Research Progress on Alumina Aerogel Composites for High-temperature Thermal Insulation

doi:10.15541/jim20200404

Abstract

Abstract:

As a nano-porous material with high porosity, low density, high specific surface area, excellent heat-resistance, and low thermal conductivity, the alumina aerogel shows broad application prospect in high-temperature thermal insulating areas such as the thermal protective system for space vehicles and the thermal insulation for industrial kilns. However, pristine alumina aerogels can’t be directly used because of their relatively poor thermal resistance above 1000 ℃, mechanical strengths and high-temperature thermal insulating performance. They need to be improved by introducing reinforcements and opacifiers (namely the alumina aerogel composite). This paper summarizes the latest research progress of synthesis of heat-resistant alumina aerogels, and preparation and properties of alumina aerogel composites. Researchers improved the thermal stability of alumina aerogels by modifications such as in-situ doping, deposition, organic chains or carbon coatings. The introduction of whiskers, particles, porous skeletons or fibers into alumina aerogels contributes to considerable improvement of mechanical performance. The cooperation of fibers and opacifiers help to increase the inhibition of infrared radiation and lower the high-temperature thermal conductivity of alumina aerogels. The future of alumina aerogel composites is also proposed: a) finely tailoring the bulk density, micro structures, and introducing proper foreign elements and opacifiers, are supposed to further optimize the thermal stability of alumina aerogels and thermal insulating performance of their composites; b) deeper attention should also be paid on the evolution of structure and properties of composites at elevated temperatures, and on the interaction between alumina aerogel and reinforcement. As a novel thermal insulation, alumina aerogel composites are expected to take their advantages and be widely applied in the future.

Key words: alumina aerogel, thermal insulation, composite, reinforcement, opacifier, review

CLC Number:

TB332

PENG Fei, JIANG Yonggang, FENG Jian, CAI Huafei, FENG Junzong, LI Liangjun. Research Progress on Alumina Aerogel Composites for High-temperature Thermal Insulation[J]. Journal of Inorganic Materials, 2021, 36(7): 673-684.

Figures/Tables 15

Fig. 1 Preparation of alumina aerogels (R refers to the alkoxyl group and X refers to the anion such as Cl-)

Fig. 2 Alumina-silica aerogels after heat-treatment[39] (a) Specific surface areas of aerogels with different molar ratios of Si; (b) TEM photos of the pristine alumina aerogel (AA-1300) and alumina-silica aerogel calcined at 1300 ℃(ASA81-1300); (c) Distribution and atomic ratio of Si and Al in the aerogel with a theoretical Si/Al molar ratio of 0.125:1 (Bars representing 20 nm; the red and green color representing Si and Al, respectively)

Fig. 3 Si-modified alumina aerogels[47] (a) Deposition modification of the gels; (b) Macro and (c) Micro changing of pristine and Si-modified alumina aerogels after heat-treatment at 1300 ℃

Fig. 4 (a) Porous structure[5] and (b) elastic moduli of alumina aerogels

Fig. 5 Synthesis of alumina aerogel composites

Fig. 6 The aluminum borate whisker reinforced alumina-silica aerogel composite[27] (a) Macro and (b) micro morphology; (c) Mechanical properties

Fig. 7 Zirconia fiber-based porous skeleton and the alumina-silica aerogel composite reinforced by the skeleton[37] Micro morphology of (a) skeleton and (b) composite, and (c) their mechanical properties

Fig. 8 The macro (a) and micro morphologies (b,c) of the quartz fiber-based porous skeleton[33]

Fig. 9 Fiber reinforced alumina (alumina-silica) aerogel composites[55,56,57] (a) Influence of mass fraction of fibers on mechanical properties[55]; (b) Behavior of composites under compressive and bending loadings[56]; (c) Morphology and (d) bending/tensile strengths of composites with different fiber densities[57]

Fig. 10 Test site (a) and temperature curves (b) of the ceramic fiber reinforced alumina aerogel composite (15 mm in thickness) heated by a quartz lamp apparatus[56]

Fig. 11 High-temperature thermal conductivities of mullite fiber reinforced alumina-silica aerogel composites[57]

Fig. 12 Opacifier embedded mullite fiber felt reinforced alumina-silica aerogel composite[68] (a) Macro morphology; (b) Temperature curves of the composite (20 mm in thickness) during one-face heating test

Fig. 13 The mullite fiber felt reinforced alumina-silica aerogel composite doped with TiO2 (a) High-temperature thermal conductivity[47]; (b) High-temperature thermal conductivity of composites with different content of TiO2[54]; (c) Temperature (cold-face) of the composite (doped with 10wt% TiO2) fired by the flame of butane spray gun at 1300 ℃ for 15 min[54]; (d) Heat transfer mechanism of the composite (λs and λg refering to solid and gaseous thermal conductivity, respectively)[54]

Fig. 14 (a) Micro morphology of SiC modified mullite fibers; (b) Thermal conductivity of the alumina-silica aerogel composite reinforced by SiC modified mullite fibers[69]

Fig. 15 Thermal conductivity of typical pristine alumina aerogels and alumina aerogel insulation composites

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