CN113648940A

CN113648940A - Ultra-light high-elasticity radiation-resistant nanofiber aerogel material and preparation method thereof

Info

Publication number: CN113648940A
Application number: CN202111113095.4A
Authority: CN
Inventors: 张恩爽; 李文静; 张晚林; 宋寒; 张昊; 张凡
Original assignee: Aerospace Research Institute of Materials and Processing Technology
Current assignee: Aerospace Research Institute of Materials and Processing Technology
Priority date: 2021-09-23
Filing date: 2021-09-23
Publication date: 2021-11-16
Anticipated expiration: 2041-09-23
Also published as: CN113648940B

Abstract

The invention relates to an ultralight high-elasticity radiation-resistant nanofiber aerogel material and a preparation method thereof, wherein the method comprises the following steps: uniformly mixing tetraethoxysilane, phosphoric acid and water, stirring for 1-24 hours, adding silicon carbide nano powder, continuously stirring for 1-12 hours, and performing ultrasonic treatment to obtain a composite hydrolysate; uniformly mixing the polyvinyl alcohol aqueous solution and the composite hydrolysate with water, stirring for 1-12h, and then performing electrostatic spinning on the precursor solution to obtain a hybrid nanofiber membrane; carrying out heat treatment on the hybrid nanofiber membrane; adding the hybrid nanofiber membrane after heat treatment, tetraethoxysilane, boric acid and aluminum chloride into water, and stirring at a high speed to obtain homogeneous dispersion liquid; and then sequentially freezing, freeze-drying and post-treating the homogeneous dispersion to prepare the ultra-light high-elasticity radiation-resistant nanofiber aerogel material. The material prepared by the invention has high elasticity, and has excellent radiation resistance, temperature resistance and high-temperature heat insulation performance.

Description

Ultra-light high-elasticity radiation-resistant nanofiber aerogel material and preparation method thereof

Technical Field

The invention relates to the technical field of aerogel preparation, in particular to an ultra-light high-elasticity radiation-resistant nanofiber aerogel material and a preparation method thereof.

Background

The nano porous aerogel material is a gel material with a dispersion medium of gas, is a nano porous solid material with a network structure formed by mutually accumulating colloidal particles or high polymer molecules, and the size of pores in the material is in the order of nanometers. The porosity of the porous ceramic is as high as 80-99.8%, the typical size of the pores is 1-100 nm, and the specific surface area is 200-1000 m²A density of as low as 3kg/m³The heat conductivity coefficient at room temperature can be as low as 0.012W/m.K. Due to the characteristics, the aerogel material has wide application potential in the aspects of thermal, acoustic, optical, microelectronic and particle detection. Currently, the widest field of application of aerogels is still the field of thermal insulation, since the unique nanostructure of aerogels can effectively reduce convection conduction, solid phase conduction and thermal radiation. The existing research proves that aerogel is an effective heat insulation material, but most of aerogel materials reported at present are rigid aerogel materials with a nanometer skeleton in a nanometer pearl necklace structure. Aerogel materials with high elasticity are often regarded as the properties that organic aerogels have, and the preparation of elastic inorganic aerogels has great difficulty. In recent years, the preparation of inorganic nanofiber aerogel materials has become a focus of attention of researchers, and the elasticity characteristics of the inorganic nanofibers with high aspect ratio can be utilized to endow the inorganic nanofiber aerogel with high elasticity. However, despite the elasticity of the nanofiber aerogel, the thermal insulation performance of the nanofiber aerogel is far from the traditional aerogel materials. Chinese patent application CN201910202661.5 discloses a method for preparing modified silica powder/silica nanofiber composite aerogel material, which combines electrostatic spinning silica nanofibers with silica aerogel powder to prepare the modified silica powder/silica nanofiber composite aerogel material, the compression resilience can reach 85%, and the heat-insulating property of pure nanofiber aerogel is improved by uniform and stable dispersion of nano-grade aerogel powder, but this patent discloses that the modified silica powder/silica nanofiber composite aerogel material is prepared by combining electrostatic spinning silica nanofibers with silica aerogel powder, and the heat-insulating property of pure nanofiber aerogel is improved by uniform and stable dispersion of nano-grade aerogel powderThe nano-fiber in the application is a pure silicon dioxide phase, the radiation resistance performance is poor at high temperature, and the problems of high thermal conductivity coefficient and insufficient heat insulation performance at high temperature exist.

In addition, the nano-fiber aerogel has larger pores and more continuous framework, which determines that the nano-fiber aerogel has larger solid phase heat conduction and gas phase heat conduction, and the single component structure causes the nano-fiber aerogel to have poorer radiation resistance. A small amount of research work relates to the preparation of silicon carbide nanofiber aerogel materials with anti-radiation effects, however, pure silicon carbide nanofibers are prone to oxidation in air and poor in temperature resistance.

With the development of science and technology, various fields put higher demands on the temperature resistance, compression resilience, high-temperature heat-insulating property and the like of aerogel materials, so that an effective method for preparing an ultralight high-elasticity radiation-resistant nanofiber aerogel material is very needed.

Disclosure of Invention

In order to solve one or more technical problems in the prior art, the invention provides an ultra-light high-elasticity radiation-resistant nanofiber aerogel material and a preparation method thereof. The ultra-light high-elasticity radiation-resistant nanofiber aerogel material prepared by the invention has high elasticity, and also has excellent radiation resistance, temperature resistance and high-temperature heat insulation performance.

The invention provides a preparation method of an ultralight high-elasticity radiation-resistant nanofiber aerogel material in a first aspect, which comprises the following steps:

(1) uniformly mixing tetraethoxysilane, phosphoric acid and water to obtain a mixed solution, stirring the mixed solution for 1-24 hours to obtain a hydrolysate, adding silicon carbide nano powder into the hydrolysate, stirring for 1-12 hours, and finally performing ultrasonic treatment for 0.5-2 hours to obtain a composite hydrolysate;

(2) uniformly mixing a polyvinyl alcohol aqueous solution and the composite hydrolysate obtained in the step (1) with water, stirring for 1-12 hours to obtain a precursor solution, and then performing electrostatic spinning by using the precursor solution as an electrostatic spinning solution to obtain a hybrid nanofiber membrane;

(3) carrying out heat treatment on the hybrid nanofiber membrane obtained in the step (2) in an inert atmosphere; the heat treatment comprises the following steps: firstly, carrying out heat treatment at 300-600 ℃ for 1-10 h, then carrying out heat treatment at 600-900 ℃ for 1-5 h, and then naturally cooling to room temperature;

(4) adding the hybrid nanofiber membrane subjected to heat treatment in the step (3), ethyl orthosilicate, boric acid and aluminum chloride into water to obtain a to-be-dispersed solution, and then stirring the to-be-dispersed solution at a high speed to obtain a homogeneous phase dispersed solution;

(5) sequentially freezing and freeze-drying the homogeneous dispersion liquid obtained in the step (4) to obtain a nanofiber aerogel material;

(6) and (5) carrying out post-treatment on the nanofiber aerogel material obtained in the step (5) in an inert atmosphere to obtain the ultra-light high-elasticity radiation-resistant nanofiber aerogel material.

Preferably, in step (1): the molar ratio of the ethyl orthosilicate to the phosphoric acid to the water is (0.5-1): (0.005-0.05): (1 to 20), preferably 1: (0.015 to 0.025): (8-15), more preferably 1:0.02: 10; and/or the dosage of the silicon carbide nano powder is 0.4-10% of the mass of the hydrolysate, and preferably 0.8-2.5%.

Preferably, in step (2): the mass fraction of polyvinyl alcohol contained in the polyvinyl alcohol aqueous solution is 1-20%; the mass ratio of the composite hydrolysate to the polyvinyl alcohol aqueous solution to the water is (1-5): (1-5): (0.5 to 5), preferably (2.5 to 3.5): (2.5-3.5): 2, more preferably 3:3: 2; and/or the stirring time is 3-6 h.

Preferably, the parameters for electrospinning are as follows: the voltage is 5-40 kV, the perfusion speed is 0.5-2 mL/h, the receiving distance is 10-25 cm, and/or the temperature in the spinning room is 15-35 ℃.

Preferably, in the step (2), the obtained hybrid nanofiber membrane is also subjected to vacuum drying; preferably, the obtained hybrid nanofiber membrane is dried in a vacuum drying oven at 60-120 ℃ for 1-3 h.

Preferably, in step (4): the mass fraction of the hybrid nanofiber membrane contained in the liquid to be dispersed is 0.4-0.6%, the mass fraction of ethyl orthosilicate contained in the liquid to be dispersed is 0.4-0.6%, the mass fraction of boric acid contained in the liquid to be dispersed is 0.05-0.2%, and the mass fraction of aluminum chloride contained in the liquid to be dispersed is 0.1-0.3%; and/or the rotating speed of the high-speed stirring is 5000-20000 r/min, and the time of the high-speed stirring is 5-30 min.

Preferably, in step (5): the freezing is performed for 10-60 min under liquid nitrogen; the freezing is carried out in a mould, the top and the side surfaces of the mould are made of materials with lower heat conductivity, the bottom of the mould is made of materials with higher heat conductivity, preferably, the top and the side surfaces of the mould are made of polytetrafluoroethylene, and the bottom of the mould is made of copper materials; and/or the freeze drying is vacuum freeze drying, preferably the vacuum freeze drying is carried out for 2-5 d under the conditions that the vacuum degree is 0.5-10 Pa and the temperature is-50 to-70 ℃.

Preferably, in step (6): the temperature of the post-treatment is 800-1000 ℃, and the time of the post-treatment is 0.1-12 h.

Preferably, the density of the ultra-lightweight high-elasticity radiation-resistant nanofiber aerogel material is not more than 0.05g/cm³The compression rebound rate is not less than 80%, the linear shrinkage rate at 1100 ℃ is not more than 1%, the thermal conductivity at room temperature is not more than 0.031W/m.K, and the thermal conductivity at 800 ℃ is not more than 0.065W/m.K.

In a second aspect, the invention provides an ultra-light high-elasticity radiation-resistant nanofiber aerogel material prepared by the preparation method in the first aspect.

Compared with the prior art, the invention at least has the following beneficial effects:

(1) according to the method, the anti-radiation agent is doped in the composite hydrolysate, and after the heat treatment process, the in-situ doping of the anti-radiation agent is realized, so that the anti-radiation agent can be embedded in the nano-fibers in situ, and the anti-radiation agent can be ensured not to lose efficacy in the heat treatment process and the post-treatment process; compared with single-component nanofiber aerogel (silicon dioxide, zirconium oxide and mullite), the ultra-light high-elasticity radiation-resistant nanofiber aerogel material has excellent radiation-resistant property, the radiation-resistant agent (silicon carbide nano powder) is embedded in the interior of the nanofiber in situ and can be uniformly dispersed, agglomeration among particles is avoided, a good radiation-resistant effect can be realized, the high-temperature heat-insulating property is good, and the ultra-light high-elasticity radiation-resistant nanofiber aerogel material prepared by the invention has a low heat conductivity coefficient at the high temperature of 800 ℃.

(2) According to the invention, the silicon carbide nano powder is doped in the composite hydrolysate to prepare the hybrid nanofiber membrane (composite nanofiber), the composite nanofiber is used as an aerogel basic unit, the self-assembly of the composite nanofiber is realized, and the preparation of the nanofiber aerogel material with good elasticity is realized by utilizing the bendable characteristic of the nanofiber with high length-diameter ratio.

(3) According to the invention, the silicon-aluminum composite component is adopted as the basic composition of the aerogel to obtain the aerogel material of the composite component, and the composite component can form a more temperature-resistant phase in the high-temperature use process, so that the temperature resistance of the material can be effectively improved.

(4) According to the nanofiber aerogel material, the anti-radiation nanoparticles are embedded in the nanofibers, so that direct contact with air at high temperature is avoided, the anti-oxidation property of the material is improved, the preparation of the core-shell structure porous network aerogel is realized, the growth and oxidation of internal silicon carbide nanocrystals can be effectively inhibited, and the thermal stability of the aerogel material is improved.

(5) The invention adopts the freeze drying process to replace the supercritical drying process, reduces the cost and the period in the material preparation process, and simultaneously improves the environmental protection of the preparation method.

(6) The ultra-light high-elasticity radiation-resistant nanofiber aerogel material prepared by the method has excellent elasticity on the premise of keeping low thermal conductivity not more than 0.031W/m.K, can realize temperature resistance of over 1100 ℃ for a short time, has low thermal conductivity at the high temperature of 800 ℃, has excellent high-temperature heat-insulating property and excellent radiation-resistant property.

(7) The ultra-light high-elasticity radiation-resistant nanofiber aerogel material prepared by the method disclosed by the invention has the porosity of more than 90%, the pore size of 5-500 nm, the diameter of the nanofiber of 100-500 nm, the compression rebound rate of not less than 80% and the heat-resistant temperature of more than 1100 ℃.

Drawings

FIG. 1 is a flow chart of the preparation of the present invention.

FIG. 2 shows the PVA/SiO after heat treatment prepared in example 1 of the present invention₂SEM image of/SiC hybrid nanofiber membrane. As can be seen from FIG. 2, PVA/SiO₂The surface of the/SiC hybridized nano fiber membrane is not distributed with silicon carbide nano powder.

FIG. 3 shows the PVA/SiO after heat treatment prepared in example 1 of the present invention₂TEM image of/SiC hybrid nanofiber membrane. As can be seen from fig. 3, the silicon carbide nano powder is embedded in the interior of the nanofibers in situ.

FIG. 4 is an EDS energy spectrum (carbon element) of the ultralight high-elasticity radiation-resistant nanofiber aerogel material prepared in example 1 of the present invention.

FIG. 5 is an EDS energy spectrum (oxygen element) of the ultralight high-elasticity radiation-resistant nanofiber aerogel material prepared in example 1 of the present invention.

FIG. 6 is an EDS energy spectrum (silicon element) of the ultralight high-elasticity radiation-resistant nanofiber aerogel material prepared in example 1 of the present invention.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the technical solutions of the present invention will be clearly and completely described below with reference to the embodiments of the present invention. It is to be understood that the embodiments described are only a few embodiments of the present invention, and not all embodiments. All other embodiments, which can be obtained by a person skilled in the art without any inventive step based on the embodiments of the present invention, are within the scope of the present invention.

(1) mixing Tetraethoxysilane (TEOS) and phosphoric acid (H)₃PO₄) Mixing with water (such as deionized water) to obtain mixed solution, and stirring the mixed solutionStirring for 1-24 h (e.g., 1, 6, 12 or 24h) to obtain a hydrolysate, adding silicon carbide nanopowder into the hydrolysate, stirring for 1-12h (e.g., 1, 3, 6, 8, 10 or 12h), and finally performing ultrasonic treatment for 0.5-2 h (e.g., 0.5, 1, 1.5 or 2h) to obtain a composite hydrolysate (also referred to as TEOS composite hydrolysate); specifically, the step (1) is as follows: at room temperature, taking TEOS and H with certain mass₃PO₄And deionized water as per n (teos): n (H)₃PO₄)：n(H₂O) ═ 0.5 to 1: (0.005-0.05): (1 to 20), preferably 1: (0.015 to 0.025): (8-15) more preferably mixing at a molar ratio of 1:0.02:10, and stirring on a magnetic stirrer for 1-12 hours, preferably 12 hours to obtain a hydrolysate; then adding silicon carbide nano powder into the hydrolysate to ensure that the dosage of the silicon carbide nano powder (anti-radiation agent) is 0.4-10% and preferably 0.8-2.5% of the mass of the hydrolysate, stirring for 1-12h, and performing ultrasonic treatment for 0.5-2 h to uniformly disperse the silicon carbide nano powder in the hydrolysate to obtain a composite hydrolysate; in the present invention, the particle size of the silicon carbide nanopowder is not particularly limited, and it is sufficient to use a nano-sized silicon carbide nanopowder, and in some specific embodiments, the silicon carbide nanopowder is preferably a silicon carbide nanopowder with a particle size range of 40-100 nm; the working frequency of the ultrasonic treatment is not particularly limited, and the ultrasonic treatment can be carried out by adopting a conventional frequency, for example, the frequency can be 25-40 kHz; in the invention, ethyl orthosilicate (TEOS) and phosphoric acid (H) are firstly required to be prepared₃PO₄) The mixed liquid formed by mixing with water is firstly hydrolyzed, then the silicon carbide nano powder is added into the hydrolysate, and through stirring and ultrasonic treatment, the silicon carbide nano powder can be uniformly dispersed in the hydrolysate, the uniform doping of the silicon carbide nano powder in the follow-up electrostatic spinning process and the uniform in-situ doping of the silicon carbide nano powder after the heat treatment process are favorably realized, the silicon carbide nano powder can be uniformly embedded in the interior of the nano fiber and can be uniformly dispersed, the agglomeration among particles is avoided, the silicon carbide nano powder can not lose efficacy in the heat treatment process and the post-treatment process, and the excellent anti-radiation effect of the silicon carbide nano powder can be effectively realizedThe silicon carbide nano powder can be prevented from directly contacting with air at high temperature, the growth and oxidation of silicon carbide nano powder crystals in the nano fibers can be effectively inhibited, the thermal stability of the aerogel material is improved, and the high-temperature thermal conductivity coefficient of the aerogel material is reduced; the invention discovers that the tetraethoxysilane and the water are in a phase-splitting state before hydrolysis, and the addition of the silicon carbide nano powder can cause adsorption, thus influencing the hydrolysis effect and the dispersion effect of the silicon carbide nano powder; after the tetraethoxysilane is completely hydrolyzed, the silicon carbide nano powder is added to be dispersed more uniformly, and homogeneous composite hydrolysate can be formed; the invention discovers that if the Tetraethoxysilane (TEOS) and the phosphoric acid (H) are directly mixed₃PO₄) Mixing and hydrolyzing the silicon carbide nano powder and water or directly mixing and stirring a polyvinyl alcohol aqueous solution, the silicon carbide nano powder and a hydrolysate which does not contain the silicon carbide nano powder by using water in the subsequent step (2) to obtain a precursor solution, wherein the two modes can not realize uniform dispersion of the silicon carbide nano powder, and finally, the silicon carbide nano powder can only be partially embedded in the nano fibers, and the silicon carbide nano powder has the phenomenon of obvious uneven distribution, so that the problem that the silicon carbide nano powder is easy to lose efficacy in the subsequent heat treatment process and the subsequent treatment process is easily caused; in addition, the invention discovers that the dispersing mode of the silicon carbide nano powder in the invention is directly compared with the dispersing mode of Tetraethoxysilane (TEOS) and phosphoric acid (H)₃PO₄) The silicon carbide nano powder and water are mixed and hydrolyzed or directly in the subsequent step (2), the compression resilience of the ultra-light high-elasticity radiation-resistant nanofiber aerogel material can be obviously improved by a dispersion mode of mixing and stirring the polyvinyl alcohol aqueous solution, the silicon carbide nano powder and the hydrolysate without the silicon carbide nano powder by water.

(2) Uniformly mixing a polyvinyl alcohol aqueous solution with the composite hydrolysate obtained in the step (1) by using water, stirring for 1-12h (for example, 1, 2, 4, 5, 6, 8, 10 or 12h) to obtain a precursor solution, and then performing electrostatic spinning by using the precursor solution as an electrostatic spinning solution to obtain a hybrid nanofiber membrane (also called as PVA/SiO)₂a/SiC hybrid nanofiber membrane); in the present invention, the polyvinyl alcohol aqueous solution (PVA aqueous solution) may be prepared, for example, by: weighing a certain massAdding the polyvinyl alcohol powder into deionized water, stirring for 1-12h, and heating and dissolving at 60-120 ℃; taking out after stirring, placing on a magnetic stirrer, stirring at room temperature, and cooling to room temperature; the mass fraction of the prepared PVA aqueous solution is 1-20 wt%; specifically, the step (2) is as follows: and (3) mixing TEOS composite hydrolysate, PVA aqueous solution and deionized water according to the ratio of (1-5): (1-5): (0.5-5), placing the mixture on a magnetic stirrer at room temperature, and stirring for 1-12 hours to obtain a uniform and clear precursor solution; then extracting the precursor solution by using an injector, and preparing PVA/SiO by using an electrostatic spinning machine₂a/SiC hybrid nanofiber membrane; the invention discovers that compared with a mode of directly mixing tetraethoxysilane and polymer and then hydrolyzing, the mode of preparing TEOS composite hydrolysate and polyvinyl alcohol aqueous solution into precursor solution by using water can obviously improve the high-temperature heat-insulating property of the nano-fiber aerogel material; the invention discovers that if TEOS, silicon carbide nano powder and polyvinyl alcohol are directly mixed and hydrolyzed, on one hand, the polyvinyl alcohol can be dissolved more uniformly under the heating condition, the hydrolysis speed is accelerated due to the heating condition, partial condensation reaction is generated, single particles of silica sol grow up, the small particle homogeneous dispersion system is not favorably formed, the effect of the hydrolyzed TEOS is obviously influenced, and finally the high-temperature heat-insulating property of the prepared aerogel material is also obviously influenced, on the other hand, the adsorption effect is also caused when the silicon carbide nano powder is added before the hydrolysis of tetraethoxysilane, the hydrolysis effect and the dispersion effect of the silicon carbide nano powder are influenced, and the high-temperature heat-insulating property and compression resilience of the prepared aerogel material are also obviously influenced.

(3) Carrying out heat treatment on the hybrid nanofiber membrane obtained in the step (2) in an inert atmosphere (for example, nitrogen, argon or a mixed atmosphere of nitrogen and argon); the heat treatment comprises the following steps: heat-treating at 300-600 deg.C (e.g. 300 deg.C, 350 deg.C, 400 deg.C, 450 deg.C, 500 deg.C, 550 deg.C or 600 deg.C) for 1-10 h (e.g. 1, 2, 3, 4, 5, 6, 7, 8, 9 or 10h), then heat-treating at 600-900 deg.C (e.g. 600 deg.C, 650 deg.C, 700 deg.C, 750 deg.C, 800 deg.C, 850 deg.C or 900 deg.C) for 1-5 h (e.g. 1, 2, 3, 4 or 5h), and naturally cooling to room temperature; in some specific embodiments, step (3) is: placing the hybrid nanofiber membrane obtained in the step (2) in an inert atmosphere furnace, setting the heating rate to be 3-6 ℃/min and preferably 5 ℃/min, firstly heating to 500 ℃ for heat treatment for 2h, then heating to 800 ℃ for heat treatment for 3h, and then naturally cooling to room temperature; the invention discovers that the heat treatment process in the step (3) is crucial in order to obtain the ultra-light high-elasticity radiation-resistant nanofiber aerogel material with high elasticity (high compression resilience), and if the heat treatment process is not carried out or the calcination is carried out only at 300-600 ℃, the temperature resistance and the high-temperature resilience characteristic of the material can be obviously reduced.

(4) Adding the hybrid nanofiber membrane subjected to heat treatment in the step (3), ethyl orthosilicate, boric acid and aluminum chloride into water to obtain a to-be-dispersed solution, and then stirring the to-be-dispersed solution at a high speed to obtain a homogeneous phase dispersed solution; in some specific embodiments, the hybrid nanofiber membrane subjected to the heat treatment in the step (3), ethyl orthosilicate, boric acid and aluminum chloride are added into water to obtain a to-be-dispersed solution, and a high-speed shearing machine is adopted to stir at a high speed of 5000-20000 r/min, preferably 10000r/min, for 5-30 min, preferably 20min, so as to obtain a homogeneous dispersion solution; the invention discovers that the addition of the ethyl orthosilicate and the aluminum chloride can form a silicon-aluminum compound at the node of the nano-fiber, and the addition of the boric acid can bond the fibers by forming boron oxide at high temperature to form continuous boron oxide phase, so that the nodes between the nano-fibers are ensured to be firm; the invention discovers that the ultra-light high-elasticity anti-radiation nanofiber aerogel material with high elasticity, room-temperature heat conductivity coefficient and lower high-temperature heat conductivity coefficient can be prepared only by adding tetraethoxysilane, boric acid and aluminum chloride.

(5) Sequentially freezing and freeze-drying the homogeneous dispersion liquid obtained in the step (4) to obtain a nanofiber aerogel material; the invention discovers that the ultra-light high-elasticity radiation-resistant nanofiber aerogel material with excellent comprehensive performance can be obtained only by sequentially freezing and freeze-drying, and if the obtained homogeneous phase dispersion liquid is subjected to freezing and normal-pressure drying, the density, the room-temperature thermal conductivity and the high-temperature thermal conductivity of the material can be increased, and the material does not have compression resilience.

(6) Carrying out post-treatment (cracking) on the nanofiber aerogel material obtained in the step (5) in an inert atmosphere to prepare an ultra-light high-elasticity anti-radiation nanofiber aerogel material; the invention discovers that after the nanofiber aerogel material obtained in the step (5) is subjected to post-treatment in an inert atmosphere, the compression resilience and the high-temperature heat-insulating property of the finally prepared ultra-light high-elasticity radiation-resistant nanofiber aerogel material can be effectively ensured, and the high-temperature heat conductivity coefficient of the material is obviously reduced.

The method of the invention carries out doping of the anti-radiation agent in the composite hydrolysate, and realizes in-situ doping of the anti-radiation agent after the heat treatment process, so that the anti-radiation agent can be embedded in the interior of the nanofiber in situ and can be dispersed uniformly, agglomeration among particles is avoided, and the anti-radiation agent can be ensured not to lose efficacy in the heat treatment process and the post-treatment process; the components and the structure of the composite nanofiber are specially designed for high-elasticity radiation-resistant heat-insulating performance, and the ultra-light high-elasticity radiation-resistant nanofiber aerogel material prepared by the method has high elasticity and excellent radiation-resistant performance, temperature-resistant performance and high-temperature heat-insulating performance.

The invention adopts an electrostatic spinning method to prepare the pearl beaded nanofiber material with the nanometer skeleton, and prepares the three-dimensional nanofiber aerogel material with the anti-radiation effect through an assembly process. Due to the coating effect of the nano-fibers, the nano-silicon carbide inside is not directly contacted with oxygen, so that the oxidation resistance and high-temperature heat insulation performance of the material are improved, and the preparation of the nano-fiber aerogel material with the characteristics of high temperature resistance, high-temperature heat insulation performance, radiation resistance and high elasticity is realized.

According to some preferred embodiments, in step (1): the molar ratio of the ethyl orthosilicate to the phosphoric acid to the water is (0.5-1): (0.005-0.05): (1 to 20), preferably 1: (0.015 to 0.025): (8-15), more preferably 1:0.02: 10; and/or the silicon carbide nanopowder is used in an amount of 0.4-10% (e.g., 0.4%, 0.8%, 1%, 1.5%, 2%, 5%, 8%, or 10%) by mass of the hydrolysate, preferably 0.8-2.5% (e.g., 0.8%, 1%, 1.2%, 1.4%, 1.6%, 1.8%, 2%, or 2.5%); in the invention, preferably, the amount of the silicon carbide nano powder is 0.4-10% of the mass of the hydrolysate, and more preferably 0.8-2.5%, and the invention finds that if the amount of the silicon carbide nano powder is too small, the radiation resistance of the material is insufficient, and if the amount of the silicon carbide nano powder is too large, the silicon carbide nano powder is not easy to disperse, the silicon carbide nano powder is seriously agglomerated, and excessive silicon carbide nano powder causes the fibers formed in the electrostatic spinning process to be discontinuous, so that the compression resilience and the overall strength of the prepared ultralight high-elasticity radiation-resistant nanofiber aerogel material are obviously reduced.

According to some preferred embodiments, in step (2): the mass fraction of polyvinyl alcohol contained in the polyvinyl alcohol aqueous solution is 1-20% (for example, 1, 5, 8, 10, 12, 15, 18 or 20%), and preferably 8-12% (for example, 8%, 9%, 10%, 11% or 12%); the mass ratio of the composite hydrolysate to the polyvinyl alcohol aqueous solution to the water is (1-5): (1-5): (0.5 to 5), preferably (2.5 to 3.5): (2.5-3.5): 2, more preferably 3:3: 2; in the invention, firstly, the polyvinyl alcohol can adjust the viscosity of the spinning solution, the fiber diameter in the spinning process is greatly influenced, and the fiber diameter determines the thermal conductivity of the nano-fiber aerogel material; and secondly, the polyvinyl alcohol is decomposed in the subsequent heat treatment process, the diameter of the obtained fiber is smaller when the content of the polyvinyl alcohol is higher, and the discontinuity of inorganic components of the fiber in the heat treatment process is caused by the overhigh content of the polyvinyl alcohol, so that the diameter of the fiber of the nanofiber aerogel material is as small as possible under the condition that the fiber diameter of the nanofiber aerogel material is kept continuous by proper mass ratio of the composite hydrolysate, the polyvinyl alcohol aqueous solution and the water, and the heat insulation performance of the finally prepared aerogel material is favorably ensured.

According to some preferred embodiments, in step (2): the stirring time is 3-6 h (for example, 3, 4, 5 or 6 h).

According to some preferred embodiments, the parameters for electrospinning are as follows: the voltage is 5-40 kV, preferably 10-30 kV, the perfusion speed is 0.5-2 mL/h, the receiving distance is 10-25 cm, and/or the temperature in the spinning room (namely the ambient temperature) is 15-35 ℃; in the present invention, the perfusion speed refers to the flow rate of the electrospinning liquid.

According to some preferred embodiments, in step (2), the obtained hybrid nanofiber membrane is also subjected to vacuum drying; preferably, the obtained hybrid nanofiber membrane is dried in a vacuum drying oven at 60-120 ℃ for 1-3 h in vacuum, so as to remove water and residual solvent in the hybrid nanofiber membrane.

According to some preferred embodiments, in step (4): the mass fraction of the hybrid nanofiber membrane contained in the liquid to be dispersed is 0.4-0.6%, the mass fraction of ethyl orthosilicate contained in the liquid to be dispersed is 0.4-0.6%, the mass fraction of boric acid contained in the liquid to be dispersed is 0.05-0.2%, and the mass fraction of aluminum chloride contained in the liquid to be dispersed is 0.1-0.3%; in some preferred embodiments, the mass fraction of the hybrid nanofiber membrane contained in the liquid to be dispersed is 0.53%, the mass fraction of the tetraethoxysilane contained in the liquid to be dispersed is 0.5%, the mass fraction of the boric acid contained in the liquid to be dispersed is 0.1%, and the mass fraction of the aluminum chloride contained in the liquid to be dispersed is 0.15%.

According to some preferred embodiments, in step (4): the high-speed stirring speed is 5000-20000 r/min (such as 5000, 10000, 15000 or 20000r/min), and the high-speed stirring time is 5-30 min (such as 5, 10, 15, 20, 25 or 30 min); in some preferred embodiments, the rotation speed of the high-speed stirring is 10000r/min, and the time of the high-speed stirring is 20 min.

According to some preferred embodiments, in step (5): the freezing is performed under liquid nitrogen for 10-60 min (for example, 10, 20, 30, 40, 50 or 60min), preferably 10-30 min; the freezing is carried out in a mould, the top and the side surfaces of the mould are made of materials with lower heat conductivity, the bottom of the mould is made of materials with higher heat conductivity, preferably, the top and the side surfaces of the mould are made of polytetrafluoroethylene, and the bottom of the mould is made of copper materials; and/or the freeze-drying is vacuum freeze-drying, preferably, the vacuum freeze-drying is carried out for 2-5 d (for example, 2, 3, 4 or 5 days) under the conditions that the vacuum degree is 0.5-10 Pa and the temperature is-50 to-70 ℃.

According to some preferred embodiments, in step (6): the temperature of the post-treatment is 800-1000 ℃ (such as 800, 850, 900, 950 or 1000 ℃), and the time of the post-treatment is 0.1-12h, preferably 3-8 h (such as 3, 4, 5, 6, 7 or 8 h).

According to some preferred embodiments, step (4) is: adding the hybrid nanofiber membrane subjected to heat treatment in the step (3), ethyl orthosilicate, boric acid and aluminum chloride into water to obtain a to-be-dispersed solution, and then adding a graphene oxide solution into the to-be-dispersed solution and stirring at a high speed to obtain a homogeneous phase dispersed solution; in the invention, preferably, in the step (4), a graphene oxide solution is further added before the to-be-dispersed solution is stirred at a high speed, the amount of the graphene oxide solution is 0.5-2% of the mass of the to-be-dispersed solution, the graphene oxide solution is a graphene oxide aqueous solution, and the concentration of the graphene oxide solution is 15-25 g/L; the invention discovers that the addition of the graphene oxide solution with proper dosage can improve the flexibility of the nano-fiber, the graphene sheet layer is used as a toughening agent to improve the flexibility of the nano-fiber, the compression resilience of the nano-fiber aerogel material is improved to a certain extent, the radiation resistance of the nano-fiber aerogel material is improved at the same time, and the heat insulation performance of the finally prepared ultra-light high-elasticity radiation-resistant nano-fiber aerogel material at high temperature is improved; the invention discovers that the addition of the graphene oxide solution with proper content can further improve the compression resilience of the ultralight high-elasticity radiation-resistant nanofiber aerogel material, and if the mass fraction of the graphene oxide contained in the homogeneous dispersion liquid is too small, the effect of improving the compression resilience of the ultralight high-elasticity radiation-resistant nanofiber aerogel material is not obvious; if the mass fraction of the graphene oxide contained in the homogeneous dispersion liquid is too high, the temperature resistance of the material is adversely affected.

According to some preferred embodiments, the ultra-lightweight high-elasticity radioresistant nano-meterThe density of the rice fiber aerogel material is not more than 0.05g/cm³The compression rebound rate is not less than 80%, the linear shrinkage rate at 1100 ℃ is not more than 1%, the thermal conductivity at room temperature is not more than 0.031W/m.K, and the thermal conductivity at 800 ℃ is not more than 0.065W/m.K.

According to some specific embodiments, the preparation of the ultralight high-elasticity radiation-resistant nanofiber aerogel material comprises the following steps:

preparation of hybrid nanofiber membranes

Preparing TEOS composite hydrolysate: at room temperature, taking TEOS and H with certain mass₃PO₄And deionized water as per n (teos): n (H)₃PO₄)：n(H₂O) ═ 0.5 to 1: (0.005-0.05): (1-20), and placing the mixture on a magnetic stirrer to stir for 1-24 hours to obtain a hydrolysate; and then adding silicon carbide nano powder into the hydrolysate to ensure that the silicon carbide nano powder accounts for 0.4-10% of the mass of the hydrolysate, stirring for 1-12h, and performing ultrasonic treatment for 0.5-2 h to uniformly disperse the silicon carbide nano powder in the hydrolysate to obtain the TEOS composite hydrolysate.

Preparation of aqueous PVA solution: weighing a certain mass of polyvinyl alcohol powder, adding the polyvinyl alcohol powder into deionized water, heating and dissolving at 60-120 ℃, and stirring for 1-12 hours; taking out after stirring, placing on a magnetic stirrer, stirring at room temperature, and cooling to room temperature; the mass fraction of the prepared PVA aqueous solution is 1-20 wt%.

Preparation of precursor solution for electrospinning: and (3) mixing TEOS composite hydrolysate, PVA aqueous solution and deionized water according to the ratio of (1-5): (1-5): (0.5-5), placing the mixture on a magnetic stirrer at room temperature, and stirring for 1-12 hours to obtain a uniform and clear precursor solution.

Extracting the precursor solution by an injector to be used as electrostatic spinning solution, and preparing PVA/SiO by using an electrostatic spinning machine₂a/SiC hybrid nanofiber membrane. The electrostatic spinning process parameters comprise voltage of 5-40 kV, perfusion speed of 0.5-2 mL/h, receiving distance of 10-25 cm and temperature in a spinning chamber of 25 +/-10 ℃. After the test is finished, collecting the hybrid nanofiber membrane (PVA/SiO)₂/SiC hybridized nano fiber membrane) at 60-120 ℃ in a vacuum drying ovenAnd drying for 2h to remove the water and residual solvent in the hybrid nanofiber membrane.

② heat treatment process

PVA/SiO prepared by electrostatic spinning₂Putting the/SiC hybridized nanofiber membrane into an atmosphere furnace, wherein the protective gas can be nitrogen, argon or argon-hydrogen mixed gas, the heating rate is set to be 3-6 ℃/min, the temperature is increased to 300-600 ℃, the temperature is kept for 1-10 h, then the temperature is increased to 600-900 ℃, the temperature is kept for 1-5 h, and then the temperature is naturally cooled to the room temperature; the room temperature in the invention is the environment temperature for carrying out the invention, and can be, for example, 15-35 ℃.

And thirdly, in the homogeneous dispersion process, adding the hybrid nanofiber membrane subjected to the heat treatment in the second step, ethyl orthosilicate, boric acid and aluminum chloride into water to obtain a to-be-dispersed solution, and then stirring the to-be-dispersed solution for 5-30 min by adopting a high-speed shearing machine under the condition that the rotating speed is 5000-20000 r/min to obtain the homogeneous dispersion solution.

Fourthly, freezing process: adding the homogeneous dispersion liquid into a mold with a fixed shape, wherein the top and the side of the mold are made of a material (polytetrafluoroethylene) with low thermal conductivity, the bottom of the mold is made of a copper sheet with good thermal conductivity (high thermal conductivity), and the sealed mold is placed in liquid nitrogen for 10-60 min of freezing.

A freeze drying process: and after the homogeneous dispersion liquid is completely frozen and molded, transferring the homogeneous dispersion liquid to a freeze dryer for vacuum freeze drying, wherein the freeze drying temperature is-50 to-70 ℃, the freeze drying time is 2 to 5 days, and the vacuum degree of freeze drying is 0.5 to 10Pa, so that the nanofiber aerogel material is prepared.

Sixthly, post-treatment process: and (4) carrying out post-treatment (cracking) on the nanofiber aerogel material prepared in the fifth step in a protective atmosphere (in a nitrogen, argon or argon-hydrogen mixed gas), carrying out post-treatment at 900 ℃ for 0.1-12h, and stabilizing the lap joint between the nanofibers to prepare the ultra-light high-elasticity radiation-resistant nanofiber aerogel material.

The invention will be further illustrated by way of example, but the scope of protection is not limited to these examples.

Example 1

Preparation of hybrid nanofiber membranes

Preparing TEOS composite hydrolysate: at room temperature, TEOS (tetraethyl orthosilicate) and H are taken₃PO₄(phosphoric acid) and deionized water as per n (teos): n (H)₃PO₄)：n(H₂Mixing O) in a molar ratio of 1:0.02:10, and stirring for 12 hours on a magnetic stirrer to obtain hydrolysate; and then adding silicon carbide nano powder into the hydrolysate to ensure that the silicon carbide nano powder accounts for 2% of the mass of the hydrolysate, stirring for 6 hours, and performing ultrasonic treatment for 1 hour to uniformly disperse the silicon carbide nano powder in the hydrolysate to obtain the TEOS composite hydrolysate.

Preparation of aqueous PVA solution: weighing polyvinyl alcohol powder, adding the polyvinyl alcohol powder into deionized water, heating and dissolving at 80 ℃, and stirring for 5 hours; taking out after stirring, placing on a magnetic stirrer, stirring at room temperature, and cooling to room temperature; the mass fraction of the prepared PVA aqueous solution is 10 wt%.

Preparation of precursor solution for electrospinning: mixing TEOS composite hydrolysate, PVA aqueous solution and deionized water according to the mass ratio of 3:3:2, placing the mixture on a magnetic stirrer at room temperature, and stirring the mixture for 4 hours to obtain uniform and clear precursor solution.

Extracting the precursor solution by an injector to be used as electrostatic spinning solution, and preparing PVA/SiO by using an electrostatic spinning machine₂a/SiC hybrid nanofiber membrane. The technological parameters of electrostatic spinning are that the voltage is 20kV, the perfusion speed is 1.5mL/h, the receiving distance is 15cm, and the temperature in the spinning chamber is 25 ℃. After the test is finished, collecting the hybrid nanofiber membrane (PVA/SiO)₂the/SiC hybridized nano fiber membrane) is dried in a vacuum drying oven at 80 ℃ for 2h to remove the water and residual solvent in the hybridized nano fiber membrane.

② heat treatment process

PVA/SiO prepared by electrostatic spinning₂Putting the/SiC hybridized nano-fiber membrane into an atmosphere furnace, setting the heating rate to be 5 ℃/min by taking nitrogen as inert protective gas, firstly heating to 500 ℃ for heat treatment for 2h, and then heating to 800 DEG CHeat-treating for 3h, and naturally cooling to room temperature.

③ homogeneous dispersion process

Adding the hybrid nanofiber membrane subjected to the heat treatment in the step two, ethyl orthosilicate, boric acid and aluminum chloride into water (deionized water) to obtain a to-be-dispersed solution, and then stirring the to-be-dispersed solution for 20min at a rotating speed of 10000r/min by using a high-speed shearing machine to obtain a homogeneous dispersed solution; the mass fraction of the hybrid nanofiber membrane contained in the liquid to be dispersed is 0.53%, the mass fraction of the tetraethoxysilane contained in the liquid to be dispersed is 0.5%, the mass fraction of the boric acid contained in the liquid to be dispersed is 0.1%, the mass fraction of the aluminum chloride contained in the liquid to be dispersed is 0.15%, and the mass fraction of the water contained in the liquid to be dispersed is 98.72%.

Fourthly, freezing process: adding the homogeneous dispersion liquid into a mold with a fixed shape, wherein the top and the side of the mold are made of a material (polytetrafluoroethylene) with lower thermal conductivity, the bottom of the mold is made of a copper sheet with good thermal conductivity (higher thermal conductivity), and the sealed mold is placed in liquid nitrogen for 20min of freezing process.

A freeze drying process: and after the homogeneous dispersion liquid is completely frozen and molded, transferring the homogeneous dispersion liquid into a freeze dryer for vacuum freeze drying, wherein the freeze drying temperature is-70 ℃, the freeze drying time is 3d, and the vacuum degree of freeze drying is 5 Pa.

Sixthly, post-treatment process: and (4) carrying out post-treatment (pyrolysis) on the nanofiber aerogel material prepared in the fifth step for 5 hours at the temperature of 900 ℃ in an inert protective atmosphere (nitrogen), and stabilizing the lap joint between the nanofibers to prepare the ultra-light high-elasticity radiation-resistant nanofiber aerogel material.

The performance test of the ultralight high-elasticity radiation-resistant nanofiber aerogel material in example 1 is carried out, and the results are shown in table 1.

The density of the ultralight high-elasticity radiation-resistant nanofiber aerogel material prepared in example 1 is 0.05g/cm³The porosity is 95%, the average nanofiber diameter is 200nm, the compression resilience is 80%, the linear shrinkage at 1100 ℃ is 0.5%, the room-temperature thermal conductivity is 0.030W/m.K, and the 800 ℃ thermal conductivity is 0.055W/m·K。

After the ultra-light high-elasticity radiation-resistant nanofiber aerogel material prepared by the embodiment is used at 1100 ℃ for 1200s, the linear shrinkage rate is only 0.5%, which shows that the material can resist the temperature of more than 1100 ℃. In particular, the linear shrinkage at 1100 ℃ in Table 1 of the present invention is the linear shrinkage results of the materials prepared in the examples and comparative examples after being used at 1100 ℃ for 1200 s; the higher the linear shrinkage of the material at 1100 ℃, the poorer the effect of the material on 1100 ℃ resistance.

Example 2

Example 2 is essentially the same as example 1, except that:

in the step I, the preparation of the TEOS composite hydrolysate comprises the following steps: at room temperature, take TEOS, H₃PO₄And deionized water as per n (teos): n (H)₃PO₄)：n(H₂Mixing O) in a molar ratio of 1:0.02:10, and stirring for 12 hours on a magnetic stirrer to obtain hydrolysate; and then adding silicon carbide nano powder into the hydrolysate to ensure that the silicon carbide nano powder accounts for 1% of the mass of the hydrolysate, stirring for 6 hours, and performing ultrasonic treatment for 1 hour to uniformly disperse the silicon carbide nano powder in the hydrolysate to obtain the TEOS composite hydrolysate.

The performance test of the ultralight high-elasticity radiation-resistant nanofiber aerogel material in example 2 is carried out, and the results are shown in table 1.

Example 3

Example 3 is essentially the same as example 1, except that:

in the step (I), the preparation of the TEOS hydrolysate comprises the following steps: at room temperature, take TEOS, H₃PO₄And deionized water as per n (teos): n (H)₃PO₄)：n(H₂Mixing O) in a molar ratio of 1:0.02:10, and continuously stirring for 12 hours on a magnetic stirrer to obtain TEOS hydrolysate; in the subsequent steps, TEOS hydrolysate is used to replace the TEOS composite hydrolysate in example 1 for experiment.

The material obtained in example 3 was subjected to the performance test, and the results are shown in table 1.

Example 4

Example 4 is essentially the same as example 1, except that:

PVA/SiO produced without electrostatic spinning₂the/SiC hybrid nanofiber membrane was subjected to a heat treatment process, and directly to the same homodisperse process, freezing process, freeze-drying process and post-treatment process as in example 1.

The material obtained in example 4 was subjected to the performance test, and the results are shown in table 1.

Example 5

Example 5 is essentially the same as example 1, except that:

in the third step, the liquid to be dispersed is stirred for 20min by a high-speed shearing machine under the condition that the rotating speed is 1000r/min, and homogeneous dispersion liquid is obtained.

The material obtained in this example was subjected to a performance test, and the results are shown in table 1.

Example 6

Example 6 is essentially the same as example 1, except that:

the homogeneous dispersion process of the third step is as follows: adding the hybrid nanofiber membrane subjected to the heat treatment in the second step into water to obtain a to-be-dispersed solution, and then stirring the to-be-dispersed solution for 20min by adopting a high-speed shearing machine under the condition that the rotating speed is 10000r/min to obtain a homogeneous dispersion solution; the mass fraction of the hybrid nanofiber membrane contained in the liquid to be dispersed is 0.53%, and the mass fraction of the water contained in the liquid to be dispersed is 99.47%.

Example 7

Example 7 is essentially the same as example 1, except that:

the fifth step is a normal pressure drying process: and after the homogeneous dispersion liquid is completely frozen and molded, transferring the homogeneous dispersion liquid to dry for 144 hours at normal temperature and normal pressure.

The material prepared in this example was subjected to a performance test, the results of which are shown in table 1; the material produced in this example had substantially no rebound resilience, and the compression rebound resilience was considered to be 0.

Example 8

Example 8 is essentially the same as example 1, except that:

this example does not include the post-treatment process of step (c).

Example 9

Example 9 is essentially the same as example 1, except that:

in the step I, the preparation of the TEOS composite hydrolysate: at room temperature, take TEOS, H₃PO₄And deionized water as per n (teos): n (H)₃PO₄)：n(H₂Mixing O) in a molar ratio of 1:0.02:10 to obtain a mixed solution; and then adding silicon carbide nano powder accounting for 2% of the mixed solution by mass into the mixed solution, and placing the mixed solution on a magnetic stirrer to continuously stir for 18 hours to obtain TEOS composite hydrolysate.

Example 10

Example 10 is essentially the same as example 1, except that:

in the step (I), preparing TEOS hydrolysate: at room temperature, take TEOS, H₃PO₄And deionized water as per n (teos): n (H)₃PO₄)：n(H₂Mixing O) in a molar ratio of 1:0.02:10, and continuously stirring for 12 hours on a magnetic stirrer to obtain TEOS hydrolysate; in this example, the TEOS hydrolysate was used instead of the TEOS composite hydrolysate in example 1 for subsequent experiments.

The preparation of the precursor solution for electrospinning was: mixing TEOS hydrolysate, PVA aqueous solution and deionized water according to the mass ratio of 3:3:2 to obtain mixed solution; then adding silicon carbide nano powder accounting for 5% of the mixed solution by mass into the mixed solution, and then placing the mixed solution on a magnetic stirrer at room temperature to stir for 4 hours to obtain a uniform and clear precursor solution.

Example 11

Example 11 is essentially the same as example 1, except that:

in the step I, the preparation of the TEOS composite hydrolysate comprises the following steps: at room temperature, take TEOS, H₃PO₄And deionized water as per n (teos): n (H)₃PO₄)：n(H₂Mixing O) in a molar ratio of 1:0.02:10, and stirring for 12 hours on a magnetic stirrer to obtain hydrolysate; and then adding silicon carbide nano powder into the hydrolysate to ensure that the silicon carbide nano powder accounts for 4% of the mass of the hydrolysate, stirring for 6h, and performing ultrasonic treatment for 1h to uniformly disperse the silicon carbide nano powder in the hydrolysate to obtain the TEOS composite hydrolysate.

Example 12

Example 12 is essentially the same as example 1, except that:

the heat treatment process of the second step is as follows: PVA/SiO prepared by electrostatic spinning₂Putting the/SiC hybridized nano fiber membrane into an atmosphere furnace, setting the heating rate to be 5 ℃/min by taking the inert protective gas as nitrogen, heating to 500 ℃ for heat treatment for 5h, and then naturally cooling to room temperature.

Example 13

Example 13 is essentially the same as example 1, except that:

the homogeneous dispersion process of the third step is as follows: adding the hybrid nanofiber membrane subjected to the heat treatment in the step two, ethyl orthosilicate, boric acid and aluminum chloride into water to obtain a to-be-dispersed solution, then adding a graphene oxide solution into the to-be-dispersed solution, and stirring at a high speed for 20min by using a high-speed shearing machine under the condition that the rotating speed is 10000r/min to obtain a homogeneous dispersion solution; the graphene oxide solution is a graphene oxide aqueous solution with the concentration of 20 g/L; the adding amount of the graphene oxide solution is 1% of the mass of the to-be-dispersed solution; the mass fraction of the hybrid nanofiber membrane contained in the liquid to be dispersed is 0.53%, the mass fraction of the tetraethoxysilane contained in the liquid to be dispersed is 0.5%, the mass fraction of the boric acid contained in the liquid to be dispersed is 0.1%, the mass fraction of the aluminum chloride contained in the liquid to be dispersed is 0.15%, and the mass fraction of the water contained in the liquid to be dispersed is 98.72%.

Example 14

Example 14 is essentially the same as example 13, except that:

the homogeneous dispersion process of the third step is as follows: adding the hybrid nanofiber membrane subjected to the heat treatment in the step two, ethyl orthosilicate, boric acid and aluminum chloride into water to obtain a to-be-dispersed solution, then adding a graphene oxide solution into the to-be-dispersed solution, and stirring at a high speed for 20min by using a high-speed shearing machine under the condition that the rotating speed is 10000r/min to obtain a homogeneous dispersion solution; the graphene oxide solution is a graphene oxide aqueous solution with the concentration of 20 g/L; the addition amount of the graphene oxide solution is 4% of the mass of the to-be-dispersed solution; the mass fraction of the hybrid nanofiber membrane contained in the liquid to be dispersed is 0.53%, the mass fraction of the tetraethoxysilane contained in the liquid to be dispersed is 0.5%, the mass fraction of the boric acid contained in the liquid to be dispersed is 0.1%, the mass fraction of the aluminum chloride contained in the liquid to be dispersed is 0.15%, and the mass fraction of the water contained in the liquid to be dispersed is 98.72%.

Comparative example 1

Preparing a nanofiber membrane: heating, stirring and dissolving polyvinyl alcohol and tetraethoxysilane in deionized water at 80 ℃ to obtain a precursor solution; the molar ratio of the ethyl orthosilicate to the water is 1: 20; the mass fraction of polyvinyl alcohol contained in the precursor solution is 10%. And extracting the precursor solution by using an injector to obtain an electrostatic spinning solution, and preparing the nanofiber membrane by using an electrostatic spinning machine. The technological parameters of electrostatic spinning are that the voltage is 20kV, the perfusion speed is 1.5mL/h, the receiving distance is 15cm, and the temperature in the spinning chamber is 25 ℃. And after the test is finished, collecting the nanofiber membrane, and drying the nanofiber membrane in a vacuum drying oven at 80 ℃ for 2h to remove water and residual solvent in the nanofiber membrane.

② heat treatment process

And (3) putting the nanofiber membrane prepared by electrostatic spinning into a muffle furnace, setting the heating rate to be 5 ℃/min, raising the temperature to 500 ℃, carrying out heat treatment for 5h, and then naturally cooling to room temperature.

③ homogeneous dispersion process

Collecting the nanofiber membrane subjected to heat treatment in the step three, adding the nanofiber membrane into deionized water to obtain a to-be-dispersed solution, and stirring the to-be-dispersed solution for 20min by adopting a high-speed shearing machine under the condition that the rotating speed is 10000r/min to obtain a homogeneous dispersion solution; the mass fraction of the nanofiber membrane contained in the liquid to be dispersed was 0.53%.

Sixthly, post-treatment process: and (4) carrying out post-treatment (cracking) on the material obtained in the step (sixthly) for 5 hours at the temperature of 900 ℃ in an inert protective atmosphere (nitrogen).

The material obtained in this comparative example was subjected to a performance test, and the results are shown in Table 1.

Comparative example 2

Comparative example 2 is substantially the same as comparative example 1 except that:

in the first step, polyvinyl alcohol, tetraethoxysilane and silicon carbide nano powder are heated and stirred at 80 ℃ and uniformly dispersed in deionized water to obtain a precursor solution in which the polyvinyl alcohol and the silicon carbide nano powder are dissolved; the molar ratio of the ethyl orthosilicate to the water is 1: 20; the mass fraction of polyvinyl alcohol contained in the precursor solution is 10%; the mass fraction of the silicon carbide nano powder contained in the precursor solution is 2%. And extracting the precursor solution by using an injector to obtain an electrostatic spinning solution, and preparing the nanofiber membrane by using an electrostatic spinning machine. The technological parameters of electrostatic spinning are that the voltage is 20kV, the perfusion speed is 1.5mL/h, the receiving distance is 15cm, and the temperature in the spinning chamber is 25 ℃. And after the test is finished, collecting the nanofiber membrane, and drying the nanofiber membrane in a vacuum drying oven at 80 ℃ for 2h to remove water and residual solvent in the nanofiber membrane.

In particular, the symbol "-" in Table 1 indicates that the performance index was not tested.

The invention has not been described in detail and is in part known to those of skill in the art.

Finally, it should be noted that: the above examples are only intended to illustrate the technical solution of the present invention, but not to limit it; although the present invention has been described in detail with reference to the foregoing embodiments, it will be understood by those of ordinary skill in the art that: the technical solutions described in the foregoing embodiments may still be modified, or some technical features may be equivalently replaced; and such modifications or substitutions do not depart from the spirit and scope of the corresponding technical solutions of the embodiments of the present invention.

Claims

1. A preparation method of an ultralight high-elasticity radiation-resistant nanofiber aerogel material is characterized by comprising the following steps:

2. The production method according to claim 1, wherein in step (1):

the molar ratio of the ethyl orthosilicate to the phosphoric acid to the water is (0.5-1): (0.005-0.05): (1 to 20), preferably 1: (0.015 to 0.025): (8-15), more preferably 1:0.02: 10; and/or

The amount of the silicon carbide nano powder is 0.4-10% of the mass of the hydrolysate, and preferably 0.8-2.5%.

3. The production method according to claim 1, wherein in step (2):

the mass fraction of polyvinyl alcohol contained in the polyvinyl alcohol aqueous solution is 1-20%;

the mass ratio of the composite hydrolysate to the polyvinyl alcohol aqueous solution to the water is (1-5): (1-5): (0.5 to 5), preferably (2.5 to 3.5): (2.5-3.5): 2, more preferably 3:3: 2; and/or

The stirring time is 3-6 h.

4. The method of claim 1, wherein the electrospinning is carried out with the following parameters:

the voltage is 5-40 kV, the perfusion speed is 0.5-2 mL/h, the receiving distance is 10-25 cm, and/or the temperature in the spinning room is 15-35 ℃.

5. The method of claim 1, wherein:

in the step (2), the obtained hybrid nanofiber membrane is also subjected to vacuum drying; preferably, the obtained hybrid nanofiber membrane is dried in a vacuum drying oven at 60-120 ℃ for 1-3 h.

6. The production method according to claim 1, wherein in step (4):

the mass fraction of the hybrid nanofiber membrane contained in the liquid to be dispersed is 0.4-0.6%, the mass fraction of ethyl orthosilicate contained in the liquid to be dispersed is 0.4-0.6%, the mass fraction of boric acid contained in the liquid to be dispersed is 0.05-0.2%, and the mass fraction of aluminum chloride contained in the liquid to be dispersed is 0.1-0.3%; and/or

The rotating speed of the high-speed stirring is 5000-20000 r/min, and the time of the high-speed stirring is 5-30 min.

7. The production method according to claim 1, wherein in step (5):

the freezing is performed for 10-60 min under liquid nitrogen;

the freezing is carried out in a mould, the top and the side surfaces of the mould are made of materials with lower heat conductivity, the bottom of the mould is made of materials with higher heat conductivity, preferably, the top and the side surfaces of the mould are made of polytetrafluoroethylene, and the bottom of the mould is made of copper materials; and/or

The freeze drying is vacuum freeze drying, preferably the vacuum freeze drying is carried out for 2-5 d under the conditions that the vacuum degree is 0.5-10 Pa and the temperature is-50 to-70 ℃.

8. The production method according to claim 1, wherein in step (6):

the temperature of the post-treatment is 800-1000 ℃, and the time of the post-treatment is 0.1-12 h.

9. The production method according to any one of claims 1 to 8, characterized in that:

the density of the ultralight high-elasticity radiation-resistant nanofiber aerogel material is not more than 0.05g/cm³The compression rebound rate is not less than 80%, the linear shrinkage rate at 1100 ℃ is not more than 1%, the thermal conductivity at room temperature is not more than 0.031W/m.K, and the thermal conductivity at 800 ℃ is not more than 0.065W/m.K.

10. Ultra-light high-elasticity radiation-resistant nanofiber aerogel material prepared by the preparation method of any one of claims 1 to 9.