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Online since: September 2016
Authors: Xu Chen, Rui Si Xing, Xiao Peng Liu
Procedia Materials Science, 2014, 6:656-665
Materials Science & Engineering A, 1998, 254(s 1–2):33-44
Journal of Materials Engineering & Performance, 2012, 22(5):1348-1350
Materials Letters, 2000, 45(3-4):186-190
Journal of Engineering Materials & Technology, 1988, 110(1):63-68
Materials Science & Engineering A, 1998, 254(s 1–2):33-44
Journal of Materials Engineering & Performance, 2012, 22(5):1348-1350
Materials Letters, 2000, 45(3-4):186-190
Journal of Engineering Materials & Technology, 1988, 110(1):63-68
Online since: July 2015
Authors: Egbe Ngu Ntui Ogork, Okorie Austine Uche, Augustine Elinwa
Materials and Methods
Materials.
This is due to the reaction mechanism of the GHA-RHA materials and cement [20] and [21].
Mahmud: Study on Properties of Rice Husk Ash and its use as Cement Replacement Material, Materials Research, vol. 13, no. 2, (2010), pp. 185-190 [11] O.
Roongreung: Cementing Material from Calcium Carbide Residue-Rice Husk Ash, Journal of Materials in Civil Engineering, vol. 15, no. 5, (2003), pp. 470-475, [20] L.
Jaturapitakkul: Development of Bagasse Ash as Pozollanic Material in Concrete, Asian Journal on Energy and Environment, vol. 10, no. 3, (2009), pp. 149-159, www.asian-energy-journal.info
This is due to the reaction mechanism of the GHA-RHA materials and cement [20] and [21].
Mahmud: Study on Properties of Rice Husk Ash and its use as Cement Replacement Material, Materials Research, vol. 13, no. 2, (2010), pp. 185-190 [11] O.
Roongreung: Cementing Material from Calcium Carbide Residue-Rice Husk Ash, Journal of Materials in Civil Engineering, vol. 15, no. 5, (2003), pp. 470-475, [20] L.
Jaturapitakkul: Development of Bagasse Ash as Pozollanic Material in Concrete, Asian Journal on Energy and Environment, vol. 10, no. 3, (2009), pp. 149-159, www.asian-energy-journal.info
Online since: March 2007
Authors: Glenn E. Byczynski, Jerry Sokolowski, Mariusz Krupiński, Wojciech Kasprzak, Leszek Adam Dobrzański
References
[1] Dobrzański L.A., Fundamentals of Materials Science and Physical Metallurgy.
[5] Dobrzański L.A., Dobrzański J., Madejski J., Zacłona J., Journal of Materials Processing Technology, 48, 1995, pp. 551
[6] Dobrzański L.A., Dobrzański J., Madejski J., Zacłona J., Journal of Materials Processing Technology, 56, 1996, pp. 718
[9] Leo Prakash D.G., Prasanna B., Regener D., Computational Materials Science, Vol. 32, 2005, pp. 480-488
[10] Zheng H., Kong L.X., Nahavandi S., Journal of Materials Processing Technology, Vol. 125126, 2002, pp. 427-433
[5] Dobrzański L.A., Dobrzański J., Madejski J., Zacłona J., Journal of Materials Processing Technology, 48, 1995, pp. 551
[6] Dobrzański L.A., Dobrzański J., Madejski J., Zacłona J., Journal of Materials Processing Technology, 56, 1996, pp. 718
[9] Leo Prakash D.G., Prasanna B., Regener D., Computational Materials Science, Vol. 32, 2005, pp. 480-488
[10] Zheng H., Kong L.X., Nahavandi S., Journal of Materials Processing Technology, Vol. 125126, 2002, pp. 427-433
Online since: September 2013
Authors: Tian Feng Zhao, Jian Bo Cao, Chu Hang Yang, Hui Huang Bao, Zhong Yao Wu, Shi Ju E, Chun Xiao Chen
To solve these problems, a new energy recovery damper was designed by analyzing the principle of vibration energy recovery and the advantages of electroactive acrylic elastomer materials.
According to the range of tensile length and size of experimental materials EAE film, it determines the types of the servo electric cylinder.
Chen: Journal of Tongji University, Vol. 39 (2011) No. 6, pp. 908-913
Zhu: Journal of Zhejiang Normal University (Natural Sciences), Vol. 34 (2011) No. 4, pp. 429-435
Mazza: Smart Materials and Structures, Vol. 14 (2005) No. 6, pp. 1396-1402
According to the range of tensile length and size of experimental materials EAE film, it determines the types of the servo electric cylinder.
Chen: Journal of Tongji University, Vol. 39 (2011) No. 6, pp. 908-913
Zhu: Journal of Zhejiang Normal University (Natural Sciences), Vol. 34 (2011) No. 4, pp. 429-435
Mazza: Smart Materials and Structures, Vol. 14 (2005) No. 6, pp. 1396-1402
Online since: November 2013
Authors: Dong Qu, Bing Wei Wei, Zhi Ming Zhou, Rong Jun Xie, Chun Feng Hu, Tian Liang Zhou, Fang Zhi Li
Advanced Materials,12 (2009)1275-1279
Materials Science and Engineering, 402 (2005)118-125
Materials Science Forum, 660 (2010)41-45
International Journal of Materials Research, 3 (2010)334-339
Materials And Design, 30 (2009)2756-2762
Materials Science and Engineering, 402 (2005)118-125
Materials Science Forum, 660 (2010)41-45
International Journal of Materials Research, 3 (2010)334-339
Materials And Design, 30 (2009)2756-2762
Online since: July 2003
Authors: Daniel J. Inman
First a quick review of smart materials is provided.
Smart Materials Smart materials is the name given to a class of materials that exhibit the ability to change mechanical force and motion into some other form of energy and visa versa.
More detailed descriptions of smart materials can be found in [1-3].
Culshaw: Smart structures and Materials (Artech House, 1996) [4] C.
Sohn: "Structural Health Monitoring Using Wireless Sensing Systems with Embedded Processing," Journal of Intelligent Materials Systems and Structures, to appear.
Smart Materials Smart materials is the name given to a class of materials that exhibit the ability to change mechanical force and motion into some other form of energy and visa versa.
More detailed descriptions of smart materials can be found in [1-3].
Culshaw: Smart structures and Materials (Artech House, 1996) [4] C.
Sohn: "Structural Health Monitoring Using Wireless Sensing Systems with Embedded Processing," Journal of Intelligent Materials Systems and Structures, to appear.
Online since: August 2013
Authors: Meng Shen, Xiang Ya Kong, Jie Zhang, Peng Fei Luo, Xiu Ling Feng
., LTD, Hebei, 050011, China
4 North China Electric Power University Science & Technology College, Hebei, 071051, China
5 China Academy of Building Research, Beijing, 100013, China
a lfxzy@163.com, d luopengfei1234@yahoo.com.cn
Keywords: Reinforced concrete column with equiaxial T shaped section; material nonlinearity; second-order effects; flexural stiffness reduction factor.
Flexural stiffness reduction factor of reinforced concrete columns with special shaped section considering characters of material nonlinearity and geometrical nonlinearity is lacking corresponding research.
As a result, a flexural stiffness reduction factor is proposed to consider characteristics of material nonlinearity and geometrical nonlinearity of reinforced concrete columns with equiaxial T shaped section.
Huo: Journal of Agricultural University of Hebei, Vol. 32 (2009), p. 121-125 (in Chinese)
Bai: Journal of Chongqing University (National Science Edition), Vol. 30 (2007), p. 61-66 (in Chinese).
Flexural stiffness reduction factor of reinforced concrete columns with special shaped section considering characters of material nonlinearity and geometrical nonlinearity is lacking corresponding research.
As a result, a flexural stiffness reduction factor is proposed to consider characteristics of material nonlinearity and geometrical nonlinearity of reinforced concrete columns with equiaxial T shaped section.
Huo: Journal of Agricultural University of Hebei, Vol. 32 (2009), p. 121-125 (in Chinese)
Bai: Journal of Chongqing University (National Science Edition), Vol. 30 (2007), p. 61-66 (in Chinese).
Online since: December 2012
Authors: Qi Han, Jia Wen Li, Wen Hao Huang
Journal of Applied Polymer Science. 1981. p. 713-732
Journal of Applied Polymer Science, 1999. 74(7): p. 1836-1845
Journal of Applied Polymer Science, 2004. 92(3): p. 1454-1458
Journal of Applied Polymer Science, 2006. 101(1): p. 42-47
Journal of Materials Science, 1992, 27 (18):p. 5031-5039
Journal of Applied Polymer Science, 1999. 74(7): p. 1836-1845
Journal of Applied Polymer Science, 2004. 92(3): p. 1454-1458
Journal of Applied Polymer Science, 2006. 101(1): p. 42-47
Journal of Materials Science, 1992, 27 (18):p. 5031-5039
Online since: October 2013
Authors: Qiao Juan Gong, Yu Liu, Yong Qiang He, Jian Ping Gao, Tao Wu, Hong Sun
Scaffold materials of tissue engineering are often chosen in two aspects: one aspect is savage cell scaffold materials: collagen materials, fibrin, and chitosan.
Research indicated that all of these materials can be cartilage cell scaffold, but their effects are different.
Journal of Polymer Science Part B: Polymer Physics Vol. 34(1996), p. 1339–1346
Marcolongo: Journal of Biomedicine Materials Research A Vol. 67(2003), p. 1329–1337
Bhat: Journal of Materials Science Materials Medicine Vol. 12(2001), p. 75–79.
Research indicated that all of these materials can be cartilage cell scaffold, but their effects are different.
Journal of Polymer Science Part B: Polymer Physics Vol. 34(1996), p. 1339–1346
Marcolongo: Journal of Biomedicine Materials Research A Vol. 67(2003), p. 1329–1337
Bhat: Journal of Materials Science Materials Medicine Vol. 12(2001), p. 75–79.
Online since: August 2021
Authors: Lian Yi Huo, Si Ming Chen, Meng Yao Zhang, Xue Tao Shi
As one of the three elements of tissue engineering, scaffolds are the framework materials used to support the growth of cells into a complete tissue [8].
At present, HPBs are mainly used in drug carriers, gene transfection, environmental purification, intelligent materials and other fields.
Journal of Applied Polymer Science. 2010;92(4):2612-20
Journal of applied polymer science. 2004;91(4):2143-50
New chemical materials. 2020;48(7):6-10.
At present, HPBs are mainly used in drug carriers, gene transfection, environmental purification, intelligent materials and other fields.
Journal of Applied Polymer Science. 2010;92(4):2612-20
Journal of applied polymer science. 2004;91(4):2143-50
New chemical materials. 2020;48(7):6-10.