WO2023201689A1 - High-temperature-resistant aerogel smoke control air pipe and manufacturing method therefor - Google Patents

Abstract

The present invention relates to the technical field of fire-fighting and smoke exhaust, and provides the technical solution that a silica aerogel can be better wrapped on the surfaces of fibers by modifying and optimizing a framework of a silica aerogel felt (a heat insulating layer), using ceramic fibers having better high-temperature resistance, and simultaneously enabling dendrites to grow on the surfaces of the ceramic fibers serving as the framework, wherein the dendrites can enable the framework and the silica aerogel to be combined more tightly. In this way, the advantage is that the heat insulating effect of the heat insulating layer is improved. Because the heat transfer of the ceramic fibers is relatively fast, the heat insulating effect of the whole heat insulating layer can be reduced due to a heat conduction effect after the fibers overlap each other. The silica aerogel has a better heat insulating effect, and the fibers are better wrapped, such that silica having better heat insulating performance between the fibers is separated from each other so as to improve the heat insulating effect of the whole heat insulating layer.

Description

A high-temperature-resistant airgel smoke-exhaust air duct and its manufacturing method Technical field

The present invention relates to the technical field of fire protection and smoke exhaust, and in particular to a smoke prevention and exhaust air duct.

Background technique

Smoke prevention and exhaust ducts are used in ventilation ducts in smoke prevention and exhaust systems. The smoke prevention system uses mechanical pressurized air supply or natural ventilation to prevent smoke from entering evacuation channels and discharge smoke to the system outside the building. . The function of the smoke prevention and exhaust system mainly has two aspects: first, to set up smoke prevention facilities in evacuation passages and densely populated areas, which is conducive to the safe evacuation of personnel; second, to discharge the toxic high-temperature smoke generated at the fire scene in a timely manner to eliminate the need for fire extinguishing. obstacles.

At present, people have higher and higher requirements for the safety of buildings, and the heat insulation and fire prevention performance of the smoke prevention and exhaust system is an important guarantee for the safety of the building. The national standard GB51251-2017 "Technical Standard for Building Smoke Prevention and Exhaust Systems" implemented on August 1, 2018, puts forward strict fire resistance time requirements for smoke prevention and exhaust ducts.

In order to meet the requirements of the new standards, the existing technical solution is to increase the thickness of the refractory material. This will cause the smoke prevention and exhaust ducts to occupy a larger space. At the same time, some existing buildings will also encounter the problem of limited space during fire protection renovation, making it difficult to meet the requirements of the new standards. Not only that, the refractory materials of traditional smoke prevention and exhaust ducts are mainly rock wool felt, aluminum silicate felt and other materials, which have serious water absorption problems. After the refractory materials absorb water, the internal structure will collapse, making the life of the smoke prevention and exhaust ducts longer. short.

Contents of the invention

The inventor discovered through extensive research that existing smoke prevention and exhaust air ducts have many deficiencies due to the characteristics of traditional heat insulation materials. The thermal insulation materials used in smoke prevention and exhaust ducts in the prior art will absorb water, causing the insulation structure to collapse and have a short lifespan. At the same time, due to the high thermal conductivity, they occupy a large space. In practice, when the fire scene air duct is locally heated, the structure of the air duct will change and collapse, and the air duct will be defective, resulting in changes in air pressure in the pipe, air leakage, and a decrease in the exhaust performance of the air duct.

Airgel has excellent thermal insulation properties. The inventor found that there is no smoke prevention and fire-resistant ventilation duct using airgel material in the prior art. In the process of realizing the present invention, the inventor provided an airgel thermal insulation layer (insulation layer), which can be applied to smoke prevention and exhaust ducts, solving the problem that airgel cannot achieve the temperature resistance of smoke prevention and exhaust ducts. In addition to the fire protection requirements, the thermal insulation layer has the characteristics of good thermal insulation, sound attenuation and sound absorption, moisture resistance, small air leakage, long service life, and reasonable cost performance. The inventor also found that although silica aerogel has very good thermal insulation properties, its high temperature resistance has certain deficiencies. Traditional silica aerogel begins to melt at over 600°C, and nanopores begin to form above 800°C. Collapse, it has basically lost its thermal insulation effect when the temperature is higher than 1000°C, and cannot meet the requirements of smoke prevention and exhaust duct standards.

The present invention provides a technical solution. The inventor has modified and optimized the skeleton of the silica airgel felt (insulation layer), using ceramic fibers with better high temperature resistance, and at the same time making the ceramic fibers as the skeleton Dendrites grow on the surface, and these dendrites can bind the skeleton and silica aerogel more closely, allowing the silica aerogel to better wrap on the fiber surface. The advantage of this is to improve the thermal insulation effect of the thermal insulation layer, because the heat transfer of ceramic fiber fibers is faster. When they are overlapped with each other, the thermal conduction effect will reduce the thermal insulation effect of the entire thermal insulation layer. Silica aerogel has better thermal insulation effect and can better wrap the fibers, so that the fibers are separated from each other by silica with better thermal insulation performance, thereby improving the thermal insulation effect of the entire thermal insulation layer. .

Ceramic fiber has water-absorbing properties. If used for a long time in a humid environment, it will absorb moisture in the environment. After absorbing water, the internal structure of the ceramic fiber is affected, thereby reducing the thermal insulation performance and affecting the product life. A preferred technical solution is that the aerogel coated on the dendrites has hydrophobic properties; further, the ceramic fiber can be completely coated by the hydrophobic aerogel. A preferred technical solution is for the silica aerogel to completely wrap the surface of the ceramic fibers and ceramic dendrites. Another preferred technical solution is to surface-treat the dendrites and fibers to have hydrophobic properties.

The present invention provides a technical solution. The inventor has improved and optimized the filler in the thermal insulation layer, synthesized and used a silica/alumina composite aerogel composed of silica and alumina. The composite aerogel The silica part in the glue provides excellent thermal insulation capabilities, and the alumina part provides excellent temperature resistance. The combination of alumina and silica molecules can inhibit and reduce the shrinkage, melting and crystal change of silica molecules at high temperatures on a microscopic level, and reduce the powder loss of the thermal insulation layer (airgel felt) on a macroscopic level, making The filler still has thermal insulation properties at high temperatures and maintains relatively good physical and chemical properties to meet usage requirements.

The invention provides a smoke-proof and fire-resistant ventilation duct, which includes a metal duct. The inner and/or outer walls of the metal duct are provided with a heat shielding layer. The heat shielding layer includes at least one of a heat insulation layer, a heat conduction layer, and a heat reflection layer. The thermal insulation layer contains skeleton, fillers, and anti-shrinkage additives. Fillers include aerogels and high temperature resistant additives. The aerogel includes at least one of silica aerogel, aluminum silicate aerogel, and alumina aerogel. The skeleton is made of fiber material, and the fiber material can be at least one of alumina fiber, glass fiber, and mullite fiber. High temperature resistant additives can be aluminum silicate, quartz powder, etc. Airgel contains silica material and aluminum silicate material. The skeleton can be surface-grafted ceramic dendrites; the surface of the ceramic fiber skeleton with dendrites is wrapped by airgel. The aerogel can be a silica/alumina composite aerogel composed of silica and alumina.

The present invention provides a technical solution. The inventor has further modified and optimized the composite silica alumina aerogel. However, under high temperature conditions, the silica aerogel part itself may still shrink and collapse. Problem, the inventor added an anti-shrink additive (silica powder) to the composite aerogel. Through the crystal form change and volume change of the anti-shrink additive (silica powder) at high temperature, the shrinkage of the silica part can be inhibited and reduced. Collapse problem, further improve the temperature resistance of the composite aerogel, enhance the performance of the thermal insulation layer to improve the high temperature performance of smoke prevention and exhaust fire-resistant ventilation ducts.

The inventor proposed that the application of reinforced airgel materials in smoke prevention and exhaust ducts can achieve a lower heat transfer coefficient while withstanding high temperatures, so that the airgel material can be used in the field of smoke prevention and exhaust ducts to enhance The heat resistance of smoke prevention and exhaust ducts allows the smoke prevention and exhaust ducts to function normally when a fire occurs. Applying airgel insulation materials in smoke prevention and exhaust ducts can also reduce the space occupied by insulation materials.

In some embodiments, the high-temperature resistant smoke exhaust duct includes a metal pipe, and the inner and/or outer walls of the metal pipe are provided with a heat shielding layer. The heat shielding layer includes a thermal insulation layer; the thermal insulation layer includes ceramic fiber. and silica aerogel, the ceramic fiber includes at least one of alumina fiber and aluminum silicate fiber, the surface of the ceramic fiber has ceramic dendrites, the silica aerogel has hydrophobic properties, and Completely wrapped on the surface of ceramic fibers and ceramic dendrites.

In some embodiments, the thermal insulation layer further includes an anti-shrink additive, and the anti-shrink additive is silica micropowder.

In some embodiments, the high temperature resistant smoke exhaust duct includes a metal pipe, and the inner wall and/or outer wall of the metal pipe is provided with a heat shielding layer, wherein the heat shielding layer includes a thermal insulation layer; the thermal insulation layer includes a thermal insulation layer skeleton, Insulating filler and anti-shrink additive. The structure of the insulating filler is airgel particles composed of silica and alumina. The airgel particles have hydrophobic properties. The anti-shrink additive is silica powder.

In some embodiments, the structure of the filler includes alumina particles wrapped with a silica aerogel layer on the outside, aluminum silicate particles with a silica aerogel layer on the outside, and silica gas wrapped with an alumina protective layer on the outside. at least one of the gel particles.

In some embodiments, the particle size of the silica powder is 1000-3000 mesh.

In some embodiments, the added amount of silica powder is 1-15%.

In some embodiments, the surface of the silica powder is covered with a titanium dioxide film.

In some embodiments, the titanium dioxide is nitrogen-doped or fluorine-doped titanium dioxide.

In some embodiments, the thermal conductivity of the insulating filler ranges from 0.01 W/m·K to 0.06 W/m·K.

In some embodiments, the particle size range of the insulating filler is 10 μm-900 μm.

In some embodiments, the thermal conductivity of the thermal insulation layer at 600-800°C is 0.015 W/m·K-0.02 W/m·K.

In some embodiments, the thermal insulation layer further includes a light-blocking agent, and the light-blocking agent is titanium dioxide powder or graphite powder.

In some embodiments, the tensile strength of the thermal insulation layer is ≥1.0MPA at 25°C; ≥0.3MPA at 800°C.

In some embodiments, the thermal insulation layer has a flexural modulus ≥6000 psi at 25°C; ≥4000 psi at 800°C.

In some embodiments, the method for producing the thermal insulation layer includes:

S100: Silica sol preparation: Mix silicon source, water, alcohol, and silica powder and stir to obtain silica sol. The stirring time is 60 minutes;

S200: Preparation of silica gel: Add alkali to the prepared silica sol, adjust the pH value and let it stand to form silica gel;

S300: Solvent replacement: Solvent replacement of silica gel using ethanol;

S400: Drying: Use normal temperature and normal pressure drying or supercritical drying to dry the silica gel after solvent replacement.

In some embodiments, the heat shielding layer is bonded to the inner wall and/or outer wall of the metal pipe through fire-resistant sealant.

In some embodiments, the inner and/or outer walls of the metal pipe are coated with an antimicrobial coating.

In some embodiments, the heat shielding layer further includes one or more of a heat conductive layer, a heat reflective layer, and a heat absorbing layer.

In some embodiments, the thermal conductivity layer has a thermal conductivity ranging from 20 W/m·K to 50 W/m·K.

In some embodiments, the thermally conductive layer has thermally conductive structural channels, and the thermally conductive structural channels are double-layer hollow metal plates.

In some embodiments, the form of the thermal conductive layer includes silicone heat dissipation film, graphite heat dissipation film, metal heat conduction plate, and heat pipe type heat conduction plate.

In some embodiments, the metal thermally conductive plate is made of copper plate or aluminum plate.

In some embodiments, the heat absorption capacity of the heat absorption layer is 500 kJ-1000 kJ/kg.

In some embodiments, the heat absorption layer is a phase change material, and the phase change temperature of the phase change material is 800°C or 1000°C or 1200°C.

In some embodiments, the phase change material is a molten salt, including carbonate, chloride salt, and fluoride salt.

In some embodiments, the heat shielding layer further includes a high temperature expansion layer located on the outermost side relative to the metal inner wall and/or outer wall.

In some embodiments, the thickness of the high-temperature expansion layer is 1-5 mm, and the thickness after expansion is 20-100 mm.

In some embodiments, the high-temperature expansion layer includes a high-temperature foaming agent, multifunctional carbon particles, and a stabilizer.

In some embodiments, the high-temperature foaming agent has a foaming temperature greater than 500°C, and the high-temperature foaming agent is silicon carbide powder or particles.

In some embodiments, the multifunctional carbon particles can be graphite or graphene; the stabilizer is manganese dioxide.

In some embodiments, the high-temperature resistant smoke exhaust duct includes a front air duct and a rear air duct; one end of the front air duct is detachably connected to the rear air duct; both ends of the front air duct and the rear air duct are respectively An angle steel flange is provided; the inner wall and/or outer wall of the front air duct is provided with a heat shielding layer, and the inner wall and/or outer wall of the rear air duct is provided with a heat shielding layer; the heat shielding layer includes a thermal insulation layer, a thermal conductive layer, At least one heat reflective layer; the thermal insulation layer is attached to the inner wall and/or outer wall of the front air duct and the rear air duct.

In addition, in some embodiments, a sunscreen agent is added to the thermal insulation layer. The sunscreen agent includes silicon powder coated with titanium dioxide on the surface. As a sunscreen agent, titanium dioxide can reduce radiation heat transfer at high temperatures and enhance the performance of the silica aerogel. High temperature thermal insulation properties. However, due to the easy agglomeration of titanium dioxide itself, the high-temperature heat insulation effect of directly adding titanium dioxide into airgel is not good. Therefore, coating titanium dioxide on the surface of silica powder and then adding it to the aerogel can not only take advantage of the silica powder's ability to regulate and inhibit the shrinkage of silica aerogels at high temperatures, but also solve the problem of titanium dioxide agglomeration, thereby further improving the performance of the silica powder. High temperature thermal insulation properties of silica aerogels.

In addition, in some embodiments, the heat shielding layer also includes a thermal conductive layer, which can quickly disperse local high temperatures and reduce damage to the smoke exhaust duct structure caused by local high temperatures. In some other embodiments, the heat shielding layer further includes a heat absorption layer. The heat absorption layer is made of a heat storage material. The heat storage material can absorb heat and keep the temperature constant. Both the thermal conductive layer and the heat absorbing layer can further ensure the overall stability of the smoke prevention and exhaust duct. It can also reduce the insulation requirements for the insulation layer of smoke prevention and exhaust ducts, thereby reducing costs.

In addition, in some embodiments, the heat shielding layer also includes a high-temperature expansion layer. The high-temperature expansion layer rapidly expands after reaching a set high temperature, and its thermal insulation performance is rapidly enhanced after expansion, thereby enhancing the performance of the entire heat shielding layer under high temperature conditions. Excellent thermal insulation performance, reducing the volume of heat shielding layer under normal conditions and reducing costs.

In order to have good thermal insulation performance at high temperatures, in addition to a very low thermal conductivity, the material also needs to have a certain thickness. However, in actual use, smoke prevention and exhaust ducts will only face high temperatures in emergency situations such as fires, and the excellent thermal insulation properties of smoke prevention and exhaust ducts will be used, and there is a demand for these excellent thermal insulation properties. It is a one-time use. In most cases, there is no need for such excellent thermal insulation and temperature resistance. In order to achieve excellent thermal insulation and temperature resistance, the thickness of the insulation layer is larger, which takes up space. In addition, more and thicker insulation layers are also added. manufacturing cost.

In order to reduce thickness, reduce space occupation, and reduce manufacturing costs, in one technical solution involved in the present invention, an anti-smoke and fire-resistant ventilation duct is provided. The anti-smoke and fire-resistant ventilation duct includes a metal pipe, the inner wall of the metal pipe and/or The outer wall is provided with a heat shielding layer, and the heat shielding layer includes a high temperature expansion layer, and at least one of a heat insulation layer, a heat conduction layer, and a heat reflection layer.

Description of the drawings

The drawings described here are used to provide a further understanding of the present application and constitute a part of the present application. The illustrative embodiments of the present application and their descriptions are used to explain the present application and do not constitute an improper limitation of the present application. In the attached picture:

Figure 1 Schematic diagram of smoke prevention and exhaust duct;

Figure 2 Schematic diagram of the thermal shielding layer;

Figure 3 is a schematic diagram of a filler wrapped with high temperature resistant additives;

Figure 4 Schematic diagram of the thermal insulation layer being wrapped by a high temperature resistant protective layer;

Figure 5 Schematic diagram of dendritic ceramic fiber aerogel;

Figure 6 Schematic diagram of titanium dioxide coating on the surface of silicon powder;

Figure 7 Schematic diagram of the morphology of the high-temperature expansion layer at different temperatures;

Figure 8 Schematic diagram of the smoke exhaust duct structure;

Figure 9 Preparation process of dendritic aluminum silicate fiber reinforced silica aerogel;

Figure 10 Composite temperature thermal conductivity characteristics diagram of alumina and silica airgel;

Figure 11 Temperature-thermal conductivity characteristic diagram of the mullite fiber dendrite skeleton insulation layer and the aluminum silicate fiber insulation layer;

Figure 12 Temperature-thermal conductivity characteristic diagram of the mullite fiber dendrite skeleton insulation layer and the aluminum silicate fiber insulation layer added with silica powder;

Figure 13. Temperature-thermal conductivity/shrinkage characteristic diagram of the thermal insulation layer of gel particle insulation layer with added silica powder;

Figure 14 shows the thermal conductivity/shrinkage characteristics of adding a thermal insulation layer coated with titanium dioxide silica powder and adding silica powder.

In the picture: 100-metal pipe; 101-antibacterial metal pipe; 110-angle steel flange; 120-surround fixing hoop; 121-bolt; 122-nut; 130-fire-resistant sealant; 140-front air duct; 150-rear Air duct; 160-mounting seat; 161-positioning rod; 162-positioning cylinder; 200-heat shielding layer; 210-insulation layer; 211-silica powder; 212-airgel particles; 213-high temperature resistant additive; 214-filler ; 215-titanium dioxide slurry; 216-silica powder particles coated with titanium dioxide slurry; 220-thermal conductive layer; 230-heat reflective layer; 250-high temperature resistant protective layer; 260-high temperature expansion layer; 300-ceramic fiber; 310- Ceramic dendrite; 320-dendritic ceramic fiber aerogel.

In the description of the drawings, the same, similar or corresponding reference numerals represent the same, similar or corresponding units, elements or functions.

Detailed ways

Terminology explanation

Heat shielding layer 200: The heat shielding layer 200 is provided on the inside or outside of the metal wall of the smoke prevention and exhaust duct, and is used to shield the heat inside or outside the smoke prevention and exhaust duct.

Thermal insulation layer 210: The thermal insulation layer 210 is a part of the heat shielding layer 200 and protects the metal structure of the smoke prevention air duct through its own low thermal conductivity.

Thermal conductive layer 220: The thermal conductive layer 220 is a part of the heat shielding layer 200. Through its high thermal conductivity, it can quickly disperse concentrated heat and reduce the risk of metal structure damage caused by local high temperatures.

Heat reflective layer 230: The heat reflective layer 230 is a part of the heat shielding layer 200. It uses its own reflection function to reflect heat radiation under high temperature conditions and reduce the internal temperature.

High temperature resistant additive 213: The high temperature resistant additive 213 is a formula of the thermal insulation layer 210 and is used to improve the physical and chemical properties of the thermal insulation layer 210 under high temperature conditions.

Preferred solution

In a technical solution involved in the present invention, a smoke-proof and fire-resistant ventilation duct is provided. The smoke-proof and fire-resistant ventilation duct includes a metal pipe 100. The inner and/or outer wall of the metal pipe 100 is provided with a heat shielding layer 200. The heat shielding layer 200 includes at least one of a thermal insulation layer 210, a thermal conductive layer 220, and a thermal reflective layer 230, as shown in FIG. 2 .

The thermal insulation layer 210 includes a skeleton, fillers 214, anti-shrinkage additives, and sunscreen agents. Filler 214 is silicon-aluminum composite aerogel. Silicon-aluminum composite aerogel is filled in the skeleton. The high temperature resistant additive 213 is heat resistant materials such as alumina and aluminum silicate. The skeleton is made of fiber material, and the fiber material can be at least one of alumina fiber, glass fiber, mullite fiber, and aluminum silicate fiber.

The fire protection grade of the thermal insulation layer 210 is non-combustible Class A. The density of the insulation layer 210 is 50-500kg/m ³ , and the preferred density is 60kg/m ³ , 70kg/m ³ , 80kg/m ³ , 90kg/m ³ , 100kg/m ³ , 150kg/m ³ , 200kg/m ^3. 250kg/m ³ , 300kg/m ³ , 350kg/m ³ , 400kg/m ³ , 450kg/m ³ , 500kg/m ³ . The thermal conductivity of the thermal insulation layer 210, W/(m·K) range is: ≤0.025 (25℃), the preferred range is ≤0.020 (25℃); ≤0.080 (600℃); the preferred range is ≤0.060 (600 ℃). The thickness range of the thermal insulation layer 210 is ≥20mm; the preferred thickness range is ≥30mm.

The metal pipe 100 has antibacterial ability, and the antibacterial ability is achieved through the antibacterial coating. The antibacterial rate is ≥95%, and the preferred antibacterial rates are ≥96%, 97%, 98%, and 99%. The pipe wall thickness of the metal pipe 100 ranges from 0.2 to 1.5 mm, and the preferred thicknesses are 0.4 mm, 0.5 mm, and 0.6 mm. The compressive strength of the material of the metal pipe 100 (thickness 0.5mm) is ≥0.8Mpa, and the preferred compressive strength is ≥0.9Mpa, 1.0Mpa, and 1.1Mpa.

The unit weight range of smoke prevention and exhaust fire-resistant ventilation ducts is ≤40kg/m ² . The fire resistance limit time of smoke prevention and exhaust fire-resistant ventilation ducts is ≥1h. The pressure resistance performance of smoke prevention and exhaust fire-resistant ventilation ducts (wind speed, ≤20m/s) ≤1500Pa. The specific friction resistance (wind speed, ≤20m/s) of smoke-proof and fire-resistant ventilation ducts is ≤24Pa/m. The air leakage volume of smoke prevention and exhaust fire-resistant ventilation ducts (1500Pa) ≤ 4.08{m3/(h.㎡)}. The pressure deformation of smoke prevention and exhaust fire-resistant ventilation ducts (1500Pa) ≤ 1.0%.

The technical problem to be solved by the embodiment of the present invention is that the internal silica microstructure of the thermal insulation layer 210 material of the heat shielding layer 200 will collapse under high temperature conditions. Processing means are used to make the thermal insulation layer 210 material with stronger fire resistance and high temperature resistance. The method of compounding the alumina material with the silica aerogel and the method of adding silica powder 211 to adjust the structural shrinkage improve the high-temperature performance of the thermal insulation layer 210.

The use of silicon-aluminum composite airgel particles can prevent the pure silica airgel structure from melting above 600°C, and at the same time improve the thermal insulation performance compared with pure alumina airgel. This enables the thermal insulation layer 210 to still have a thermal insulation effect under high temperature conditions, thereby meeting the usage requirements of smoke prevention and exhaust ducts.

The thermal conductivity range of silicon-aluminum composite airgel particles at 800°C is 0.01W/m·K-0.2W/m·K, and the initial melting temperature of silicon-aluminum composite airgel particles is 1000°C. The thermal conductivity of the thermal insulation layer 210 is 0.01W/m·K-0.1W/m·K. The particle size range of silicon-aluminum composite airgel is 10μm-900μm.

The thermal insulation layer 210, the thermal conductive layer 220, and the heat reflective layer 230 are fixed to each other by bonding and hot pressing. The outside of the heat shielding layer 200 can also be wrapped with fiberglass cloth or aluminum foil layers to prevent the filler 214 from breaking and falling off.

Preferred solution

In one technical solution involved in the present invention, the thermal insulation layer 210 includes dendrite-reinforced mullite fiber silica airgel felt. Since aluminum silicate can be used in an environment of 1200°C for a long time, mullite dendrites are grown in situ on the surface of aluminum silicate/mullite fibers through dipping and freeze-drying methods. Using mullite fiber as the skeleton, combined with vacuum impregnation method and sol-gel process, mullite dendrite-reinforced silica airgel insulation material with high temperature resistance and low thermal conductivity was prepared on the basis of mullite fiber. The process flow is shown in Figure 9.

Silicon-aluminum dendrite (dendrite) structure: ceramic fiber 300 is used as a skeleton, and ceramic dendrites 310 are grafted on the surface of the skeleton; airgel is wrapped on the surface of ceramics and ceramic dendrites 310 to form dendritic ceramic fiber 300 aerogels. The gel can be silica aerogel or alumina aerogel. Its form is shown in Figure 5.

Since aluminum silicate materials have water-absorbing properties, long-term use in humid environments will absorb moisture in the environment. After absorbing water, the internal structure of the aluminum silicate fiber is affected, thereby reducing the thermal insulation performance and affecting the product life. A preferred technical solution is that the aerogel coated on the dendrites has hydrophobic properties. Another preferred technical solution is to surface-treat the dendrites and fibers to have hydrophobic properties.

Mullite dendrite preparation:

(1) Dip: Dip the aluminum silicate fiber felt into the impregnation liquid, which is silica sol. The impregnation environment can be low pressure or vacuum, and the impregnation time is 15 minutes.

(2) Freeze drying: Freeze the aluminum silicate fiber mat impregnated with silica sol. The freezing temperature is -20°C and the freezing time is 30°C.

(3) Repeat the operation: Repeat the steps (1) dipping and (2) drying steps. The dipping liquid for the second time is AINO3 solution, and the third time is NHAF solution. The molar ratio of silicon source, aluminum source and fluorine source for three impregnations is 1:3:12.

(4) Heat treatment: After completing three impregnations and freeze-drying, put the impregnated aluminum silicate fiber felt into a high-temperature sintering furnace for heat treatment. During heat treatment, the starting temperature is 50°C, first raised to 200°C at a heating rate of 2°C/min, then raised to 1200°C at a heating rate of 5°C/min, kept for 2 hours, and finally allowed to cool down to room temperature naturally in the sintering furnace.

Preparation of mullite dendrite reinforced silica airgel felt:

Sol preparation: Mix silicon source, water and alcohol, and also add a hydrolysis catalyst to accelerate hydrolysis to obtain a silicon-containing sol. Silicon sources include sodium silicate, ethyl orthosilicate, methyl orthosilicate, etc., and hydrolysis catalysts include hydrochloric acid, oxalic acid, nitric acid, sulfuric acid, etc. Sunscreen agents can also be added to the sol to enhance the temperature insulation performance at high temperatures and inhibit infrared radiation. Sunscreen agents include titanium dioxide, carbon black, SiC, potassium hexatitanate, ZrO2, etc.

Gel preparation: Add a gel catalyst to transform the silica-containing sol into a gel. The gel catalyst can be ammonia, dimethylformamide, etc. After adding the gel catalyst, let it stand for 24-72h to obtain the gel. You can also add the gel catalyst, pour it into the fiber preform and let it stand for 24-72 hours to obtain the gel. You can also add reinforcing fiber and fiber dispersant after adding gel catalyst, and let it stand for 24-72 hours to obtain gel; the reinforcing fiber is dendrite reinforced mullite fiber =; the fiber dispersing agent can be dodecyl Sodium sulfonate, polyethylene glycol, sodium lauryl sulfate, sodium hexametaphosphate, etc.

Aging/aging: After adding ethanol, let it sit for 24-48h.

Solvent replacement: When the silicon source contains metal ions, first remove the metal ions by washing with water, and then use an organic solvent for solvent replacement. If the silicon source does not contain metal ions, use organic solvents for solvent replacement. The organic solvent can be one or a mixture of ethanol, isopropyl alcohol, and n-hexane.

Drying: Drying methods can be drying at normal temperature and pressure, supercritical drying, etc. The conditions for drying at normal temperature and pressure are to dry at 60, 80 and 120°C for 2 hours respectively, and finally obtain white silica aerogel powder. When the solvent is ethanol, soak it with liquid carbon dioxide for 3 days at 5℃, 5.5MPa, and release the displaced ethanol; then raise the temperature to 35℃, 10.5MPa and maintain it for 3h, and then increase the temperature to 0.5MPa/h. Slowly release the pressure to normal pressure to obtain an airgel block. When the solvent is ethanol, the temperature is raised to over 240°C and the pressure exceeds 8Mpa, and then the pressure is slowly released to obtain an airgel block. When the solvent is ethanol, after the temperature and pressure are raised to the critical point according to the preset program, the fluid inside the reactor is released at a slow rate at a constant temperature until the internal and external pressures are balanced. Then when the temperature drops to room temperature, the finished product is obtained.

The technical problem to be solved by the embodiment of the present invention is that the material of the insulation layer 210 of the heat shielding layer 200 cannot withstand high temperatures. Mullite fibers with dendrites are used so that the insulation layer 210 can withstand higher temperatures. .

Preferred solution

The volume of airgel will shrink at high temperatures (above 800 degrees), resulting in structural changes and reduced thermal insulation performance.

In a technical solution involved in the present invention, a smoke-proof and fire-resistant ventilation duct is provided. The smoke-proof and fire-resistant ventilation duct includes a metal pipe 100. The inner and/or outer wall of the metal pipe 100 is provided with a heat shielding layer 200. The heat shielding layer 200 includes at least one of a thermal insulation layer 210, a thermal conductive layer 220, and a thermal reflective layer 230, as shown in FIG. 2 .

The thermal insulation layer 210 includes a skeleton, fillers 214, and anti-shrinkage additives. Filler 214 includes aerogel and high temperature resistant additives 213 . Filler 214 is filled in the skeleton. The filler 214 may also be silica airgel particles coated with a high temperature resistant additive 213. The high temperature resistant additive 213 may be a heat resistant material such as alumina, aluminum silicate. Its process and form are shown in Figure 3. The filler 214 may also be aluminum salt or aluminum oxide particles encapsulated using silica aerogel. Silica aerogel is filled in the skeleton in the form of silica aerogel particles. The skeleton is made of fiber material, and the fiber material can be at least one of alumina fiber, glass fiber, mullite fiber, and aluminum silicate fiber. The anti-shrinkage additive is silica powder 211, which can be crystalline silica powder particles or amorphous (amorphous) silica powder particles.

Silicon powder 211, especially the volume change caused by the crystal phase change of amorphous silica powder particles at high temperatures, is used to adjust and suppress the shrinkage of the insulation layer 210 at high temperatures. At the same time, amorphous silicon powder 211 can also improve The temperature tolerance of the insulation layer 210. Amorphous silicon powder 211 is a silica material, and there will be a volume change caused by the transformation of the crystal form under temperature changes. The volume expansion of the amorphous silicon powder 211 will suppress and reduce the internal stress when the thermal insulation layer 210 experiences high temperature, thereby reducing the structural changes inside the thermal insulation layer 210 and stabilizing its thermal insulation performance under high temperature conditions.

Silica powder 211 will react and transform in the direction of mullite at high temperatures and containing aluminum elements. Mullite is an excellent refractory material, so the addition of silica powder 211 further improves the performance of the silica aerogel. Felt's high temperature resistance.

Silica aerogel is filled in the skeleton in the form of silica aerogel particles. After the silica airgel particles are processed, the outer surface of the silica airgel particles is coated with a high-temperature resistant additive 213. The high-temperature resistant additive 213 can be heat-resistant materials such as alumina and aluminum silicate.

The particle size of amorphous silicon powder 211 is 800-8000 mesh, 1000-2000 mesh, 2000-3000 mesh, 3000-4000 mesh, 4000-5000 mesh, 5000-6000 mesh, 6000-7000 mesh, 7000-8000 mesh, 1000-1500 mesh, 1500 mesh-3000 mesh, or 10-800nm, 10-100nm, 50-200nm, 100-400nm, 300-800nm. Preferred particle sizes are 800-1000 mesh, 1000-1200 mesh, and 1000-3000 mesh. The addition amount of silica powder 211 is 3-25%, 1-10%, 3-15%, 5-20%, 5-25%, 10-25%, and the preferred addition amount is 2-10%, 3-8% , 3-6%. The added amounts of amorphous silicon powder 211 are 1-20%, 1-15%, 2-10%, and 3-8%. The preferred particle size can better promote the bonding of silicon, aluminum and oxygen bonds, making the structure more stable. The optimal addition amount can better improve the material's ability to resist shrinkage at high temperatures while maintaining high thermal insulation performance and mechanical strength.

The preparation method of the thermal insulation layer 210 adding amorphous silicon powder 211 is as follows:

Sol preparation: Mix silicon source, water and alcohol, and also add a hydrolysis catalyst to accelerate hydrolysis to obtain a silicon-containing sol. Silicon sources include sodium silicate, ethyl orthosilicate, methyl orthosilicate, etc., and hydrolysis catalysts include hydrochloric acid, oxalic acid, nitric acid, sulfuric acid, etc. Sunscreen agents can also be added to the sol to enhance the temperature insulation performance at high temperatures. Sunscreen agents include titanium dioxide, carbon black, SiC, potassium hexatitanate, ZrO2, etc.

High temperature resistance/anti-shrinkage enhancement: Add silica micropowder 211 to the prepared sol.

Gel preparation: Add a gel catalyst to transform the silica-containing sol into a gel. The gel catalyst can be ammonia, dimethylformamide, etc. After adding the gel catalyst, let it stand for 24-72h to obtain the gel. You can also add the gel catalyst, pour it into the fiber preform and let it stand for 24-72 hours to obtain the gel. You can also add reinforcing fiber and fiber dispersant after adding gel catalyst, and let it stand for 24-72 hours to obtain gel; reinforcing fiber can be brucite fiber, ceramic fiber 300, glass fiber, quartz fiber; fiber The dispersant can be sodium lauryl sulfonate, polyethylene glycol, sodium lauryl sulfate, sodium hexametaphosphate, etc.

Aging/aging: After adding ethanol, let it sit for 24-48h.

Solvent replacement: When the silicon source contains metal ions, first remove the metal ions by washing with water, and then use an organic solvent for solvent replacement. If the silicon source does not contain metal ions, use organic solvents for solvent replacement. The organic solvent can be one or a mixture of ethanol, isopropyl alcohol, and n-hexane.

Modification: Use a modifier to modify the gel after solvent replacement. The modifier can be TMCS/n-hexane system, trimethylchlorosilane/n-hexane system (volume ratio 1:9), etc. Use the modifier to soak for 24-48 hours for modification, and wash with n-hexane after modification. The modified aerogel has hydrophobic properties. The modification temperature is 20-50°C.

Drying: Drying methods can be drying at normal temperature and pressure, supercritical drying, etc. The conditions for drying at normal temperature and pressure are to dry at 60, 80 and 120°C for 2 hours respectively, and finally obtain white silica aerogel powder. When the solvent is ethanol, soak it in liquid carbon dioxide for 2-5 days at 5-20°C, 4-8MPa, and release the displaced ethanol; then raise the temperature to 30-50°C, 9-15MPa and maintain it for 1- 3h, and then slowly release the pressure to normal pressure at a rate of 0.1-1MPa/h, and the airgel block is obtained. When the solvent is ethanol, the temperature is raised to over 200°C and the pressure exceeds 8Mpa, and then the pressure is slowly released to obtain an airgel block. When the solvent is ethanol, after the temperature and pressure are raised to the critical point according to a preset program, the fluid inside the reactor is released at a slow rate at a constant temperature until the internal and external pressures are balanced. Then when the temperature drops to room temperature, the finished product is obtained.

Preferred solution

At high temperatures, the phenomenon of thermal radiation is enhanced. In order to reduce the deterioration of thermal insulation performance due to thermal radiation at high temperatures, opacifiers can be added to the material to reduce the radiation phenomenon. Titanium dioxide is a commonly used sunscreen agent, but titanium dioxide is prone to agglomeration during the addition process, making it impossible to disperse the titanium dioxide evenly. Especially during the sol-gel process, agglomeration occurs, which affects the final sunscreen effect.

In a technical solution involved in the present invention, a smoke-proof and fire-resistant ventilation duct is provided. The smoke-proof and fire-resistant ventilation duct includes a metal pipe 100. The inner and/or outer wall of the metal pipe 100 is provided with a heat shielding layer 200. The heat shielding layer 200 includes at least one of a thermal insulation layer 210, a thermal conductive layer 220, and a thermal reflective layer 230.

The sunscreen agent is titanium dioxide. Since titanium dioxide is easy to agglomerate during the addition process, a dispersant is also added during the addition process to inhibit the agglomeration of titanium dioxide.

Titanium dioxide can also be coated on the surface of the silicon powder 211 so that it can be stably combined with the surface of the silicon powder 211 to suppress the agglomeration of titanium dioxide, as shown in Figure 6 . Titanium dioxide can use fluorine-doped or nitrogen-doped titanium dioxide nanoparticles to enhance the light-shielding effect in the infrared band. The crystalline form of titanium dioxide may be anatase.

The thermal insulation layer 210 includes a skeleton, fillers 214, and opacifier. Filler 214 is filled in the skeleton. Filler 214 includes aerogel and high temperature resistant additives 213 . The filler 214 may also be silica airgel particles coated with a high temperature resistant additive 213. The high temperature resistant additive 213 may be a heat resistant material such as alumina, aluminum silicate. The filler 214 may also be aluminum salt or aluminum oxide particles encapsulated using silica aerogel. Silica aerogel is filled in the skeleton in the form of silica aerogel particles. The skeleton is made of fiber material, and the fiber material can be at least one of alumina fiber, glass fiber, mullite fiber, and aluminum silicate fiber.

The principle of anti-reflection coating can also be applied to enhance the absorption of infrared band radiation by setting the thickness of the coating. The absorption of infrared band radiation can also be further enhanced by setting a multi-layer anti-reflection coating.

Sol preparation: Mix silicon source, water and alcohol, and also add a hydrolysis catalyst to accelerate hydrolysis to obtain a silicon-containing sol. Silicon sources include sodium silicate, ethyl orthosilicate, methyl orthosilicate, etc., and hydrolysis catalysts include hydrochloric acid, oxalic acid, nitric acid, sulfuric acid, etc. Sunscreen agents can also be added to the sol to enhance the temperature insulation performance at high temperatures. Sunscreen agents include titanium dioxide, carbon black, SiC, potassium hexatitanate, ZrO2, etc.

Sunscreen agent enhancement: Add titanium dioxide and dispersant to the prepared sol, or add silicon micropowder 211 coated with titanium dioxide film to the prepared sol.

The dispersant can be: sodium silicate, sodium tripolyphosphate, sodium hexametaphosphate, polycarboxylate, polyammonium methacrylate, polyethylene glycol.

Gel preparation: Add a gel catalyst to transform the silica-containing sol into a gel. The gel catalyst can be ammonia, dimethylformamide, etc. After adding the gel catalyst, let it stand for 24-72h to obtain the gel. You can also add the gel catalyst, pour it into the fiber preform and let it stand for 24-72 hours to obtain the gel. You can also add reinforcing fiber and fiber dispersant after adding gel catalyst, and let it stand for 24-72 hours to obtain gel; reinforcing fiber can be brucite fiber, ceramic fiber 300, glass fiber, quartz fiber; fiber The dispersant can be sodium lauryl sulfonate, polyethylene glycol, sodium lauryl sulfate, sodium hexametaphosphate, etc.

Aging/aging: After adding ethanol, let it sit for 24-48h.

Solvent replacement: When the silicon source contains metal ions, first remove the metal ions by washing with water, and then use an organic solvent for solvent replacement. If the silicon source does not contain metal ions, use organic solvents for solvent replacement. The organic solvent can be one or a mixture of ethanol, isopropyl alcohol, and n-hexane.

Modification: Use a modifier to modify the gel after solvent replacement. The modifier can be TMCS/n-hexane system, trimethylchlorosilane/n-hexane system (volume ratio 1:9), etc. Use the modifier to soak for 24-48 hours for modification, and wash with n-hexane after modification. The modified aerogel has hydrophobic properties. The modification temperature is 20-50°C.

Drying: Drying methods can be drying at normal temperature and pressure, supercritical drying, etc. The conditions for drying at normal temperature and pressure are to dry at 60, 80 and 120°C for 2 hours respectively, and finally obtain white silica aerogel powder. When the solvent is ethanol, soak it with liquid carbon dioxide for 3 days at 5℃, 5.5MPa, and release the displaced ethanol; then raise the temperature to 35℃, 10.5MPa and maintain it for 3h, and then increase the temperature to 0.5MPa/h. Slowly release the pressure to normal pressure to obtain an airgel block. When the solvent is ethanol, the temperature is raised to over 240°C and the pressure exceeds 8Mpa, and then the pressure is slowly released to obtain an airgel block. When the solvent is ethanol, after the temperature and pressure are raised to the critical point according to a preset program, the fluid inside the reactor is released at a slow rate at a constant temperature until the internal and external pressures are balanced. Then when the temperature drops to room temperature, the finished product is obtained.

The silicon micropowder 211 titanium dioxide coating method is as follows.

Preparation of titanium dioxide precursor: The formula includes titanium source, deionized water, acid, hydrolysis inhibitor, and solvent; the titanium source can be at least one of titanate esters such as tetrabutyl titanate, tetraethyl titanate, and tetrapropyl titanate. A sort of.

Preparation of silicon-containing precursor: The formula includes silicon source, acidic catalyst, solvent, and pH adjuster; the silicon source can be methyl orthosilicate, ethyl orthosilicate, methyltrimethoxysilane, methyltriethoxysilane, At least one of siloxanes such as dimethyldiethoxysilane and vinyltriethoxysilane, or titanium dioxide powder. Silicon-containing precursors may also include polypropylene glycol and ethylene oxide.

Preparation of titanium dioxide sol liquid: Mix titanium dioxide precursor and silicon-containing precursor to prepare titanium dioxide sol. Or directly use titanium dioxide precursor as titanium dioxide sol.

Microsilica powder 211 coating: Dip silica powder 211 into titanium dioxide sol for 5-15 minutes, then take it out and dry it at 400-600°C.

Adding a silicon-containing precursor to the titanium dioxide sol, the silicon source in it can better bond the titanium source/titanium dioxide to the surface of the silicon powder 211.

Example 1

In a technical solution involved in the present invention, a filler 214 is provided. The filler 214 includes silica aerogel. The preparation method of the silica aerogel is as follows.

Preparation of silica sol: Mix silicon source, water and alcohol, take 440ml of ethyl orthosilicate, 72ml of water, 720ml of ethanol and 1ml of hydrochloric acid, add them to a container and stir to obtain silica sol.

Preparation of alumina sol: 30g aluminum isopropoxide, 270ml water, add 0.1ml ethyl acetoacetate, hydrolyze aluminum isopropoxide, the hydrolysis temperature is 75°C, the hydrolysis time is 3h, and a stable alumina sol is obtained.

Gel preparation: Take 200ml of silica sol and 150ml of alumina sol, add 1ml of ammonia water, and let stand for 36 hours to obtain a gel.

Solvent replacement: Use ethanol solvent for solvent replacement.

Drying: Soak with liquid carbon dioxide at 5°C, 5.5MPa, and release the displaced ethanol; then raise the temperature to 35°C, 10.5MPa and maintain for 3 hours, and then slowly release the pressure to normal pressure at a rate of 0.5MPa/h to obtain Airgel blocks. When the solvent is ethanol, the temperature is raised to over 240°C and the pressure exceeds 8Mpa, and then the pressure is slowly released to obtain an airgel block. When the solvent is ethanol, after the temperature and pressure are raised to the critical point according to a preset program, the fluid inside the reactor is released at a slow rate at a constant temperature until the internal and external pressures are balanced. Then when the temperature drops to room temperature, the finished product is obtained.

Table 1 Parameter table of silica gas and alumina composite airgel insulation layer B and conventional silica insulation layer A

​	Insulation layer B	Insulation layer A
Temperature(℃)	Thermal conductivity (W/m·K)	Thermal conductivity (W/m·K)
300	0.040	0.038
400	0.051	0.0490
500	0.052	0.061
600	0.061	>0.1
700	0.063	>0.1
800	0.065	>0.1
900	0.070	>0.1
1000	0.072	>0.1

Example 2

Mullite dendrite preparation:

(1) Dip: Dip the aluminum silicate fiber felt into the impregnation liquid, which is silica sol. The impregnation environment can be low pressure or vacuum, and the impregnation time is 15mn.

(2) Freeze drying: Freeze the aluminum silicate fiber mat impregnated with silica sol. The freezing temperature is -20°C and the freezing time is 30°C.

(3) Repeat operation: Repeat steps (1) impregnation and (2) drying steps. The impregnation liquid for the second impregnation is AlNO3 solution, and the third impregnation solution is NHAF solution. The molar ratio of silicon source, aluminum source and fluorine source for three impregnations is 1:3:12.

(4) Heat treatment: After completing three impregnations and freeze-drying, put the impregnated aluminum silicate fiber felt into a high-temperature sintering furnace for heat treatment. During heat treatment, the starting temperature is 50°C, first raised to 200°C at a heating rate of 2°C/min, then raised to 1200°C at a heating rate of 5°C/min, kept for 2 hours, and finally allowed to cool down to room temperature naturally in the sintering furnace.

Preparation of mullite dendrite reinforced silica airgel felt:

In one technical solution involved in the present invention, a mullite dendrite-reinforced silica airgel felt is provided, and its preparation method is as follows.

Preparation of silica sol: Mix silicon source, water and alcohol, take 440ml of ethyl orthosilicate, 72ml of water, 720ml of ethanol, 1ml of hydrochloric acid and 15g of silica powder, add them to a container and stir to obtain silica sol.

Gel preparation: Take 200ml of silica sol and 150ml of alumina sol, add 1ml of ammonia water, and let it stand for 36 hours to obtain the gel. After pouring it into the mullite fiber prefabricated part with dendrites, let it stand for more than 36 hours. Get the gel.

Solvent replacement: Use ethanol solvent for solvent replacement.

Drying: Soak with liquid carbon dioxide at 5°C, 5.5MPa, and release the displaced ethanol; then raise the temperature to 35°C, 10.5MPa and maintain for 3 hours, and then slowly release the pressure to normal pressure at a rate of 0.5MPa/h to obtain Airgel blocks. When the solvent is ethanol, the temperature is raised to over 240°C and the pressure exceeds 8Mpa, and then the pressure is slowly released to obtain an airgel block. When the solvent is ethanol, after the temperature and pressure are raised to the critical point according to a preset program, the fluid inside the reactor is released at a slow rate at a constant temperature until the internal and external pressures are balanced. Then when the temperature drops to room temperature, the finished product is obtained.

The gelling time needs to be greater than 36 hours. This operation can make the silica aerogel completely coat the mullite fiber and enhance the hydrophobic properties of the mullite fiber.

Table 2 Parameters of the thermal insulation layer C with mullite fiber dendrite skeleton and the aluminum silicate fiber thermal insulation layer

​	Insulation layer C	Aluminum silicate fiber insulation
Temperature(℃)	Thermal conductivity (W/m·K)	Thermal conductivity (W/m·K)
300	0.029	0.040
400	0.036	0.064
500	0.039	0.072
600	0.045	0.094
700	0.049	0.125
800	0.052	0.198
900	0.076	0.248
1000	0.089	0.286
1100	0.106	0.328
1200	0.118	0.379
1300	0.126	0.412

Example 3

Mullite dendrite preparation:

(1) Dip: Dip the aluminum silicate fiber felt into the impregnation liquid, which is silica sol. The impregnation environment can be low pressure or vacuum, and the impregnation time is 15mn.

(2) Freeze drying: Freeze the aluminum silicate fiber mat impregnated with silica sol. The freezing temperature is -20°C and the freezing time is 30°C.

(3) Repeat operation: Repeat steps (1) impregnation and (2) drying steps. The impregnation liquid for the second impregnation is AlNO3 solution, and the third impregnation solution is NHAF solution. The molar ratio of silicon source, aluminum source and fluorine source for three impregnations is 1:3:12.

(4) Heat treatment: After completing three impregnations and freeze-drying, put the impregnated aluminum silicate fiber felt into a high-temperature sintering furnace for heat treatment. During heat treatment, the starting temperature is 50°C, first raised to 200°C at a heating rate of 2°C/min, then raised to 1200°C at a heating rate of 5°C/min, kept for 2 hours, and finally allowed to cool down to room temperature naturally in the sintering furnace.

Preparation of mullite dendrite reinforced silica airgel felt:

In one technical solution involved in the present invention, a mullite dendrite-reinforced silica airgel felt is provided, and its preparation method is as follows.

Preparation of silica sol: Mix silicon source, water and alcohol, take 440ml of ethyl orthosilicate, 72ml of water, 720ml of ethanol and 1ml of hydrochloric acid, add them to a container and stir to obtain silica sol.

Gel preparation: Take 200ml silica sol and 150ml alumina sol, add 1ml ammonia water, and let it stand for 36 hours to obtain the gel. Then pour it into the mullite fiber preform with dendrites and let it stand for 36 hours to obtain the gel. glue.

Solvent replacement: Use ethanol solvent for solvent replacement.

Drying: Soak with liquid carbon dioxide at 5°C, 5.5MPa, and release the displaced ethanol; then raise the temperature to 35°C, 10.5MPa and maintain for 3 hours, and then slowly release the pressure to normal pressure at a rate of 0.5MPa/h to obtain Airgel blocks. When the solvent is ethanol, the temperature is raised to over 240°C and the pressure exceeds 8Mpa, and then the pressure is slowly released to obtain an airgel block. When the solvent is ethanol, after the temperature and pressure are raised to the critical point according to a preset program, the fluid inside the reactor is released at a slow rate at a constant temperature until the internal and external pressures are balanced. Then when the temperature drops to room temperature, the finished product is obtained.

Table 3 Parameter table of insulation layer D and insulation layer C with mullite fiber dendrite skeleton and silica powder

Example 4

In a technical solution involved in the present invention, a filler 214 is provided, and its preparation method is as follows.

Preparation of silica sol: Mix silicon source, water and alcohol, take 440ml of ethyl orthosilicate, 72ml of water, 720ml of ethanol, 1ml of hydrochloric acid, 20g of silica powder, 211 silica powder with a particle size of 1000 mesh, add it to a container and stir. An ultrasonic dispersion step can also be added to better disperse the silica powder 211 to obtain silica sol. The stirring or ultrasonic dispersing time is 30min-120min, the preferred stirring time is 60mi, and the preferred ultrasonic dispersing time is 30min.

Gel preparation: Take 500ml silica sol, add 1ml ammonia water, and let it stand for 36 hours to obtain a gel.

Solvent replacement: Use ethanol solvent for solvent replacement.

Drying: Soak with liquid carbon dioxide at 5°C, 5.5MPa, and release the displaced ethanol; then raise the temperature to 35°C, 10.5MPa and maintain for 3 hours, and then slowly release the pressure to normal pressure at a rate of 0.5MPa/h to obtain Airgel blocks. When the solvent is ethanol, the temperature is raised to over 240°C and the pressure exceeds 8Mpa, and then the pressure is slowly released to obtain an airgel block. When the solvent is ethanol, after the temperature and pressure are raised to the critical point according to a preset program, the fluid inside the reactor is released at a slow rate at a constant temperature until the internal and external pressures are balanced. Then when the temperature drops to room temperature, the finished product is obtained.

Table 4 Parameters of added silica powder silica airgel insulation layer E and conventional silica insulation layer A

Example 5

In a technical solution involved in the present invention, a filler 214 is provided, and its preparation method is as follows.

Preparation of silica sol: Mix silicon source, water and alcohol, take 440ml of ethyl orthosilicate, 72ml of water, 720ml of ethanol, 1ml of hydrochloric acid and 20g of silica powder, add them to a container and stir to obtain silica sol.

Gel preparation: Take 500ml silica sol, add 1ml ammonia water, and let it stand for 36 hours to obtain a gel.

Solvent replacement: Use ethanol solvent for solvent replacement.

Modification: Use trimethylchlorosilane/n-hexane system modifier to modify the gel after soaking for 24-48 hours. The volume ratio of trimethylchlorosilane/n-hexane is 1:9, and the temperature is 40°C.

Drying: Soak with liquid carbon dioxide at 5°C, 5.5MPa, and release the displaced ethanol; then raise the temperature to 35°C, 10.5MPa and maintain for 3 hours, and then slowly release the pressure to normal pressure at a rate of 0.5MPa/h to obtain Airgel blocks. When the solvent is ethanol, the temperature is raised to over 240°C and the pressure exceeds 8Mpa, and then the pressure is slowly released to obtain an airgel block. When the solvent is ethanol, after the temperature and pressure are raised to the critical point according to a preset program, the fluid inside the reactor is released at a slow rate at a constant temperature until the internal and external pressures are balanced. Then when the temperature drops to room temperature, the finished product is obtained.

Example 6

In a technical solution involved in the present invention, a filler 214 is provided, and its preparation method is as follows.

Preparation of silica sol: Mix silicon source, water and alcohol, take 440ml of ethyl orthosilicate, 72ml of water, 720ml of ethanol, 1ml of hydrochloric acid, and 20g of silicon powder with titanium dioxide coating on the surface, add it to a container and stir to obtain silica sol .

Gel preparation: Take 500ml silica sol, add 1ml ammonia water, and let it stand for 36 hours to obtain a gel.

Solvent replacement: Use ethanol solvent for solvent replacement.

Drying: Soak with liquid carbon dioxide at 5°C, 5.5MPa, and release the displaced ethanol; then raise the temperature to 35°C, 10.5MPa and maintain for 3 hours, and then slowly release the pressure to normal pressure at a rate of 0.5MPa/h to obtain Airgel blocks. When the solvent is ethanol, the temperature is raised to over 240°C and the pressure exceeds 8Mpa, and then the pressure is slowly released to obtain an airgel block. When the solvent is ethanol, after the temperature and pressure are raised to the critical point according to a preset program, the fluid inside the reactor is released at a slow rate at a constant temperature until the internal and external pressures are balanced. Then when the temperature drops to room temperature, the finished product is obtained.

Table 5 Parameters of the thermal insulation layer H and thermal insulation layer E added with silicon powder with titanium dioxide coating

​	Insulation layer H	Insulation layer E
Temperature(℃)	Thermal conductivity (W/m·K)	Thermal conductivity (W/m·K)
300	0.042	0.039
400	0.054	0.045
500	0.058	0.055
600	0.062	0.061
700	0.063	0.068
800	0.065	0.072
900	0.066	0.077

The technical problem to be solved by the embodiments of the present invention is to add titanium dioxide sunscreen in order to suppress the enhancement of thermal radiation at high temperatures, but the titanium dioxide sunscreen will cause agglomeration. Silicon powder 211 with titanium dioxide coating on the surface is used. While solving the problem of titanium dioxide agglomeration, it can also suppress the problem of high-temperature shrinkage of airgel materials.

Example 7

In a technical solution involved in the present invention, a filler 214 is provided, and its preparation method is as follows.

Preparation of silica sol: Mix silicon source, water and alcohol, take 440ml of ethyl orthosilicate, 72ml of water, 720ml of ethanol, 1ml of hydrochloric acid, and 20g of silicon powder with titanium dioxide coating on the surface, add it to a container and stir to obtain silica sol .

Gel preparation: Take 500ml silica sol, add 1ml ammonia water, and let it stand for 36 hours to obtain a gel. Silica gel prepared by mechanical disruption.

Prepare alumina sol: 30g aluminum isopropoxide, 270ml water, add 0.1ml ethyl acetoacetate, hydrolyze aluminum isopropoxide, the hydrolysis temperature is 75°C, the hydrolysis time is 3h, and a stable alumina sol is obtained.

Alumina wrapping: Disperse and mix 50g of crushed silica gel into 200ml of the prepared alumina sol, add 15g of polyethylene glycol to gel the alumina sol, and cast it into the aluminum silicate fiber preform. After medium, let it stand for 36 hours to obtain a gel.

Solvent replacement: Use ethanol solvent for solvent replacement.

Drying: Soak with liquid carbon dioxide at 5°C, 5.5MPa, and release the displaced ethanol; then raise the temperature to 35°C, 10.5MPa and maintain for 3 hours, and then slowly release the pressure to normal pressure at a rate of 0.5MPa/h to obtain Airgel blocks. When the solvent is ethanol, the temperature is raised to over 240°C and the pressure exceeds 8Mpa, and then the pressure is slowly released to obtain an airgel block. When the solvent is ethanol, after the temperature and pressure are raised to the critical point according to the preset program, the fluid inside the reactor is released at a slow rate at a constant temperature until the internal and external pressures are balanced. Then when the temperature drops to room temperature, the finished product is obtained.

Table 6 Adding silica powder with titanium dioxide coating, and the thermal insulation layer of alumina-coated silica aerogel particles compared with conventional

Silicon oxide insulation layer A parameter table

​	Insulation I	Insulation layer A
Temperature(℃)	Thermal conductivity (W/m·K)	Thermal conductivity (W/m·K)
300	0.041	0.038
400	0.051	0.0490
500	0.054	0.061
600	0.055	>0.1
700	0.062	>0.1
800	0.064	>0.1
900	0.069	>0.1

Example 8

In a technical solution involved in the present invention, a filler 214 is provided, and its preparation method is as follows.

Preparation of silica sol: Mix silicon source, water and alcohol, take 440ml of ethyl orthosilicate, 72ml of water, 720ml of ethanol, 1ml of hydrochloric acid, and 20g of silicon powder with titanium dioxide coating on the surface, add it to a container and stir to obtain silica sol .

Gel preparation: Take 500ml silica sol, add 1ml ammonia water, and let it stand for 36 hours to obtain a gel.

Solvent replacement: Use ethanol solvent for solvent replacement.

Modification: Use trimethylchlorosilane/n-hexane system modifier to modify the gel after soaking for 24-48 hours. The volume ratio of trimethylchlorosilane/n-hexane is 1:9, and the temperature is 40°C.

Drying: Soak with liquid carbon dioxide at 5°C, 5.5MPa, and release the displaced ethanol; then raise the temperature to 35°C, 10.5MPa and maintain for 3 hours, and then slowly release the pressure to normal pressure at a rate of 0.5MPa/h to obtain Airgel blocks. When the solvent is ethanol, the temperature is raised to over 240°C and the pressure exceeds 8Mpa, and then the pressure is slowly released to obtain an airgel block. When the solvent is ethanol, after the temperature and pressure are raised to the critical point according to a preset program, the fluid inside the reactor is released at a slow rate at a constant temperature until the internal and external pressures are balanced. Then when the temperature drops to room temperature, the finished product is obtained.

Example 9

In a technical solution involved in the present invention, a smoke-proof and fire-resistant ventilation duct is provided. The smoke-proof and fire-resistant ventilation duct includes a metal pipe 100. The inner and/or outer wall of the metal pipe 100 is provided with a heat shielding layer 200. The heat shielding layer 200 includes at least one of a thermal insulation layer 210, a thermal conductive layer 220, and a thermal reflective layer 230.

The thermal insulation layer 210 includes a skeleton and fillers 214 . The filler 214 includes at least one of silica aerogel and aluminum silicate aerogel. Airgel contains silica material, aluminum silicate. The skeleton is made of fiber material, and the fiber material can be at least one of alumina fiber, glass fiber, aluminum silicate fiber, and mullite fiber. The silica airgel can be filled in the skeleton in the form of silica airgel particles; it can also be filled in the skeleton in the form of one-piece molding. Silica powder 211 can also be added to the airgel as an anti-shrinkage additive to reduce the shrinkage problem of the airgel under high temperature conditions.

The high temperature resistant protective layer 250 covers the surface of the thermal insulation layer 210 or wraps the thermal insulation layer 210, as shown in FIG. 4 . The high-temperature resistant protective layer 250 can be made of heat-resistant materials such as aluminum oxide and aluminum silicate. The thermal insulation layer 210 is obtained by impregnating the silica airgel felt with aluminum-containing slurry and drying it at high temperature to obtain a silica airgel felt with an aluminum oxide temperature-resistant shell.

The thermal conductivity range of airgel particles coated with high temperature resistant additive 213 is 0.01W/m·K-0.2W/m·K, and the initial melting temperature of silica aerogel coated with high temperature resistant additive 213 It's 1000℃. The thermal conductivity of the thermal insulation layer 210 is 0.01W/m·K-0.1W/m·K. The particle size range of the silica airgel coated with the high temperature resistant additive 213 is 10 μm-900 μm, and the preferred particle size range is 10 μm-50 μm, 50 μm-100 μm, 100 μm-200 μm, 200 μm-300 μm, 300 μm-500 μm, 500 μm- 600μm, 600μm-800μm, 800μm-900μm. The thickness range of the high temperature resistant additive 213 coating layer is 5 μm-500 μm, and the preferred thickness range is 5 μm-15 μm, 15 μm-40 μm, 40 μm-80 μm, 80 μm-150 μm, 150 μm-300 μm, and 300 μm-500 μm.

The thermal insulation layer 210, the thermal conductive layer 220, and the heat reflective layer 230 are fixed to each other by bonding and hot pressing. The outside of the heat shielding layer 200 can also be wrapped with fiberglass cloth, an aluminum foil layer, or a polymer film to prevent the filler 214 from breaking and falling off, and it can also be moisture-proof and hydrophobic.

The method in which the thermal insulation layer 210 is covered by the high temperature resistant protective layer 250 is:

Preparation of high temperature resistant slurry: Mix aluminum hydroxide, ceramic fiber 300, and water in a certain proportion to make slurry. Alternatively, aluminum salt, ceramic fiber 300, and water can be mixed in a certain proportion, and then the pH is adjusted to generate a slurry containing aluminum hydroxide.

High temperature resistant slurry coating: Dip the heat insulation layer 210 into the high temperature resistant slurry.

Drying of the high temperature resistant protective layer 250: The heat insulating layer 210 impregnated with the high temperature resistant slurry is heated for high temperature treatment, and the slurry is dried to obtain the heat insulating layer 210 containing the high temperature resistant protective layer 250.

Hydrophobic treatment: Wrap a hydrophobic material outside the thermal insulation layer 210. The hydrophobic material can be a polymer coating, a spray repellent, etc.

After the thermal insulation layer 210 covers the high-temperature resistant protective layer 250, it can prevent the internal silica airgel particles from melting at high temperatures such as above 600°C, so that the high-temperature resistant thermal insulation layer 210 can still maintain the thermal insulation effect under high temperature conditions, meeting the requirements for preventing emissions. Requirements for the use of smoke ducts.

Example 10

In order to achieve the performance of thermal insulation and high temperature resistance, conventional smoke prevention and exhaust ducts usually use thicker insulation materials and higher-grade refractory materials to block heat transfer, thereby achieving the requirements of thermal insulation and high temperature resistance. The inventor found that in emergency situations, smoke-proof and fire-resistant ventilation ducts are often locally affected by high temperatures, thus affecting their structural stability. Most of the remaining positions of smoke prevention and exhaust have not reached the design limit and caused performance problems. Therefore, the inventor believes that methods of heat conduction, heat insulation, and temperature resistance can be used to spread local high temperatures to the rest of the smoke prevention and exhaust air duct, thereby reducing the local high temperature so that the smoke prevention and exhaust air duct can withstand higher temperatures.

In a technical solution involved in the present invention, a smoke-proof and fire-resistant ventilation duct is provided. The smoke-proof and fire-resistant ventilation duct includes a metal pipe 100. The inner and/or outer wall of the metal pipe 100 is provided with a heat shielding layer 200. The heat shielding layer 200 includes at least one of a thermal insulation layer 210, a thermal conductive layer 220, and a thermal reflective layer 230.

The thermal conductive layer 220 may be a metal thermal conductive plate, such as copper, aluminum and other metal materials with high thermal conductivity; it may also be a thermal conductive metal structure, such as a hollow thermal conductive interlayer; or it may be the thermal conductive layer 220 of a device equipped with a heat pipe.

The thermal conductive layer 220, the thermal reflective layer 230, and the thermal insulation layer 210 are sequentially stacked to form the thermal shielding layer 200. Another arrangement is that the heat reflective layer 230, the heat conductive layer 220, and the heat insulating layer 210 are sequentially stacked to form the heat shielding layer 200. The thermal insulation layer 210 is attached to the inner wall and/or outer wall of the metal pipe 100 .

The form of the thermal conductive layer 220 includes silicone heat dissipation film, graphite heat dissipation film, metal heat conduction plate, and heat pipe type heat conduction plate. The material of the metal thermal conductive plate can be copper plate or aluminum plate. The thermal conductive layer 220 may also be in the form of a channel with a thermal conductive structure, such as a double-layer hollow metal thermal conductive plate. The thermal conductivity of the thermal conductive layer 220 ranges from 20 W/m·K to 50 W/m·K at 800°C.

Setting the thermal conductive layer 220 in the smoke prevention and exhaust air duct can enhance the heat conduction and heat dissipation performance of the smoke prevention and exhaust fire-resistant ventilation duct, prevent local high temperatures, and prevent the internal silica aerogel particles from melting at high temperatures such as above 600°C, causing the thermal insulation layer to 210 can still maintain structural stability under high temperature conditions and meet the requirements for smoke prevention and exhaust ducts.

The inventor also believes that the local high temperature can be reduced by arranging a heat absorption layer inside the smoke prevention and exhaust air duct, so that the smoke prevention and exhaust air duct can withstand higher temperatures.

In a technical solution involved in the present invention, a smoke-proof and fire-resistant ventilation duct is provided. The smoke-proof and fire-resistant ventilation duct includes a metal pipe 100. The inner and/or outer wall of the metal pipe 100 is provided with a heat shielding layer 200. The heat shielding layer 200 includes a thermal insulation layer 210, and the thermal shielding layer 200 may also include at least one of a thermal conductive layer 220, a thermal reflective layer 230, and a heat absorbing layer.

A preferred way is to stack the heat conductive layer 220, the heat reflective layer 230, the heat absorbing layer, and the heat insulating layer 210 in sequence to form the heat shielding layer 200. Another arrangement method is that the heat reflective layer 230, the heat absorbing layer, and the heat insulating layer 210 are sequentially stacked to form the heat shielding layer 200. The thermal insulation layer 210 is attached to the inner wall and/or outer wall of the metal pipe 100 .

The heat absorption layer is composed of heat storage materials. The heat storage materials can be phase change materials, heated volatilization materials, etc., or preset cooling materials such as preset water tanks, preset carbon dioxide tanks, etc., which can be released when encountering high temperatures. The loaded water, carbon dioxide and other cooling carriers absorb heat. The phase change material can absorb heat and keep the temperature constant, so that when there is a local high temperature, it absorbs heat and produces a phase change without increasing the temperature, thereby protecting the airgel structure of the thermal insulation layer 210 from collapse, so that the thermal insulation layer 210 maintains insulation. Thermal effect, so that the entire heat shielding layer 200 can still maintain the thermal insulation effect at high temperatures.

Phase change materials are molten salts, and molten salts include carbonate, chloride salt, and fluoride salt.

Setting up a heat-absorbing layer in the smoke-proof and exhaust-proof air duct can reduce the temperature of the smoke-proof and fire-resistant ventilation duct, prevent local high temperatures, and prevent the internal silica airgel particles from melting at high temperatures such as above 600°C, making the airgel thermal insulation reach Requirements.

The heat insulation layer 210, the heat conduction layer 220, the heat reflection layer 230, and the heat absorption layer are fixed to each other by adhesion and hot pressing. The outside of the heat shielding layer 200 can also be wrapped with fiberglass cloth or aluminum foil layers to prevent the filler 214 from breaking and falling off.

Example 11

In order to have good thermal insulation performance at high temperatures, in addition to a very low thermal conductivity, the material also needs to have a certain thickness. However, in actual use, smoke prevention and exhaust ducts will only face high temperatures in emergency situations such as fires, and the excellent thermal insulation properties of smoke prevention and exhaust ducts will be used, and there is a demand for these excellent thermal insulation properties. It is a one-time use. In most cases, there is no need for such excellent thermal insulation and temperature resistance. In order to achieve excellent thermal insulation and temperature resistance, the thickness of the insulation layer is larger, which takes up space. In addition, more and thicker insulation layers are also added. manufacturing cost.

In order to reduce thickness, reduce space occupation, and reduce manufacturing costs, in one technical solution involved in the present invention, an anti-smoke and fire-resistant ventilation duct is provided. The anti-smoke and fire-resistant ventilation duct includes a metal pipe 100, the inner wall of the metal pipe 100 and/or Or the outer wall is provided with a heat shielding layer 200. The heat shielding layer 200 includes a high temperature expansion layer 260, and at least one of a heat insulation layer 210, a heat conduction layer 220, and a heat reflection layer 230.

The thermal insulation performance of dendrite-reinforced mullite fiber silica airgel is lower than that of silica aerogel. Therefore, in order to meet the thermal insulation requirements when using dendrite-reinforced mullite fiber silica airgel felt alone, It will still take up a lot of space. Therefore, the dendrite-reinforced mullite fiber silica airgel felt can be combined with the high-temperature expansion layer 260 to form a thermal insulation layer, which reduces space occupation and ensures the thermal insulation performance of the thermal insulation layer under high temperature conditions. .

The high-temperature expansion layer 260 includes high-temperature foaming agent, multifunctional carbon particles, and stabilizer. The foaming temperature of the high-temperature foaming agent is greater than 500°C. The high-temperature foaming agent is silicon carbide powder or particles, as shown in Figure 7. Multifunctional carbon particles can be graphite or graphene. The stabilizer is manganese dioxide. The thickness of the high temperature expansion layer 260 is 1-5mm, and the thickness after expansion is 20-100mm. A preferred solution is to also include airgel particles to improve the thermal insulation performance of the high-temperature expansion layer 260 . The added mass proportion of airgel particles is 3-5%. The high-temperature expansion layer 260 may also contain a water-reducing agent, and the water-reducing agent is sodium tripolyphosphate or sodium hexametaphosphate.

The high-temperature expansion layer 260 will expand and foam when it encounters high temperatures. The thickness of the high-temperature expansion layer 260 increases and the thermal conductivity decreases. At the same time, the multi-functional carbon particles added inside also act as a sunscreen under high temperature conditions, reducing high temperature conditions. Thermal radiation below. Protect the structural stability of the smoke exhaust duct under high temperature conditions. When the high-temperature expansion layer 260 is not foamed (below 500°C), the multifunctional carbon particles are still in a tightly pressed state, so they have relatively good thermal conductivity and can quickly disperse heat and reduce local overheating. When the temperature exceeds 500°C and the overall temperature cannot be lowered below the tolerable temperature of the exhaust duct through thermal conduction and dispersion, the high-temperature expansion layer 260 expands and foams, and the multifunctional carbon particles in it are dispersed and are no longer closely connected to conduct heat. The performance disappears, and the high-temperature expansion layer 260 changes from a thermal conductive function to a functional layer with high-temperature thermal insulation properties. At the same time, these multifunctional carbon particles have the effect of absorbing infrared rays and acting as sunscreen agents in this situation, further improving the heat insulation performance at high temperatures.

Table 7 Parameter table A of heat shielding layer containing high temperature expansion and conventional silica insulation layer

​	Heat shield with high temperature expansion	Insulation layer A	Insulation layer C
Temperature(℃)	Thermal conductivity (W/m·K)	Thermal conductivity (W/m·K)	Thermal conductivity (W/m·K)
300	0.039	0.038	0.029
400	0.048	0.0490	0.036
500	0.054	0.061	0.039
600	0.058	>0.1	0.045

700	0.062	>0.1	0.049
800	0.041	>0.1	0.052
900	0.049	>0.1	0.076
1000	0.052	>0.1	0.089
1100	0.063	>0.1	0.106
1200	0.067	>0.1	0.118

Example 12

In a technical solution involved in the present invention, a thermal insulation layer 210 is provided. The thermal insulation layer 210 includes a skeleton and fillers 214 . The filler 214 includes at least one of silica aerogel and aluminum silicate aerogel. The skeleton is made of fiber material, and the fiber material can be at least one of ceramic fiber 300 and glass fiber. The silica airgel can be filled in the skeleton in the form of silica airgel particles; it can also be filled in the skeleton in the form of one-piece molding.

The filler 214 is in the form of silica airgel particles. The surface of the silica airgel particles is wrapped by a high-temperature resistant protective layer 250. The high-temperature resistant protective layer 250 can be alumina, aluminum silicate or other heat-resistant materials.

One method (organic aluminum alkoxide method) in which the surface of silica airgel particles is wrapped with a high temperature resistant protective layer 250 is:

(1) Preparation of (hydro)aluminum sol: First, disperse and hydrolyze the organoaluminum precursor in water. A hydrolysis catalyst can also be added to enhance the hydrolysis reaction. The aluminum-containing precursor includes at least one of aluminum isopropoxide and aluminum sec-butoxide. Hydrolysis catalysts include nitric acid, ethyl acetoacetate, hydrochloric acid, etc. The hydrolysis temperature is 60℃-90℃. Hydrolysis time is 3-4h.

(2) Wrapping with the high temperature resistant protective layer 250: Disperse and mix the silica airgel particles into the aluminum (hydr)oxide sol, and add a gel catalyst to gel the aluminum (hydr)oxide sol. The gel catalyst can be propylene oxide, glacial acetic acid, ethyl acetoacetate, acetylacetone, alkali, etc. Methanol can also be added to adjust the airgel density of the high temperature resistant protective layer 250 .

(3) Drying: Dry the silica particles wrapped with the high temperature resistant protective layer 250 through high temperature, normal pressure, supercritical and other drying methods.

One method (inorganic aluminum salt method) in which the surface of silica airgel particles is wrapped with a high-temperature resistant protective layer 250 is:

(1) Preparation of (hydro)aluminum sol: first hydrolyze the aluminum salt under alkaline conditions. After complete hydrolysis to form a precipitate, centrifuge or evaporate the water, wash the precipitate to remove anions, and add a peptizing solvent to peptize the precipitate. By controlling the pH value of the sol, a stable, clear and transparent (hydr)aluminum oxide sol can be formed. The aluminum salts include aluminum chloride hexahydrate, aluminum nitrate nonahydrate, aluminum amine sulfate, etc. The alkaline conditions can be obtained by using alkaline substances such as ammonia water.

(2) High temperature resistant protective layer 250 wrapping: Disperse and mix the silica airgel particles into the (hydr)alumina sol, and add a gel network inducer to gel the (hydro)alumina sol, and the gel network Inducers include polyethylene glycol.

(3) Drying: Dry the silica particles wrapped with the high temperature resistant protective layer 250 through high temperature, normal pressure, supercritical and other drying methods.

One method (powder dispersion method) in which the surface of silica airgel particles is wrapped with a high-temperature resistant protective layer 250 is:

(1) Preparation of (hydrogen)alumina sol: Apply powder dispersion method (or physical and chemical powder method), using hydrated alumina powder such as SB powder (pure boehmite powder produced by Condea Company in Germany), PB powder (prepared to Boehmite) is the precursor, which is dispersed in a medium to form a suspension. The medium can be water. Add a peptizing agent to disperse the solid particles into (hydro)alumina sol particles through physical and chemical reactions. The temperature stated for the suspension is 85°C. The sol agent includes nitric acid and hydrochloric acid, and the acid concentration can be 1.6 mol/L. The acid-aluminum ratio is (H+/Al)=0.09.

(2) High temperature resistant protective layer 250 wrapping: Disperse and mix the silica airgel particles into the (hydr)alumina sol, and add a gel network inducer to gel the (hydro)alumina sol, and the gel network Inducers include polyethylene glycol. The gelation time is at least 5 hours and the temperature is 60-90°C.

(3) Drying: Dry the silica particles wrapped with the high temperature resistant protective layer 250 through high temperature, normal pressure, supercritical and other drying methods.

After the silica particles are processed by the high-temperature resistant protective layer 250, the internal silica airgel particles can be prevented from melting at high temperatures such as above 600°C, so that the thermal insulation layer 210 can still have a thermal insulation effect at high temperatures, meeting the requirements for preventing emissions. Requirements for the use of smoke ducts.

Example 13

In a technical solution involved in the present invention, a filler 214 is provided. The filler 214 includes silica aerogel. The preparation method of the silica aerogel is as follows.

Sol preparation: Mix silicon source, water and alcohol, and also add a hydrolysis catalyst to accelerate hydrolysis to obtain a silicon-containing sol. Silicon sources include sodium silicate, ethyl orthosilicate, methyl orthosilicate, etc., and hydrolysis catalysts include hydrochloric acid, oxalic acid, nitric acid, sulfuric acid, etc. Sunscreen agents can also be added to the sol to enhance the temperature insulation performance at high temperatures. Sunscreen agents include titanium dioxide, carbon black, SiC, potassium hexatitanate, ZrO2, etc.

Gel preparation: Add a gel catalyst to transform the silica-containing sol into a gel. The gel catalyst can be ammonia, dimethylformamide, etc. After adding the gel catalyst, let it stand for 24-72h to obtain the gel. You can also add the gel catalyst, pour it into the fiber preform and let it stand for 24-72 hours to obtain the gel. You can also add reinforcing fiber and fiber dispersant after adding gel catalyst, and let it stand for 24-72 hours to obtain gel; reinforcing fiber can be brucite fiber, ceramic fiber 300, glass fiber, quartz fiber; fiber The dispersant can be sodium lauryl sulfonate, polyethylene glycol, sodium lauryl sulfate, sodium hexametaphosphate, etc.

Aging/aging: After adding ethanol, let it sit for 24-48h.

Solvent replacement: When the silicon source contains metal ions, first remove the metal ions by washing with water, and then use an organic solvent for solvent replacement. If the silicon source does not contain metal ions, use organic solvents for solvent replacement. The organic solvent can be one or a mixture of ethanol, isopropyl alcohol, and n-hexane.

Modification: Use a modifier to modify the gel after solvent replacement. The modifier can be TMCS/n-hexane system, trimethylchlorosilane/n-hexane system (volume ratio 1:9), etc. Use the modifier to soak for 24-48 hours for modification, and wash with n-hexane after modification. The modified aerogel has hydrophobic properties. The modification temperature is 20-50°C.

Drying: Drying methods can be drying at normal temperature and pressure, supercritical drying, etc. The conditions for drying at normal temperature and pressure are to dry at 60, 80 and 120°C for 2 hours respectively, and finally obtain white silica aerogel powder. When the solvent is ethanol, soak it with liquid carbon dioxide for 3 days at 5°C, 5.5MPa, and release the displaced ethanol; then raise the temperature to 35°C, 10.5MPa and maintain it for 3 hours, and then increase the temperature to 0.5MPa/h. Slowly release the pressure to normal pressure to obtain an airgel block. When the solvent is ethanol, the temperature is raised to over 240°C and the pressure exceeds 8Mpa, and then the pressure is slowly released to obtain an airgel block. When the solvent is ethanol, after the temperature and pressure are raised to the critical point according to a preset program, the fluid inside the reactor is released at a slow rate at a constant temperature until the internal and external pressures are balanced. Subsequently, when the temperature dropped to room temperature, a conventional silica airgel insulation layer A was obtained.

Example 14

The technical problem to be solved by this quick-connected and fixed smoke-proof and exhaust air duct structure that is easy to install is to overcome the existing defects, provide a quick-connected and fixed air duct structure that is easy to install, and facilitates the installation and disassembly of the air duct. It can realize quick connection between two air ducts, improve work efficiency, and at the same time ensure that the smoke prevention and exhaust airtightness and fire resistance of the air duct will not be reduced. It is highly practical and can effectively solve the problems in the background technology.

The following technical solutions are provided to achieve the above goals:

A smoke prevention and exhaust air duct with a fast-connecting fixed structure, the air duct is spliced through air duct units.

The main structure of each air duct unit is shown in Figure 8, including a metal duct 100, an inner wall heat shielding layer 200 that fits the inner wall of the metal duct 100, an outer wall heat shielding layer 200 that fits the outer wall of the metal duct 100, and an outer wall heat shielding layer 200 that fits the inner wall of the metal duct 100. The fire-resistant sealant 130 is attached to the outside of the shielding layer 200 . Among them, the inner wall heat shielding layer 200, the metal pipe 100, the outer wall heat shielding layer 200, and the outer fire-resistant sealant 130 are sequentially covered and connected. The connection method can be common physical or chemical connection methods such as rivet fixing and adhesion. The inner wall heat shielding layer 200 and the outer wall heat shielding layer 200 may be composed of a single layer or multiple layers of the heat insulation layer 210, the heat conduction layer 220, and the heat reflection layer 230. In addition, in order to ensure that the air duct units can be closely connected to achieve the functions of sealing, heat insulation and preventing thermal bridges, extension layers and receiving areas are provided at both ends of each air duct unit.

Preferably, the metal pipe 100 is a color steel plate

Preferably, the surface of the metal pipe 100 is coated with an antibacterial coating to form an antibacterial metal pipe 101.

The extension layer refers to the structural layer at one end of an air duct unit that extends outward from the main structure in a direction parallel to the pipe wall. The receiving area refers to the other end of the extension layer on the duct unit, the area reserved for connecting to the extension layer of another duct unit. When two duct units are connected, the end of the extension layer should be connected to the extension layer. One end with the receiving area is connected. After connection, the two air duct units can fit tightly at the connection and be fixed by the connecting component at the connection. Depending on the structure of the extension layer, at one end of the receiving area, the structure of the air duct unit can be extended in a single layer or in multiple layers according to the structure of the extension layer, so that it can fit with the extension layer when the air duct units are connected. The structure that is partially extended at the receiving end is defined as the extended receiving layer.

Preferably, there are two air duct units to be connected, and the two air ducts have the same structure. Both structures include the main body of the air duct unit, the extension layer and the receiving area, excluding the extension receiving layer. The main body of the air duct unit is composed of a metal pipe 100, an inner wall heat shielding layer 200 of the metal pipe 100, and an outer wall heat shielding layer 200 of the metal pipe 100. The extension layer is composed of the outer wall heat shielding layer 200 extending outward in a direction parallel to the pipe wall. The extension length of the layer in the direction parallel to the tube wall is the same as the reserved width of the receiving area in the direction parallel to the tube wall.

The connection method is: one end of an air duct unit with an extension layer is connected to an end of another air duct unit with a receiving area, and the metal pipes 100 of the two air duct units are in contact, and the extended outer wall heat shielding layer 200 is in contact with each other. In contact, the outer wall heat shielding layer 200 extending from one end of the extension layer of one air duct unit covers the metal pipe 100 of one end of the receiving area of the other air duct unit. After connection, the two air duct units fit tightly and are fixed through the connecting components.

Preferably, the above-mentioned connection components include: a surrounding fixing hoop 120 made of metal or other high-temperature resistant materials, bolts 121, and nuts 122, as shown in Figure 1 . The surrounding fixing hoop 120 also includes a limiting hole, and the width of the surrounding fixing hoop 120 is not less than the length of the outer wall heat shielding layer 200 extending from the air duct.

An anti-smoke and exhaust air duct includes a front air duct 140 and a rear air duct 150. One end of the front air duct 140 is detachably connected to the rear air duct 150.

Further, the smoke prevention and exhaust air duct also includes a mounting seat 160, a positioning rod 161 and a positioning cylinder 162. The mounting seat 160 is symmetrically provided on the sides of the front air duct 140 and the rear air duct 150. The positioning rod 161 and the positioning cylinder 162 correspond to each other. They are provided on opposite sides of the mounting seats 160 on both sides, and the positioning rod 161 and the positioning cylinder 162 are in sliding fit.

The fixing method after the two air duct units are connected can be: the surrounding fixing hoop 120 covers the gap connecting the metal pipes 100 of the two air duct units and the heat shielding layer 200, the bolts pass through the corresponding limit holes, and the nuts 122 are used to tighten them. Tightly fixed.

The air duct can be rectangular, the long side length of the air duct is b≤500mm, the distance between supports and hangers is d≤2800mm; 500mm≤the long side length of the air duct b≤1000mm, the distance between supports and hangers is d≤2400mm; 1000mm≤air duct length The side length b≤2000mm, the distance between supports and hangers d≤1400.

Rectangular duct sizes can be 120mm, 160mm, 200mm, 250mm, 320mm, 400mm, 500mm, 630mm, 800mm, 1000mm, 1250mm, 1600mm, 2000mm, 2500mm, 3000mm, 3500mm, 4000mm.

Preferably, the two air duct units to be connected are respectively provided with angle steel flange structures 110 for connection at both ends. The flanges are made of metal or other high-temperature resistant materials. When the two air duct units are connected, they are located on both ends. The two angle steel flange 110 structures on both sides of the air duct unit connection seam can be tightly fitted and fixed through the connecting components.

Preferably, the above-mentioned connection component includes: a plurality of bolts 121 and nuts 122 made of metal or other high temperature resistant materials. The connection method is that the nut 122 passes through the limit hole on the corresponding angle flange 110, and is fixed and locked by the bolt 121 and the nut 122.

Although specific embodiments of the present application have been described above, those skilled in the art will understand that these are only examples, and the protection scope of the present application is defined by the appended claims. Those skilled in the art can make various changes or modifications to these embodiments without departing from the principles and essence of the present application, but these changes and modifications all fall within the protection scope of the present application.

Claims (26)

1. A high-temperature-resistant and smoke-exhaust-proof air duct, characterized in that it includes a metal pipe, the inner wall and/or the outer wall of the metal pipe is provided with a heat shielding layer, the heat shielding layer includes a thermal insulation layer; the thermal insulation layer includes ceramic fiber and silica aerogel, the ceramic fiber includes at least one of alumina fiber and aluminum silicate fiber, the surface of the ceramic fiber has ceramic dendrites, the silica aerogel has hydrophobic properties, and Completely wrapped on the surface of ceramic fibers and ceramic dendrites.
2. The high-temperature resistant smoke exhaust duct according to claim 1, wherein the thermal insulation layer further includes an anti-shrink additive, and the anti-shrink additive is silica powder.
3. A high-temperature-resistant smoke exhaust duct, characterized in that it includes a metal pipe, and the inner wall and/or outer wall of the metal pipe is provided with a heat shielding layer, wherein the heat shielding layer includes a thermal insulation layer; the thermal insulation layer includes a thermal insulation layer skeleton, Insulating filler and anti-shrink additive. The structure of the insulating filler is airgel particles composed of silica and alumina. The airgel particles have hydrophobic properties. The anti-shrink additive is silica powder.
4. The high-temperature resistant smoke exhaust air duct according to claim 2 or 3, characterized in that the particle size of the silica powder is 1000-3000 mesh.
5. The high-temperature-resistant and smoke-exhaust-proof air duct according to any one of claims 2 to 4, characterized in that the added amount of the silicon micropowder is 1-15%.
6. The high-temperature resistant smoke exhaust air duct according to any one of claims 2 to 5, characterized in that the surface of the silicon powder is covered with a titanium dioxide film.
7. The high-temperature resistant smoke exhaust duct according to claim 6, wherein the titanium dioxide is nitrogen-doped or fluorine-doped titanium dioxide.
8. The high-temperature resistant and smoke-proof air duct according to any one of the preceding claims, characterized in that the thermal conductivity of the thermal insulation layer at 600-800°C is 0.015W/m·K-0.02W/m·K.
9. The high-temperature-resistant and anti-smoke exhaust air duct according to any of the preceding claims, characterized in that the thermal insulation layer further includes a light-shielding agent, and the light-shielding agent is titanium dioxide powder and graphite powder.
10. The high-temperature resistant smoke exhaust duct according to any one of the preceding claims, characterized in that the tensile strength of the thermal insulation layer is ≥1.0MPA at 25°C; ≥0.3MPA at 800°C.
11. The high-temperature resistant and smoke-proof air duct according to any one of the preceding claims, characterized in that the production method of the thermal insulation layer includes:

    S100: Preparation of silica sol: Mix silicon source, water, alcohol and silica powder and stir to obtain silica sol. The stirring time is 60 minutes;

    S200: Preparation of silica gel: Add alkali to the prepared silica sol, adjust the pH value and let it stand to form silica gel;

    S300: Solvent replacement: Solvent replacement of silica gel using ethanol;

    S400: Drying: Use normal temperature and normal pressure drying or supercritical drying to dry the silica gel after solvent replacement.
12. The high-temperature resistant smoke exhaust air duct according to any one of the preceding claims, wherein the heat shielding layer is bonded to the inner and/or outer wall of the metal pipe through a fire-resistant sealant.
13. The high-temperature resistant smoke exhaust air duct according to any of the preceding claims, characterized in that the inner and/or outer walls of the metal pipe are coated with an antibacterial coating.
14. The high-temperature resistant and anti-smoke exhaust duct according to any of the preceding claims, wherein the heat shielding layer further includes one or more of a heat conductive layer, a heat reflective layer, and a heat absorbing layer.
15. The high-temperature-resistant and anti-smoke exhaust air duct according to claim 14, characterized in that the thermal conductivity coefficient of the thermal conductive layer ranges from 20W/m·K to 50W/m·K.
16. The high-temperature resistant smoke exhaust duct according to claim 14 or 15, characterized in that the thermal conductive layer has a thermal conductive structural channel, and the thermal conductive structural channel is a double-layer hollow metal plate.
17. The high-temperature-resistant and smoke-exhaust-proof air duct according to claim 15 or 16, wherein the heat-conducting layer is in the form of a silicone heat-dissipating film, a graphite heat-dissipating film, a metal heat-conducting plate, or a heat pipe-type heat-conducting plate.
18. The high-temperature-resistant and smoke-exhaust-proof air duct according to claim 17, characterized in that the material of the metal heat-conducting plate is copper plate or aluminum plate.
19. The high-temperature-resistant and smoke-exhaust-proof air duct according to claim 14, characterized in that the heat absorption capacity of the heat absorption layer is 500kJ-1000kJ/kg.
20. The high-temperature resistant smoke exhaust duct according to claim 19, wherein the heat-absorbing layer is a phase change material, and the phase change temperature of the phase change material is 800°C or 1000°C or 1200°C.
21. The high-temperature resistant smoke exhaust duct according to claim 20, wherein the phase change material is molten salt, and the molten salt includes carbonate, chloride salt, and fluoride salt.
22. The high-temperature resistant smoke exhaust duct according to any of the preceding claims, wherein the heat shielding layer further includes a high-temperature expansion layer located at the outermost side relative to the metal inner wall and/or outer wall.
23. The high-temperature-resistant and smoke-exhaust-proof air duct according to claim 22, wherein the thickness of the high-temperature expansion layer is 1-5 mm, and the thickness after expansion is 20-100 mm.
24. The high-temperature resistant smoke exhaust air duct according to claim 22 or 23, wherein the high-temperature expansion layer contains a high-temperature foaming agent, multifunctional carbon particles and a stabilizer.
25. The high-temperature-resistant and smoke-exhaust-proof air duct according to claim 24, wherein the foaming temperature of the high-temperature foaming agent is greater than 500°C, and the high-temperature foaming agent is silicon carbide powder or particles.
26. The high-temperature resistant smoke exhaust air duct according to claim 24 or 25, wherein the multifunctional carbon particles can be graphite or graphene; and the stabilizer is manganese dioxide.

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