Rubing Zhang scite author profile

Aerogel-based solar collectors inherently possess superinsulated performance, which can achieve green and sustainable thermal collection under atmospheric pressure without the need of a vacuum gap. However, the inherent brittleness, low transparency, and weak mechanical properties of aerogels limit the practical application as solar collectors. Herein, polyimide aerogel membranes (PIAMs) with integrated properties of robust flexibility, high transparency, and low thermal conductivity have been prepared. The prepared PIAMs achieve the adjustable transparency and significant transformation from fragility to high flexibility by introducing the asymmetric molecular structure. In particular, the prepared PIAMs realize an average optical transmittance of ∼90% over the long wavelength range of 500–2650 nm and exhibit high flexibility, a low density of 0.161 g/cm3, a low thermal conductivity of 0.045 W/mK, and a robust tensile strength of 6.02 MPa. Moreover, a simple and low-cost parabolic trough solar collecting device is assembled using PIAMs as an exterior structure, which could operate at atmospheric conditions and achieve highly efficient thermal collection. The results demonstrate that the effective thermal collecting temperature of solar collector was up to 231.5 °C. The as-prepared PIAMs with robust flexibility and high optical transparency can be used as the candidate for the application of solar collectors and advanced optical elements.

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High-temperature resistant Y2SiO5–TiO2 aerogel composite for efficient thermal insulation

Zhang

Hou

et al. 2020

J Porous Mater

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Novel high‐temperature‐resistant Y₂SiO₅ aerogel with ultralow thermal conductivity

Hou

Zhang

et al. 2019

Int J Applied Ceramic Tech

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A novel Y 2 SiO 5 ternary aerogel was prepared from tetraethoxysilane and yttrium chloride hexahydrate via the sol-gel method followed by high-temperature calcination.The effects of different calcination temperatures on the microstructure, mechanical and thermal stability of the Y 2 SiO 5 aerogels were investigated. The aerogels exhibited low densities of 0.33-0.62 g/cm 3 , low thermal conductivities of 0.029-0.05 W/ (m·K), and a relatively high strength of 0.16-56.47 MPa. Moreover, compared with the Al 2 O 3 -SiO 2 aerogel, the Y 2 SiO 5 aerogel has higher thermal stability and more excellent high-temperature insulation, which has potential applications as a thermal protection material in hypersonic vehicles. K E Y W O R D S aerogel, insulation, thermal propertiesHow to cite this article: Gu H, Hou X, Zhang R, Fang D. Novel high-temperature-resistant Y 2 SiO 5 aerogel with ultralow thermal conductivity. Int J Appl Ceram

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Rubing Zhang

Polyimide Aerogel Membranes with Adjustable Transparency and High Flexibility for Highly Efficient Solar Thermal Collection

High-temperature resistant Y2SiO5–TiO2 aerogel composite for efficient thermal insulation

Novel high‐temperature‐resistant Y₂SiO₅ aerogel with ultralow thermal conductivity

Contact Info

Product

Resources

About

Rubing Zhang

Polyimide Aerogel Membranes with Adjustable Transparency and High Flexibility for Highly Efficient Solar Thermal Collection

High-temperature resistant Y2SiO5–TiO2 aerogel composite for efficient thermal insulation

Novel high‐temperature‐resistant Y2SiO5 aerogel with ultralow thermal conductivity

Contact Info

Product

Resources

About

Novel high‐temperature‐resistant Y₂SiO₅ aerogel with ultralow thermal conductivity