Pengfei Liu scite author profile

Phase change materials (PCMs) have triggered considerable attention as candidates for solar‐thermal energy conversion. However, their intrinsic low thermal conductivity prevents the rapid spreading of heat into the interior of the PCM, causing low efficiencies in energy storage/release. Herein, anisotropic and lightweight high‐quality graphene aerogels are developed by directionally freezing aqueous suspensions of polyamic acid salt and graphene oxide to form vertically aligned monoliths, followed by freeze‐drying, imidization at 300 °C and graphitization at 2800 °C. After impregnating with paraffin wax, the resultant phase change composite (PCC) exhibits a high transversal thermal conductivity of 2.68 W m−1 K−1 and an even higher longitudinal thermal conductivity of 8.87 W m−1 K−1 with an exceptional latent heat retention of 98.7%. When subjected to solar radiation, solar energy is converted to heat at the exposed surface of the PCC. As a result of the PCC's high thermal conductivity in the thickness direction, heat can spread readily into the interior of the PCC enabling a small temperature gradient of <3.0 K cm−1 and a fast charging feature. These results demonstrate the potential for real‐time and fast‐charging solar‐thermal energy conversion using phase change materials with tailored anisotropy in their thermal properties.

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Microseismic signals of double-layer hard and thick igneous strata separation and fracturing

Liu

Wang

et al. 2016

International Journal of Coal Geology

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Sealing performance analysis of rubber O-ring in high-pressure gaseous hydrogen based on finite element method

Zhou

Zheng

et al. 2017

International Journal of Hydrogen Energy

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Damage mode identification of composite wind turbine blade under accelerated fatigue loads using acoustic emission and machine learning

Liu

et al. 2019

Structural Health Monitoring

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This article studies experimentally the damage behaviors of a 59.5-m-long composite wind turbine blade under accelerated fatigue loads using acoustic emission technique. First, the spectral analysis using the fast Fourier transform is used to study the components of acoustic emission signals. Then, three important objectives including the attenuation behaviors of acoustic emission waves, the arrangement of sensors as well as the detection and positioning of defect sources in the composite blade by developing the time-difference method among different acoustic emission sensors are successfully reached. Furthermore, the clustering analysis using the bisecting K-means method is performed to identify different damage modes for acoustic emission signal sources. This work provides a theoretical and technique support for safety precaution and maintaining of in-service blades.

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Pengfei Liu

Development of high pressure gaseous hydrogen storage technologies

Thermally Conductive Phase Change Composites Featuring Anisotropic Graphene Aerogels for Real‐Time and Fast‐Charging Solar‐Thermal Energy Conversion

Microseismic signals of double-layer hard and thick igneous strata separation and fracturing

Sealing performance analysis of rubber O-ring in high-pressure gaseous hydrogen based on finite element method

Damage mode identification of composite wind turbine blade under accelerated fatigue loads using acoustic emission and machine learning

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