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HomeApplied Mechanics and MaterialsApplied Mechanics and Materials Vol. 320Preparation of ASZ Thermal Storage Ceramics for...

Preparation of ASZ Thermal Storage Ceramics for Solar Thermal Power Generation

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Abstract:

This paper aims to investigate the properties and microstructure of Al₂O₃-SiC-ZrO₂(ASZ) composite ceramics for solar thermal power generation. The composite ceramics were prepared from α-Al₂O₃, partially stabilized zirconia (Y₂O₃5.2 wt%) and silicon carbide fired at 1280 °C for 2 h through pressureless sintering. Influence of the contents of SiC and ZrO₂ on the performance of ASZ composite ceramics have been observed and extensively investigated via XRD, SEM, etc. The results revealed that the thermal shock resistance and high-temperature thermal properties would increase with the increase of the SiC content. No cracking occurred after 30 times thermal shock (from room temperature to 800°C with air cooling) while the bending strength after thermal shock test, the thermal expansion coefficient, the heat capacity, the thermal conductivity coefficient and the thermal conductivity were 76.99MPa (with a growth rate of 27.89% after thermal shock), 5.85×10^-6°C^-1, 1.05 kJ(kgK)^-1, 0.01 cm²s^-1, 2.26 W(mK)^-1, respectively. The XRD patterns indicated that the main crystal phases included corundum, silicon carbide and zirconium silicate while the SEM images illustrated the well-grown crystal grains had the sizes distributed among 5-120 μm.Key words: Al₂O₃-SiC-ZrO₂composite ceramics, Silicon carbide, Thermal properties,Microstructure, Solar thermal power generation

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Periodical:

Applied Mechanics and Materials (Volume 320)

Pages:

44-51

DOI:

https://doi.org/10.4028/www.scientific.net/AMM.320.44

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Online since:

May 2013

Authors:

Jian Feng Wu, Bin Zheng Fang, Xiao Hong Xu, Peng Li, Xin Bin Lao, Shu Qing Zheng

Keywords:

Al₂O₃-SiC-ZrO₂Composite Ceramics, Microstructure, Silicon Carbide (SiC), Solar Thermal Power Generation, Thermal Property

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[1] R. J. Liao and S. L. Li: Appl Energy Technol, (2007), p.28

[2] M. M. Farid, A. M. Khudhair, S. A. K. Razack and S. Al-Hallaj: Energy. Convers. Manage 45, (2004), p.1597

[3] D. Laing, D. Lehmann, M. Fib and C. Bahl: Sol. Energy. Eng., Vol.131 (2009) No.4, p.1

[4] D. Brosseaud, J. W. Kelton, D. Ray, K. Chisman and B. Emms: Sol. Energy. Eng., Vol.127 (2004) No.1, p.109

[5] Z. Yang and S.V. Garimella: Applied Energy, Vol.87 (2010) No.11, p.3322

[6] D.Laing, W. D. Steinmann, R. Tamme and C. Richter: Solar Energy, Vol.80 (2006) No.10, p.1283

[7] G. Frank, E. Christian and K. Dietmar: International Journal of Applied Ceramic Technology, Vol.8 (2011) No.3, p.646

[8] A. McMahan, S. A. Klein and D. T. Reindl: Journal of Solar Energy Engineering, Vol.129 (2007) No.4, p.355

[9] A. Francis, H. Neil, E. Philip and M. Smyth: Renewable and Sustain Energy Reviews, Vol.14 (2010) No.2, p.615

[10] J. D. Chung, S. H. Cho, C. S. Tae and H. Yoo: Renew Energy, Vol.33 (2008) No.10, p.2236

[11] M. Najjari and S. B. Nasrassah: International Journal of Thermal Sciences, Vol.47 (2008) No.7, p.825

[12] D. Sarkar, S. Adak, M. C. Chu, S. J. Cho and N. K. Mitra: Ceramics International, Vol.33 (2007) No.2, p.255

[13] F. Wu, L. Huo, Z. J. Li, X. W. Li, N. Xu and L. Zhang: Refractories (In Chinese), Vol.44 (2010) No.1, p.52

[14] Y. X. Chen, C. S. Pan, Z. Fan and X. Wang: Journal of Ceramics (In Chinese), Vol.28 (2007) No.3, p.227

[15] S. Q. Miao and C. W. Ge: Journal of Yangzhou Univensity Nataral Science Edition (In Chinese), Vol.5 (2002) No.1, p.40

[16] W. M. Ma, Z. M. Xiu, L. Wen, X. D. Sun and W. L. Tie: Journal of the Chinese Rare Earth Society (In Chinese), Vol.22 (2004) No.2, p.229

[17] S. Maensiri, and S. G. Roberts: Journal of the European Ceramic Society, Vol.22 (2002) No.16, p.2945

[18] G. Y. Lin and T. C. Lei: Ceramics International, Vol.24 (1998) No.4, p.313

[19] W. Zhang and Y. L. Han: Journal of Ceramics (In Chinese), Vol.29 (2008) No.2, p.193

[20] W. W. Chen, K. Soshu and M. Yoshinari: International Journal of Applied Ceramic Technology, Vol.5 (2008) No.4, p.353

[21] S. Avraham, P. Beyer, R. Janssen, N. Claussen and W. D. Kaplan: Journal of the European Ceramic Society, Vol.26 (2006) No.13, p.2719

DOI: 10.1016/j.jeurceramsoc.2005.06.024

[22] P. Vena, D. Gastald, R. Contro and L. Petrini: International Journal of Plasticity, Vol.22 (2006) No.5, p.895

[23] Q. Qi, S. M. Deng and Y. Q. Jiang: Solar Energy, Vol.82 (2008), p.669

[24] X. H. Xu, F. Zhao, J. F. Wu, J. Li and C. G. Li: Journal of Wuhan University of Technology (In Chinese), Vol.31 (2009) No.13, p.8

[25] J. F. Wu, J. Li, X. H. Xu, L. F. Yang and J. F. Wu: Journal of Wuhan University of Technology (In Chinese), Vol.31 (2009) No.9, p.1

[26] S. Maensiri and S. G. Roberts, J. Am. Ceram. Soc., Vol.85 (2002) No.8, p.(1971)