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Online since: February 2014
Authors: Chih Ming Chen, Huey Ling Chang, Chin Huang Sun
These were concluded that a material with an appropriate amount of nanopowder can enhance the performance of the photopolymerizable substrates to the preparation of novelty materials in green production process.
Experimental Materials. 2-Hydroxyethyl methacrylate (HEMA) and Trimethylolpropane Trimethacrylate (TMPTA) produced by Aldrich chemical Comp.
Note that all the purchased materials were used as-received without further purification.
Acknowledgements The research was supported by National Science Council of the Republic of China.
Lee: Journal of Applied Polymer Science, Vol.94, pp.812-818, 2004
Experimental Materials. 2-Hydroxyethyl methacrylate (HEMA) and Trimethylolpropane Trimethacrylate (TMPTA) produced by Aldrich chemical Comp.
Note that all the purchased materials were used as-received without further purification.
Acknowledgements The research was supported by National Science Council of the Republic of China.
Lee: Journal of Applied Polymer Science, Vol.94, pp.812-818, 2004
Online since: September 2014
Authors: Nattadon Rungruangkitkrai, Charoon Klaichoi, Rattanaphol Mongkholrattanasit
The optimal ratio of colour resistant materials from flour of wild taro were compose of 20% flour of wild taro corm, 36% water, 30% sodium chloride, 10% calcium hydroxide, and 4% vegetable oil.
Experimental Materials Wild taro corms used in this experiment was collected from Sukhothai province, Thailand.
Nassar, The Journal of The Textile Institute, Vol. 100 (2009), p. 486
Shastrakar, Journal of Textile Science and Engineering, Vol. 4 (2014), p. 2
Science Asia.
Experimental Materials Wild taro corms used in this experiment was collected from Sukhothai province, Thailand.
Nassar, The Journal of The Textile Institute, Vol. 100 (2009), p. 486
Shastrakar, Journal of Textile Science and Engineering, Vol. 4 (2014), p. 2
Science Asia.
Online since: January 2021
Authors: Ananya Mathu, Syed Arham Asif, Kinnal Chandra, Suneel Motru, Devji Patel, Rayyan Syed
Materials and Methodology
2.1.
Taking into account the fact that all the materials used to make the composite are recycled materials, reinforcement of recycled PET may be an important and economical step for the development of sustainable engineering materials. 6.
Damage Assessment of FRP Composite Materials using Izod Test.
An overview of mechanical and physical testing of composite materials.
Materials Science Forum Vols 775-776 (2014) pp 261-265
Taking into account the fact that all the materials used to make the composite are recycled materials, reinforcement of recycled PET may be an important and economical step for the development of sustainable engineering materials. 6.
Damage Assessment of FRP Composite Materials using Izod Test.
An overview of mechanical and physical testing of composite materials.
Materials Science Forum Vols 775-776 (2014) pp 261-265
Online since: March 2010
Authors: Bin Fang, Chong Hai Xu, Chuan Zhen Huang, Sheng Sun
The details of simulation model and Monte Carlo
algorithm for two-phase ceramic tool materials have been given [7, 8].
Fig.1 SEM micrograph of Al2O3/SiC ceramic tool materials Simulation Results and Discussion The simulation of microstructure evolution for two-phase ceramic tool materials at the different simulation time (MCS) is shown in Fig.2.
The microstructure evolution for two-phase ceramic tool materials is simulated at the different duration time.
SEM micrographs of Al2O3/5vol% SiC ceramic tool materials Acknowledgements This project is supported by National Outstanding Young Scholar Science Foundation of NSFC (50625517) and Excellent Younger Scientist Foundation of Shandong Province (No.2008BS05005).
Journal of the European Ceramic Society 19 (1999), p. 615 [2] B.
Fig.1 SEM micrograph of Al2O3/SiC ceramic tool materials Simulation Results and Discussion The simulation of microstructure evolution for two-phase ceramic tool materials at the different simulation time (MCS) is shown in Fig.2.
The microstructure evolution for two-phase ceramic tool materials is simulated at the different duration time.
SEM micrographs of Al2O3/5vol% SiC ceramic tool materials Acknowledgements This project is supported by National Outstanding Young Scholar Science Foundation of NSFC (50625517) and Excellent Younger Scientist Foundation of Shandong Province (No.2008BS05005).
Journal of the European Ceramic Society 19 (1999), p. 615 [2] B.
Online since: July 2014
Authors: Hua Zhou, Wan Tai Yu, Ying Zhao
Materials and methods
Experimental Design.
Table 1 TOC, ON and C/N ratio of the investigated soil and organic materials.
Fig. 4 TOC of observed value and predicted value in mixed organic materials.
Yu, Chinese Journal Soil Science Vol. 28 (1997), p. 71 (in Chinese)
Shen, Chinese Journal Applied Ecology Vol. 18 (2007), p. 2503 (in Chinese)
Table 1 TOC, ON and C/N ratio of the investigated soil and organic materials.
Fig. 4 TOC of observed value and predicted value in mixed organic materials.
Yu, Chinese Journal Soil Science Vol. 28 (1997), p. 71 (in Chinese)
Shen, Chinese Journal Applied Ecology Vol. 18 (2007), p. 2503 (in Chinese)
Online since: February 2015
Authors: Shi Quan Li, Bei Chen, Gui Hua Xie
The clips and the colloidal are selected elastic line materials, plastic deformation is not considered.
China Clvil Engineering Journal, 2007, (1): 54-58
China Civil Engineering Journal, 2006, 39(6): 74-78
China Civil Engineering Journal, 2010, 43(2): 79-87
Journal of Jiangsu University(Natural Science Edition), 2012, 33(6): 726-729.
China Clvil Engineering Journal, 2007, (1): 54-58
China Civil Engineering Journal, 2006, 39(6): 74-78
China Civil Engineering Journal, 2010, 43(2): 79-87
Journal of Jiangsu University(Natural Science Edition), 2012, 33(6): 726-729.
Online since: April 2011
Authors: Li Jiu Wang, Ming Li Cao, Hang Yao
Introduction
Nowadays cement-based materials are the most widely consumed building materials.
In recent years, the research and application on cement-based materials have obtained considerable progress [1].
Experiment Materials.
References [1] Wang Zhiyong, Zhang Wensheng and Ye Jiayuan: “Research Progress in High Strength Cement-based Materials”, Bulletin of the Chinese Ceramic Society, Vol. 28(4) (2009), p. 762-765 [2] Yu Qiaozhen and Xiong Jie: “A number of issues on the research of fiber reinforced cement-based composites”, Journal of Zhejiang Institute of Science and Technology, Vol. 19(4) (2002), p. 254-259 [3] Wu Zhongwei: “Fiber reinforcement—the future of cement-based materials”, China Concrete and Cement Products, (1) (1999), p. 5-6 [4] Wang Chengqi and Wu Keru: “Hybrid fiber cement-based composite and its usage”, Industrial Construction, Vol. 32(9) (2002), p. 51-53 [5] Xu Zhaoyu: “Research Progress of Whisker And its Application”, Technology & Development of Chemical Industry, Vol. 34(2) (2005), p. 11-17 [6] Cao Mingli and Wei Jianqiang: “Microstructure and mechanical properties of CaCO3 whisker-reinforced cement”, submitted to Journal of Wuhan University of Technology-Materials Science Edition
(2010) [7] Cao Mingli and Wei Jianqiang: “Study of low content whisker to reinforce Portland cements”, submitted to Journal of Wuhan University of Technology-Materials Science Edition (2011) [8] Yao Wu, Ma Yiping, TanMuhua and Wu Keru: “Effects of Polypropylene Fibers on the Physical and Mechanical Properties of Cement Based Composites(Ⅱ)—Mechanical Properties”, Journal of Building Materials, Vol. 3(3) (2000), p. 235-239 [9] Li Guozhong, Ning Chao, Yuan Haiyan and Chen Juan: “Effect of Modified Polypropylene Fiber on Mechanical Properties of Cement Mortar”, Journal of Building Materials, Vol. 13(2) (2010), p. 135-138 [10] Liu Ling, Yin Ning, Kang Maoqing and Wang Xinkui: “Research on Whisker Toughening Mechanism for Composites”, Materials Science & Engineering, Vol. 18(2) (2000), p. 116-119 [11] Song Guiming, Zhou Yu and Sun Yi: “Modeling of Fiber Toughening in Fiber-reinforced Ceramic Matrix Composites”, Journal of Solid Rocket Technology, Vol. 22(1) (1999), p. 59-63 [12] Jin Peipeng
In recent years, the research and application on cement-based materials have obtained considerable progress [1].
Experiment Materials.
References [1] Wang Zhiyong, Zhang Wensheng and Ye Jiayuan: “Research Progress in High Strength Cement-based Materials”, Bulletin of the Chinese Ceramic Society, Vol. 28(4) (2009), p. 762-765 [2] Yu Qiaozhen and Xiong Jie: “A number of issues on the research of fiber reinforced cement-based composites”, Journal of Zhejiang Institute of Science and Technology, Vol. 19(4) (2002), p. 254-259 [3] Wu Zhongwei: “Fiber reinforcement—the future of cement-based materials”, China Concrete and Cement Products, (1) (1999), p. 5-6 [4] Wang Chengqi and Wu Keru: “Hybrid fiber cement-based composite and its usage”, Industrial Construction, Vol. 32(9) (2002), p. 51-53 [5] Xu Zhaoyu: “Research Progress of Whisker And its Application”, Technology & Development of Chemical Industry, Vol. 34(2) (2005), p. 11-17 [6] Cao Mingli and Wei Jianqiang: “Microstructure and mechanical properties of CaCO3 whisker-reinforced cement”, submitted to Journal of Wuhan University of Technology-Materials Science Edition
(2010) [7] Cao Mingli and Wei Jianqiang: “Study of low content whisker to reinforce Portland cements”, submitted to Journal of Wuhan University of Technology-Materials Science Edition (2011) [8] Yao Wu, Ma Yiping, TanMuhua and Wu Keru: “Effects of Polypropylene Fibers on the Physical and Mechanical Properties of Cement Based Composites(Ⅱ)—Mechanical Properties”, Journal of Building Materials, Vol. 3(3) (2000), p. 235-239 [9] Li Guozhong, Ning Chao, Yuan Haiyan and Chen Juan: “Effect of Modified Polypropylene Fiber on Mechanical Properties of Cement Mortar”, Journal of Building Materials, Vol. 13(2) (2010), p. 135-138 [10] Liu Ling, Yin Ning, Kang Maoqing and Wang Xinkui: “Research on Whisker Toughening Mechanism for Composites”, Materials Science & Engineering, Vol. 18(2) (2000), p. 116-119 [11] Song Guiming, Zhou Yu and Sun Yi: “Modeling of Fiber Toughening in Fiber-reinforced Ceramic Matrix Composites”, Journal of Solid Rocket Technology, Vol. 22(1) (1999), p. 59-63 [12] Jin Peipeng
Online since: July 2012
Authors: Xin Ping Lin, Shu Juan Jiang, Lei Ji Zhou
Su: Journal of Applied Polymer Science Vol.81 (2001), p. 1175
[9] X.
Lee:Journal of Magnetism and Magnetic Material.
Cho: Physical Status Solid Applications and Materials Science Vol. 204 (2007), p. 4198 [13] M.
Pan: Journal of Magnetism and Magnetic Materials Vol. 311 (2007), p. 36 [15] E.
Pollert: Journal of Magnetism and Magnetic Materials Vol. 306 (2006), p. 241 [16] D.
Lee:Journal of Magnetism and Magnetic Material.
Cho: Physical Status Solid Applications and Materials Science Vol. 204 (2007), p. 4198 [13] M.
Pan: Journal of Magnetism and Magnetic Materials Vol. 311 (2007), p. 36 [15] E.
Pollert: Journal of Magnetism and Magnetic Materials Vol. 306 (2006), p. 241 [16] D.
Online since: October 2011
Authors: Jia Jun Pan, Ling Jiang, Yu Juan Yang
In addition, the safe operation of some earth-rockfill dams had been endangered due to the rheology from coarse grain materials.
Chinese Journal of rock mechanics and engineering, Vol.19(2000), p.526 [2] LIANG Jun, LIU Han-long.
Chinese Journal of Geotechnical Engineering, Vol.24(2002), 257 [3] CHENG.
Chinese Journal of Geotechnical Engineering, Vol.26 (2004), p. 473 [4] WANG Mingyuan, HE.
Jiaji: Concrete face rock-fill dam [M], Huazhong University of science and Technology Press. (1993).
Chinese Journal of rock mechanics and engineering, Vol.19(2000), p.526 [2] LIANG Jun, LIU Han-long.
Chinese Journal of Geotechnical Engineering, Vol.24(2002), 257 [3] CHENG.
Chinese Journal of Geotechnical Engineering, Vol.26 (2004), p. 473 [4] WANG Mingyuan, HE.
Jiaji: Concrete face rock-fill dam [M], Huazhong University of science and Technology Press. (1993).
Online since: July 2011
Authors: Xing Po Li, Wei Guo Yang
Shape Finding Analysis of Membrane Structures based on real material property
Weiguo Yang a, Xingpo Li b
School of Civil Engineering & Architecture,Beijing Jiaotong University,Beijing 100044,China
aE-mail: wg_yang@263.net, b09121586@bjtu.edu.cn
Keywords: membrane structure; shape finding; nonlinear; real material properties
Abstract.
In order to obtain a real shape of membrane structure, a new shape finding method was developed based on real material property.
The real cable and membrane material properties in table 3 were input and the prestress loads were then applied.
Acknowledgements This work was financially supported by the National Natural Science Foundation of China (50808011).
Beijing: Publishing House of Construction Material Industry, 2002,385-391(in Chinese) [7] T.S.
In order to obtain a real shape of membrane structure, a new shape finding method was developed based on real material property.
The real cable and membrane material properties in table 3 were input and the prestress loads were then applied.
Acknowledgements This work was financially supported by the National Natural Science Foundation of China (50808011).
Beijing: Publishing House of Construction Material Industry, 2002,385-391(in Chinese) [7] T.S.