WO2019223323A1

WO2019223323A1 - Ultra-high alumina glass product manufactured by means of industrial method employing novel cross-fired furnace production system

Info

Publication number: WO2019223323A1
Application number: PCT/CN2019/000091
Authority: WO
Inventors: 杨德宁
Original assignee: Yang Dening
Priority date: 2018-05-21
Filing date: 2019-05-07
Publication date: 2019-11-28
Also published as: CN110510868A

Abstract

An industrial method employing a novel cross-fired furnace production system and an ultra-high alumina glass product manufactured by means of the method. In percentage by weight, the content of aluminium oxide is 6%-19.9% or 20%-49%; the content of magnesium oxide is 5%-20%; the content of silicon oxide is 2.51-5.8 times that of calcium oxide; and the content of calcium oxide is 0.8-2.3 times that of magnesium oxide. The product is manufactured by means of the industrial method employing a novel cross-fired furnace production system.

Description

Ultra-high alumina glass product produced by a process method using a new lateral flame pool kiln production system

[Technical Field]

The invention belongs to the technical field of glass and relates to a process method using a transverse flame pool kiln production system to produce ultra-high aluminum glass products.

Technical solution of the present invention:

The invention belongs to a product claim that contains the characteristics of the preparation method. Not only the product has a novel composition and structure compared with the prior art, and the structure is novel; moreover, the innovative process of the present invention can lead to alumina than the prior art product. Microscopic changes and progress inside glass products with a content of 20--49%,

Compared with the ultra-high alumina glass products, the present invention can truly have different and stable-[transmittance, high strength, light-thinning, light-weight performance] inside the glass products of micro changes and improved product characteristics.

The present invention [a process method using a new horizontal flame pool kiln production system and ultra-high aluminum glass products produced] in the field of electronic flat glass, architectural and industrial flat glass, glass fiber, industrial or daily glassware and devices In this case, unexpected technical effects were produced.

The present invention [a process method using a new transverse flame tank kiln production system, and ultra-high alumina glass products produced] represents a technological development trend in these fields; the present invention also overcomes the above-mentioned fields of use, people Technical problems that are eager to solve but have never been successful.

[Prior art]

(1) Prior comparative technology 1: The present inventor's prior invention: the application and related components of high-strength, flatness and low-viscosity flat glass with high annealing points, environmental protection, energy saving and emission reduction, patent number 201110060944.4.

(2) Prior invention 2: 201510161553.61 of the present inventor, a flat glass with a low thermal expansion coefficient and a preparation process thereof.

(3) The third invention: the inventor's: PCT / CN2015 / 000795, an application of low difference in thermal expansion coefficient, low crystallization speed, super high strength, high softening point, fireproof and explosion-proof flat glass in high temperature region .

(4) Invention 4: The present inventor's: PCT / CN2015 / 000793, a low crystallization temperature, low crystallization speed, high temperature resistance, ultra-high aluminum glass fiber application, preparation method thereof, and composite material.

(5) Prior Invention No. 5: The inventor's: PCT / CN2015 / 000794, an application of low difference in thermal expansion coefficient, low crystallization speed, high softening point, high temperature resistant explosion-proof glassware or glass daily necessities in high temperature area .

(6) In the prior art, Corning Corporation ’s electronic flat-panel cover gorilla 1-4 generations, 15-22% alumina; but containing calcium oxide less than 1%, not in the present invention [silicon oxide content is oxidized The content of calcium is 2.51 to 5.8 times, and the content of calcium oxide is in the range of 0.8 to 2.3 times that of magnesium oxide.

In the prior art, S grade glass fiber contains 23-25-26% alumina, but it contains less than 1% calcium oxide, which is not in the present invention. [The silicon oxide content is 2.51-5.8 of the calcium oxide content Times, the calcium oxide content is in the range of 0.8 to 2.3 times the magnesium oxide content].

And the above-mentioned prior arts are all adopted in the process-only about 10CM diameter platinum channel technology, the output is very small; none of the process technology production methods of the present invention.

(7) Prior to the electrolysis kiln technology and flame kiln technology, the existing technology of all-electric melting kiln glass production equipment mainly produces low aluminum products with alumina content of 1-4% and alumina content of 5- 9% medium aluminum products, high aluminum products with alumina content of 10-16%.

Prior to the electrolysis kiln technology and flame kiln technology, it did not have the characteristics of several technical elements of the process method of the present invention. Therefore, the prior electrolysis kiln technology did not have the technological conditions to overcome its technical difficulties.

Prior to the electrolysis kiln process technology and flame kiln process technology, the main considerations were the melting of the glass, the removal of air bubbles, and the homogenization of the glass liquid. It was hoped that the formation of the electric field [temperature field] between the electrodes was uniform. Without the requirements of the present invention, the requirements for the design of 3-20 electrode devices in a specific area of the glass liquid in a region 5-30CM away from the bottom refractory in a plurality of regions, and without the requirements of the present invention The working process temperature of the glass liquid in a region with a distance of 5-30CM from the bottom of the refractory in a plurality of areas with a volume of at least 100 cubic CM must be maintained at 1320 ° C-1450 ° C, which is higher than the distance from the bottom Process method for working glass temperature of refractory within 30-60CM distance from 20-80 ℃.

First, the present invention [a process method using a new transverse flame tank kiln production system, ultra-high alumina glass products produced] and the technical solutions of the prior inventions (1)-(7) and the components of any prior technical solutions The structures are different: according to the present invention, the alumina content is 20% -49% by weight percentage; the magnesium oxide content is 5% -20%, the silicon oxide content is 2.51-5.8 times the calcium oxide content, and the calcium oxide content is The content is 0.8 times to 2.3 times the magnesium oxide content; therefore, the present invention is novel.

In addition, the preparation method of the process features according to the present invention is also different from the technical solutions of the prior inventions (1) to (7) and any of the prior technical solutions. The characteristics of the preparation method described in the present invention can produce completely different from the previous similar products. [The glass has no milky white aluminum-rich stripes or aluminum-rich blocks at all, and the characteristics of glass delamination have no alumina content of 20- -49% glass products].

However, if the characteristics of the preparation method described in the present invention are not adopted, glass products with an alumina content of 20-49% will be susceptible to major defects such as milky white aluminum-rich stripes or opaque aluminum-rich blocks, or Major defects in glass delamination occurred.

[Summary of the Invention]

[A] The composition of glass products is: based on weight percentage, its alumina content is 20% -49%; magnesium oxide content is 5% -20%; silicon oxide content is 2.51-5.8 times of calcium oxide content; The calcium content is 0.8 times to 2.3 times the magnesium oxide content;

[B] A process method using a new horizontal flame pool kiln production system is:

(a) Prepare the production equipment of the horizontal flame tank kiln, including:

Flame thermal energy dominates glass melting in a transverse flame cell kiln crusting device (10); glass liquid chuck channel device (60); uses electrodes to temperature control the glass liquid flowing from top to bottom to clarify, remove bubbles and Anti-crystallization device (30); bottom flow channel (20); glass liquid ascending channel structure (40) for temperature control of glass liquid flowing from bottom to top using electrodes; molding device (50) for glass products:

The depth of the glass liquid flow channel device (60) between the surface of the liquid glass and the bottom of the device is the horizontal flame pool kiln crusting device (10) that uses flame thermal energy to dominate glass melting and uses electrode pairs from top to bottom. 10% -40% of the depth between the surface of the glass liquid and the bottom of the device in the device (30) for clarifying, de-airing and anti-crystallization of the glass liquid flowing downward; (60) 3-20 electrode devices are designed in the glass liquid in the area 5-30CM from the bottom refractory;

It uses electrodes to control the temperature of the glass liquid flowing from top to bottom to clarify, remove bubbles and prevent the crystallization (30). Around the device is designed 4-50 electrodes to control the temperature of the glass liquid. The glass liquid in the lower flowing glass liquid for temperature control clarification, degassing and anti-crystallizing device (30) is located at a distance of 5-30CM from the bottom refractory, and 3-20 electrode devices are designed;

3-20 electrode devices are designed in the glass liquid in the bottom liquid flow channel (20) in the area 5-30CM away from the bottom refractory;

The glass liquid ascending channel structure adopting electrodes to control the temperature of the glass liquid flowing from bottom to top-(40) is designed with 4-50 electrodes for controlling the temperature of the liquid glass; In the glass liquid in the area of 5-30CM, 3-20 electrode devices are designed;

Desired devices: flame flame kiln crusting device (10) for glass melting, squeegee channel device (60) for glass liquid, electrode for temperature controlled clarification of glass liquid flowing from top to bottom The device for removing air bubbles and preventing crystallization (30), adopts electrodes to control the temperature of the glass liquid flowing from bottom to top, the glass liquid rising channel structure (40), and the glass product forming device (50); Of the electrode energy, when the glass product forming device (50) stops working, the glass liquid in the respective device is maintained above 1300 ° C and above the glass crystallization temperature;

(b) A process method of a new horizontal flame pool kiln production system for the production of ultra-high aluminum glass products, the process is as follows:

Prepare the required devices: the flame heating kiln crusting device (10) for the glass melting, the glass liquid chuck channel device (60), the temperature of the glass liquid flowing from top to bottom is controlled by electrodes Device (30) for clarification, degassing, and anti-crystallization, using electrodes for glass liquid ascending channel structure (40) for temperature control of glass liquid flowing from bottom to top, forming device (50) of glass products; The energy of the electrodes in the device can keep the glass liquid in the respective devices above 1300 ° C and above the glass crystallization temperature when the glass product forming device (50) stops working;

Step 1. The predetermined glass raw material is passed through a glass raw material transport device into a lateral flame pool kiln crusting device (10) where flame thermal energy predominates glass melting, and is melted to form a glass liquid, and the glass liquid passes through the neck of the glass liquid. Channel device (60), which enters from the upper part of the side into the clarification, bubble removal and anti-crystallization device (30) for controlling the temperature of the glass liquid flowing from top to bottom using electrodes; and the card neck channel device (60) ) And the temperature of the glass liquid in the clarifying, bubble-releasing and crystallizing preventing device (30) controlled by the electrode for the glass liquid flowing from top to bottom, are controlled to be higher than the clarifying and bubble-releasing 10 ² Pa · s Above the viscosity temperature and above the glass crystallization temperature;

The process is characterized by passing 3 to 20 electrode devices in the glass liquid in the region of the glass liquid in the area of 5-30CM from the bottom refractory through the glass liquid channel device (60), so that the liquid channel device (60) In the region of the glass liquid at a distance of 10-30CM from the bottom of the refractory, the working process temperature of the zone with a volume of at least 100 cubic CM must be maintained at 1320 ℃ -1450 ℃, which is higher than 30-60CM from the bottom refractory The working process temperature of the liquid glass in the distance area is 20-80 ℃;

The process features: temperature controlled clarification, bubble removal and anti-crystallization equipment (30) designed by glass liquid flowing from top to bottom. The glass liquid in the area 5-30CM away from the bottom refractory, each 3 -20 electrode devices, in the glass liquid in the area of 5-30cm distance from the bottom of the refractory, for the temperature control of the glass liquid flowing from top to bottom for clarification, bubble elimination and anti-crystallization equipment (30), The working process temperature in the area with a minimum volume of 100 cubic CM should be maintained at 1320 ° C-1450 ° C, which is higher than the working process temperature of the glass liquid in the area 30-60CM away from the bottom refractory material 20-80 ° C;

Step 2. Make the glass liquid from the bottom of the liquid flow channel (20) entering the bottom liquid flow channel (20) by using the electrode to lower the temperature of the glass liquid flowing from the top to the bottom, and remove the bubbles. A connected glass liquid ascending channel structure using electrodes for temperature control of glass liquid flowing from bottom to top (40);

The process is characterized by the design of 3-20 electrode devices in the glass liquid in the bottom liquid flow channel (20), 5-30CM away from the bottom refractory, and the bottom liquid flow channel (20) area. In the glass liquid in the area of 5-30CM distance from the bottom of the refractory material, the working process temperature in the section with a volume of at least 100 cubic CM must be maintained at 1320 ℃ -1450 ℃, which is higher than the distance of 30-60CM from the bottom refractory material. Regional glass liquid working process temperature 20-80 ℃;

The process is characterized by: designed in the glass liquid ascending channel structure (40) for temperature control of glass liquid flowing from bottom to top by using electrodes, in the glass liquid in the area 5-30CM from the bottom refractory, the designed 3- 20 electrode devices, so that the working process temperature of the glass liquid in the area of the bottom flow channel (20), at a distance of 5-30CM away from the bottom of the refractory material, has a volume of at least 100 cubic CM, which must be maintained at 1320 ° C- 1450 ° C, which is 20-80 ° C higher than the working process temperature of the glass liquid in the area 30-60CM away from the bottom refractory;

The process is characterized by the design of 3-20 electrode devices in the glass liquid in the area 5-30CM away from the bottom refractory, so that the bottom liquid flow channel (20) area is 5-30CM away from the bottom of the refractory. In the region of the liquid glass, the working process temperature of the zone with a volume of at least 100 cubic CM must be maintained at 1320 ° C to 1450 ° C, which is higher than the working process temperature of the liquid glass in the area at a distance of 30-60CM from the bottom refractory material. ℃

Step 3. The glass liquid flows from the bottom liquid flow channel (20) and enters the glass liquid rising channel structure (40) for controlling the temperature of the glass liquid flowing from bottom to top with an electrode;

The process is characterized by a glass liquid ascending channel structure (3-20 electrode devices designed by the glass liquid in the area 5-30CM away from the bottom refractory, using electrodes to temperature control the glass liquid flowing from the bottom up) 40) In the glass liquid in the area with a distance of 5-30CM from the bottom of the refractory material, the working process temperature of the zone with a volume of at least 100 cubic CM must be maintained at 1320 ° C-1450 ° C, which is higher than 30 from the bottom refractory The working process temperature of the glass liquid in the region of -60CM distance is 20-80 ℃;

Step 4. Selection of molding process:

Selection of the first glass product molding process: The aforementioned glass liquid passing through the top outlet of the ascending channel structure (40) enters the glass product molding device (5); the glass product molding device (5) is float plate glass The tin kiln structure of the process; the molten glass enters the flat surface of the tin kiln structure which is melted with tin metal, and the glass liquid is thinned and polished; and then the glass ribbon formed by the pair of 10-40 pairs of edger is pulled on both sides To the required thickness; and then annealing and cutting to form a float plate glass product; or

Selection of the second glass product molding process: the aforementioned glass liquid that passes through the top outlet of the ascending channel structure (40) enters the main channel of the glass liquid, and the glass liquid enters and is connected with 2-30 glass liquid distribution channels; the glass liquid Enter the molding device for glass fiber production of the glass products connected to each of the shunts; flow into the corresponding 2-30 dry pots carrying the glass liquid, and the glass liquid passes through the corresponding 2-30 drawing boards, in the corresponding drawing machine. Forms glass fibers under action; or

Choice of the third glass product molding process: the aforementioned glass liquid passing through the top outlet of the ascending channel structure (40) enters the main channel of the glass liquid, and the glass liquid enters and is connected with 2-30 glass liquid distribution channels; the glass liquid Enter the 2-30 industrial and daily glassware blow molding devices of the glass products connected to each of the shunts; blow the products of industrial and daily glass separately; and then process them by the annealing device of the glass products. Blow moulded products for industrial and household glass; or

Choice of the fourth glass product molding process: The aforementioned glass liquid that passes through the top outlet of the ascending channel structure (40) enters the main channel of the glass liquid, and the glass liquid enters and is connected with 2-30 glass liquid branching channels; the glass liquid Enter the 2-30 industrial and daily glassware press forming devices of the glass products connected to each of the shunts; press the products of industrial and daily glass respectively; and then process them by the annealing device of glass products to make industrial and Pressed molded articles of daily glass; or

Selection of the fifth glass product molding process: The aforementioned glass liquid passing through the top outlet of the ascending channel structure (40) enters the main channel of the glass liquid, and the glass liquid enters and is connected with 2-30 glass liquid branching channels; the glass liquid Enter the 2-30 industrial and daily glass drawing devices of the glass products connected to each of the shunts, draw the industrial and daily glass products respectively; and then process them through the annealing device of the glass products to make Drawn products of industrial and household glass; or

Choice of the sixth glass product molding process: The aforementioned glass liquid that has passed through the top outlet of the ascending channel structure (40) enters the main channel of the glass liquid, and the glass liquid enters and is connected with 2-30 glass liquid distribution channels; the glass liquid Enter the blow molding device of 2-30 sanitary glass products connected to the glass products of each shunt, and make sanitary glass products respectively; and then process the annealing device of the glass products to make sanitary glass products.

A glass window comprising a resin frame or a metal frame supporting device installed on the four perimeters of the glass; characterized in that its glass is [an ultra-high aluminum glass product produced by a process method of a new horizontal flame pool kiln production system] The flat glass according to claim 1 is required.

A colored glaze flat glass, characterized in that the glass surface has colored glaze layers of 1 to 10 colors; its glass is [an ultra-high aluminum glass product produced by a new horizontal flame pool kiln production system process method] The flat glass according to claim 1 is required.

A kind of hollow glass includes support devices on the four perimeters of each layer of glass; there is a vacuum insulation space of 3-50mm between each layer of glass; its characteristics are: its glass is [a new transverse flame tank kiln production system The ultra-high alumina glass products produced by the method] The flat glass according to claim 1.

A glass curtain wall of a building, the glass is fixed on an upper metal supporting device; characterized in that the glass is [an ultra-high aluminum glass product produced by a process method of a new horizontal flame pool kiln production system] as claimed in claim 1 The described flat glass.

An ultra-large area building with thin glass windows, characterized in that the thickness of its glass is 4 to 10 mm, the size of its glass is 3 to 40 square meters, or the thickness of its glass is .4 to 20 mm, and the size of its glass It is 15.1 to 80 square meters; the glass is the flat glass according to claim 1 [a high-aluminum glass product produced by a process method of a new horizontal flame pool kiln production system].

A tempered glass, characterized in that the glass is made by chemical tempering or physical tempering; the glass is [ultra-high alumina glass products produced by a new transverse flame tank kiln production system process method] plate glass.

A tempered glass countertop furniture, characterized in that: a supporting device is provided below the countertop; and the glass is [a high-aluminum glass product produced by a process method of a new horizontal flame pool kiln production system] the flat glass according to claim 1 .

A laminated glass is characterized in that a resin material layer is provided between each layer of the glass; the glass is [an ultra-high aluminum glass product produced by a process method of a new horizontal flame pool kiln production system] The described flat glass.

A bullet-proof and explosion-proof glass, characterized in that each glass plate is bonded by a resin sheet; and the glass is [an ultra-high aluminum glass product produced by a process method of a new horizontal flame pool kiln production system] The described flat glass.

A color-glazed glass plate combination cabinet is characterized in that: the glass surface has a color glaze layer of 1 to 10 colors on the back surface; the color-glazed glass plate combination cabinet is surrounded by a metal frame around the flat glass; and the color-glazed glass plate combination cabinet There is a metal connecting device between the metal frames; the glass is the flat glass according to claim 1 [a high-aluminum glass product produced by a process method of a new horizontal flame pool kiln production system].

A color glaze glass panel combined sliding door cabinet is characterized in that: there are 1-10 colors of colored glaze layers on the surface or back of the combined sliding glass door cabinet; there is a metal frame around the glass of the combined sliding door cabinet glass; there are rollers on the upper and lower sides of the metal frame ; Its glass is the ultra-high alumina glass product produced by a process method of a new horizontal flame pool kiln production system] The flat glass according to claim 1.

A colored-glazed glass-plate combination wardrobe is characterized in that: the glass-plate combined wardrobe has 1-10 colors of colored glaze layers on the surface or back of the glass; the colored-glazed glass is surrounded by a metal frame, and there is metal between the metal frames Coupling device; the glass is the flat glass according to claim 1 [a super high alumina glass product produced by a process method of a new horizontal flame pool kiln production system].

A colored glaze countertop glass furniture is characterized in that: there are 1-10 colored glaze layers on the surface or back of the glass countertop, and the lower part of the countertop is provided with a supporting device; the glass is [a new type of horizontal flame pool kiln production system Ultra-high alumina glass product produced by the process method] The flat glass according to claim 1.

A photovoltaic solar device, characterized in that the photovoltaic solar device includes a solar cell, and a glass substrate or a cover plate; and the glass thereof is [an ultra-high aluminum glass product produced by a process method of a new horizontal flame pool kiln production system] The flat glass according to claim 1 is required.

A thin-film solar device, characterized in that the thin-film solar device comprises: a thin-film solar cell; and the glass thereof is [an ultra-high aluminum glass product produced by a process method of a new horizontal flame pool kiln production system] according to claim 1 plate glass.

A liquid crystal display screen includes an array substrate including a substrate, a pixel structure on the substrate, and the substrate is a composition according to claim 1 with an ultra-high alumina content and ultra-high Application of strength and high softening point glass;

A color filter substrate comprising a substrate and a color filter layer on the substrate, the substrate being a glass substrate;

A liquid crystal layer sandwiched between the array substrate and the color filter substrate; and a backlight system;

It is characterized in that the glass is the flat glass according to claim 1 [ultra-high alumina glass products produced by a process method of a new horizontal flame pool kiln production system].

A low-temperature polysilicon display screen includes a low-temperature polysilicon array substrate including a substrate and a pixel structure produced on the substrate using a low-temperature polysilicon process;

A liquid crystal layer sandwiched between the array substrate and the color filter substrate; and

Backlight system;

A curved LCD screen,

include:

Substrate glass

An array substrate comprising a substrate and a pixel structure on the substrate, the substrate being a glass plate;

A front or back shell structure of a display, characterized in that the glass is the flat glass according to claim 1 [a kind of ultra-high aluminum glass product produced by a process method of a transverse flame cell kiln production system].

A bullet-proof and explosion-proof automobile structure, comprising: 1 to 3 layers of glass of 1 to 10 car windows, each of which is bonded by a resin sheet;

Bulletproof structures in metal plates or metal frames around the car;

And power units; dashboards; direction controllers; car shells; car chassis; car brakes; car tires;

An anti-robbery, anti-theft, explosion-proof, anti-impact, anti-rollover injury automobile, comprising: 1 to 3 layers of glass of 1 to 10 windows, and bulletproof glass is a composition as described in claim 1, which is highly oxidized Application of glass with aluminum content, ultra-high strength, and high softening point; and power units; instrument panels; direction controllers; car shells; car chassis; car brakes; car tires; characterized by: its glass is [a new horizontal Ultra-high alumina glass products produced by the process method of a flame tank kiln production system] The flat glass according to claim 1.

A solar vehicle includes: a device having propeller power to propel flight, wings, a driving control system device, and a thin-film solar device, including: a thin-film solar cell; a substrate glass on the thin-film solar device; and its characteristics It is that the glass is the flat glass according to claim 1 [a super high alumina glass product produced by a process method of a new horizontal flame pool kiln production system].

A composite plate with colored glaze flat glass and a metal layer, comprising: a glass glaze layer with 1 to 10 colors on the surface of the substrate glass, a metal plate with a thickness of 0.1 to 5 mm, and a layer of adhesion between the glass plate and the metal plate The material layer is characterized in that the glass is the flat glass according to claim 1 [a high-aluminum glass product produced by a process method of a new horizontal flame pool kiln production system].

A colored glaze glass composite material plate comprises: a glass glaze layer with 1 to 10 colors on the substrate glass surface, a metal plate with a thickness of 0.1 to 5 mm, and a layer of adhesive material between the glass plate and the metal plate. It is characterized in that the 2 to 4 sides of the metal plate on the back bottom surface of the composite plate of the product protrude by a distance of 10 to 30 mm from the edge portion of the superimposed colored glaze decorative flat glass product; it is characterized in that: The glass is the flat glass according to claim 1 [a high-aluminum glass product produced by a process method of a new transverse flame cell kiln production system].

A colored glaze glass composite material floor comprises: a base layer thereof, or a wood board; or a metal material board; or a wood board composite board; or a wood flour particle composite board; or a resin material board; its characteristics are: The glass is the flat glass according to claim 1 [a high-aluminum glass product produced by a process method of a new transverse flame cell kiln production system].

A glass washbasin structure, characterized in that the glass is the glass according to claim 1 [a high-aluminum glass product produced by a process method of a new horizontal flame pool kiln production system].

The utility model relates to a glass lifting panel and a combined wash basin, which are characterized in that: 1. a flat glass lifting panel; 2. another part of the combination is a glass wash basin; the feature is that the glass is [ Ultra-high alumina glass product produced by a process method of a new transverse flame pool kiln production system] The glass according to claim 1.

The utility model relates to an ultra-long glass plate of a balcony protection bar. The length of the glass plate of the balcony protection bar is 3 to 8m. It is characterized in that the glass is an ultra-high glass produced by a process method of a new horizontal flame pool kiln production system. Aluminum glass products] The flat glass according to claim 1.

A bullet-proof building structure includes: a wall structure, a ground structure, a roof structure, a door structure, a glass window structure, a bullet-proof glass in a glass window structure, or a bullet-proof glass in a door structure; characterized in that its glass is [一Ultra-high alumina glass product produced by a process method of a new transverse flame pool kiln production system] The flat glass according to claim 1.

A glass back shell of a display, the glass back shell is flat, the glass back shell is a 3D curved shape, and a glass glaze layer is attached to the glass back shell, or The structural layer of the grating feature; characterized in that the glass is the flat glass according to claim 1 [an ultra-high alumina glass product produced by a process method of a new horizontal flame pool kiln production system].

A glass back shell structure in a display structure, the glass back shell is flat, the glass back shell is a 3D curved shape, and a glass glaze layer is attached to the glass back shell, or A structure layer with a grating feature is attached; the glass is an ultra-high alumina glass product produced by the process method of a new transverse flame tank kiln production system].

A glass fiber composite material includes: a plastic matrix and glass fibers embedded in the plastic matrix; the glass fiber is an ultra-high aluminum glass product produced by a process method of a new horizontal flame pool kiln production system The glass according to claim 1.

A glass fiber composite material blade for wind power includes a plastic substrate and glass fiber embedded in the plastic substrate, a composite material manufactured by the same, and a blade for wind power production;

Wind blade composition: glass fiber composite wind blade leaf shell; glass fiber composite wind blade blade root; glass fiber composite wind blade structure beam;

It is characterized in that the glass fiber is the glass according to claim 1 [ultra-high alumina glass product produced by a process method of a new horizontal flame pool kiln production system].

A glass fiber composite material aircraft shell includes: a plastic matrix and glass fiber embedded in the plastic matrix, a composite material manufactured by the aircraft, and an aircraft shell structure; characterized in that its glass fiber is [A new Ultra-high alumina glass products produced by the process method of a transverse flame cell kiln production system] The glass according to claim 1.

A marine vessel with a glass fiber composite material structure,

Contains a plastic matrix, and

Glass fiber embedded in plastic matrix, composite materials manufactured, hull structure made; power plant; cockpit; ship deck;

A glass fiber composite material chemical pipe structure includes a plastic matrix and glass fibers embedded in the plastic matrix, a manufactured composite material, and a chemical or petroleum pipe or a natural gas composite pipe;

A glass fiber composite material shell or chassis automobile includes a plastic substrate and a vehicle shell or vehicle chassis made of glass fiber embedded in the plastic substrate; a car window structure; and a power unit; an instrument panel; an orientation Controller; automobile casing; automobile chassis; automobile brake device; automobile tire; characterized in that its glass fiber is [an ultra-high aluminum glass product produced by a process method of a new transverse flame pool kiln production system] Mentioned glass.

A wind power generation device structure includes: a wind blade includes a plastic substrate and embedded plastic

The glass fiber in the matrix, the wind power blade made of the composite material manufactured; also includes bearings; generators; wind power tower pillars; characterized in that its glass fiber is [a new process method of a new transverse flame pond kiln production system Produced ultra-high alumina glass article] The glass according to claim 1.

A daily-use glass and industrial glass product is characterized in that its glass is [A horizontal

The ultra-high alumina glass product produced by the process method of the flame tank kiln production system is the glass according to claim 1].

A glass insulator product, characterized in that the glass fiber is the glass according to claim 1 [a high-aluminum glass product produced by a process method of a new horizontal flame pool kiln production system].

A glass toilet product, characterized in that its glass is the glass according to claim 1 [a high-aluminum glass product produced by a process method of a new horizontal flame pool kiln production system].

BRIEF DESCRIPTION OF THE DRAWINGS

1 and the accompanying drawings are schematic plan views of flat glass products of ultra-high alumina glass products produced by a process method using a new lateral flame pool kiln production system according to the present invention;

2 is a schematic cross-sectional view of a glass fiber product of ultra-high aluminum glass products produced by a process method using a new transverse flame tank kiln production system according to the present invention;

3 is a cross-sectional schematic view of a blown glass product of ultra-high alumina glass products produced by a process method using a new transverse flame pool kiln production system according to the present invention;

4 is a schematic cross-sectional view of a drawn glass tube product of ultra-high aluminum glass products produced by a process method using a new transverse flame tank kiln production system according to the present invention;

5 is a schematic cross-sectional view of a pressed glass product of ultra-high alumina glass products produced by a process method using a new lateral flame pool kiln production system according to the present invention;

FIG. 6 is a schematic side sectional view of the equipment composition of a process method for ultra-high aluminum glass products produced by a process method using a new transverse flame tank kiln production system according to the present invention.

FIG. 7 is a schematic flow chart of a float glass manufacturing process for ultra-high alumina glass products produced by a process method using a new lateral flame pool kiln production system according to the present invention.

FIG. 8 is a schematic flow chart of a glass fiber preparation process for an ultra-high alumina glass product produced by a process method using a new transverse flame tank kiln production system according to the present invention.

FIG. 9 is a cross-sectional view of a bottom flow channel (20) of an ultra-high alumina glass product produced by a process method using a new transverse flame tank kiln production system according to the present invention.

Symbol Description

FIG. 6 is a schematic side sectional view of the equipment composition of a process method for ultra-high alumina glass products produced by a process method using a new transverse flame tank kiln production system according to the present invention:

The symbol 10 represents a lateral flame pool kiln crusting device in which flame heat dominates glass melting;

The symbol 60 represents a device for clamping the channel of the liquid glass;

Symbol 30 denotes a device for controlling the temperature of the glass liquid flowing from the top to the bottom by using an electrode;

Symbol 40 represents a glass liquid ascending channel structure that uses electrodes to control the temperature of the glass liquid flowing from bottom to top;

The symbol 20 indicates the bottom flow channel;

Reference numeral 50 denotes a molding device for glass products;

The symbol 8 represents the electrode (8) in the glass liquid;

The symbol 9 represents the electric heating device (9) of the upper space of the glass liquid;

FIG. 7 is a schematic flow chart of a float glass preparation process for ultra-high aluminum glass products produced by a process method using a new transverse flame pool kiln production system according to the present invention:

The symbol 60 represents a device for clamping the channel of the liquid glass;

The symbol 20 indicates the bottom flow channel;

Reference numeral 50 denotes a molding device for glass products.

FIG. 8 is a schematic flowchart of a glass fiber preparation process for ultra-high alumina glass products produced by a process method using a new transverse flame tank kiln production system according to the present invention:

The symbol 60 represents a device for clamping the channel of the liquid glass;

Reference numeral 40 denotes a glass liquid that uses an electrode to control the temperature of the glass liquid flowing from bottom to top, and a glass liquid having a channel structure;

The symbol 20 indicates the bottom flow channel (20);

Reference numeral 50 denotes a molding apparatus for a glass fiber product.

Detailed ways

The embodiments of the present invention will be described below with reference to the drawings. It should be noted that the following drawings are simplified schematic diagrams, and the basic concept of the present invention is illustrated only in a schematic manner. Only the structures related to the present invention are illustrated in the drawings. Rather than drawing according to the number, shape and size of the components during actual implementation, the type, quantity and ratio of each component during actual implementation are not limited to the illustrations, and can be changed according to the actual design needs, which will be described first.

In the present invention, an embodiment of an ultra-high aluminum glass product produced by a process method using a new transverse flame pool kiln production system:

Step 4. Selection of molding process:

Selection of the first glass product molding process: The aforementioned glass liquid passing through the top outlet of the ascending channel structure (40) enters the glass product molding device (5); the glass product molding device (5) is float plate glass The tin kiln structure of the process; the molten glass enters the flat surface of the tin kiln structure which is melted with tin metal, and the glass liquid is thinned and polished; To the required thickness; and then annealing and cutting to form a float plate glass product; or

Regarding the remarkable progress and creativity of the present invention:

The technical solution of the present invention belongs to an invention that includes the product claim characteristics of the preparation method. Not only the product has a novel composition and structure compared with the prior art, but also has novelty. In addition, the innovative process method of the present invention is superior to the prior art product. It can cause micro changes and progress inside glass products with alumina content of 20-49%. Compared with the ultra-high aluminum glass products, the present invention can truly have different and stable properties-[light transmission, high strength, Lightness, thinning, and lightweight performance] Microscopic changes in glass products and progressive product features.

The unique manufacturing method of the present invention is characterized by:

The glass liquid clamping device (60) of the glass liquid is located at a distance of 5-30CM from the bottom refractory, and 3-20 electrode devices are designed;

It uses electrodes to clarify the temperature of the glass liquid flowing from top to bottom, remove bubbles and prevent the crystallizing device (30). The glass liquid in the area 5-30CM from the bottom refractory is designed with 3-20 Electrode device

The glass liquid in the glass liquid ascending channel structure (40) whose temperature is controlled from the bottom to the top by using electrodes is provided with 3-20 electrode devices in the glass liquid in a region 5-30CM away from the bottom refractory;

Step 1 is different from the comparison file and all the prior art processes. The characteristics are: 3-20 pieces of glass liquid are designed in the area of 5-30CM from the bottom refractory through the card liquid channel device (60) of the glass liquid. Electrode device, so that the working process temperature of the glass liquid in the area of the card neck runner device (60) area at a distance of 10-30CM from the bottom of the refractory material has a volume of at least 100 cubic CM, which must be maintained at 1320 ° C-1450 ℃, which is 20-80 ℃ higher than the working process temperature of the glass liquid in the area 30-60CM away from the bottom refractory;

Step 2 is different from the comparison document and all the prior art processes. The characteristics are: the temperature controlled clarification, bubble removal and anti-crystallization device (30) flowing from the top to the bottom of the glass. In the glass liquid in the area of 5-30CM, 3-20 electrode devices are used to make the glass liquid flowing from top to bottom for temperature control clarification, bubble elimination and anti-crystallization equipment (30) area, away from fire resistance. In the glass liquid in the area with a distance of 5-30CM from the bottom of the material, the working process temperature in the area with a minimum volume of 100 cubic CM must be maintained at 1320 ° C-1450 ° C, which is higher than the glass liquid in the area with a distance of 30-60CM from the bottom refractory. Working process temperature of 20-80 ℃;

Step 3 is different from the reference file and all the prior art processes. The characteristic is: 3-20 electrode devices are designed in the glass liquid in the area of 5-30CM from the bottom refractory through the area of the bottom flow channel (20). Keep the working process temperature in the glass liquid in the area of the bottom flow channel (20) at a distance of 5-30CM away from the bottom of the refractory at least 100 cubic CM volume, and maintain it at 1320 ℃ -1450 ℃. The working process temperature of the liquid glass in the area 30-60CM away from the bottom refractory material is 20-80 ℃;

Step 4 is different from the reference file and all the prior art processes. The feature is that the glass liquid enters the glass liquid ascending channel structure (40) which controls the temperature of the glass liquid flowing from the bottom up with an electrode; In the glass liquid in the area of -30CM, the designed 3-20 electrode devices use electrodes to control the temperature of the glass liquid flowing from the bottom to the glass liquid ascending channel structure (40). The working process temperature of the glass liquid in the area with a distance of 30CM with a volume of at least 100 cubic CM volume must be maintained at 1320 ℃ -1450 ℃, which is higher than the working process temperature of the glass liquid in the area with a distance of 30-60CM from the bottom refractory. 20-80 ° C.

[Comparison of prior art]

(7) Prior to the electrolysis kiln technology and flame kiln technology, glass products mainly produced low aluminum products with alumina content of 1-4%, medium aluminum products with alumina content of 5-9%, and alumina content of 10-16% high aluminum products.

The prior electrolysis kiln process technology and flame kiln process technology do not have the characteristics of several technical elements of the process method of the present invention. Therefore, the prior art does not have the process conditions to overcome its technical difficulties.

[Different from the prior art (1)-(7)]

(1) First, the present invention [an ultra-high alumina glass product produced by a process method using a new transverse flame tank kiln production system] and the technical solutions of the prior inventions (1)-(7) and any prior technical solutions The composition and structure of the components are all different: according to the present invention, the content of alumina is 20% -49%; the content of magnesium oxide is 5% -20%, and the content of silicon oxide is 2.51-5.8 times that of calcium oxide. The calcium oxide content is 0.8 times to 2.3 times the magnesium oxide content; therefore, the present invention is novel.

(2) Because the present invention adopts a completely new process: 3-20 electrode devices are all designed in the glass liquid in the area of the refractory with a distance of 5-30CM at the bottom of the melting kiln crusting device in multiple areas. A new process is adopted: at least one section of the glass liquid in the region of the refractory material at a distance of 10-30CM from the bottom of the kiln crusting device area in multiple areas is maintained at a temperature of 1320 ℃ -1450 ℃, which is higher than The working process temperature of the liquid glass in the area of 30-60CM from the bottom refractory is 20-80 ° C. Therefore, the upper and lower flows of the glass liquid with a distance of 5-30-60CM from the bottom refractory can be formed in these areas, so that the "aluminum-rich sedimentation phenomenon-that is, the glass liquid part with high alumina content, "The phenomenon of sedimentation and accumulation at the bottom due to the large specific gravity" was homogenized and resolved. It can fundamentally solve the problem that the glass finished product is severely uneven in the molding stage, which causes glass bars, stripes, white opaque oxygen-enriched blocks and strips to be completely unqualified, making high-qualified production of 20--49%. Glass products with alumina content are possible.

In addition, the present invention can also overcome the difficulties caused by the "aluminum-rich sedimentation phenomenon" at the bottom of the glass liquid by using the traditional stirring process to achieve the purpose through the prior art.

Overcoming one of the difficulties of its traditional stirring process: The traditional stirring process is used near the bottom of the electric melting furnace or the top of the ascending channel of the glass forming area. The stirring process is prone to generate secondary bubbles and a large number of bubbles appear directly in the product;

Overcoming the difficulties of its traditional mixing process: using the traditional mixing process, if the temperature exceeds 1300 ° C, using a stainless steel mixer with cooling water circulation to reduce the temperature will cause serious glass liquid near the side wall of the mixer, due to long-term water cooling When the temperature is reduced, a large amount of crystallization of the molten glass is generated. At the bottom of the electric melting furnace near the glass forming area or at the top of the ascending channel, the crystallization will directly appear in the product in large quantities;

Overcoming the difficulties of its traditional mixing process: the use of platinum stirrers will cause too high costs and platinum will react with glass at high temperatures. New bubbles will appear at the bottom of the electric melting kiln near the glass forming area or at the top of the ascending channel. Secondary bubbles will also cause a large number of bubbles to appear directly in the product. This is an important reason why the existing technologies are not qualified to produce glass products with an ultra-high aluminum content of more than 20%.

Therefore, it is possible to produce glass products with an alumina content of 20-49%, not only to keep the glass liquid in the respective devices, especially the bottom region, above 1300 ° C during normal production; When the molding device (5) stops working, that is, the glass liquid when the high temperature glass liquid does not flow from the melting furnace crusting device, it can also form a glass with a distance of 5-30-60cm from the bottom refractory in these areas. The working process temperature of at least one section of the liquid is maintained at 1320 ° C to 1450 ° C, and the working process temperature of at least one section is maintained at 1320 ° C to 1450 ° C, which is higher than the area glass at a distance of 30-60CM from the bottom refractory. The working process temperature of the liquid is 20-80 ° C; and the upper and lower flows are homogenized in a small range, so that "the phenomenon of aluminum-rich sedimentation and accumulation-that is, the phenomenon that the glass liquid part with a high alumina content content sediments and accumulates at the bottom due to the specific gravity" , Get homogenized and get resolved.

The brand-new process invention concept is an invention of glass products produced in a specific environment for a specific region's process technology solution, which has produced unexpected technical effects.

Based on Chapter 3 of Chapter 4 of the Patent Examination Guidelines [Page 175] 3.2.2 Significant Progressive Judgment ,,,,,,,. In the following circumstances, the invention should generally be considered to have beneficial technical effects and significant progress. (2) The invention provides a technical solution with different technical concepts, the effect of which can basically reach the current technology level; [for example, improvement in quality, increase in yield, energy conservation, prevention of environmental pollution, etc.]. And the present invention [a process method using a new horizontal flame pool kiln production system, ultra-high aluminum glass products produced] in electronic flat glass, architectural and industrial flat glass, fiberglass, industrial or daily glassware and devices In the field, there are unexpected effects that can overcome the major defects of the prior art, especially the process in my prior invention. In the production of glass products with alumina content of 20-49%, It will be prone to opaque major defects of milky aluminum-rich stripes or milky-white aluminum-rich blocks, or major defects of glass layering; because of the present invention [a process method using a new transverse flame pool kiln production system, Produced ultra-high alumina glass products] can overcome the above problems, so the glass products with an alumina content of 20-49% according to the present invention can achieve true stability than the previous ultra-high alumina glass products-[light transmission Performance, high strength, thin and light, lightweight performance] (because the industry knows that if glass products appear milky rich aluminum stripes or milky rich The major opaque defects of the block, or the major defects of glass delamination, cannot have the products of the present invention different from all the prior arts-[qualified light transmission, ultra-high strength of ultra-high aluminum, lighter and thinner, Lighter performance]). Therefore, the present invention has remarkable progress.

The above-mentioned solution to the problem of producing glass products with an alumina content of more than 20% in the prior art is the high-strength glass production field of ultra-high aluminum. People have been eager to solve but have never been successful. The technical invention solves the technical problem that people have been eager to solve but has not been successful. Therefore, the present invention has outstanding substantive features, remarkable progress, and creativity.

According to Chapter IV of Part Two of the Patent Examination Guidelines, page 3.2.2-175-Judgment of Significant Progress-(2) The invention provides a technical solution with different technical concepts, and its technical effect can basically reach the existing The level of technology. The present invention also belongs to the comparison of my prior inventions, and provides a new technical solution with different technical concepts. The technical effect can not only reach the level of my prior invention technology, but also exceed the level of my prior invention technology. .

According to Chapter 2 of Chapter 4 of the Patent Examination Guidelines, it is judged whether the claimed invention is obvious to those skilled in the art: in the judgment process, it is necessary to determine whether there is some technical inspiration in the existing technology as a whole ... The above-mentioned technical inspiration is generally considered to exist in the prior art in the following situations: (i) the distinguishing feature is common knowledge, for example, the conventional means in the art to solve the re-determined technical problem, or a monograph or reference book The technical means disclosed in the technical solution to this re-determined technical problem. However, the technical solutions of the present invention are not common knowledge, nor are the conventional methods in the art to solve the technical problems that are re-determined, or the technical methods for solving the technical problems that are re-determined as disclosed in the medical books or reference books.

According to the second chapter of Chapter 4 of the Patent Examination Guidelines, the concept of inventiveness of invention in Law 22.3: The inventiveness of invention means that the invention has outstanding substantive features and significant advancement compared with the prior art. 2.2 The outstanding substantive features refer to the fact that the invention is not obvious to those skilled in the art in comparison with the prior art. If the invention can be obtained by a person skilled in the art based on the existing technology only through logical analysis, reasoning, or limited experimentation, then the invention is obvious and does not have the substantive characteristics of assault.

However, none of the technical solutions of the present invention can be obtained by those skilled in the art based on the existing technology only through logical analysis, reasoning, or limited experiments.

In short, the technical solution of the present invention belongs to an invention that includes the product claim characteristics of the preparation method. Not only the product has a novel composition and structure compared with the prior art, and has novelty. In addition, the innovative process method of the present invention is superior to the prior art product. Can lead to microscopic changes and progress inside glass products with alumina content of 20-49%. Compared with the ultra-high aluminum glass products, the present invention can truly have different and stable properties-[light transmission, high strength] , Thin and light, light weight performance] micro changes in glass products and advanced product characteristics.

The preparation method of the present invention results in glass products with an alumina content of 20-49%. Unlike previous products, there is no opaque defect structure of milky white aluminum-rich stripes or milky white aluminum-rich blocks in the product, or does not exist. Defective structure of glass delamination; In addition, the innovative process of the present invention can cause microscopic changes and advances in glass products with alumina content of 20-49% compared to the prior art products. Only aluminous glass products can have different and stable product characteristics of [transmittance, high strength, light weight, light weight performance].

Because people in the industry understand that if glass products have milky white aluminum-rich stripes or milky white aluminum-rich blocks with major opacity defects or major defects in glass delamination, it is impossible to have the product of this invention different from all the prior art. -[Qualified light transmission, ultra-high aluminum ultra-high strength, lighter and thinner, lighter performance].

Therefore, the present invention is not only novel, but also significantly improved.

The above description is only for the purpose of illustrating the preferred embodiment of the ultra-high alumina glass products produced by the process method of the new transverse flame tank kiln production system of the present invention, but it is not a limitation on the present invention. Any Those skilled in the art may use the disclosed technical content to modify or modify the equivalent embodiments with equivalent changes, and they may implement a process method using a new transverse flame tank kiln production system according to different requirements and performances of the present invention. Production of ultra-high aluminum glass products. It can be seen that, without departing from the content of the technical solution of the present invention, especially the content of the claims, any simple modifications, equivalent changes and modifications made to the above embodiments in accordance with the technical essence of the present invention still fall within the scope of the technical solution of the present invention. .

Claims

Ultra-high aluminum glass products produced by a process method using a new transverse flame pool kiln production system,

[A] The composition of glass products is: its alumina content is 6-19.9% or 20% -49% by weight percentage; magnesium oxide content is 5% -20%, and silicon oxide content is 2.51 of calcium oxide content -5.8 times, calcium oxide content is 0.8-2.3 times that of magnesium oxide content;

[B] A process method for the production of a new horizontal flame tank kiln is:

(a) Prepare the production equipment of the horizontal flame tank kiln, including:

Flame thermal energy dominates glass melting in a transverse flame cell kiln crusting device (10); glass liquid chuck channel device (60); uses electrodes to temperature control the glass liquid flowing from top to bottom to clarify, remove bubbles and Anti-crystallization device (30); bottom flow channel (20); glass liquid ascending channel structure (40) for temperature control of glass liquid flowing from bottom to top using electrodes; molding device (50) for glass products:

The depth of the glass liquid flow channel device (60) between the surface of the liquid glass and the bottom of the device is the horizontal flame pool kiln crusting device (10) that uses flame thermal energy to dominate glass melting and uses electrode pairs from top to bottom. 10% -40% of the depth between the surface of the glass liquid and the bottom of the device in the device (30) for clarifying, de-airing and anti-crystallization of the glass liquid flowing downward; (60) 3-20 electrode devices are designed in the glass liquid in the area 5-30CM from the bottom refractory;

It uses electrodes to control the temperature of the glass liquid flowing from top to bottom to clarify, remove bubbles and prevent the crystallization (30). Around the device is designed 4-50 electrodes to control the temperature of the glass liquid. The glass liquid in the lower flowing glass liquid for temperature control clarification, degassing and anti-crystallizing device (30) is located at a distance of 5-30CM from the bottom refractory, and 3-20 electrode devices are designed;

3-20 electrode devices are designed in the glass liquid in the bottom liquid flow channel (20) in the area 5-30CM away from the bottom refractory;

The glass liquid ascending channel structure adopting electrodes to control the temperature of the glass liquid flowing from bottom to top-(40) is designed with 4-50 electrodes for controlling the temperature of the liquid glass; In the glass liquid in the area of 5-30CM, 3-20 electrode devices are designed;

Desired devices: flame flame kiln crusting device (10) for glass melting, squeegee channel device (60) for glass liquid, electrode for temperature controlled clarification of glass liquid flowing from top to bottom The device for removing air bubbles and preventing crystallization (30), adopts electrodes to control the temperature of the glass liquid flowing from bottom to top, the glass liquid rising channel structure (40), and the glass product forming device (50); Of the electrode energy, when the glass product forming device (50) stops working, the glass liquid in the respective device is maintained above 1300 ° C and above the glass crystallization temperature;

(b) A process method of a new horizontal flame pool kiln production system for the production of ultra-high aluminum glass products, the process is as follows:

Prepare the required devices: the flame heating kiln crusting device (10) for the glass melting, the glass liquid chuck channel device (60), the temperature of the glass liquid flowing from top to bottom is controlled by electrodes Device (30) for clarification, degassing, and anti-crystallization, using electrodes for glass liquid ascending channel structure (40) for temperature control of glass liquid flowing from bottom to top, forming device (50) of glass products; The energy of the electrodes in the device can keep the glass liquid in the respective devices above 1300 ° C and above the glass crystallization temperature when the glass product forming device (50) stops working;

Step 1. The predetermined glass raw material is passed through a glass raw material transport device into a lateral flame pool kiln crusting device (10) where flame thermal energy predominates glass melting, and is melted to form a glass liquid, and the glass liquid passes through the neck of the glass liquid. Channel device (60), which enters from the upper part of the side into the clarification, bubble removal and anti-crystallization device (30) for controlling the temperature of the glass liquid flowing from top to bottom using electrodes; and the card neck channel device (60) ) And the temperature of the glass liquid in the clarifying, bubble-releasing and crystallizing preventing device (30) controlled by the electrode for the glass liquid flowing from top to bottom, are controlled to be higher than the clarifying and bubble-releasing 10 2 Pa · s Above the viscosity temperature and above the glass crystallization temperature;

The process is characterized by passing 3 to 20 electrode devices in the glass liquid in the region of the glass liquid in the area of 5-30CM from the bottom refractory through the glass liquid channel device (60), so that the liquid channel device (60) In the region of the glass liquid at a distance of 10-30CM from the bottom of the refractory, the working process temperature of the zone with a volume of at least 100 cubic CM must be maintained at 1320 ℃ -1450 ℃, which is higher than 30-60CM from the bottom refractory The working process temperature of the liquid glass in the distance area is 20-80 ℃;

The process features: temperature controlled clarification, bubble removal and anti-crystallization equipment (30) designed by glass liquid flowing from top to bottom. The glass liquid in the area 5-30CM away from the bottom refractory, each 3 -20 electrode devices, in the glass liquid in the area of 5-30cm distance from the bottom of the refractory, for the temperature control of the glass liquid flowing from top to bottom for clarification, bubble elimination and anti-crystallization equipment (30), The working process temperature in the area with a minimum volume of 100 cubic CM should be maintained at 1320 ° C-1450 ° C, which is higher than the working process temperature of the glass liquid in the area 30-60CM away from the bottom refractory material 20-80 ° C;

Step 2. Make the glass liquid from the bottom of the liquid flow channel (20) entering the bottom liquid flow channel (20) by using the electrode to lower the temperature of the glass liquid flowing from the top to the bottom, and remove the bubbles. A connected glass liquid ascending channel structure using electrodes for temperature control of glass liquid flowing from bottom to top (40);

The process is characterized by the design of 3-20 electrode devices in the glass liquid in the bottom liquid flow channel (20), 5-30CM away from the bottom refractory, and the bottom liquid flow channel (20) area. In the glass liquid in the area of 5-30CM distance from the bottom of the refractory material, the working process temperature in the section with a volume of at least 100 cubic CM must be maintained at 1320 ℃ -1450 ℃, which is higher than the distance of 30-60CM from the bottom refractory material. Regional glass liquid working process temperature 20-80 ℃;

The process is characterized by: designed in the glass liquid ascending channel structure (40) for temperature control of glass liquid flowing from bottom to top by using electrodes, in the glass liquid in the area 5-30CM from the bottom refractory, the designed 3- 20 electrode devices, so that the working process temperature of the glass liquid in the area of the bottom flow channel (20), at a distance of 5-30CM away from the bottom of the refractory material, has a volume of at least 100 cubic CM, which must be maintained at 1320 ° C- 1450 ° C, which is 20-80 ° C higher than the working process temperature of the glass liquid in the area 30-60CM away from the bottom refractory;

The process is characterized by the design of 3-20 electrode devices in the glass liquid in the area 5-30CM away from the bottom refractory, so that the bottom liquid flow channel (20) area is 5-30CM away from the bottom of the refractory. In the region of the liquid glass, the working process temperature of the zone with a volume of at least 100 cubic CM must be maintained at 1320 ° C to 1450 ° C, which is higher than the working process temperature of the liquid glass in the area at a distance of 30-60CM from the bottom refractory material. ℃

Step 3. The glass liquid flows from the bottom liquid flow channel (20) and enters the glass liquid rising channel structure (40) for controlling the temperature of the glass liquid flowing from bottom to top with an electrode;

The process is characterized by a glass liquid ascending channel structure (3-20 electrode devices designed by the glass liquid in the area 5-30CM away from the bottom refractory, using electrodes to temperature control the glass liquid flowing from the bottom up) 40) In the glass liquid in the area with a distance of 5-30CM from the bottom of the refractory material, the working process temperature of the zone with a volume of at least 100 cubic CM must be maintained at 1320 ° C-1450 ° C, which is higher than 30 from the bottom refractory The working process temperature of the glass liquid in the region of -60CM distance is 20-80 ℃;

Step 4. Selection of molding process:

Selection of the first glass product molding process: The aforementioned glass liquid passing through the top outlet of the ascending channel structure (40) enters the glass product molding device (5); the glass product molding device (5) is float plate glass The tin kiln structure of the process; the molten glass enters the flat surface of the tin kiln structure which is melted with tin metal, and the glass liquid is thinned and polished; and then the glass ribbon formed by the pair of 10-40 pairs of edger is pulled on both sides To the required thickness; and then annealing and cutting to form a float plate glass product; or

Selection of the second glass product molding process: the aforementioned glass liquid that passes through the top outlet of the ascending channel structure (40) enters the main channel of the glass liquid, and the glass liquid enters and is connected with 2-30 glass liquid distribution channels; the glass liquid Enter the molding device for glass fiber production of the glass products connected to each of the shunts; flow into the corresponding 2-30 dry pots carrying the glass liquid, and the glass liquid passes through the corresponding 2-30 drawing boards, in the corresponding drawing machine. Forms glass fibers under action; or

Choice of the third glass product molding process: the aforementioned glass liquid passing through the top outlet of the ascending channel structure (40) enters the main channel of the glass liquid, and the glass liquid enters and is connected with 2-30 glass liquid distribution channels; the glass liquid Enter the 2-30 industrial and daily glassware blow molding devices of the glass products connected to each of the shunts; blow the products of industrial and daily glass separately; and then process them by the annealing device of the glass products. Blow moulded products for industrial and household glass; or

Choice of the fourth glass product molding process: The aforementioned glass liquid that passes through the top outlet of the ascending channel structure (40) enters the main channel of the glass liquid, and the glass liquid enters and is connected with 2-30 glass liquid branching channels; the glass liquid Enter the 2-30 industrial and daily glassware press forming devices of the glass products connected to each of the shunts; press the products of industrial and daily glass respectively; and then process them by the annealing device of glass products to make industrial and Pressed molded articles of daily glass; or

Selection of the fifth glass product molding process: The aforementioned glass liquid passing through the top outlet of the ascending channel structure (40) enters the main channel of the glass liquid, and the glass liquid enters and is connected with 2-30 glass liquid branching channels; the glass liquid Enter the 2-30 industrial and daily glass drawing devices of the glass products connected to each of the shunts, draw the industrial and daily glass products respectively; and then process them through the annealing device of the glass products to make Drawn products of industrial and household glass; or

Choice of the sixth glass product molding process: The aforementioned glass liquid that has passed through the top outlet of the ascending channel structure (40) enters the main channel of the glass liquid, and the glass liquid enters and is connected with 2-30 glass liquid distribution channels; the glass liquid Enter the blow molding device of 2-30 sanitary glass products connected to the glass products of each shunt, and make sanitary glass products respectively; and then process the annealing device of the glass products to make sanitary glass products.
A glass window comprising a resin frame or a metal frame supporting device installed on the four perimeters of the glass; characterized in that its glass is [an ultra-high aluminum glass product produced by a process method of a new horizontal flame pool kiln production system] The flat glass according to claim 1 is required.
A colored glaze flat glass, characterized in that the glass surface has colored glaze layers of 1 to 10 colors; its glass is [an ultra-high aluminum glass product produced by a new horizontal flame pool kiln production system process method] The flat glass according to claim 1 is required.
A kind of hollow glass includes support devices on the four perimeters of each layer of glass; there is a vacuum insulation space of 3-50mm between each layer of glass; its characteristics are: its glass is [a new transverse flame tank kiln production system The ultra-high alumina glass products produced by the method] The flat glass according to claim 1.
A glass curtain wall of a building, the glass is fixed on an upper metal supporting device; characterized in that the glass is [an ultra-high aluminum glass product produced by a process method of a new horizontal flame pool kiln production system] as claimed in claim 1 The described flat glass.
An ultra-large area building with thin glass windows, characterized in that the thickness of its glass is 4 to 10 mm, the size of its glass is 3 to 40 square meters, or the thickness of its glass is .4 to 20 mm, and the size of its glass It is 15.1 to 80 square meters; the glass is the flat glass according to claim 1 [a high-aluminum glass product produced by a process method of a new horizontal flame pool kiln production system].
A tempered glass, characterized in that the glass is made by chemical tempering or physical tempering; the glass is [ultra-high alumina glass products produced by a new transverse flame tank kiln production system process method] plate glass.
A tempered glass countertop furniture, characterized in that: a supporting device is provided below the countertop; and the glass is [a high-aluminum glass product produced by a process method of a new horizontal flame pool kiln production system] the flat glass according to claim 1 .
A laminated glass is characterized in that a resin material layer is provided between each layer of the glass; the glass is [an ultra-high aluminum glass product produced by a process method of a new horizontal flame pool kiln production system] The described flat glass.
A bullet-proof and explosion-proof glass, characterized in that each glass plate is bonded by a resin sheet; and the glass is [an ultra-high aluminum glass product produced by a process method of a new horizontal flame pool kiln production system] The described flat glass.
A color-glazed glass plate combination cabinet is characterized in that: the glass surface has a color glaze layer of 1 to 10 colors on the back surface; the color-glazed glass plate combination cabinet is surrounded by a metal frame around the flat glass; and the color-glazed glass plate combination cabinet There is a metal connecting device between the metal frames; the glass is the flat glass according to claim 1 [a high-aluminum glass product produced by a process method of a new horizontal flame pool kiln production system].
A color glaze glass panel combined sliding door cabinet is characterized in that: there are 1-10 colors of colored glaze layers on the surface or back of the combined sliding glass door cabinet; there is a metal frame around the glass of the combined sliding door cabinet glass; there are rollers on the upper and lower sides of the metal frame ; Its glass is the ultra-high alumina glass product produced by a process method of a new horizontal flame pool kiln production system] The flat glass according to claim 1.
A colored-glazed glass-plate combination wardrobe is characterized in that: the glass-plate combined wardrobe has 1-10 colors of colored glaze layers on the surface or back of the glass; the colored-glazed glass is surrounded by a metal frame, and there is metal between the metal frames Coupling device; the glass is the flat glass according to claim 1 [a super high alumina glass product produced by a process method of a new horizontal flame pool kiln production system].
A colored glaze countertop glass furniture is characterized in that: there are 1-10 colored glaze layers on the surface or back of the glass countertop, and the lower part of the countertop is provided with a supporting device; the glass is [a new type of horizontal flame pool kiln production system Ultra-high alumina glass product produced by the process method] The flat glass according to claim 1.
A photovoltaic solar device, characterized in that the photovoltaic solar device includes a solar cell, and a glass substrate or a cover plate; and the glass thereof is [an ultra-high aluminum glass product produced by a process method of a new horizontal flame pool kiln production system] The flat glass according to claim 1 is required.
A thin-film solar device, characterized in that the thin-film solar device comprises: a thin-film solar cell; and the glass thereof is [an ultra-high aluminum glass product produced by a process method of a new horizontal flame pool kiln production system] according to claim 1 plate glass.
A liquid crystal display screen includes an array substrate including a substrate, a pixel structure on the substrate, and the substrate is a composition according to claim 1 with an ultra-high alumina content and ultra-high Application of strength and high softening point glass;

A color filter substrate comprising a substrate and a color filter layer on the substrate, the substrate being a glass substrate;

A liquid crystal layer sandwiched between the array substrate and the color filter substrate; and a backlight system;

It is characterized in that the glass is the flat glass according to claim 1 [ultra-high alumina glass products produced by a process method of a new horizontal flame pool kiln production system].
A low-temperature polysilicon display screen includes a low-temperature polysilicon array substrate including a substrate and a pixel structure produced by the low-temperature polysilicon process on the substrate;

A color filter substrate comprising a substrate and a color filter layer on the substrate, the substrate being a glass substrate;

A liquid crystal layer sandwiched between the array substrate and the color filter substrate; and

Backlight system;

It is characterized in that the glass is the flat glass according to claim 1 [ultra-high alumina glass products produced by a process method of a new horizontal flame pool kiln production system].
A curved LCD screen,

include:

Substrate glass

An array substrate comprising a substrate and a pixel structure on the substrate, the substrate being a glass plate;

A color filter substrate comprising a substrate and a color filter layer on the substrate, the substrate being a glass substrate;

A liquid crystal layer sandwiched between the array substrate and the color filter substrate; and a backlight system;

It is characterized in that the glass is the flat glass according to claim 1 [ultra-high alumina glass products produced by a process method of a new horizontal flame pool kiln production system].
A front or back shell structure of a display, characterized in that the glass is the flat glass according to claim 1 [a kind of ultra-high aluminum glass product produced by a process method of a transverse flame cell kiln production system].
A bullet-proof and explosion-proof automobile structure, comprising: 1 to 3 layers of glass of 1 to 10 car windows, each of which is bonded by a resin sheet;

Bulletproof structures in metal plates or metal frames around the car;

And power units; dashboards; direction controllers; car shells; car chassis; car brakes; car tires;

It is characterized in that the glass is the flat glass according to claim 1 [ultra-high alumina glass products produced by a process method of a new horizontal flame pool kiln production system].
An anti-robbery, anti-theft, explosion-proof, anti-impact, anti-rollover injury automobile, comprising: 1 to 3 layers of glass of 1 to 10 windows, and bulletproof glass is a composition as described in claim 1, which is highly oxidized Application of glass with aluminum content, ultra-high strength, and high softening point; and power units; instrument panels; direction controllers; car shells; car chassis; car brakes; car tires; characterized by: its glass is [a new horizontal Ultra-high alumina glass products produced by the process method of a flame tank kiln production system] The flat glass according to claim 1.
A solar vehicle includes: a device having propeller power to propel flight, wings, a driving control system device, and a thin-film solar device, including: a thin-film solar cell; a substrate glass on the thin-film solar device; and its characteristics It is that the glass is the flat glass according to claim 1 [a super high alumina glass product produced by a process method of a new horizontal flame pool kiln production system].
A composite plate with colored glaze flat glass and a metal layer, comprising: a glass glaze layer with 1 to 10 colors on the surface of the substrate glass, a metal plate with a thickness of 0.1 to 5 mm, and a layer of adhesion between the glass plate and the metal plate The material layer is characterized in that the glass is the flat glass according to claim 1 [a high-aluminum glass product produced by a process method of a new horizontal flame pool kiln production system].
A colored glaze glass composite material plate comprises: a glass glaze layer with 1 to 10 colors on the substrate glass surface, a metal plate with a thickness of 0.1 to 5 mm, and a layer of adhesive material between the glass plate and the metal plate. It is characterized in that the 2 to 4 sides of the metal plate on the back bottom surface of the composite plate of the product protrude by a distance of 10 to 30 mm from the edge portion of the superimposed colored glaze decorative flat glass product; it is characterized in that: The glass is the flat glass according to claim 1 [a high-aluminum glass product produced by a process method of a new transverse flame cell kiln production system].
A colored glaze glass composite material floor comprises: a base layer thereof, or a wood board; or a metal material board; or a wood board composite board; or a wood flour particle composite board; or a resin material board; its characteristics are: The glass is the flat glass according to claim 1 [a high-aluminum glass product produced by a process method of a new transverse flame cell kiln production system].
A glass washbasin structure, characterized in that the glass is the glass according to claim 1 [a high-aluminum glass product produced by a process method of a new horizontal flame pool kiln production system].
The utility model relates to a glass lifting panel and a combined wash basin, which are characterized in that: 1. a flat glass lifting panel; 2. another part of the combination is a glass wash basin; the feature is that the glass is [ Ultra-high alumina glass product produced by a process method of a new transverse flame pool kiln production system] The glass according to claim 1.
The utility model relates to an ultra-long glass plate of a balcony protection bar. The length of the glass plate of the balcony protection bar is 3 to 8m. It is characterized in that the glass is an ultra-high glass produced by a process method of a new horizontal flame pool kiln production system. Aluminum glass products] The flat glass according to claim 1.
A bullet-proof building structure includes: a wall structure, a ground structure, a roof structure, a door structure, a glass window structure, a bullet-proof glass in a glass window structure, or a bullet-proof glass in a door structure; characterized in that its glass is [一Ultra-high alumina glass product produced by a process method of a new transverse flame pool kiln production system] The flat glass according to claim 1.
A glass back shell of a display, the glass back shell is flat, the glass back shell is a 3D curved shape, and a glass glaze layer is attached to the glass back shell, or The structural layer of the grating feature; characterized in that the glass is the flat glass according to claim 1 [an ultra-high alumina glass product produced by a process method of a new horizontal flame pool kiln production system].
A glass back shell structure in a display structure, the glass back shell is flat, the glass back shell is a 3D curved shape, and a glass glaze layer is attached to the glass back shell, or A structure layer with a grating feature is attached; the glass is an ultra-high alumina glass product produced by the process method of a new transverse flame tank kiln production system].
A glass fiber composite material includes: a plastic matrix and glass fibers embedded in the plastic matrix; the glass fiber is an ultra-high aluminum glass product produced by a process method of a new horizontal flame pool kiln production system The glass according to claim 1.
A glass fiber composite material blade for wind power includes a plastic substrate and glass fiber embedded in the plastic substrate, a composite material manufactured by the same, and a blade for wind power production;

Wind blade composition: glass fiber composite wind blade leaf shell; glass fiber composite wind blade blade root; glass fiber composite wind blade structure beam;

It is characterized in that the glass fiber is the glass according to claim 1 [ultra-high alumina glass product produced by a process method of a new horizontal flame pool kiln production system].
A glass fiber composite material aircraft shell includes: a plastic matrix and glass fiber embedded in the plastic matrix, a composite material manufactured by the aircraft, and an aircraft shell structure; characterized in that its glass fiber is [A new Ultra-high alumina glass products produced by the process method of a transverse flame cell kiln production system] The glass according to claim 1.
A marine vessel with a glass fiber composite material structure,

Contains a plastic matrix, and

Glass fiber embedded in plastic matrix, composite materials manufactured, hull structure made; power plant; cockpit; ship deck;

It is characterized in that the glass fiber is the glass according to claim 1 [ultra-high alumina glass product produced by a process method of a new horizontal flame pool kiln production system].
A glass fiber composite material chemical pipe structure includes a plastic matrix and glass fibers embedded in the plastic matrix, a manufactured composite material, and a chemical or petroleum pipe or a natural gas composite pipe;

It is characterized in that the glass fiber is the glass according to claim 1 [ultra-high alumina glass product produced by a process method of a new horizontal flame pool kiln production system].
A glass fiber composite material shell or chassis automobile includes a plastic substrate and a vehicle shell or vehicle chassis made of glass fiber embedded in the plastic substrate; a car window structure; and a power unit; an instrument panel; an orientation Controller; automobile casing; automobile chassis; automobile brake device; automobile tire; characterized in that its glass fiber is [ultra high-aluminum glass product produced by the process method of a new transverse flame pool kiln production system] Mentioned glass.
A wind power generation device structure includes: a wind blade comprising a plastic matrix and glass fibers embedded in the plastic matrix; a phoenix blade made of a composite material manufactured by the manufacture; further comprising a bearing; a generator; a wind power tower pillar; and It is characterized in that the glass fiber is the glass according to claim 1 [a super high alumina glass product produced by a process method of a new transverse flame tank kiln production system].
A daily-use glass and industrial glass product, characterized in that the glass is [a glass according to claim 1 of an ultra-high alumina glass product produced by a process method of a transverse flame cell kiln production system].
A glass insulator product, characterized in that the glass fiber is [the ultra-high alumina glass product produced by the process method of a new horizontal flame pool kiln production system] The glass according to claim 1.
A glass toilet product, characterized in that its glass is the glass according to claim 1 [a high-aluminum glass product produced by a process method of a new horizontal flame pool kiln production system].