the frame support height of the toughened glass plate corresponding to the convex hull or the convex corrugation and other heights is arranged between the edges of the two toughened glass plates. Or the edge between two toughened glass plates is provided with a processed and formed annular closed toughened glass plate adjacent edge bending support frame, wherein the outline shape and the size of the processed and formed annular closed toughened glass plate adjacent edge corresponds to the edge of the toughened glass plate, and the frame support height of the toughened glass plate corresponds to the heights of the convex hulls or the convex corrugations. Or the edge between two toughened glass plates is provided with a ring-shaped closed toughened glass plate four-side bending support frame which is formed by processing and corresponds to the two toughened glass plates in outline shape and size to the edge of the toughened glass plates, and the frame support height of the toughened glass plates is equal to the height of the convex hulls or the convex corrugations.

Or the annular closed toughened glass plate is parallel to the bending support frame with the height equal to the total height of the opposite support superposition of the convex hulls of the dot matrix or the convex corrugations, and the edge of the two toughened glass plates. Or the annular closed toughened glass plate is parallel to the height of the bending support frame and the edges of the two toughened glass plates are provided with the annular closed toughened glass plate adjacent edge bending support frame with the same height as the dot matrix convex hull or the total height of the opposite support superposition of the convex corrugations. Or the annular closed toughened glass plate is parallel to the height of the bending support frame and the edges of the two toughened glass plates are provided with annular closed toughened glass plate four-edge bending support frames with the same height as the dot matrix convex hulls or the total height of the opposite support superposition of the convex corrugations.

Two lattice convex hull toughened glass plates with corresponding outline shapes and sizes are arranged on one or two of the two lattice convex hull toughened glass plates which are formed by die pressing and stretching, or corrugated toughened glass plates which are formed by die pressing and stretching, the supporting frame is stretched and bent through the edges of the toughened glass plates, and the stretching convex hulls or stretching corrugations of the two toughened glass plates and the edges of the toughened glass plates are bent and supported, so that the point contact and surface contact mutually-buckled sheets are bonded and sealed.

Or a layer of metal thin strip with good plasticity is arranged on the periphery of the two mutually buckled sheets for bonding and sealing the toughened glass plate through airtight sealing and gluing and is used as an airtight sealing ring of the isolation sealing layer.

(C) Or two toughened glass plates forming the interlayer cavity are mutually corresponding in outline shape and size, and at least two glass plates are manufactured by printing glass powder paste and then sintering. And (5) melting the sintered glass powder paste and cooling to obtain the glass supporting convex points.

The edges of the two toughened glass plates are provided with annular closed toughened glass plates with the same height as the protruding points and are bent and supported frames in parallel. Or the edges of the two toughened glass plates are provided with annular closed toughened glass plate bending support frames with the same height as the protruding points. Or the edges of the two toughened glass plates are provided with annular closed toughened glass plate four-edge bending support frames with the same height as the protruding points. Or the edges of the two toughened glass plates are provided with annular closed toughened glass plates with the same total height as the total height of the annular closed toughened glass plates which are supported and overlapped by the raised points in a parallel bending mode. Or the edges of the two toughened glass plates are provided with annular closed toughened glass plate bending support frames which are opposite to the raised points and are stacked to have the same height. Or the edges of the two toughened glass plates are provided with annular closed toughened glass plate four-edge bending supporting frames with the same total height as the total height of the raised points which are supported and overlapped relatively. Sintering glass powder paste, bending and supporting frames or synchronously carrying out glass tempering.

The two toughened glass plates are bonded and sealed by the point contact or line contact and surface contact of the two toughened glass plates and the annular sealing frame through the airtight sealant coated on the sealing surface of the bending support frame of the edges of the toughened glass plates. A step of

(D) Or two toughened glass plates forming the interlayer cavity are mutually corresponding to each other in outline shape and size, and at least one of the two toughened glass plates is provided with a support which is uniformly distributed in a lattice manner through bonding and is connected with the toughened glass plates into a whole.

The edges of the two toughened glass plates are provided with annular closed toughened glass plates which are parallel to the supporting frames for supporting the same height. Or the edges of the two toughened glass plates are provided with annular closed toughened glass plate bending support frames which are at the same height as the support frames. Or four sides of the annular closed toughened glass plate with the same height as the support are arranged at the edges of the two toughened glass plates to form a bending support frame. Or the edges of the two toughened glass plates are provided with annular closed toughened glass plates with the same height as the total height of the opposite support stack, and the annular closed toughened glass plates are parallel to the bending support frames. Or the edges of the two toughened glass plates are provided with annular closed toughened glass plate bending support frames with the same height as the total height of the opposite support stack. Or the edges of the two toughened glass plates are provided with annular closed toughened glass plate four-edge bending support frames with the same height as the total height of the opposite support stack.

The two toughened glass plates are bent by the edges of the toughened glass plates to support the frames, and the two toughened glass plates and the annular closed frame are bonded and closed together by the point contact and the surface contact of the two toughened glass plates and the annular closed frame.

The outer side of the periphery of the hollow sandwich toughened glass plate body is wrapped with a closed-loop corrugated stainless steel frame with a U-shaped section, and the groove of the corrugated stainless steel frame is filled with structural sealant which does not generate chemical reaction with airtight sealant. The self elasticity of the closed-loop corrugated stainless steel frame with the U-shaped section is utilized to stretch and sleeve the periphery outer side of the hollow interlayer toughened glass plate body, and the self resilience of the closed-loop corrugated stainless steel frame is utilized to enable the closed-loop corrugated stainless steel frame with the U-shaped section to be tightly attached and adhered with the periphery outer side of the hollow interlayer toughened glass plate body.

Or the outer side of the periphery of the hollow sandwich toughened glass plate body is wrapped with a hollow sandwich toughened glass plate structure protection frame, the upper section of which is L-shaped and reverse L-shaped, and the closed-loop stainless steel frame coated with the structural sealant is buckled and sleeved with the hollow sandwich toughened glass plate structure protection frame.

And then, at least one tempered glass plate blank is sent into a vacuum furnace, heated and vacuumized. And then spraying water mist into the vacuum furnace or introducing high-humidity air and cooling, and opening the furnace after the cooling temperature is reached, so that the double-glue sealing groove is prepared while supporting and buckling the interlayer to regulate and control the vacuum toughened glass plate.

A method for manufacturing a double-glue sealing groove side supporting buckling interlayer regulation and control vacuum toughened glass plate comprises the steps of toughened glass plate, bonding sealant and a vacuum furnace. The method is characterized in that: the hollow interlayer is arranged between the two toughened glass plates through the supporting frame, the airtight sealant is arranged on the sealing cover and the face of the closed-loop supporting and bonding sealing cover of the two toughened glass plates and the closed-loop supporting frame or the metal section, and the structural sealant is filled in the peripheral groove of the hollow interlayer toughened glass plate body to form the sealing sealant ring of the sealing structure for bonding the closed-loop supporting frame or the closed-loop supporting frame groove bottom of the metal section and the glass groove walls on two sides. And (5) manufacturing a hollow interlayer toughened glass plate blank.

And then horizontally placing at least one hollow interlayer toughened glass plate blank into a vacuum furnace provided with a supporting base, a fixed supporting clamp or a tray. The glass tray of the vacuum furnace is provided with an ultrasonic transducer for improving the bonding quality of glass and glass, glass and metal. Closing the vacuum furnace door, and vacuumizing the hollow interlayer toughened glass plate blank in the vacuum furnace. The gas in the airtight seal and the structural seal is exhausted entirely. And under the action of self cohesive force after the contact gaps among the stainless steel, the glass and the stainless steel and the airtight sealant and the structural sealant are exhausted, the airtight sealant, the structural sealant, the glass bonding surface and the stainless steel bonding surface are fully immersed and wetted, so that the bonding of the airtight sealant and the structural sealant to the glass and the stainless steel frame is realized.

Meanwhile, as the groove of the stainless steel frame with the U-shaped closed loop in the cross section is designed deeper, the sealing glue layer of the closed loop structure corresponding to the groove is longer, so that the formed bonding connection sealing layer is thicker, the bonding strength of the structural sealing glue, glass and stainless steel is high, and the airtight sealing performance is good.

When the vacuum degree and the set vacuumizing time are reached, high-humidity air is introduced into the vacuum furnace, and an exhaust vacuum valve arranged on the pipe orifice of the communicated sealing pipe fitting is closed instantaneously. The air generates pressure, and the stainless steel frame rapidly compacts the airtight sealant and the structural sealant layer in a softened state under the action of air pressure, and adheres and solidifies the airtight sealant and the structural sealant layer.

Through the process, the bonding quality of glass and stainless steel through airtight sealant and structural sealant is improved. And opening the vacuum furnace door to manufacture the heat-insulating toughened glass plate body, wherein the hollow air inlet and outlet communication sealing pipe fittings are arranged on the heat-insulating toughened glass plate body, and two annular sealing adhesive sealing belts and a stainless steel closed loop protection frame are arranged on the periphery of the toughened glass plate body.

Or horizontally placing at least one hollow sandwich toughened glass plate blank into a vacuum furnace provided with a supporting base, a fixed supporting clamp or a tray. Closing the vacuum furnace door, and heating and vacuumizing the hollow interlayer toughened glass plate blank in the vacuum furnace. The gases in the hot melt hermetic seal and the structural seal are all exhausted. And under the action of the capillary action of contact gaps between stainless steel and glass, between glass and between stainless steel and the self cohesive force after the hot-melt airtight sealant and the structural sealant are discharged, the bonding surfaces of the hot-melt airtight sealant, the structural sealant and the glass and the bonding surfaces of the stainless steel are fully immersed and wetted, so that the bonding of the hot-melt airtight sealant and the structural sealant to the glass and the stainless steel frame is realized.

When the heating temperature, the vacuum degree and the set vacuumizing time are reached, high-humidity air is introduced into the vacuum furnace, and an exhaust vacuum valve arranged on the pipe orifice of the communicated sealing pipe fitting is closed instantaneously. The air absorbs heat, heats up and expands to generate pressure, the stainless steel frame rapidly compacts the hot-melt airtight sealant and the structural sealant layer in a softened state under the action of air pressure, and releases heat to solidify, and then, or a cooling device arranged in the vacuum furnace is started to cool the vacuum furnace.

Or high humidity air is introduced into the vacuum furnace, and an exhaust vacuum valve arranged on the pipe orifice of the communicated sealing pipe fitting is closed instantaneously. The air absorbs heat, heats up and expands to generate pressure, the stainless steel frame rapidly compacts the hot-melt airtight sealant and the structural sealant layer in a softened state under the action of air pressure, and releases heat to solidify, and then the vacuum furnace is cooled by discharging hot air and filling cold air, or a cooling device arranged in the vacuum furnace is started to cool the vacuum furnace, so that the structural sealant in the stainless steel frame can be naturally cooled and solidified.

Through the process, the bonding quality of glass and stainless steel through hot melt airtight sealant and structural sealant is improved. When the temperature of the vacuum furnace is reduced to 50-55 ℃, the vacuum furnace door is opened, a hollow air inlet and outlet communicating sealing pipe fitting is arranged on the manufactured heat-preservation toughened glass plate body, two annular sealing bonding sealing belts and a stainless steel closed-loop protection frame are arranged on the periphery of the toughened glass plate body, and the vacuum degree of the hollow interlayer of the glass is adjustable, so that the heat-preservation daylighting toughened glass plate is manufactured.

The double-glue sealing groove edge support buckling interlayer regulation vacuum toughened glass plate comprises a glass raw sheet, toughened glass, cloth-grain glass, embossed glass, halogenated glass, frosted glass and coated glass, wherein functional films of the coated glass comprise an antireflection film, a metal film and a decorative film. The surface of the glass panel is compounded with a coating film, so that the coating film must be removed from the bonding surface of the glass panel; the toughened glass plate is double-layer or multi-layer laminated glass.

The double-glue sealing groove edge supports the buckling interlayer to regulate and control the vacuum toughened glass plate, and the convex point embossing toughened glass plate is formed by calendaring glass convex points through a glass calendaring machine at a proper temperature position in a glass tin bath when a flat glass raw sheet is produced. The surface of one rolling roller of the glass rolling machine is carved with a series of pits which are uniform in shape and size and are arranged according to the dot matrix of the convex point support. The convex point embossing toughened glass plate is subjected to cutting, edging and toughening treatment.

Or after the convex point embossing toughened glass plate is formed by edging and shaping a flat glass raw sheet, heating the flat glass raw sheet by a toughening furnace, calendaring convex points by a glass calendaring machine, bending a supporting frame, and carrying out toughening treatment after shaping. The surface of one rolling roller of the glass rolling machine is carved with a series of pits which are uniform in shape and size and are arranged according to the dot matrix of the convex point support.

Or convex hull toughened glass plate or corrugated toughened glass plate is formed by calendaring glass pits on a proper temperature position in a glass tin bath when producing a flat glass raw sheet by a glass calendaring machine. The surface of one rolling roller of the glass rolling machine is carved with a series of convex points which are uniform in shape and size and are arranged according to the lattice of the concave point supports. The pit embossing toughened glass plate is subjected to cutting, edging and toughening treatment.

Or after edging and shaping the convex hull toughened glass plate or the corrugated toughened glass plate, heating the glass plate or the corrugated toughened glass plate by a toughening furnace, stretching the convex points by a glass die, bending the supporting frame, and carrying out toughening treatment after shaping.

Or the bump toughened glass plate is a glass raw sheet, and is manufactured by printing glass powder paste and then sintering. Printing low-temperature glass powder paste on a piece of flat glass according to the bump support object point array pattern, then sending the flat glass into a tempering sintering furnace, heating to a proper temperature of the melting point of the glass powder paste, converting a glass powder paste stack into glass bumps fused with the surface of the flat glass, bending a support frame, and performing tempering treatment.

Cutting the plate glass with proper thickness according to the designed size, edging, tempering and using the tempered glass panel as raw material. The surface of the glass is required to be deoiled, cleaned and dried.

The double-glue sealing groove edge support buckling interlayer regulation vacuum toughened glass plate is supported by a support with at least one end coated with an adhesive, and comprises high-hardness glass supports, high-hardness metal supports and high-hardness ceramic supports which are equal or close to the height of a closed-loop sealing support frame, and columnar or spherical or annular support lattice-shaped arrangement. Or the support is a support heat insulation material pad with an aerogel heat insulation pad adhered to the end support surface, and the surfaces of the aerogel heat insulation pads at the two ends of the support heat insulation material pad are coated with a hot melt adhesive, a glass adhesive, an ultraviolet curing adhesive or a water glass adhesive.

The double-glue sealing groove edge supports the buckling interlayer to regulate and control the vacuum toughened glass plate, and an opening hole in the middle interlayer toughened glass plate body is arranged on the glass panel or on the closed-loop sealing support frame. The pipe fitting is a pipe fitting with a T-shaped section and provided with threads on the outer wall of the baffle pipe, the root of each pipe fitting thread is provided with a tooth ridge correspondingly, the pipe fitting is provided with an upward conical nut, the pipe fitting is screwed and sealed on the hollow interlayer toughened glass plate body through airtight sealant and the nut, or the outer wall of the pipe is provided with a threaded pipe fitting, the root of each pipe fitting thread is provided with a tooth ridge correspondingly, the upward conical nut is provided with an upward conical nut correspondingly, and the pipe fitting is screwed and sealed on the hollow interlayer toughened glass plate body through airtight sealant and the nut. The sealing pipe fitting is provided with a fastening sealing pipe fitting corresponding to the opening of the toughened glass plate, the air inlet and outlet pipe head is tightly sealed and fixed on the opening of the air inlet and outlet pipe head on the toughened glass plate through airtight sealant and fastening sealing pipe fitting lock, the section of the sealing pipe fitting is T-shaped and provided with a blocking head, the blocking head is provided with a ventilation groove, and the outer wall of the pipe is provided with a threaded pipe fitting or is made of magnetic material.

The double-glue sealing groove edge supports the buckling interlayer to regulate and control the vacuum toughened glass plate, the periphery of the annular sealing glass or the annular sealing glass supporting frame is sealed and bonded through airtight sealant and structural sealant which do not generate chemical reaction mutually. The sealant on the inner sides of the peripheries of the two pieces of glass is first adhesive, and is bonded by airtight sealant. The first gas-tight seal includes butyl-type seals such as polyisobutylene, hot melt butyl. The sealant at the outer sides of the peripheries of the two pieces of glass is second-path adhesive, and is adhered by structural sealant. The second sealant is a cured weather-proof structure sealant, and comprises elastic sealants for glass, such as polysulfide, silicone and polyurethane. The structural sealant in hot melt form includes a hot melt polyisobutylene adhesive, a hot melt butyl adhesive.

The metal thin strip with good plasticity for prolonging the thickness of the airtight sealing adhesive comprises an aluminum strip, a copper strip and a stainless steel strip.

The double-glue sealing groove edge supports the buckling interlayer to regulate and control the vacuum tempered glass plate, and the outer side of the periphery of the middle interlayer tempered glass plate body is wrapped with a closed-loop corrugated stainless steel frame with a U-shaped section. The U-shaped corrugated stainless steel groove section is formed by stamping and stretching a stainless steel plate strip through a die, or the U-shaped corrugated stainless steel groove section is formed by rolling a stainless steel plate strip through a rolling mill. The closed-loop corrugated stainless steel frame is a U-shaped corrugated stainless steel groove profile, and is made by bending and welding or cutting and welding.

The U-shaped closed-loop corrugated stainless steel frame groove is required to be deoiled, cleaned and dried when in use.

The double-glue sealing groove edge supports the buckling interlayer to regulate and control the vacuum toughened glass plate, and the outer side of the periphery of the middle interlayer toughened glass plate body is wrapped with a hollow interlayer toughened glass plate structure protection frame formed by buckling and sleeving closed-loop stainless steel frames with L-shaped sections and reverse L-shaped sections. The L-shaped stainless steel section is a stainless steel strip, and is formed by stamping and stretching through a die, or the L-shaped stainless steel section is a stainless steel strip, and is formed by rolling through a rolling mill. The closed loop L-shaped stainless steel frame is made of L-shaped stainless steel sections through bending welding or cutting welding.

The L-shaped stainless steel section is subjected to deoiling, cleaning and drying treatment when in use.

The double-glue sealing groove side supporting and buckling interlayer regulating and controlling vacuum toughened glass plate system comprises a toughened glass plate provided with an air inlet and outlet pipe fitting sealing glass periphery regulating and controlling interlayer functional gas pressure, a vacuum valve, a vacuum meter, an air inlet and outlet pipeline and a vacuum pump set. The method is characterized in that: at least one toughened glass plate provided with an air inlet and outlet pipe fitting, a sealing glass periphery and a regulating and controlling interlayer functional gas pressure, wherein the air inlet and outlet pipe fitting is connected with an air inlet and outlet pipe through a pipe fitting comprising a tee joint and a four-way joint in a bolting way by using a sealing pipe fitting comprising welding, bonding and a screw cap, and is connected with an air inlet and outlet pipe in a parallel sealing way, and a vacuum gauge is connected on the air inlet and outlet pipe. The air inlet and outlet pipeline is connected with the vacuum pump set in a sealing way through the vacuum valve, and the vacuum pump set is opened and closed through a numerical standard set by the vacuum meter. Or the variable-frequency vacuum pump set changes the power output through a numerical standard set by the vacuum meter.

The air inlet and outlet pipeline is provided with a functional air inlet pipeline which is connected and controlled by a vacuum valve and is controlled to be opened and closed by a preposed vacuum valve. On the intake conduit provided before the vacuum valve, or on a dryer assembly. The dryer component is provided with an electric heating and dehumidifying device and an air outlet valve.

On the pipe before the dryer or on the pipes there are groups of functional gas cylinders comprising air. The functional gas tank group comprises a low heat conductivity gas argon tank and a carbon dioxide gas tank, and the high heat conductivity gas comprises a hydrogen tank and a helium tank.

The vacuum gauge is a conventional vacuum gauge or an artificial intelligent vacuum gauge, and the vacuum valve is a conventional vacuum valve or an artificial intelligent vacuum valve.

The vacuum pump set is provided with a coarse vacuum pump and a fine vacuum pump, and the coarse vacuum pump and the fine vacuum pump can be operated in parallel or in series. Or when the rough vacuumizing pump is pumped to the set vacuum, the rough vacuumizing pump is closed, and the fine vacuumizing pump is started until the rough vacuumizing pump is pumped to the set vacuum, and then the fine vacuumizing pump is closed. When the vacuum degree is reduced to a set value, the vacuum pump set is started again. Or the vacuum pump set is a variable frequency vacuum pump set which continuously operates.

After the vacuum degree of the gas pressure heat-preserving toughened glass plate with the sealing glass periphery regulating and controlling interval interlayer function is reduced to a set value, or a vacuum valve arranged on a pipe fitting of the vacuum valve is automatically closed, a vacuum pump measures the vacuum degree in the interlayer of the sealing glass periphery regulating and controlling interval interlayer function gas pressure heat-preserving toughened glass plate, whether the heat-preserving heat-dissipating light-transmitting toughened glass cover leaks vacuum is judged, and when the vacuum rises to or falls to the set value, the vacuum valve is automatically opened and closed.

The heat-insulating, heat-dissipating and light-transmitting toughened glass cover of the gas pressure heat-insulating toughened glass plate with the interlayer function of regulating the periphery of the sealing glass realizes good heat dissipation of the heat-insulating, heat-dissipating and light-transmitting toughened glass cover by introducing hydrogen or helium gas with high heat conductivity coefficient into the heat-insulating, heat-dissipating and light-transmitting toughened glass cover according to design requirements.

And air is introduced into the heat-insulating heat-radiating light-transmitting toughened glass cover to realize the conventional heat radiation of the heat-insulating heat-radiating light-transmitting toughened glass cover.

The conventional heat preservation of the heat-preserving heat-dissipating light-transmitting tempered glass cover is realized by introducing argon or carbon dioxide with low-heat-conductivity gas into the heat-preserving heat-dissipating light-transmitting tempered glass cover.

The heat-insulating heat-radiating light-transmitting toughened glass cover is vacuumized, so that good heat preservation of the heat-insulating heat-radiating light-transmitting toughened glass cover is realized.

The beneficial effects of the invention are as follows:

The functional vacuum glass manufactured by the invention can realize the manufacture of glass and stainless steel frames by double-glue sealing and bonding. The glass-metal bonding quality can be very good, and the problem of tempering failure of the vacuum glass is solved, so that the safety problem of the vacuum glass is solved, and the energy-saving requirements of facility agriculture and buildings are very well met. The functional vacuum glass has the advantages of simple manufacturing process, wide application of common toughened glass on materials, great reduction in manufacturing cost, great improvement in safety and yield, and diversification in structural form. The toughened glass plate has the characteristics of thinness, light weight, high strength, safety, long service life, large size, high yield, strong functionality, low energy consumption, high efficiency, light transmission, safety, low manufacturing cost, dew prevention, convenience for mass production and the like.

The invention relates to a functional vacuum glass regulating and controlling vacuum system which is composed of a vacuum pump group, an artificial intelligent control system, an airtight vacuum pipeline device, a vacuum valve, a vacuum meter, functional gas, a dryer and other devices, wherein the vacuum degree of a glass isolation interlayer cavity is regulated and controlled, and the functions of vacuum heat preservation, sound insulation and light transmission of the functional vacuum glass are realized. The functional vacuum glass system can realize automatic remote regulation and control of artificial intelligence and reliable operation. Overcomes the defects of prior hollow glass, vacuum glass and prior application of the inventor, and has the following patent numbers: 2010103000382A laminated sheet glass curtain wall for regulating and controlling the vacuum degree of a cavity. The heat insulation performance is adjustable, the sound insulation performance is adjustable, and the heat insulation and sound insulation performance is good. Therefore, the invention has good economic benefit, environmental benefit and social benefit.

Drawings

The invention will be further described with reference to the drawings and examples.

FIG. 1 is a cross-sectional view of a tempered glass plate with double-sided parallel bending support frames for glass, single-sided composite distribution of lattice embossing support salient points, and a U-shaped corrugated stainless steel groove profile frame double-glue sealing vacuum tempered glass plate;

FIG. 2 is a cross-sectional view of a tempered glass plate complementarily fitted with double-sided composite distributed lattice embossing supporting salient points and a U-shaped corrugated stainless steel groove profile frame double-glue sealing vacuum tempered glass plate provided with glass double-sided parallel bending supporting frames;

FIG. 3 is a cross-sectional view of a double-glue sealed vacuum tempered glass plate with double-sided parallel bending support frames of glass, double-sided composite tempered glass plates with lattice embossing support salient points distributed on the two sides, and U-shaped corrugated stainless steel groove profile frames, aiming at the stack Luo Ge sheets;

FIG. 4 is a cross-sectional view of a tempered glass plate with double-sided parallel bending support frames and single-sided composite distribution of lattice stretching support salient points and a U-shaped corrugated stainless steel groove profile frame double-glue sealing vacuum tempered glass plate, wherein the glass double-sided parallel bending support frames are arranged;

FIG. 5 is a cross-sectional view of a tempered glass plate complementarily fitted with double-sided composite distributed lattice stretching supporting salient points and a U-shaped corrugated stainless steel groove profile frame double-glue sealing vacuum tempered glass plate provided with glass double-sided parallel bending supporting frames;

FIG. 6 is a cross-sectional view of a double-glue sealed vacuum tempered glass plate with double-sided parallel bending support frames of glass, double-sided composite tempered glass plates with lattice stretching support salient points distributed on both sides, and U-shaped corrugated stainless steel groove profile frames, aiming at a stack Luo Ge sheets;

FIG. 7 is a cross-sectional view of a tempered glass plate with glass double-sided parallel bending support frames, single-sided composite distribution of lattice sintering support salient points, and a U-shaped corrugated stainless steel groove profile frame double-glue sealing vacuum tempered glass plate;

FIG. 8 is a cross-sectional view of a tempered glass plate complementarily fitted with double-sided composite distributed lattice sintering supporting salient points and a U-shaped corrugated stainless steel groove profile frame double-glue sealed vacuum tempered glass plate provided with glass double-sided parallel bending supporting frames;

FIG. 9 is a cross-sectional view of a double-sided parallel glass bending support frame, a double-sided composite toughened glass plate with lattice sintering support protruding points distributed on the two sides, a stack Luo Ge sheets, and a double-glue sealing vacuum toughened glass plate with a U-shaped corrugated stainless steel groove profile frame;

FIG. 10 is a cross-sectional view of a tempered glass plate with glass double-sided parallel bending support frames, composite tempered glass plates with lattice bonding support bumps distributed thereon, and a U-shaped corrugated stainless steel groove profile frame double-glue sealing vacuum tempered glass plate;

FIG. 11 is a cross-sectional view of a tempered glass plate with double-sided mutually adjacent glass bending support frames, single-sided composite distribution of lattice embossing support salient points, and a U-shaped corrugated stainless steel groove profile frame double-glue sealing vacuum tempered glass plate;

FIG. 12 is a cross-sectional view of a tempered glass plate complementarily fitted with double-sided composite distributed lattice embossing supporting salient points and a U-shaped corrugated stainless steel groove profile frame double-glue sealed vacuum tempered glass plate provided with glass double-sided mutually-facing bending supporting frames;

FIG. 13 is a cross-sectional view of a double-sided mutually adjacent glass bending support frame, a double-sided composite toughened glass plate with lattice embossing support bumps distributed on both sides, a double-sided double-glue sealing vacuum toughened glass plate with a U-shaped corrugated stainless steel groove profile frame, and a laminated Luo Ge sheet;

FIG. 14 is a cross-sectional view of a tempered glass plate with glass double-sided mutually adjacent bending support frames, single-sided composite distribution of lattice stretching support salient points, and a U-shaped corrugated stainless steel groove profile frame double-glue sealing vacuum tempered glass plate;

FIG. 15 is a cross-sectional view of a tempered glass plate complementarily fitted with double-sided composite distributed lattice stretching support bumps and a double-glue sealed vacuum tempered glass plate with a U-shaped corrugated stainless steel channel section frame, wherein the double-sided composite distributed lattice stretching support bumps are arranged on the double-sided mutually adjacent glass support frames;

FIG. 16 is a cross-sectional view of a double-sided mutually adjacent glass bending support frame, a double-sided composite glass sheet with lattice stretching support bumps distributed on both sides, a double-sided double-glue sealing vacuum tempered glass sheet for stacking Luo Ge sheets, and a U-shaped corrugated stainless steel groove profile frame;

FIG. 17 is a cross-sectional view of a tempered glass plate with glass double-sided mutually adjacent bending support frames, single-sided composite distribution of lattice sintering support salient points, and a U-shaped corrugated stainless steel groove profile frame double-glue sealing vacuum tempered glass plate;

FIG. 18 is a cross-sectional view of a tempered glass plate complementarily fitted with double-sided composite distributed lattice sintering supporting bumps and a double-glue sealed vacuum tempered glass plate with a U-shaped corrugated stainless steel channel section frame, wherein the double-sided composite distributed lattice sintering supporting bumps are arranged on the double-sided mutually adjacent glass supporting frames;

FIG. 19 is a cross-sectional view of a double-sided mutually adjacent glass bending support frame, a double-sided composite toughened glass plate with lattice sintering support bumps distributed on both sides, a stack Luo Ge sheets, and a double-glue sealed vacuum toughened glass plate with a U-shaped corrugated stainless steel groove profile frame;

FIG. 20 is a cross-sectional view of a tempered glass plate with glass double-sided mutually adjacent bending support frames, composite tempered glass plates with lattice bonding support bumps distributed thereon, and a U-shaped corrugated stainless steel channel profile frame double-glue sealed vacuum tempered glass plate;

FIG. 21 is a cross-sectional view of a tempered glass plate with double-sided four-sided bending support frames and single-sided composite distributed lattice embossing support salient points and a U-shaped corrugated stainless steel groove profile frame double-glue sealing vacuum tempered glass plate;

FIG. 22 is a cross-sectional view of a tempered glass plate complementarily fitted with double-sided composite distributed lattice embossing supporting salient points and a U-shaped corrugated stainless steel groove profile frame double-glue sealed vacuum tempered glass plate provided with glass double-sided four-sided bending supporting frames;

FIG. 23 is a cross-sectional view of a double-glue sealed vacuum tempered glass plate with double-sided four-sided bending support frames of glass, double-sided composite tempered glass plates with lattice embossing support salient points distributed on the two sides, and U-shaped corrugated stainless steel groove profile frames, aiming at the stack Luo Ge sheets;

FIG. 24 is a cross-sectional view of a tempered glass plate with double-sided four-sided bending support frames and single-sided composite distribution of lattice stretching support salient points and a U-shaped corrugated stainless steel groove profile frame double-glue sealing vacuum tempered glass plate;

FIG. 25 is a cross-sectional view of a tempered glass plate complementarily fitted with double-sided composite distributed lattice stretching support bumps and a double-glue sealed vacuum tempered glass plate with a U-shaped corrugated stainless steel channel section frame, wherein the glass double-sided four-sided bending support frame is provided with the invention;

FIG. 26 is a cross-sectional view of a double-sided four-sided bending support frame provided with glass, a double-sided composite toughened glass plate with lattice stretching support bumps distributed on both sides, a stack Luo Ge of the toughened glass plate, and a double-glue sealed vacuum toughened glass plate of a U-shaped corrugated stainless steel groove profile frame;

FIG. 27 is a cross-sectional view of a tempered glass plate with double-sided four-sided bending support frames and single-sided composite distribution of lattice sintering support salient points and a double-glue sealed vacuum tempered glass plate with a U-shaped corrugated stainless steel groove profile frame;

FIG. 28 is a cross-sectional view of a tempered glass plate complementarily fitted with double-sided composite distributed lattice sintering supporting bumps and a U-shaped corrugated stainless steel channel profile frame double-glue sealed vacuum tempered glass plate provided with glass double-sided four-sided bending supporting frames;

FIG. 29 is a cross-sectional view of a double-glue sealed vacuum tempered glass plate with double-sided four-sided bending support frames, double-sided composite tempered glass plates with lattice sintering support salient points distributed on both sides, and U-shaped corrugated stainless steel groove profile frames, for stacking Luo Ge sheets;

FIG. 30 is a cross-sectional view of a tempered glass plate with glass double-sided four-sided bending support frames, composite tempered glass plates with lattice bonding support bumps distributed thereon, and a U-shaped corrugated stainless steel groove profile frame double-glue sealing vacuum tempered glass plate;

FIG. 31 is a cross-sectional view of a tempered glass plate with double-sided parallel bending support frames and single-sided composite distributed lattice embossing support salient points, and a double-glue sealed vacuum tempered glass plate with a buckled L-shaped stainless steel groove profile frame;

FIG. 32 is a cross-sectional view of a tempered glass plate complementarily fitted with double-sided composite distributed lattice embossing supporting bumps and a double-glue sealed vacuum tempered glass plate buckled with an L-shaped stainless steel groove profile frame, wherein the glass double-sided parallel bending supporting frame is arranged;

FIG. 33 is a cross-sectional view of a double-sided parallel glass bending support frame, a double-sided composite toughened glass plate with lattice embossing support bumps distributed on both sides, a laminated Luo Ge sheet, and a double-glue sealed vacuum toughened glass plate buckled with an L-shaped stainless steel groove profile frame;

FIG. 34 is a cross-sectional view of a tempered glass plate with double-sided parallel bending support frames and single-sided composite distributed lattice stretching support salient points, and a double-glue sealed vacuum tempered glass plate with a buckled L-shaped stainless steel groove profile frame;

FIG. 35 is a cross-sectional view of a tempered glass plate complementarily fitted with double-sided composite distributed lattice stretching support bumps and a double-glue sealed vacuum tempered glass plate buckled with an L-shaped stainless steel groove profile frame, wherein the double-sided parallel bending support frame is provided with glass;

FIG. 36 is a cross-sectional view of a double-sided parallel glass bending support frame, a double-sided composite glass sheet with lattice stretching support bumps distributed on both sides, a stack Luo Ge sheets, and a double-glue sealed vacuum tempered glass sheet with an L-shaped stainless steel groove profile frame;

FIG. 37 is a cross-sectional view of a tempered glass plate with glass double-sided parallel bending support frames, single-sided composite distributed lattice sintering support salient points, and a double-glue sealed vacuum tempered glass plate buckled with an L-shaped stainless steel groove profile frame;

FIG. 38 is a cross-sectional view of a tempered glass plate complementarily fitted with glass double-sided parallel bending support frames, double-sided composite distributed lattice sintering support bumps, and a double-glue sealed vacuum tempered glass plate buckled with an L-shaped stainless steel groove profile frame;

FIG. 39 is a cross-sectional view of a double-sided parallel glass bending support frame, a double-sided composite toughened glass plate with lattice sintering support bumps distributed on both sides, a stack Luo Ge of the toughened glass plate, and a double-glue sealing vacuum toughened glass plate for buckling an L-shaped stainless steel groove profile frame;

FIG. 40 is a cross-sectional view of a tempered glass plate with glass double-sided parallel bending support frames, composite tempered glass plates with lattice adhesive support bumps distributed thereon, and a double-glue sealed vacuum tempered glass plate with an L-shaped stainless steel groove profile frame;

FIG. 41 is a cross-sectional view of a tempered glass plate with glass double-sided mutually adjacent bending support frames, single-sided composite distributed lattice embossing support salient points, and a double-glue sealed vacuum tempered glass plate buckled with an L-shaped stainless steel groove profile frame;

FIG. 42 is a cross-sectional view of a tempered glass plate complementarily fitted with double-sided composite distributed lattice embossing supporting bumps and a double-adhesive sealed vacuum tempered glass plate buckled with an L-shaped stainless steel groove profile frame, wherein the double-sided composite distributed lattice embossing supporting bumps are arranged on the double-sided mutually adjacent glass supporting frames;

FIG. 43 is a cross-sectional view of a double-sided mutually adjacent glass bending support frame, a double-sided composite toughened glass plate with lattice embossing support bumps distributed on both sides, a double-sided double-glue sealing vacuum toughened glass plate for stacking Luo Ge sheets, and a buckled L-shaped stainless steel groove profile frame;

FIG. 44 is a cross-sectional view of a tempered glass plate with glass double-sided mutually adjacent bending support frames, single-sided composite distribution of lattice stretching support salient points, and double-glue sealing vacuum tempered glass plates for buckling an L-shaped stainless steel groove profile frame;

FIG. 45 is a cross-sectional view of a tempered glass plate complementarily fitted with double-sided composite distributed lattice stretching supporting convex points and a double-adhesive sealed vacuum tempered glass plate buckled with an L-shaped stainless steel groove profile frame, wherein the double-sided composite distributed lattice stretching supporting convex points are provided with glass double-sided mutually-facing bending supporting frames;

FIG. 46 is a cross-sectional view of a double-sided mutually adjacent glass bending support frame, a double-sided composite glass sheet with lattice stretching support bumps distributed on both sides, a double-sided double-glue sealing vacuum tempered glass sheet for stacking Luo Ge sheets, and a buckled L-shaped stainless steel groove profile frame;

FIG. 47 is a cross-sectional view of a tempered glass plate with glass double-sided mutually adjacent bending support frames, single-sided composite distribution of lattice sintering support salient points, and double-glue sealing vacuum tempered glass plates for buckling an L-shaped stainless steel groove profile frame;

FIG. 48 is a cross-sectional view of a tempered glass plate complementarily fitted with double-sided composite distributed lattice sintering supporting bumps and a double-adhesive sealed vacuum tempered glass plate buckled with an L-shaped stainless steel groove profile frame, wherein the double-sided composite distributed lattice sintering supporting bumps are arranged on the double-sided mutually adjacent glass supporting frames;

FIG. 49 is a cross-sectional view of a double-sided mutually adjacent glass bending support frame, a double-sided composite toughened glass plate with lattice sintering support bumps distributed on both sides, a stack Luo Ge of the toughened glass plates, and a double-adhesive sealed vacuum toughened glass plate for buckling an L-shaped stainless steel groove profile frame;

FIG. 50 is a cross-sectional view of a tempered glass plate with glass double-sided mutually adjacent bending support frames, composite tempered glass plates with lattice bonding support bumps distributed thereon, and double-glue sealed vacuum tempered glass plates with buckled L-shaped stainless steel groove profile frames;

FIG. 51 is a cross-sectional view of a tempered glass plate with double-sided four-sided bending support frames and single-sided composite distributed lattice embossing support salient points, and a double-glue sealed vacuum tempered glass plate with an L-shaped stainless steel groove profile frame;

FIG. 52 is a cross-sectional view of a tempered glass plate complementarily fitted with double-sided composite distributed lattice embossing supporting bumps and a double-glue sealed vacuum tempered glass plate buckled with an L-shaped stainless steel groove profile frame, wherein the glass double-sided four-sided bending supporting frame is arranged;

FIG. 53 is a cross-sectional view of a double-sided four-sided bending support frame provided with glass, a double-sided composite toughened glass plate with lattice embossing support bumps distributed on both sides, a double-sided composite laminated Luo Ge-piece laminated glass plate, and a double-adhesive sealed vacuum toughened glass plate buckled with an L-shaped stainless steel groove profile frame;

FIG. 54 is a cross-sectional view of a tempered glass plate with double-sided four-sided bending support frames and single-sided composite distributed lattice stretching support salient points, and a double-glue sealed vacuum tempered glass plate with an L-shaped stainless steel groove profile frame;

FIG. 55 is a cross-sectional view of a tempered glass plate complementarily fitted with double-sided composite distributed lattice stretching support bumps and a double-glue sealed vacuum tempered glass plate buckled with an L-shaped stainless steel groove profile frame, wherein the glass double-sided four-sided bending support frame is provided with the invention;

FIG. 56 is a cross-sectional view of a double-sided four-sided bending support frame provided with glass, a double-sided composite toughened glass plate with lattice stretching support bumps distributed on both sides, a stack Luo Ge of the toughened glass plate, and a double-adhesive sealing vacuum toughened glass plate buckled with an L-shaped stainless steel groove profile frame;

FIG. 57 is a cross-sectional view of a tempered glass plate with double-sided four-sided bending support frames, single-sided composite distribution of lattice sintering support salient points, and double-glue sealing vacuum tempered glass plates for buckling an L-shaped stainless steel groove profile frame;

FIG. 58 is a cross-sectional view of a tempered glass plate complementarily fitted with glass double-sided four-sided bending support frames, double-sided composite distributed lattice sintering support salient points, and a double-glue sealed vacuum tempered glass plate buckled with an L-shaped stainless steel groove profile frame;

FIG. 59 is a cross-sectional view of a double-sided four-sided bending support frame provided with glass, a double-sided composite toughened glass plate with lattice sintering support bumps distributed on both sides, a stack Luo Ge of the toughened glass plate, and a double-adhesive sealing vacuum toughened glass plate buckled with an L-shaped stainless steel groove profile frame;

FIG. 60 is a cross-sectional view of a tempered glass plate with glass double-sided four-sided bending support frames, composite tempered glass plates with lattice bonding support salient points distributed and double-glue sealing vacuum tempered glass plates with buckled L-shaped stainless steel groove profile frames;

FIG. 61 is a cross-sectional view of a tempered glass plate with double-sided parallel bending support frames of glass, single-sided composite distributed lattice embossing support bumps, and double-sided glue sealing of a U-shaped corrugated stainless steel channel section frame, wherein a metal thin strip is arranged on the periphery of the tempered glass plate;

FIG. 62 is a cross-sectional view of a tempered glass plate complementarily fitted with double-sided composite distributed lattice embossing support bumps and a U-shaped corrugated stainless steel channel profile frame double-glue seal with a glass double-sided parallel bending support frame, and with a metal thin strip on the periphery of the tempered glass plate;

FIG. 63 is a cross-sectional view of a double-sided parallel glass bending support frame, a double-sided composite toughened glass plate with lattice embossing support bumps distributed on both sides, a double-sided glue seal for a stack Luo Ge of sheets, and a U-shaped corrugated stainless steel channel profile frame, wherein a metal thin strip is arranged on the periphery of the toughened glass plate;

FIG. 64 is a cross-sectional view of a tempered glass plate with double-sided parallel bending support frames for glass, single-sided composite distributed lattice stretching support bumps, and a double-sided glue seal of a U-shaped corrugated stainless steel channel section frame, with a metal ribbon on the periphery of the tempered glass plate;

FIG. 65 is a cross-sectional view of a tempered glass plate complementarily fitted with double-sided composite distributed lattice stretching support bumps and a double-sided adhesive seal of a U-shaped corrugated stainless steel channel section frame with a metal ribbon on the periphery of the tempered glass plate, provided with glass double-sided parallel bending support frames;

FIG. 66 is a cross-sectional view of a double-sided parallel glass bending support frame, a double-sided composite toughened glass plate with lattice stretching support bumps distributed on both sides, a double-sided glue seal for a stack Luo Ge of sheets, and a U-shaped corrugated stainless steel channel profile frame, wherein a metal thin strip is arranged on the periphery of the toughened glass plate;

FIG. 67 is a cross-sectional view of a toughened glass plate with double-sided parallel bending support frames of glass, single-sided composite distribution of lattice sintering support salient points, and double-glue sealing of a U-shaped corrugated stainless steel groove profile frame, wherein a metal thin strip is arranged on the periphery of the toughened glass plate;

FIG. 68 is a cross-sectional view of a tempered glass plate complementarily fitted with double-sided composite distributed lattice sintering support bumps and a "U" -shaped corrugated stainless steel channel profile frame double-glue seal with a glass double-sided parallel bending support frame, with a metal ribbon on the periphery of the tempered glass plate;

FIG. 69 is a cross-sectional view of a double-sided parallel glass bending support frame, a double-sided composite toughened glass plate with lattice sintering support bumps distributed on both sides, a double-sided glue seal for a stack Luo Ge of sheets, and a U-shaped corrugated stainless steel groove profile frame, wherein a metal thin strip is arranged on the periphery of the toughened glass plate;

FIG. 70 is a cross-sectional view of a toughened glass plate with double-sided parallel bending support frames for glass, composite laminated toughened glass plates with lattice adhesive support bumps, and double-sided adhesive sealing of a U-shaped corrugated stainless steel groove profile frame, wherein a metal thin strip is arranged on the periphery of the toughened glass plate;

FIG. 71 is a cross-sectional view of a tempered glass plate with double-sided mutually adjacent glass bending support frames, single-sided composite distributed lattice embossing support salient points, and double-sided glue sealing of a U-shaped corrugated stainless steel groove profile frame, wherein a metal thin strip is arranged on the periphery of the tempered glass plate;

FIG. 72 is a cross-sectional view of a tempered glass plate complementarily fitted with double-sided composite distributed lattice embossing support bumps and a U-shaped corrugated stainless steel channel section frame double-glue seal with a glass double-sided mutually facing bending support frame, and with a metal thin strip on the periphery of the tempered glass plate;

FIG. 73 is a cross-sectional view of a tempered glass plate with double-sided mutually adjacent glass bending support frames, double-sided composite distributed lattice embossing support salient points, for stacking Luo Ge sheets, and double-glue sealing of a U-shaped corrugated stainless steel groove profile frame, wherein a metal thin strip is arranged on the periphery of the tempered glass plate;

FIG. 74 is a cross-sectional view of a tempered glass plate with double-sided mutually adjacent glass bending support frames, single-sided composite distribution of lattice stretching support salient points, and double-sided glue sealing of a U-shaped corrugated stainless steel groove profile frame, wherein a metal thin strip is arranged on the periphery of the tempered glass plate;

FIG. 75 is a cross-sectional view of a tempered glass plate complementarily fitted with double-sided composite distributed lattice stretching support bumps and a double-sided adhesive seal of a U-shaped corrugated stainless steel channel section frame with a metal ribbon on the periphery of the tempered glass plate, provided with glass double-sided mutually facing bending support frames;

FIG. 76 is a cross-sectional view of a double-sided mutually adjacent glass bending support frame, a double-sided composite toughened glass plate with lattice stretching support bumps distributed on both sides, a double-sided double-glue seal for a stack Luo Ge of the toughened glass plate, and a U-shaped corrugated stainless steel groove profile frame, wherein a metal thin strip is arranged on the periphery of the toughened glass plate;

FIG. 77 is a cross-sectional view of a tempered glass plate with double-sided mutually adjacent glass bending support frames, single-sided composite distribution of lattice sintering support salient points, and double-sided glue sealing of a U-shaped corrugated stainless steel groove profile frame, wherein a metal thin strip is arranged on the periphery of the tempered glass plate;

FIG. 78 is a cross-sectional view of a tempered glass plate complementarily fitted with double-sided composite distributed lattice sintering support bumps and a double-sided adhesive seal of a U-shaped corrugated stainless steel channel section frame with metal strips on the periphery of the tempered glass plate, provided with glass double-sided mutually facing bending support frames;

FIG. 79 is a cross-sectional view of a toughened glass plate with double-sided mutually adjacent glass bending support frames, double-sided composite distributed lattice sintering support salient points, for stacking Luo Ge sheets, and double-glue sealing of a U-shaped corrugated stainless steel groove profile frame, wherein a metal thin strip is arranged on the periphery of the toughened glass plate;

FIG. 80 is a cross-sectional view of a composite distribution of a toughened glass plate with lattice adhesive support bumps and a double-glue seal of a U-shaped corrugated stainless steel channel section frame with glass double-sided mutually adjacent bent support frames, and a metal ribbon on the periphery of the toughened glass plate;

FIG. 81 is a cross-sectional view of a tempered glass plate with double-sided four-sided bending support frames, single-sided composite distributed lattice embossing support bumps, and a U-shaped corrugated stainless steel channel profile frame double-glue seal, with a metal thin strip on the periphery of the tempered glass plate;

FIG. 82 is a cross-sectional view of a tempered glass plate complementarily fitted with double-sided composite distributed lattice embossing support bumps and a U-shaped corrugated stainless steel channel profile frame double-glue seal with a glass double-sided four-sided bending support frame, and with a metal thin strip on the periphery of the tempered glass plate;

FIG. 83 is a cross-sectional view of a double sided composite distribution of lattice embossed support bumps for a stack Luo Ge of tempered glass plates with double sided composite distribution of glass double sided four sided folded support rims, and a double glue seal of a U-shaped corrugated stainless steel channel section frame, with a thin metal strip on the periphery of the tempered glass plates;

FIG. 84 is a cross-sectional view of a tempered glass plate with double-sided four-sided bending support frames and single-sided composite distribution of lattice stretching support bumps, and a U-shaped corrugated stainless steel groove profile frame double-glue seal, wherein the periphery of the tempered glass plate is provided with a metal thin strip;

FIG. 85 is a cross-sectional view of a tempered glass plate complementarily fitted with double-sided composite distributed lattice stretching support bumps and a U-shaped corrugated stainless steel channel section frame double-glue seal, wherein the periphery of the tempered glass plate is provided with a metal thin strip;

FIG. 86 is a cross-sectional view of a double-sided four-sided bending support frame provided with glass, a double-sided composite toughened glass plate with lattice stretching support bumps distributed on both sides, a double-sided glue seal for a stack Luo Ge of sheets, and a U-shaped corrugated stainless steel groove profile frame, wherein a metal thin strip is arranged on the periphery of the toughened glass plate;

FIG. 87 is a cross-sectional view of a toughened glass plate with double-sided four-sided bending support frames, single-sided composite distribution of lattice sintering support salient points, and double-sided glue sealing of a U-shaped corrugated stainless steel groove profile frame, wherein a metal thin strip is arranged on the periphery of the toughened glass plate;

FIG. 88 is a cross-sectional view of a tempered glass plate complementarily fitted with double-sided composite distributed lattice sintering support bumps and a U-shaped corrugated stainless steel channel profile frame double-glue seal with a glass double-sided four-sided bending support frame, and a metal thin strip arranged on the periphery of the tempered glass plate;

FIG. 89 is a cross-sectional view of a double-sided four-sided bending support frame provided with glass, a double-sided composite toughened glass plate with lattice sintering support bumps distributed on both sides, a double-sided glue seal for a stack Luo Ge of sheets, and a U-shaped corrugated stainless steel groove profile frame, wherein a metal thin strip is arranged on the periphery of the toughened glass plate;

FIG. 90 is a cross-sectional view of a toughened glass plate with double-sided four-sided bending support frames, composite laminated toughened glass plates with lattice bonding support bumps, and double-sided sealing of a U-shaped corrugated stainless steel groove profile frame, wherein a metal thin strip is arranged on the periphery of the toughened glass plate;

FIG. 91 is a cross-sectional view of a toughened glass plate with double-sided parallel bending support frames, single-sided composite distributed lattice embossing support bumps, double-sided adhesive sealing of a frame of an L-shaped stainless steel groove profile, and a metal thin strip arranged on the periphery of the toughened glass plate;

FIG. 92 is a cross-sectional view of a tempered glass plate complementarily fitted with double-sided composite distributed lattice embossing support bumps and a double-sided adhesive seal for buckling an L-shaped stainless steel groove profile frame, wherein the periphery of the tempered glass plate is provided with a metal thin strip;

FIG. 93 is a cross-sectional view of a toughened glass plate with double-sided parallel bending support frames, double-sided composite distributed lattice embossing support salient points, for stacking Luo Ge sheets, and double-glue sealing of an L-shaped stainless steel groove profile frame, wherein a metal thin belt is arranged on the periphery of the toughened glass plate;

FIG. 94 is a cross-sectional view of a toughened glass plate with double-sided parallel bending support frames for glass, single-sided composite distribution of lattice stretching support bumps, double-sided glue sealing for buckling an L-shaped stainless steel groove profile frame, and a metal thin strip arranged on the periphery of the toughened glass plate;

FIG. 95 is a cross-sectional view of a toughened glass plate complementarily fitting sheets with lattice stretching supporting convex points distributed on two sides in a composite manner and a double-glue seal for buckling an L-shaped stainless steel groove profile frame, wherein the two sides of the toughened glass plate are provided with glass double-side parallel bending supporting frames, and a metal thin belt is arranged on the periphery of the toughened glass plate;

FIG. 96 is a cross-sectional view of a tempered glass plate with double-sided parallel bending support frames, double-sided composite distribution of lattice stretching support salient points, for stacking Luo Ge sheets, and double-glue sealing of an L-shaped stainless steel groove profile frame, wherein a metal thin strip is arranged on the periphery of the tempered glass plate;

FIG. 97 is a cross-sectional view of a toughened glass plate with double-sided parallel bending support frames, single-sided composite distribution of lattice sintering support salient points, double-sided glue sealing of a frame of an L-shaped stainless steel groove profile, and a metal thin strip arranged on the periphery of the toughened glass plate;

FIG. 98 is a cross-sectional view of a toughened glass plate complementarily fitting sheets with lattice sintering supporting convex points distributed on two sides in a composite manner and a double-glue seal for buckling an L-shaped stainless steel groove profile frame, wherein the two sides of the toughened glass plate are provided with glass double-side parallel bending supporting frames, and a metal thin belt is arranged on the periphery of the toughened glass plate;

FIG. 99 is a cross-sectional view of a toughened glass plate with double-sided parallel bending support frames, double-sided composite distribution of lattice sintering support salient points, for stacking Luo Ge sheets, and double-glue sealing of an L-shaped stainless steel groove profile frame, wherein a metal thin strip is arranged on the periphery of the toughened glass plate;

FIG. 100 is a cross-sectional view of a toughened glass plate with double-sided parallel bending support frames for glass, composite distribution of lattice bonding support salient points, double-sided glue sealing for buckling an L-shaped stainless steel groove profile frame, and a metal thin strip arranged on the periphery of the toughened glass plate;

FIG. 101 is a cross-sectional view of a tempered glass plate with double-sided mutually adjacent glass bending support frames, single-sided composite distributed lattice embossing support salient points, double-sided glue sealing of a buckled L-shaped stainless steel groove profile frame, and a metal thin strip arranged on the periphery of the tempered glass plate;

FIG. 102 is a cross-sectional view of a tempered glass plate complementarily fitted with double-sided composite distributed lattice embossing supporting bumps and a double-sided adhesive seal for buckling an L-shaped stainless steel groove profile frame, wherein the periphery of the tempered glass plate is provided with a metal thin strip;

FIG. 103 is a cross-sectional view of a toughened glass plate with double-sided mutually adjacent glass bending support frames, double-sided composite distributed lattice embossing support salient points, for stacking Luo Ge sheets, and double-glue sealing of an L-shaped stainless steel groove profile frame, wherein a metal thin belt is arranged on the periphery of the toughened glass plate;

FIG. 104 is a cross-sectional view of a toughened glass plate with double-sided mutually adjacent glass bending supporting frames, single-sided composite distribution of lattice stretching supporting convex points, double-sided double-adhesive sealing of an L-shaped stainless steel groove profile frame, and a metal thin belt arranged on the periphery of the toughened glass plate;

FIG. 105 is a cross-sectional view of a toughened glass plate complementarily fitting a sheet with two sides compositely distributed with lattice stretching supporting convex points and a double-glue seal for buckling an L-shaped stainless steel groove profile frame, wherein the periphery of the toughened glass plate is provided with a metal thin belt;

FIG. 106 is a cross-sectional view of a toughened glass plate with double-sided mutually adjacent glass bending support frames, double-sided composite distributed lattice stretching support salient points, for stacking Luo Ge sheets, and double-glue sealing of an L-shaped stainless steel groove profile frame, wherein a metal thin belt is arranged on the periphery of the toughened glass plate;

FIG. 107 is a cross-sectional view of a toughened glass plate with glass double-sided mutually adjacent bending support frames, single-sided composite distribution of lattice sintering support salient points, double-glue sealing of a buckled L-shaped stainless steel groove profile frame, and a metal thin belt arranged on the periphery of the toughened glass plate;

FIG. 108 is a cross-sectional view of a toughened glass plate complementarily fitting a piece with two sides compositely distributed with lattice sintering supporting convex points and a double-glue seal for buckling an L-shaped stainless steel groove profile frame, wherein the periphery of the toughened glass plate is provided with a metal thin belt;

FIG. 109 is a cross-sectional view of a toughened glass plate with double-sided mutually adjacent glass bending support frames, double-sided composite distributed lattice sintering support salient points, for stacking Luo Ge sheets, and double-glue sealing of an L-shaped stainless steel groove profile frame, wherein a metal thin belt is arranged on the periphery of the toughened glass plate;

FIG. 110 is a cross-sectional view of a toughened glass plate with glass double-sided mutually adjacent bending support frames, composite toughened glass plate with lattice adhesive support bumps distributed thereon, and a double-adhesive seal for buckling an L-shaped stainless steel groove profile frame, wherein a metal thin strip is arranged on the periphery of the toughened glass plate;

FIG. 111 is a cross-sectional view of a toughened glass plate with double-sided four-sided bending support frames, single-sided composite distributed lattice embossing support bumps, double-sided glue sealing of a frame of an L-shaped stainless steel groove profile, and a metal thin strip arranged on the periphery of the toughened glass plate;

FIG. 112 is a cross-sectional view of a tempered glass plate complementarily fitted with double-sided composite distributed lattice embossing support bumps and a double-sided adhesive seal for buckling an L-shaped stainless steel groove profile frame, wherein the periphery of the tempered glass plate is provided with a metal thin strip;

FIG. 113 is a cross-sectional view of a toughened glass plate with double-sided four-sided bending support frames, double-sided composite distributed lattice embossing support salient points, for stacking Luo Ge sheets, and double-sided glue sealing of an L-shaped stainless steel groove profile frame, wherein a metal thin belt is arranged on the periphery of the toughened glass plate;

FIG. 114 is a cross-sectional view of a tempered glass plate with double-sided four-sided bending support frames, single-sided composite distributed lattice stretching support bumps, and double-sided glue sealing of a frame of an L-shaped stainless steel groove profile, wherein the periphery of the tempered glass plate is provided with a metal thin strip;

FIG. 115 is a cross-sectional view of a tempered glass plate complementarily fitted with two sides compositely distributed with lattice stretching supporting bumps and a double-glue seal for buckling an L-shaped stainless steel groove profile frame, wherein the periphery of the tempered glass plate is provided with a metal thin strip;

FIG. 116 is a cross-sectional view of a toughened glass plate with double-sided four-sided bending support frames, double-sided composite distribution of lattice stretching support salient points, for stacking Luo Ge sheets, and double-sided glue sealing of an L-shaped stainless steel groove profile frame, wherein a metal thin strip is arranged on the periphery of the toughened glass plate;

FIG. 117 is a cross-sectional view of a toughened glass plate with double-sided four-sided bending support frames, single-sided composite distribution of lattice sintering support salient points, double-sided sealing of a frame of an L-shaped stainless steel groove profile, and a metal thin strip arranged on the periphery of the toughened glass plate;

FIG. 118 is a cross-sectional view of a toughened glass plate complementarily fitting sheets with lattice sintering supporting convex points distributed on two sides and a double-glue seal for buckling an L-shaped stainless steel groove profile frame, wherein the toughened glass plate is provided with two sides and four sides of a bending supporting frame;

FIG. 119 is a cross-sectional view of a toughened glass plate with double-sided four-sided bending support frames, double-sided composite distribution of lattice sintering support salient points, for stacking Luo Ge sheets, and double-sided glue sealing of a buckled L-shaped stainless steel groove profile frame, wherein a metal thin belt is arranged on the periphery of the toughened glass plate;

FIG. 120 is a cross-sectional view of a toughened glass plate with glass bilateral four-sided bending support frames, composite toughened glass plate with lattice bonding support salient points distributed thereon, and double-glue sealing of a buckled L-shaped stainless steel groove profile frame, wherein a metal thin belt is arranged on the periphery of the toughened glass plate;

fig. 121 and 122 are schematic diagrams of connection of the air intake and exhaust system of the glass curtain wall according to the present invention.

In the figure: 1"U ' shaped stainless steel corrugated protective frame, 2 structural sealant, 3 lower side toughened plate glass, 4 airtight sealant, 5 upper side toughened plate glass, 6 embossing supporting convex points, 7 water glass, 8 supporting frame, 9 vacuum valve, 10 air inlet and exhaust pipe, 11 stretching supporting convex points, 12 sintering supporting convex points, 13 bonding supporting convex points, 14 inner side ' L ' shaped stainless steel protective frame, 15 side ' L ' shaped stainless steel protective frame, 16 metal thin belt, 17 refined vacuum pump, 18 vacuum gauge, 19 three-way pipe fitting, 20 dryer, 21 artificial intelligent controller, 22 dryer exhaust valve, 23 carbon dioxide gas tank, 24 argon gas tank, 25 helium gas tank, 26 oxyhydrogen tank, 27 air inlet pipe, 28 rough vacuum pump, 29 rough vacuum pump exhaust pipe, 30 refined vacuum pump exhaust pipe, 31 four-way pipe fitting.

Detailed Description

As shown in fig. 1: the parallel bending support frame 8 of the upper toughened glass 5 and the parallel bending support frame 6 of the lower toughened glass 3 distributed with lattice embossing support bumps 6 are mutually corresponding in outline shape and size, are complementarily buckled and form a vacuum interlayer at intervals. The closed-loop U-shaped stainless steel corrugated protective frame 1 is bonded with the structural sealant 2 and the airtight sealant 4 to prepare the tempered glass plate frame support mutually bonded stainless steel frame vacuum tempered glass plate. An air inlet and outlet pipe 10 is arranged on the vacuum toughened glass plate, and an exhaust vacuum valve 9 is arranged on the air inlet and outlet pipe 10.

As shown in fig. 2: lattice embossing supporting convex points 6 are distributed on the upper side toughened glass 5 and the lower side toughened glass 3, and the other is identical to the figure 1.

As shown in fig. 3: the toughened glass plates with lattice embossing supporting convex points 6 on the upper toughened glass 5 and the lower toughened glass 3 are opposite to the stack Luo Ge, and are otherwise identical to those in FIG. 1.

As shown in fig. 4: lattice stretching supporting convex points 11 are distributed on the lower toughened glass 3, and the lower toughened glass is otherwise identical to the lower toughened glass in fig. 1.

As shown in fig. 5: lattice stretching supporting convex points 11 are distributed on the upper side toughened glass 5 and the lower side toughened glass 3, and the other is identical to the drawing of fig. 1.

As shown in fig. 6: the toughened glass plates with lattice stretching supporting convex points 11 on the upper toughened glass 5 and the lower toughened glass 3 are opposite to the stack Luo Ge, and are otherwise identical to those in fig. 1.

As shown in fig. 7: lattice sintering supporting convex points 12 are distributed on the lower toughened glass 3, and are otherwise identical to those in fig. 1.

As shown in fig. 8: lattice sintering supporting convex points 12 are distributed on the upper side toughened glass 5 and the lower side toughened glass 3, and are otherwise identical to those in fig. 1.

As shown in fig. 9: the toughened glass plates with lattice sintering supporting convex points 12 on the upper toughened glass 5 and the lower toughened glass 3 are opposite to the stack Luo Ge, and are otherwise identical to those in FIG. 1.

As shown in fig. 10: the interlayer of the upper side toughened glass 5 and the lower side toughened glass 3 is compositely distributed with lattice bonding supporting convex points 13, and the other is identical to the figure 1.

As shown in fig. 11: the parallel bending support frame 8 of the upper side toughened glass 5 and the mutually adjacent bending support frame 6 of the lower side toughened glass 3 distributed with the lattice embossing support convex points 6 are mutually corresponding in outline shape and size, are mutually complementary buckled and form a vacuum interlayer at intervals. The closed-loop U-shaped stainless steel corrugated protective frame 1 is bonded with the structural sealant 2 and the airtight sealant 4 to prepare the tempered glass plate frame support mutually bonded stainless steel frame vacuum tempered glass plate. An air inlet and outlet pipe 10 is arranged on the vacuum toughened glass plate, and an exhaust vacuum valve 9 is arranged on the air inlet and outlet pipe 10.

As shown in fig. 12: lattice embossing supporting convex points 6 are distributed on the upper side toughened glass 5 and the lower side toughened glass 3, and the other is identical to fig. 11.

As shown in fig. 13: the toughened glass plates with lattice embossing supporting convex points 6 on the upper toughened glass 5 and the lower toughened glass 3 are opposite to the stack Luo Ge, and are otherwise identical to those in FIG. 11.

As shown in fig. 14: lattice stretching supporting convex points 11 are distributed on the lower toughened glass 3, and are otherwise identical to those in fig. 11.

As shown in fig. 15: lattice stretching supporting convex points 11 are distributed on the upper side toughened glass 5 and the lower side toughened glass 3, and the other is identical to fig. 11.

As shown in fig. 16: the toughened glass plates with lattice stretching supporting convex points 11 on the upper toughened glass 5 and the lower toughened glass 3 are opposite to the stack Luo Ge, and are otherwise identical to those in FIG. 11.

As shown in fig. 17: lattice sintering supporting convex points 12 are distributed on the lower toughened glass 3, and are otherwise identical to those in FIG. 11.

As shown in fig. 18: lattice sintering supporting convex points 12 are distributed on the upper side toughened glass 5 and the lower side toughened glass 3, and are otherwise identical to those in FIG. 11.

As shown in fig. 19: the toughened glass plates with lattice sintering supporting convex points 12 on the upper toughened glass 5 and the lower toughened glass 3 are opposite to the stack Luo Ge, and are otherwise identical to those in FIG. 11.

As shown in fig. 20: the interlayer of the upper side toughened glass 5 and the lower side toughened glass 3 is compositely distributed with lattice bonding supporting convex points 13, and the other is identical to the figure 11.

As shown in fig. 21: the parallel bending support frame 8 of the upper toughened glass 5 and the four-side bending support frame 6 of the lower toughened glass 3 distributed with the lattice embossing support salient points 6 are mutually corresponding in outline shape and size, are complementarily buckled and form a vacuum interlayer at intervals. The closed-loop U-shaped stainless steel corrugated protective frame 1 is bonded with the structural sealant 2 and the airtight sealant 4 to prepare the tempered glass plate frame support mutually bonded stainless steel frame vacuum tempered glass plate. An air inlet and outlet pipe 10 is arranged on the vacuum toughened glass plate, and an exhaust vacuum valve 9 is arranged on the air inlet and outlet pipe 10.

As shown in fig. 22: lattice embossing supporting convex points 6 are distributed on the upper side toughened glass 5 and the lower side toughened glass 3, and the other is identical to fig. 21.

As shown in fig. 23: the toughened glass plates with lattice embossing supporting convex points 6 on the upper toughened glass 5 and the lower toughened glass 3 are opposite to the stack Luo Ge, and are otherwise identical to those in fig. 21.

As shown in fig. 24: lattice stretching supporting convex points 11 are distributed on the lower toughened glass 3, and the lower toughened glass is otherwise identical to the lower toughened glass in fig. 21.

As shown in fig. 25: lattice stretching supporting convex points 11 are distributed on the upper side toughened glass 5 and the lower side toughened glass 3, and the other is identical to fig. 21.

As shown in fig. 26: the toughened glass plates with lattice stretching supporting convex points 11 on the upper toughened glass 5 and the lower toughened glass 3 are opposite to the stack Luo Ge, and are otherwise identical to those in fig. 21.

As shown in fig. 27: lattice sintering supporting convex points 12 are distributed on the lower toughened glass 3, and the lower toughened glass is otherwise identical to the lower toughened glass in fig. 21.

As shown in fig. 28: lattice sintering supporting convex points 12 are distributed on the upper side toughened glass 5 and the lower side toughened glass 3, and the other is identical to fig. 21.

As shown in fig. 29: the toughened glass plates with lattice sintering supporting convex points 12 on the upper toughened glass 5 and the lower toughened glass 3 are opposite to the stack Luo Ge, and are otherwise identical to those in fig. 21.

As shown in fig. 30: the interlayer of the upper side toughened glass 5 and the lower side toughened glass 3 is compositely distributed with lattice bonding supporting convex points 13, and the other is identical to fig. 21.

As shown in fig. 31: the parallel bending support frame 8 of the upper toughened glass 5 and the parallel bending support frame 6 of the lower toughened glass 3 distributed with lattice embossing support bumps 6 are mutually corresponding in outline shape and size, are complementarily buckled and form a vacuum interlayer at intervals. The buckled L-shaped stainless steel protective frame formed by the inner L-shaped stainless steel protective frame 14 and the outer L-shaped stainless steel protective frame 15 is bonded with the structural sealant 2 and the airtight sealant 4 to form a tempered glass plate frame support mutually bonded stainless steel frame vacuum tempered glass plate. An air inlet and outlet pipe 10 is arranged on the vacuum toughened glass plate, and an exhaust vacuum valve 9 is arranged on the air inlet and outlet pipe 10.

As shown in fig. 32: lattice embossing supporting convex points 6 are distributed on the upper side toughened glass 5 and the lower side toughened glass 3, and the other is identical to fig. 31.

As shown in fig. 33: the toughened glass plates with lattice embossing supporting convex points 6 on the upper toughened glass 5 and the lower toughened glass 3 are opposite to the stack Luo Ge, and are otherwise identical to those in fig. 31.

As shown in fig. 34: lattice stretching supporting convex points 11 are distributed on the lower toughened glass 3, and are otherwise identical to those in fig. 31.

As shown in fig. 35: lattice stretching supporting convex points 11 are distributed on the upper side toughened glass 5 and the lower side toughened glass 3, and the other is identical to fig. 31.

As shown in fig. 36: the toughened glass plates with lattice stretching supporting convex points 11 distributed on the upper toughened glass 5 and the lower toughened glass 3 are opposite to the stack Luo Ge, and are otherwise identical to those in fig. 31.

As shown in fig. 37: lattice sintering supporting convex points 12 are distributed on the lower toughened glass 3, and are otherwise identical to those in fig. 31.

As shown in fig. 38: lattice sintering supporting convex points 12 are distributed on the upper side toughened glass 5 and the lower side toughened glass 3, and the other is identical to fig. 31.

As shown in fig. 39: the toughened glass plates with lattice sintering supporting convex points 12 on the upper toughened glass 5 and the lower toughened glass 3 are opposite to the stack Luo Ge, and are otherwise identical to those in fig. 31.

As shown in fig. 40: the interlayer of the upper side toughened glass 5 and the lower side toughened glass 3 is compositely distributed with lattice bonding supporting convex points 13, and the other is identical to fig. 31.

As shown in fig. 41: the parallel bending support frame 8 of the upper side toughened glass 5 and the mutually adjacent bending support frame 6 of the lower side toughened glass 3 distributed with the lattice embossing support convex points 6 are mutually corresponding in outline shape and size, are mutually complementary buckled and form a vacuum interlayer at intervals. The buckled L-shaped stainless steel protective frame formed by the inner L-shaped stainless steel protective frame 14 and the outer L-shaped stainless steel protective frame 15 is bonded with the structural sealant 2 and the airtight sealant 4 to form a tempered glass plate frame support mutually bonded stainless steel frame vacuum tempered glass plate. An air inlet and outlet pipe 10 is arranged on the vacuum toughened glass plate, and an exhaust vacuum valve 9 is arranged on the air inlet and outlet pipe 10.

As shown in fig. 42: lattice embossing supporting convex points 6 are distributed on the upper side toughened glass 5 and the lower side toughened glass 3, and the other is identical to fig. 41.

As shown in fig. 43: the toughened glass plates with lattice embossing supporting convex points 6 on the upper toughened glass 5 and the lower toughened glass 3 are opposite to the stack Luo Ge, and are otherwise identical to those in fig. 41.

As shown in fig. 44: lattice stretching supporting convex points 11 are distributed on the lower toughened glass 3, and the lower toughened glass is otherwise identical to the lower toughened glass in fig. 41.

As shown in fig. 45: lattice stretching supporting convex points 11 are distributed on the upper side toughened glass 5 and the lower side toughened glass 3, and the other is identical to fig. 41.

As shown in fig. 46: the toughened glass plates with lattice stretching supporting convex points 11 distributed on the upper toughened glass 5 and the lower toughened glass 3 are opposite to the stack Luo Ge, and are otherwise identical to those in fig. 41.

As shown in fig. 47: lattice sintering supporting convex points 12 are distributed on the lower toughened glass 3, and the other is identical to fig. 41.

As shown in fig. 48: lattice sintering supporting convex points 12 are distributed on the upper side toughened glass 5 and the lower side toughened glass 3, and the other is identical to fig. 41.

As shown in fig. 49: the toughened glass plates with lattice sintering supporting convex points 12 on the upper toughened glass 5 and the lower toughened glass 3 are opposite to the stack Luo Ge, and are otherwise identical to those in fig. 41.

As shown in fig. 50: the interlayer of the upper side toughened glass 5 and the lower side toughened glass 3 is compositely distributed with lattice bonding supporting convex points 13, and the other is identical to fig. 41.

As shown in fig. 51: the parallel bending support frame 8 of the upper toughened glass 5 and the four-side bending support frame 6 of the lower toughened glass 3 distributed with the lattice embossing support salient points 6 are mutually corresponding in outline shape and size, are complementarily buckled and form a vacuum interlayer at intervals. The buckled L-shaped stainless steel protective frame formed by the inner L-shaped stainless steel protective frame 14 and the outer L-shaped stainless steel protective frame 15 is bonded with the structural sealant 2 and the airtight sealant 4 to form a tempered glass plate frame support mutually bonded stainless steel frame vacuum tempered glass plate. An air inlet and outlet pipe 10 is arranged on the vacuum toughened glass plate, and an exhaust vacuum valve 9 is arranged on the air inlet and outlet pipe 10.

As shown in fig. 52: lattice embossing supporting convex points 6 are distributed on the upper side toughened glass 5 and the lower side toughened glass 3, and the other is identical to fig. 51.

As shown in fig. 53: the toughened glass plates with lattice embossing supporting convex points 6 on the upper toughened glass 5 and the lower toughened glass 3 are opposite to the stack Luo Ge, and are otherwise identical to those in fig. 51.

As shown in fig. 54: lattice stretching supporting convex points 11 are distributed on the lower toughened glass 3, and the lower toughened glass is otherwise identical to the lower toughened glass in fig. 51.

As shown in fig. 55: lattice stretching supporting convex points 11 are distributed on the upper side toughened glass 5 and the lower side toughened glass 3, and the other is identical to fig. 51.

As shown in fig. 56: the toughened glass plates with lattice stretching supporting convex points 11 on the upper toughened glass 5 and the lower toughened glass 3 are opposite to the stack Luo Ge, and are otherwise identical to those in fig. 51.

As shown in fig. 57: lattice sintering supporting convex points 12 are distributed on the lower toughened glass 3, and are otherwise identical to those in fig. 51.

As shown in fig. 58: lattice sintering supporting convex points 12 are distributed on the upper side toughened glass 5 and the lower side toughened glass 3, and the other is identical to fig. 51.

As shown in fig. 59: the toughened glass plates with lattice sintering supporting convex points 12 on the upper toughened glass 5 and the lower toughened glass 3 are opposite to the stack Luo Ge, and are otherwise identical to those in fig. 51.

As shown in fig. 60: the interlayer of the upper side toughened glass 5 and the lower side toughened glass 3 is compositely distributed with lattice bonding supporting convex points 13, and the other is identical to fig. 51.

As shown in fig. 61: the parallel bending support frame 8 of the upper toughened glass 5 and the parallel bending support frame 6 of the lower toughened glass 3 distributed with lattice embossing support bumps 6 are mutually corresponding in outline shape and size, are complementarily buckled and form a vacuum interlayer at intervals. A layer of metal thin strip 16 with good plasticity is connected to the periphery of the buckled toughened glass plate through airtight sealant 4 and is used as an airtight sealing ring of an isolation sealing layer. The buckled toughened glass plates are bonded with the structural sealant 2, the airtight sealant 4 and the metal thin strip 16 through the closed-loop U-shaped stainless steel corrugated protective frame 1, and the vacuum toughened glass plates with the stainless steel frames bonded with each other are manufactured by the frame support of the toughened glass plates. An air inlet and outlet pipe 10 is arranged on the vacuum toughened glass plate, and an exhaust vacuum valve 9 is arranged on the air inlet and outlet pipe 10.

As shown in fig. 62: lattice embossing supporting convex points 6 are distributed on the upper side toughened glass 5 and the lower side toughened glass 3, and the other is identical to fig. 61. An air inlet and outlet pipe 10 is arranged on the vacuum toughened glass plate, and an exhaust vacuum valve 9 is arranged on the air inlet and outlet pipe 10.

As shown in fig. 63: the toughened glass plates with lattice embossing supporting convex points 6 on the upper toughened glass 5 and the lower toughened glass 3 are opposite to the stack Luo Ge, and are otherwise identical to the figure 61.

As shown in fig. 64: lattice stretching supporting convex points 11 are distributed on the lower toughened glass 3, and the lower toughened glass is otherwise identical to the lower toughened glass in fig. 61.

As shown in fig. 65: lattice stretching supporting convex points 11 are distributed on the upper side toughened glass 5 and the lower side toughened glass 3, and the other is identical to fig. 61.

As shown in fig. 66: the toughened glass plates with lattice stretching supporting convex points 11 distributed on the upper toughened glass 5 and the lower toughened glass 3 are opposite to the stack Luo Ge, and are otherwise identical to those in fig. 61.

As shown in fig. 67: lattice sintering supporting convex points 12 are distributed on the lower toughened glass 3, and are otherwise identical to those in fig. 61.

As shown in fig. 68: lattice sintering supporting convex points 12 are distributed on the upper side toughened glass 5 and the lower side toughened glass 3, and the other is identical to fig. 61.

As shown in fig. 69: the toughened glass plates with lattice sintering supporting convex points 12 on the upper toughened glass 5 and the lower toughened glass 3 are opposite to the stack Luo Ge, and are otherwise identical to the figure 61.

As shown in fig. 70: the interlayer of the upper side toughened glass 5 and the lower side toughened glass 3 is compositely distributed with lattice bonding supporting convex points 13, and the other is identical to the figure 61.

As shown in fig. 71: the parallel bending support frame 8 of the upper side toughened glass 5 and the mutually adjacent bending support frame 6 of the lower side toughened glass 3 distributed with the lattice embossing support convex points 6 are mutually corresponding in outline shape and size, are mutually complementary buckled and form a vacuum interlayer at intervals. A layer of metal thin strip 16 with good plasticity is connected to the periphery of the buckled toughened glass plate through airtight sealant 4 and is used as an airtight sealing ring of an isolation sealing layer. The buckled toughened glass plates are bonded with the structural sealant 2, the airtight sealant 4 and the metal thin strip 16 through the closed-loop U-shaped stainless steel corrugated protective frame 1, and the vacuum toughened glass plates with the stainless steel frames bonded with each other are manufactured by the frame support of the toughened glass plates. An air inlet and outlet pipe 10 is arranged on the vacuum toughened glass plate, and an exhaust vacuum valve 9 is arranged on the air inlet and outlet pipe 10.

As shown in fig. 72: lattice embossing supporting convex points 6 are distributed on the upper side toughened glass 5 and the lower side toughened glass 3, and the other is identical to fig. 71.

As shown in fig. 73: the toughened glass plates with lattice embossing supporting convex points 6 on the upper toughened glass 5 and the lower toughened glass 3 are opposite to the stack Luo Ge, and are otherwise identical to the figure 71.

As shown in fig. 74: the lower toughened glass 3 is distributed with lattice stretching supporting convex points 11, which are otherwise identical to those in fig. 71.

As shown in fig. 75: lattice stretching supporting convex points 11 are distributed on the upper side toughened glass 5 and the lower side toughened glass 3, and the other is identical to fig. 71.

As shown in fig. 76: the toughened glass plates with lattice stretching supporting convex points 11 distributed on the upper toughened glass 5 and the lower toughened glass 3 are opposite to the stack Luo Ge, and are otherwise identical to the figure 71.

As shown in fig. 77: lattice sintering supporting convex points 12 are distributed on the lower toughened glass 3, and are otherwise identical to the graph 71.

As shown in fig. 78: lattice sintering supporting convex points 12 are distributed on the upper side toughened glass 5 and the lower side toughened glass 3, and the other is identical to the graph 71.

As shown in fig. 79: the toughened glass plates with lattice sintering supporting convex points 12 on the upper toughened glass 5 and the lower toughened glass 3 are opposite to the stack Luo Ge, and are otherwise identical to the figure 71.

As shown in fig. 80: the interlayer of the upper side toughened glass 5 and the lower side toughened glass 3 is compositely distributed with lattice bonding supporting convex points 13, and the other is identical to the figure 71.

As shown in fig. 81: the parallel bending support frame 8 of the upper toughened glass 5 and the four-side bending support frame 6 of the lower toughened glass 3 distributed with the lattice embossing support salient points 6 are mutually corresponding in outline shape and size, are complementarily buckled and form a vacuum interlayer at intervals. A layer of metal thin strip 16 with good plasticity is connected to the periphery of the buckled toughened glass plate through airtight sealant 4 and is used as an airtight sealing ring of an isolation sealing layer. The buckled toughened glass plate is bonded with the structural sealant 2, the airtight sealant 4 and the metal thin strip 16 through a buckled L-shaped stainless steel protection frame consisting of an inner L-shaped stainless steel protection frame 14 and an outer L-shaped stainless steel protection frame 15, so that the toughened glass plate frame support and mutual bonding stainless steel frame vacuum toughened glass plate is manufactured. An air inlet and outlet pipe 10 is arranged on the vacuum toughened glass plate, and an exhaust vacuum valve 9 is arranged on the air inlet and outlet pipe 10.

As shown in fig. 82: lattice embossing supporting convex points 6 are distributed on the upper side toughened glass 5 and the lower side toughened glass 3, and the other is identical to fig. 81.

As shown in fig. 83: the toughened glass plates with lattice embossing supporting convex points 6 on the upper toughened glass 5 and the lower toughened glass 3 are opposite to the stack Luo Ge, and are otherwise identical to the graph 81.

As shown in fig. 84: lattice stretching supporting convex points 11 are distributed on the lower toughened glass 3, and the lower toughened glass is otherwise identical to the lower toughened glass in fig. 81.

As shown in fig. 85: lattice stretching supporting convex points 11 are distributed on the upper side toughened glass 5 and the lower side toughened glass 3, and the other is identical to fig. 81.

As shown in fig. 86: the toughened glass plates with lattice stretching supporting convex points 11 distributed on the upper toughened glass 5 and the lower toughened glass 3 are opposite to the stack Luo Ge, and are otherwise identical to the figure 81.

As shown in fig. 87: lattice sintering supporting convex points 12 are distributed on the lower toughened glass 3, and the other is identical to fig. 81.

As shown in fig. 88: lattice sintering supporting convex points 12 are distributed on the upper side toughened glass 5 and the lower side toughened glass 3, and the other is identical to fig. 81.

As shown in fig. 89: the toughened glass plates with lattice sintering supporting convex points 12 on the upper toughened glass 5 and the lower toughened glass 3 are opposite to the stack Luo Ge, and are otherwise identical to the graph 81.

As shown in fig. 90: the interlayer of the upper side toughened glass 5 and the lower side toughened glass 3 is compositely distributed with lattice bonding supporting convex points 13, and the other is identical to fig. 81.

As shown in fig. 91: the parallel bending support frame 8 of the upper toughened glass 5 and the parallel bending support frame 6 of the lower toughened glass 3 distributed with lattice embossing support bumps 6 are mutually corresponding in outline shape and size, are complementarily buckled and form a vacuum interlayer at intervals. A layer of metal thin strip 16 with good plasticity is connected to the periphery of the buckled toughened glass plate through airtight sealant 4 and is used as an airtight sealing ring of an isolation sealing layer. The buckled toughened glass plate is bonded with the structural sealant 2, the airtight sealant 4 and the metal thin strip 16 through a buckled L-shaped stainless steel protection frame consisting of an inner L-shaped stainless steel protection frame 14 and an outer L-shaped stainless steel protection frame 15, so that the toughened glass plate frame support and mutual bonding stainless steel frame vacuum toughened glass plate is manufactured. An air inlet and outlet pipe 10 is arranged on the vacuum toughened glass plate, and an exhaust vacuum valve 9 is arranged on the air inlet and outlet pipe 10.

As shown in fig. 92: lattice embossing supporting convex points 6 are distributed on the upper side toughened glass 5 and the lower side toughened glass 3, and the other is identical to fig. 91.

As shown in fig. 93: the toughened glass plates with lattice embossing supporting convex points 6 on the upper toughened glass 5 and the lower toughened glass 3 are opposite to the stack Luo Ge, and are otherwise identical to the graph 91.

As shown in fig. 94: lattice stretching supporting convex points 11 are distributed on the lower toughened glass 3, and the lower toughened glass is otherwise identical to the lower toughened glass in fig. 91.

As shown in fig. 95: lattice stretching supporting convex points 11 are distributed on the upper side toughened glass 5 and the lower side toughened glass 3, and the other is identical to fig. 91.

As shown in fig. 96: the toughened glass plates with lattice stretching supporting convex points 11 distributed on the upper toughened glass 5 and the lower toughened glass 3 are opposite to the stack Luo Ge, and are otherwise identical to the figure 91.

As shown in fig. 97: lattice sintering supporting convex points 12 are distributed on the lower toughened glass 3, and are otherwise identical to the graph 91.

As shown in fig. 98: lattice sintering supporting convex points 12 are distributed on the upper side toughened glass 5 and the lower side toughened glass 3, and the other is identical to the graph 91.

As shown in fig. 99: the toughened glass plates with lattice sintering supporting convex points 12 on the upper toughened glass 5 and the lower toughened glass 3 are opposite to the stack Luo Ge, and are otherwise identical to the graph 91.

As shown in fig. 100: the interlayer of the upper side toughened glass 5 and the lower side toughened glass 3 is compositely distributed with lattice bonding supporting convex points 13, and the other is identical to the figure 91.

As shown in fig. 101: the parallel bending support frame 8 of the upper side toughened glass 5 and the mutually adjacent bending support frame 6 of the lower side toughened glass 3 distributed with the lattice embossing support convex points 6 are mutually corresponding in outline shape and size, are mutually complementary buckled and form a vacuum interlayer at intervals. A layer of metal thin strip 16 with good plasticity is connected to the periphery of the buckled toughened glass plate through airtight sealant 4 and is used as an airtight sealing ring of an isolation sealing layer. The buckled toughened glass plate is bonded with the structural sealant 2, the airtight sealant 4 and the metal thin strip 16 through a buckled L-shaped stainless steel protection frame consisting of an inner L-shaped stainless steel protection frame 14 and an outer L-shaped stainless steel protection frame 15, so that the toughened glass plate frame support and mutual bonding stainless steel frame vacuum toughened glass plate is manufactured. An air inlet and outlet pipe 10 is arranged on the vacuum toughened glass plate, and an exhaust vacuum valve 9 is arranged on the air inlet and outlet pipe 10.

As shown in fig. 102: lattice embossing supporting convex points 6 are distributed on the upper side toughened glass 5 and the lower side toughened glass 3, and the other is identical to fig. 101.

As shown in fig. 103: the toughened glass plates with lattice embossing supporting convex points 6 on the upper toughened glass 5 and the lower toughened glass 3 are opposite to the stack Luo Ge, and are otherwise identical to the graph 101.

As shown in fig. 104: lattice stretching supporting convex points 11 are distributed on the lower toughened glass 3, and the lower toughened glass is otherwise identical to the drawing in fig. 101.

As shown in fig. 105: lattice stretching supporting convex points 11 are distributed on the upper side toughened glass 5 and the lower side toughened glass 3, and the other is identical to fig. 101.

As shown in fig. 106: the toughened glass plates with lattice stretching supporting convex points 11 distributed on the upper toughened glass 5 and the lower toughened glass 3 are opposite to the stack Luo Ge, and are otherwise identical to the graph 101.

As shown in fig. 107: lattice sintering supporting convex points 12 are distributed on the lower toughened glass 3, and are otherwise identical to the graph 101.

As shown in fig. 108: lattice sintering supporting convex points 12 are distributed on the upper side toughened glass 5 and the lower side toughened glass 3, and the other is identical to the graph 101.

As shown in fig. 109: the toughened glass plates with lattice sintering supporting convex points 12 on the upper toughened glass 5 and the lower toughened glass 3 are opposite to the stack Luo Ge, and are otherwise identical to the graph 101.

As shown in fig. 110: the interlayer of the upper side toughened glass 5 and the lower side toughened glass 3 is compositely distributed with lattice bonding supporting convex points 13, and the other is identical to the figure 101.

As shown in fig. 111: the parallel bending support frame 8 of the upper toughened glass 5 and the four-side bending support frame 6 of the lower toughened glass 3 distributed with the lattice embossing support salient points 6 are mutually corresponding in outline shape and size, are complementarily buckled and form a vacuum interlayer at intervals. A layer of metal thin strip 16 with good plasticity is connected to the periphery of the buckled toughened glass plate through airtight sealant 4 and is used as an airtight sealing ring of an isolation sealing layer. The buckled toughened glass plate is bonded with the structural sealant 2, the airtight sealant 4 and the metal thin strip 16 through a buckled L-shaped stainless steel protection frame consisting of an inner L-shaped stainless steel protection frame 14 and an outer L-shaped stainless steel protection frame 15, so that the toughened glass plate frame support and mutual bonding stainless steel frame vacuum toughened glass plate is manufactured. An air inlet and outlet pipe 10 is arranged on the vacuum toughened glass plate, and an exhaust vacuum valve 9 is arranged on the air inlet and outlet pipe 10.

As shown in fig. 112: lattice embossing supporting convex points 6 are distributed on the upper side toughened glass 5 and the lower side toughened glass 3, and the other is identical to the graph 111.

As shown in fig. 113: the toughened glass plates with lattice embossing supporting convex points 6 distributed on the upper toughened glass 5 and the lower toughened glass 3 are opposite to the stack Luo Ge, and are otherwise identical to those in fig. 111.

As shown in fig. 114: lattice stretching supporting convex points 11 are distributed on the lower toughened glass 3, and are otherwise identical to those in fig. 111.

As shown in fig. 115: lattice stretching supporting convex points 11 are distributed on the upper side toughened glass 5 and the lower side toughened glass 3, and the other is identical to the drawing in fig. 111.

As shown in fig. 116: the toughened glass plates with lattice stretching supporting convex points 11 distributed on the upper toughened glass 5 and the lower toughened glass 3 are opposite to the stack Luo Ge, and are otherwise identical to those in fig. 111.

As shown in fig. 117: lattice sintering supporting convex points 12 are distributed on the lower toughened glass 3, and are otherwise identical to those in fig. 111.

As shown in fig. 118: lattice sintering supporting convex points 12 are distributed on the upper side toughened glass 5 and the lower side toughened glass 3, and the other is identical to the graph 111.

As shown in fig. 119: the toughened glass plates with lattice sintering supporting convex points 12 on the upper toughened glass 5 and the lower toughened glass 3 are opposite to the stack Luo Ge, and are otherwise identical to those in fig. 111.

As shown in fig. 120: the interlayer of the upper side toughened glass 5 and the lower side toughened glass 3 is compositely distributed with lattice bonding supporting convex points 13, and the other is identical to the figure 111.

As shown in fig. 121: the air inlet and exhaust pipe of the double-glue sealing groove side support buckling interlayer regulation vacuum toughened glass plate is connected with the air inlet and exhaust pipe in a sealing parallel connection mode through a three-way pipe fitting 19 or a four-way pipe fitting 31 by using a mode of bolting the pipe fitting including welding, bonding and nut sealing. The air inlet and outlet pipeline is provided with a vacuum valve F3. A front vacuum gauge 18 is arranged in front of the vacuum valve F3, and a rear vacuum gauge 18 is arranged behind the vacuum valve F3. The air inlet and outlet pipeline is connected with the vacuum pump set through a pipe orifice at one end of the three-way pipe fitting 19; the other end pipe orifice of the three-way pipe fitting 19 is connected with the functional gas tank group through a vacuum valve F2.

The double-glue sealing groove edge support buckling interlayer regulation vacuum toughened glass plate provided with the air inlet and outlet pipe fittings as shown in fig. 121 comprises upper toughened glass 5 and lower toughened glass 3 distributed with lattice support convex points, and is mutually corresponding in outline shape and size, complementary buckling and interval forming hollow interlayer 4. And bonding and sealing the periphery of the glass through the structural sealant 1 and the airtight sealant 2 to prepare the vacuum adjustable toughened glass plate. An air inlet and outlet pipe fitting 8 is arranged on the vacuum toughened glass plate.

The air inlet and outlet pipeline is in sealing connection with a vacuum pump set through a pipe orifice at one end of a three-way pipe fitting 19, and the vacuum pump set is opened and closed through a numerical standard set by a vacuum meter 18; or variable frequency vacuum pump sets are powered out by a numerical standard set by the vacuum gauge 18.

The vacuum pump set is provided with a rough vacuum pump 28 and a fine vacuum pump 17, when the rough vacuum pump 28 pumps set vacuum, the rough vacuum pump 28 is closed, the fine vacuum pump 17 is started until the fine vacuum pump 17 is closed after the set vacuum is pumped; when the vacuum degree is reduced to a set value, starting the vacuum pump set again; or the vacuum pump set is a variable frequency vacuum pump set which continuously operates.

The vacuum pump set is provided with a rough vacuum pump and a fine vacuum pump which are connected in parallel, and the rapid vacuum pumping and the high vacuum pumping are realized by running the two groups of vacuum pumps of the rough vacuum pump 28 and the fine vacuum pump 17 in parallel or in series.

If the vacuum pump is closed F4 and F18, and opened F5, F6, F7, F8 and F19, the rough vacuum pump 28 is opened to vacuumize the system, and the gas is discharged through the exhaust pipe 18 of the rough vacuum pump 28 by the rough vacuum pump 28 and the vacuum valve F19.

After the vacuum degree of the gas pressure heat-preserving toughened glass plate with the function of regulating and controlling the interlayer at the periphery of the sealing glass is increased to a set value, the efficiency of the rough vacuumizing pump is greatly reduced. Closing the vacuum valves F5, F6, F7, F8, F18 and F19, and closing the rough vacuumizing pump; the fine vacuumizing pump 17 is started, the vacuum valves F4, F9, F10, F16 and F17 are opened until the set vacuum is pumped, the vacuum valves F4, F9, F10, F16 and F17 are closed, and then the fine vacuumizing pump 17 is started. When the vacuum degree is reduced to a set value, starting the vacuum pump set again;

or after the vacuum degree of the gas pressure heat-preserving toughened glass plate with the interlayer function of regulating and controlling the periphery of the sealing glass is increased to a set value, closing the vacuum valve F19, starting the fine vacuumizing pump 17, opening the vacuum valves F18, F9, F10, F16 and F17 until the set vacuum is pumped, closing the vacuum valves F5, F6, F7, F8, F18 and F19, and closing the rough vacuumizing pump; the vacuum valves F4, F9, F10, F16, F17 are then closed, and the vacuum pump 17 is refined. When the vacuum degree is reduced to a set value, starting the vacuum pump set again;

The air inlet and outlet pipeline is provided with a vacuum valve F2 connected with the pipe orifice at the other end of the three-way pipe fitting 19. A vacuum valve F2 controls the on-off functional gas inlet pipeline; a dryer assembly 20 is provided on an air intake duct provided before the vacuum valve F2; the dryer assembly is provided with an electric heating and dehumidifying device and an air outlet valve 22;

a plurality of groups of functional gas tanks including air are provided on the pipe before the dryer 20; the functional gas tank group comprises a low heat conductivity gas argon tank 24, a carbon dioxide gas tank 23, and a high heat conductivity gas comprising a hydrogen tank 26 and a helium tank 25;

The heat-insulating heat-dissipating light-transmitting toughened glass plate of the gas pressure heat-insulating toughened glass plate with the interlayer function of regulating and controlling the periphery of the sealing glass realizes good heat dissipation of the heat-insulating heat-dissipating light-transmitting toughened glass plate by introducing hydrogen or helium with high-heat-conductivity gas into the heat-insulating heat-dissipating light-transmitting toughened glass plate according to design requirements;

air is introduced into the heat-insulating heat-dissipating light-transmitting tempered glass plate, so that conventional heat dissipation of the heat-insulating heat-dissipating light-transmitting tempered glass plate is realized;

The conventional heat preservation of the heat-preserving heat-dissipating light-transmitting tempered glass plate is realized by introducing argon or carbon dioxide with low-heat-conductivity gas into the heat-preserving heat-dissipating light-transmitting tempered glass plate;

The heat-insulating heat-dissipating light-transmitting tempered glass plate is vacuumized, so that good heat preservation of the heat-insulating heat-dissipating light-transmitting tempered glass plate is realized.

The vacuum gauge 18 is a conventional vacuum gauge, or an artificial intelligent vacuum gauge, and the vacuum valve is a conventional vacuum valve, or an artificial intelligent vacuum valve.

As shown in fig. 122: a vacuum meter is arranged on the air inlet and exhaust pipe of the double-glue sealing groove edge support buckling interlayer regulation vacuum tempered glass plateAnd a vacuum valve F16, vacuum gauge/>Or an artificial intelligent vacuum gauge, a vacuum valve F16 or an artificial intelligent vacuum valve; the vacuum valve F16 is connected with the main air inlet and outlet pipeline 19 in a sealing parallel manner through a tee joint or a four-way pipe fitting in a bolting manner comprising welding, bonding and a nut sealing pipe fitting; otherwise identical to fig. 121. /(I)

Claims

1. The utility model provides a double glue seal groove limit supports lock intermediate layer regulation and control vacuum toughened glass board, includes toughened glass board, bonding sealant, stainless steel frame, characterized by: a communicating sealing pipe fitting which is adhered and sealed through airtight sealant and structural sealant is arranged on one of the two toughened glass plates; or one of the two toughened glass plates is provided with two communicated sealing pipe fittings which are adhered, sealed, screwed and locked through a connecting fastener and airtight sealing glue; or one of the two toughened glass plates is provided with a communicating sealing pipe fitting which is communicated with two sides and is sealed by brazing with low-melting-point metal brazing flux; or one of the two toughened glass plates is provided with two communicated sealing pipe fittings which are tightly screwed and locked by the brazing of the connecting fastener and the low-melting-point metal brazing flux;

(A) The method comprises the steps that two toughened glass plates forming a space interlayer cavity correspond to each other in outline shape and size, and embossed glass integrated with the toughened glass plates and uniformly distributed with dot matrix raised points or raised lines is arranged on one of at least two toughened glass plates;

The edges of the two toughened glass plates are provided with annular closed toughened glass plates with the same height as the protruding points and are bent and supported by frames in parallel; or the edges of the two toughened glass plates are provided with annular closed toughened glass plate bending support frames with the same height as the protruding points; or the edges of the two toughened glass plates are provided with annular closed toughened glass plate four-side bending support frames with the same height as the protruding points; or the edges of the two toughened glass plates are provided with annular closed toughened glass plates with the same total height as the total height of the annular closed toughened glass plates which are supported and overlapped by the raised points in a parallel bending manner; or the edges of the two toughened glass plates are provided with annular closed toughened glass plate bending support frames with the same total height as the total height of the raised points which are supported and overlapped relatively; or the edges of the two toughened glass plates are provided with annular closed toughened glass plate four-edge bending supporting frames with the same total height as the total height of the raised points which are supported and overlapped relatively;

the two pieces of embossed glass and flat glass with corresponding outline shapes and sizes, at least one of which is provided with convex points or convex lines, or the embossed glass and the embossed glass are adhered and sealed by bending and supporting frames at the edges of the tempered glass plates;

or a layer of metal thin strip with good plasticity is arranged on the periphery of the double-layer toughened glass plate bonded and sealed by the two toughened glass plate bonding sheets through airtight sealing and bonding, and is used as an airtight sealing ring of the isolation sealing layer;

(B) Or two toughened glass plates forming the interlayer cavity are mutually corresponding in outline shape and size, and at least one of the two toughened glass plates is provided with a lattice convex hull toughened glass plate formed by die pressing and stretching, or a corrugated toughened glass plate formed by die pressing and stretching;

A processed and formed annular closed toughened glass plate parallel bending support frame with the frame support height of the toughened glass plate corresponding to the convex hull or the convex corrugation and other heights is arranged between the edges of the two toughened glass plates and the edges of the two toughened glass plates in the outline shape and the size corresponding to the edges of the toughened glass plates; or the edge between two toughened glass plates is provided with a processed and formed annular closed toughened glass plate adjacent edge bending support frame which corresponds to the two toughened glass plates in outline shape and size to the edge of the toughened glass plates, wherein the frame support height of the toughened glass plates corresponds to the heights of the convex hulls or the convex corrugations; or the edge between two toughened glass plates is provided with a ring-shaped closed toughened glass plate four-side bending support frame which is formed by processing and corresponds to the two toughened glass plates in outline shape and size to the edge of the toughened glass plates, and the frame support height of the toughened glass plates is equal to the heights of the convex hulls or the convex corrugations;

Or the annular closed toughened glass plates are parallel to the bending support frame with the height equal to the total height of the opposite support superposition of the convex hulls of the dot matrix or the convex corrugations; or the annular closed toughened glass plate is parallel to the height of the bending support frame and the edges of the two toughened glass plates are provided with the annular closed toughened glass plate adjacent edge bending support frame with the same height as the dot matrix convex hulls or the total height of the opposite support superposition of the convex corrugations; or the annular closed toughened glass plate is parallel to the height of the bending support frame and the edges of the two toughened glass plates are provided with annular closed toughened glass plate four-side bending support frames with the same height as the dot matrix convex hulls or the total height of the opposite support superposition of convex corrugations;

the two contour shapes and the sizes are mutually corresponding, one or two of the two contour shapes and the sizes are provided with a lattice convex hull toughened glass plate which is formed by die pressing and stretching, or a corrugated toughened glass plate which is formed by die pressing and stretching, the supporting frame is stretched and bent through the edge of the toughened glass plate, the stretched convex hulls or stretched corrugations of the two toughened glass plates and the edge of the toughened glass plate are bent and supported along the edge of the toughened glass plate, and the point contact and surface contact mutually buckled sheets are bonded and sealed;

or a layer of metal thin strip with good plasticity is arranged on the periphery of the two mutually buckled sheets for bonding and sealing the toughened glass plate through airtight sealing and gluing and is used as an airtight sealing ring of the isolation sealing layer;

(C) Or two toughened glass plates forming the interlayer cavity are mutually corresponding in outline shape and size, at least two glass plates are manufactured by printing glass powder paste and then sintering; the sintered glass powder paste is cooled into glass supporting convex points after being melted;

the edges of the two toughened glass plates are provided with annular closed toughened glass plates with the same height as the protruding points and are bent and supported by frames in parallel; or the edges of the two toughened glass plates are provided with annular closed toughened glass plate bending support frames with the same height as the protruding points; or the edges of the two toughened glass plates are provided with annular closed toughened glass plate four-side bending support frames with the same height as the protruding points; or the edges of the two toughened glass plates are provided with annular closed toughened glass plates with the same total height as the total height of the annular closed toughened glass plates which are supported and overlapped by the raised points in a parallel bending manner; or the edges of the two toughened glass plates are provided with annular closed toughened glass plate bending support frames with the same total height as the total height of the raised points which are supported and overlapped relatively; or the edges of the two toughened glass plates are provided with annular closed toughened glass plate four-edge bending supporting frames with the same total height as the total height of the raised points which are supported and overlapped relatively; sintering glass powder paste, bending a supporting frame or synchronously carrying out glass tempering;

The two toughened glass plates are bonded and sealed by the point contact or line contact and surface contact bonding sheets of the two toughened glass plates and the annular sealing frame through the airtight sealant coated on the sealing surface of the bending support frame at the edges of the toughened glass plates;

(D) Or two toughened glass plates forming the interlayer cavity are mutually buckled with each other in the shape and the size of the outline, and at least one of the two toughened glass plates is provided with a support which is uniformly distributed in a lattice manner through bonding and is connected with the toughened glass plates into a whole;

The edges of the two toughened glass plates are provided with annular closed toughened glass plates with the same height as the support, and bending support frames are parallel to the annular closed toughened glass plates; or the edges of the two toughened glass plates are provided with annular closed toughened glass plate bending support frames with the same height as the support frame; or four sides of the annular closed toughened glass plate with the same height as the support are provided with bending support frames at the edges of the two toughened glass plates; or the edges of the two toughened glass plates are provided with annular closed toughened glass plates with the same height as the total height of the opposite supports in a superimposed manner, and are bent in parallel to support frames; or the edges of the two toughened glass plates are provided with annular closed toughened glass plate bending support frames with the same height as the total height of the opposite supports; or the edges of the two toughened glass plates are provided with annular closed toughened glass plate four-edge bending support frames with the same height as the total height of the opposite support stack;

The two toughened glass plates and the flat toughened glass plates which are provided with bonding supports or the bonding supports are bonded and sealed by bending the supporting frame through the edges of the toughened glass plates, and the two toughened glass plates and the annular sealing frame are in point contact and surface contact;

The outer side of the periphery of the hollow sandwich toughened glass plate body is wrapped with a closed-loop corrugated stainless steel frame with a U-shaped section, and a structural sealant which does not generate chemical reaction with the airtight sealant is filled in a groove of the corrugated stainless steel frame; stretching and sleeving the hollow sandwich toughened glass plate body by utilizing the self elasticity of a closed-loop corrugated stainless steel frame with a U-shaped section, and tightly attaching and bonding the closed-loop corrugated stainless steel frame with the U-shaped section and the outer side of the periphery of the hollow sandwich toughened glass plate body by utilizing the self resilience of the closed-loop corrugated stainless steel frame;

or the outer side of the periphery of the hollow sandwich toughened glass plate body is wrapped with a hollow sandwich toughened glass plate structure protection frame formed by buckling and sleeving a closed-loop stainless steel frame coated with structural sealant, wherein the cross section of the hollow sandwich toughened glass plate body is L-shaped and inverted L-shaped;

then, at least one tempered glass plate blank is sent into a vacuum furnace, heated and vacuumized; and then spraying water mist into the vacuum furnace or introducing high-humidity air and cooling, and opening the furnace after the cooling temperature is reached, so that the double-glue sealing groove is prepared while supporting and buckling the interlayer to regulate and control the vacuum toughened glass plate.

2. The double-glue sealing groove side-supported buckling interlayer regulation and control vacuum tempered glass plate according to claim 1, wherein the double-glue sealing groove side-supported buckling interlayer regulation and control vacuum tempered glass plate is characterized in that: the toughened glass plate comprises a glass raw sheet, toughened glass, cloth-grain glass, embossed glass, halogenated glass, frosted glass and coated glass, and functional films of the coated glass comprise an antireflection film, a metal film and a decorative film; the surface of the glass panel is compounded with a coating film, so that the coating film must be removed from the bonding surface of the glass panel; the toughened glass plate is double-layer or multi-layer laminated glass.

3. The double-glue sealing groove side-supported buckling interlayer regulation and control vacuum tempered glass plate according to claim 1, wherein the double-glue sealing groove side-supported buckling interlayer regulation and control vacuum tempered glass plate is characterized in that: the embossing of the convex points on the tempered glass plate is that when the flat glass raw sheet is produced, the convex points on the glass are rolled by a glass calender at a proper temperature position in a glass tin bath; a series of pits which are uniform in shape and size and are arranged according to the convex point support point array are engraved on the surface of one calendaring roller of the glass calendaring machine; cutting, edging and tempering the convex point embossing tempered glass plate;

or embossing the salient points to toughened glass plates into flat glass raw sheets, edging and shaping, heating by a toughening furnace, calendaring the salient points by a glass calendaring machine, bending the supporting frame, and carrying out toughening treatment after shaping; a series of pits which are uniform in shape and size and are arranged according to the convex point support point array are engraved on the surface of one calendaring roller of the glass calendaring machine;

Or convex hull toughened glass plates or corrugated toughened glass plates are formed by calendaring glass pits on a proper temperature position in a glass tin bath when producing flat glass raw sheets by a glass calendaring machine; the surface of one calendaring roller on the glass calendaring machine is carved with a series of convex points which are uniform in shape and size and are arrayed according to the lattice of the concave point supports; cutting, edging and tempering the concave embossing tempered glass plate;

Or the convex hull toughened glass plate or the corrugated toughened glass plate is subjected to edging and shaping, then is heated by a toughening furnace, the convex points are stretched by a glass die, the supporting frame is bent, and after shaping, toughening treatment is carried out;

Or the bump toughened glass plate is a glass raw sheet, and is manufactured by printing glass powder paste and then using a sintering method; printing low-temperature glass powder paste on a piece of flat glass according to the bump support object point array pattern, then sending the flat glass into a tempering sintering furnace, heating to a certain proper temperature of the melting point of the glass powder paste, converting a glass powder paste stack into glass bumps fused with the surface of the flat glass, and bending a support frame to perform tempering treatment;

Cutting the plate glass with proper thickness according to the designed size, edging, tempering and using the tempered glass panel as raw material; the surface of the glass is required to be deoiled, cleaned and dried.

4. The double-glue sealing groove side-supported buckling interlayer regulation and control vacuum tempered glass plate according to claim 1, wherein the double-glue sealing groove side-supported buckling interlayer regulation and control vacuum tempered glass plate is characterized in that: the support is a support with at least one end coated with an adhesive, and comprises a high-hardness glass support, a high-hardness metal support and a high-hardness ceramic support which are equal or close to the height of the closed-loop sealing support frame, and the columnar or spherical or annular supports are arrayed in a lattice shape; or the support is a support heat insulation material pad with an aerogel heat insulation pad adhered to the end support surface, and the surfaces of the aerogel heat insulation pads at the two ends of the support heat insulation material pad are coated with a hot melt adhesive, a glass adhesive, an ultraviolet curing adhesive or a water glass adhesive.

5. The double-glue sealing groove side-supported buckling interlayer regulation and control vacuum tempered glass plate according to claim 1, wherein the double-glue sealing groove side-supported buckling interlayer regulation and control vacuum tempered glass plate is characterized in that: the open hole on the hollow sandwich toughened glass plate body is arranged on the glass panel or on the closed-loop sealing support frame; the communicated sealing pipe fitting is a pipe fitting with a T-shaped section and provided with threads on the outer wall of a baffle pipe, the threads of the pipe fitting are correspondingly provided with screw caps with teeth ridges at the root parts, the screw caps are upwards conical, the pipe fitting is tightly screwed and sealed on a hollow interlayer toughened glass plate body through airtight sealant and the screw caps, or the outer wall of the pipe is provided with a threaded pipe fitting, the threads of the pipe fitting are correspondingly provided with screw caps with teeth ridges at the root parts and upwards conical, and the pipe fitting is tightly screwed and sealed on the hollow interlayer toughened glass plate body through airtight sealant and the screw caps; the sealing pipe fitting is provided with a fastening sealing pipe fitting corresponding to the opening of the toughened glass plate, the air inlet and outlet pipe head is tightly sealed and fixed on the opening of the air inlet and outlet pipe head on the toughened glass plate through airtight sealant and fastening sealing pipe fitting lock, the section of the sealing pipe fitting is T-shaped and provided with a blocking head, the blocking head is provided with a ventilation groove, and the outer wall of the pipe is provided with a threaded pipe fitting or is made of magnetic material.

6. The double-glue sealing groove side-supported buckling interlayer regulation and control vacuum tempered glass plate according to claim 1, wherein the double-glue sealing groove side-supported buckling interlayer regulation and control vacuum tempered glass plate is characterized in that: the periphery of the annular sealing glass or the annular sealing glass supporting frame is sealed and bonded through airtight sealant and structural sealant which do not generate chemical reaction mutually; the sealant at the inner sides of the peripheries of the two pieces of glass is first adhesive, and is bonded by airtight sealant; the first airtight sealant comprises butyl sealant, and the butyl sealant comprises polyisobutylene glue and hot melt butyl glue; the sealant at the outer sides of the peripheries of the two pieces of glass is second adhesive, and is adhered by structural sealant; the second sealant is a cured weather-proof structure sealant, and comprises an elastic sealant for glass, wherein the elastic sealant comprises polysulfide, silicone and polyurethane; the structural sealant in a hot-melt form comprises a hot-melt polyisobutylene adhesive and a hot-melt butyl adhesive;

7. The double-glue sealing groove side-supported buckling interlayer regulation and control vacuum tempered glass plate according to claim 1, wherein the double-glue sealing groove side-supported buckling interlayer regulation and control vacuum tempered glass plate is characterized in that: the outer side of the periphery of the hollow sandwich toughened glass plate body is wrapped with a closed-loop corrugated stainless steel frame with a U-shaped section; the U-shaped corrugated stainless steel groove section is formed by stamping and stretching a stainless steel plate strip through a die, or the U-shaped corrugated stainless steel groove section is formed by rolling a stainless steel plate strip through a rolling mill; the closed-loop corrugated stainless steel frame is a U-shaped corrugated stainless steel groove profile, and is made into an elastically contracted closed-loop corrugated stainless steel frame by bending and welding or cutting and welding;

8. The double-glue sealing groove side-supported buckling interlayer regulation and control vacuum tempered glass plate according to claim 1, wherein the double-glue sealing groove side-supported buckling interlayer regulation and control vacuum tempered glass plate is characterized in that: the outer side of the periphery of the hollow sandwich toughened glass plate body is wrapped with a hollow sandwich toughened glass plate structure protection frame formed by buckling and sleeving closed-loop stainless steel frames with L-shaped sections and reverse L-shaped sections; the L-shaped stainless steel section is a stainless steel strip, and is formed by stamping and stretching through a die, or the L-shaped stainless steel section is a stainless steel strip, and is formed by rolling through a rolling mill; the closed loop L-shaped stainless steel frame is made of L-shaped stainless steel sections through bending welding or cutting welding;

9. The double-glue sealing groove edge support buckling interlayer regulation and control vacuum tempered glass plate system according to claim 1, comprising a tempered glass plate, a vacuum valve, a vacuum meter, an air inlet and outlet pipeline and a vacuum pump group, wherein the tempered glass plate is provided with air inlet and outlet pipe fitting sealing glass periphery regulation and control interlayer functional gas pressure, and the system is characterized in that: at least one toughened glass plate provided with an air inlet and outlet pipe fitting, a sealing glass periphery and a function air pressure regulating and controlling a spacing interlayer, wherein the air inlet and outlet pipe fitting is connected with an air inlet and outlet pipe through a pipe fitting comprising a tee joint and a four-way joint in a sealing mode by using a mode comprising welding, bonding and screw cap sealing pipe fitting bolting, and is connected with an air inlet and outlet pipe in parallel in a sealing mode, and a vacuum gauge is connected on the air inlet and outlet pipe; the air inlet and outlet pipeline is in sealing connection with the vacuum pump set through a vacuum valve, and the vacuum pump set is opened and closed through a numerical standard set by a vacuum meter; or the variable-frequency vacuum pump set changes the power output through a numerical standard set by a vacuum meter;

The air inlet and outlet pipeline is provided with a functional air inlet pipeline which is connected and controlled by a vacuum valve and is controlled to be opened and closed by a preposed vacuum valve; a dryer component is arranged on an air inlet pipeline arranged in front of the vacuum valve; the dryer component is provided with an electric heating and dehumidifying device and an air outlet valve;

A plurality of groups of functional gas tanks comprising air are arranged on the pipeline in front of the dryer or are arranged on the pipeline in front of the dryer; the functional gas tank group comprises a low-heat-conductivity gas argon tank and a carbon dioxide gas tank, and the high-heat-conductivity gas comprises a hydrogen tank and a helium tank;

The vacuum gauge is a conventional vacuum gauge or an artificial intelligent vacuum gauge, and the vacuum valve is a conventional vacuum valve or an artificial intelligent vacuum valve;

The vacuum pump set is provided with a coarse vacuum pump and a fine vacuum pump, and the coarse vacuum pump and the fine vacuum pump can be operated in parallel or in series; or when the rough vacuumizing pump pumps to the set vacuum, the rough vacuumizing pump is closed, and the fine vacuumizing pump is started until the rough vacuumizing pump pumps to the set vacuum, and then the fine vacuumizing pump is closed; when the vacuum degree is reduced to a set value, starting the vacuum pump set again; or the vacuum pump set is a variable-frequency vacuum pump set which runs continuously;

After the vacuum degree of the gas pressure heat-preserving toughened glass plate with the sealing glass periphery regulating and controlling interval interlayer function is reduced to a set value, or a vacuum valve arranged on a pipe fitting of the vacuum valve is automatically closed, a vacuum pump measures the vacuum degree in the interlayer of the sealing glass periphery regulating and controlling interval interlayer function gas pressure heat-preserving toughened glass plate, whether the heat-preserving heat-dissipating light-transmitting toughened glass cover leaks vacuum or not is judged, and when the vacuum rises to or falls to the set value, the vacuum valve is automatically opened and closed;

The heat-insulating, heat-dissipating and light-transmitting toughened glass cover of the gas pressure heat-insulating toughened glass plate with the interlayer function is regulated and controlled at the periphery of the sealing glass, and good heat dissipation of the heat-insulating, heat-dissipating and light-transmitting toughened glass cover is realized by introducing hydrogen or helium with high-heat-conductivity gas into the heat-insulating, heat-dissipating and light-transmitting toughened glass cover according to design requirements;

The heat-insulating heat-radiating light-transmitting tempered glass cover is filled with air, so that the conventional heat radiation of the heat-insulating heat-radiating light-transmitting tempered glass cover is realized;

the conventional heat preservation of the heat-preserving heat-dissipating light-transmitting tempered glass cover is realized by introducing argon or carbon dioxide with low-heat-conductivity gas into the heat-preserving heat-dissipating light-transmitting tempered glass cover;

10. A method for manufacturing the double-glue sealing groove side-supporting buckling interlayer regulation and control vacuum toughened glass plate, which comprises the steps of toughened glass plate, bonding sealant and a vacuum furnace, and is characterized in that: a hollow interlayer is arranged between two toughened glass plates through a supporting frame, an airtight sealant is arranged on a sealing cover and a face of the sealing cover for bonding the two toughened glass plates with a closed-loop supporting frame or a metal section closed-loop support, and a structural sealant is filled in a peripheral groove of a hollow interlayer toughened glass plate body to form a sealing sealant ring with a sealing structure for bonding the closed-loop supporting frame or the metal section closed-loop supporting frame groove bottom and glass groove walls on two sides; manufacturing a hollow interlayer toughened glass plate blank;

Then horizontally placing at least one hollow interlayer toughened glass plate blank into a vacuum furnace provided with a supporting base, a fixed supporting clamp or a tray; the glass tray of the vacuum furnace is provided with an ultrasonic transducer for improving the bonding quality of glass and glass, glass and metal; closing a vacuum furnace door, and vacuumizing a hollow interlayer toughened glass plate blank in the vacuum furnace; the gas in the airtight sealant and the structural sealant is completely discharged; under the action of the self cohesive force after the contact gaps among the stainless steel, the glass and the stainless steel and the airtight sealant and the structural sealant are exhausted, the airtight sealant, the structural sealant, the glass bonding surface and the stainless steel bonding surface are fully immersed and wetted, so that the bonding of the airtight sealant and the structural sealant to the glass and the stainless steel frame is realized;

Meanwhile, as the groove of the stainless steel frame with the U-shaped closed loop in the cross section is designed deeper, the sealing glue layer of the closed loop structure corresponding to the groove is longer, so that the formed bonding connection sealing layer is thicker, the bonding strength of the structural sealing glue, glass and stainless steel is high, and the airtight sealing performance is good;

when the vacuum degree and the set vacuumizing time are reached, introducing high-humidity air into the vacuum furnace, and closing an exhaust vacuum valve arranged on the pipe orifice of the communicated sealing pipe fitting instantaneously; air generates pressure, and the stainless steel frame rapidly compacts the airtight sealant and the structural sealant layer in a softened state under the action of air pressure, so that the airtight sealant and the structural sealant layer are adhered and solidified;

Through the process, the bonding quality of glass and stainless steel through airtight sealant and structural sealant is improved; opening a vacuum furnace door to manufacture a heat-insulating toughened glass plate body, wherein a hollow air inlet and outlet communication sealing pipe fitting is arranged on the heat-insulating toughened glass plate body, two annular sealing adhesive sealing belts and a stainless steel closed-loop protection frame are arranged on the periphery of the toughened glass plate body, and the vacuum degree of a glass hollow interlayer is adjustable;

Or horizontally placing at least one hollow interlayer toughened glass plate blank into a vacuum furnace provided with a supporting base, a fixed supporting clamp or a tray; closing a vacuum furnace door, and heating and vacuumizing a hollow interlayer toughened glass plate blank in the vacuum furnace; the gas in the hot melt airtight sealant and the structural sealant is completely discharged; under the action of capillary action of contact gaps between stainless steel and glass, between glass and between stainless steel and the action of self cohesive force after the hot-melt airtight sealant and the structural sealant discharge gas, the bonding surfaces of the hot-melt airtight sealant, the structural sealant and the glass and the bonding surfaces of the stainless steel are fully immersed and wetted, so that the bonding of the hot-melt airtight sealant and the structural sealant to the glass and the stainless steel frame is realized;

When the heating temperature, the vacuum degree and the set vacuumizing time are reached, introducing high-humidity air into the vacuum furnace, and closing an exhaust vacuum valve arranged on a pipe orifice of the communicated sealing pipe fitting instantaneously; the air absorbs heat, heats up and expands to generate pressure, the stainless steel frame rapidly compacts the hot-melt airtight sealant and the structural sealant layer in a softened state under the action of air pressure, and releases heat to solidify, and then, or a cooling device arranged in the vacuum furnace is started to cool the vacuum furnace;

Or high-humidity air is introduced into the vacuum furnace, and an exhaust vacuum valve arranged on the pipe orifice of the communicated sealing pipe fitting is closed instantaneously; the air absorbs heat, heats up and expands to generate pressure, the stainless steel frame rapidly compacts the hot-melt airtight sealant and the structural sealant layer in a softened state under the action of air pressure, releases heat and solidifies, and then the vacuum furnace is cooled by discharging hot air and filling cold air or a cooling device arranged in the vacuum furnace is started to cool the vacuum furnace, so that the structural sealant in the stainless steel frame can be naturally cooled and solidified;

Through the process, the bonding quality of glass and stainless steel through hot melt airtight sealant and structural sealant is improved; when the temperature of the vacuum furnace is reduced to 50-55 ℃, the vacuum furnace door is opened, a hollow air inlet and outlet communicating sealing pipe fitting is arranged on the manufactured heat-preservation toughened glass plate body, two annular sealing bonding sealing belts and a stainless steel closed-loop protection frame are arranged on the periphery of the toughened glass plate body, and the vacuum degree of the hollow interlayer of the glass is adjustable, so that the heat-preservation daylighting toughened glass plate is manufactured.