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Online since: September 2018
Authors: Tolya Khezhev, Sergei V. Klyuev, Yu.V. Pukharenko, Alexander V. Klyuev
Lemm, Fiber-Reinforced Concrete: Principles, Properties, Developments and Applications (Building Materials Science), William Andrew; The illustrated edition Feb, 1990
Durachenko, High-Strength Fiber-Reinforced Concrete Containing Technogenic Raw Materials and Composite Binders with Use of Nano-dispersed Powder, Research Journal of Applied Sciences. 9 (2014) 1153 – 1157
Durachenko, Fine-Grain concrete reinforced by polypropylene fiber, Research Journal of Applied Sciences. 10 (10) (2015) 624 – 628
Durachenko, The Development of textile fine-grained fiber concrete using technogenic raw materials, Research Journal of Applied Sciences. 10 (10) (2015) 701 – 706
Klyuev Fiber Gypsum Concrete Composites with Using Volcanic Tuff Sawing Waste, ARPN Journal of Engineering and Applied Sciences. 13 (8) 2018 2935 – 2946.
Durachenko, High-Strength Fiber-Reinforced Concrete Containing Technogenic Raw Materials and Composite Binders with Use of Nano-dispersed Powder, Research Journal of Applied Sciences. 9 (2014) 1153 – 1157
Durachenko, Fine-Grain concrete reinforced by polypropylene fiber, Research Journal of Applied Sciences. 10 (10) (2015) 624 – 628
Durachenko, The Development of textile fine-grained fiber concrete using technogenic raw materials, Research Journal of Applied Sciences. 10 (10) (2015) 701 – 706
Klyuev Fiber Gypsum Concrete Composites with Using Volcanic Tuff Sawing Waste, ARPN Journal of Engineering and Applied Sciences. 13 (8) 2018 2935 – 2946.
Online since: April 2012
Authors: Qi Hua Xu, Yong Xin Pan, Michael Short, Qiang Xu
Xu and Barrans, S., JSME International Journal: Series A: Solid Mechanic and Material Engineering, Vol. 46 (2003), P. 51-59
[3] Q.
Sun, International Journal of Mechanical Science, Vol. 76, (1999), P. 515-525 [8] T.
Hayhurst, J.Lin, and R.J.Hauhurst, International Journal of Solide and structures, Vol. 45, (2008), P. 2233-2250 [14] J.
Kostenko, Materials Science and Engineering A 510-511, (2009), P. 169-174 [19] T.
Andersson, Computational Materials Science, Vol 25(1-2), (2002), P. 34-41 [21] W.Sun, T.H.
Sun, International Journal of Mechanical Science, Vol. 76, (1999), P. 515-525 [8] T.
Hayhurst, J.Lin, and R.J.Hauhurst, International Journal of Solide and structures, Vol. 45, (2008), P. 2233-2250 [14] J.
Kostenko, Materials Science and Engineering A 510-511, (2009), P. 169-174 [19] T.
Andersson, Computational Materials Science, Vol 25(1-2), (2002), P. 34-41 [21] W.Sun, T.H.
Online since: July 2013
Authors: C.R. Tang, C. Zhao, D.D. Liu
Zhang, Journal of Functional Materials, 37 (2006) 4
Jiang, Journal of Functional Materials, 37 (2006) 5
Grunwald, Materials & Design, 28 (2007) 10
Wereley, Smart Materials and Structures, 17 (2008) 25-24
Ai, Journal of Functional Materials, 7 (2006) 37.
Jiang, Journal of Functional Materials, 37 (2006) 5
Grunwald, Materials & Design, 28 (2007) 10
Wereley, Smart Materials and Structures, 17 (2008) 25-24
Ai, Journal of Functional Materials, 7 (2006) 37.
Online since: July 2022
Authors: Pétia Georgieva, Rúben Lourenço, António Andrade-Campos
Materials with complex behaviors require complex models with a higher number of
parameters, resulting in expensive and time-consuming experimental campaigns [1].
Computational Materials Science, 43(4):752-758, oct 2008
Journal of Applied Mechanics, Transactions ASME, 87(8):1-8, 2020
Springer Science & Business Media, 2012
International Journal of Mechanical Sciences, 145:330 - 345, 2018.
Computational Materials Science, 43(4):752-758, oct 2008
Journal of Applied Mechanics, Transactions ASME, 87(8):1-8, 2020
Springer Science & Business Media, 2012
International Journal of Mechanical Sciences, 145:330 - 345, 2018.
Online since: March 2008
Authors: Pei Yan Huang, Jun Deng, Yi Yang
Experiment
Materials
The Ordinary Portland cement, locally available sand, crushed granite rock and water with the ratio of
66.3:06.2:5.0:0.1 by weight are used for making the concrete.
The CFL is bonded to the tension face of the concrete beam, shown as Fig.1. 100 1850 1600 200 CFL steel bar concrete Fig.1 RC beam strengthened with prestressed CFL Experimental program 4 RC beams are prepared by the materials described upper.
Acknowledgments This research project is supported in part by the National Natural Science Foundation of China (10672060, 10272047), the China Postdoctoral Science Foundation (20060400757) and SCUT Postdoctoral Innovation Science Foundation.
Key Engineer Materials, 2004, 274-276: 1159-1163
Journal of Mechanical strength, 2004, 26(s): 025-027
The CFL is bonded to the tension face of the concrete beam, shown as Fig.1. 100 1850 1600 200 CFL steel bar concrete Fig.1 RC beam strengthened with prestressed CFL Experimental program 4 RC beams are prepared by the materials described upper.
Acknowledgments This research project is supported in part by the National Natural Science Foundation of China (10672060, 10272047), the China Postdoctoral Science Foundation (20060400757) and SCUT Postdoctoral Innovation Science Foundation.
Key Engineer Materials, 2004, 274-276: 1159-1163
Journal of Mechanical strength, 2004, 26(s): 025-027
Online since: May 2011
Authors: Xiao Yan Ma, Nai Yun Gao, Jun Li, Chen Chen
As a result, the efficiency of granular carbons made from different materials for removing odor compounds was discussed in this article.
Material and experimental methods Instrument.
Generally, in Frenudlich equation about one kind GAC adsorption of different materials, K is a parameter that represent adsorption capacity, the value of K is larger the adsorption capacity become larger. 1/n is adsorption capacity index, it shows variation of velocity of adsorption.
Table 2 showed maximum adsorption capacity of three granular carbons made from different materials such as coal, coconut shell and jujube seed.
:Environmental pollution & control,Vol.28 (2006), p.631 [7] MA Xiao-yan,GAO Nai-yun,LI Qing-song etc.: Journal of instrumental analysis, Vol.26(2007), p.267 [8] Ye Zhenhua, Chemical Separation Engineering (China Petrochemical Press Publications, China,1992) [9] Gao Naiyun, Yan Min, Le Linsheng: Enhanced Treatment of Potable Water(Chemical Industry Press Publications, China, 2005), [10] Xu Jianhua: Special Treatment for Water(Tongji University, China,2000) [11] Anna Bembnowska, Robert Pelech, and Eugeniusz Milchert: Journal of Colloid and Interface Science, Vol.265 (2000), p.276
Material and experimental methods Instrument.
Generally, in Frenudlich equation about one kind GAC adsorption of different materials, K is a parameter that represent adsorption capacity, the value of K is larger the adsorption capacity become larger. 1/n is adsorption capacity index, it shows variation of velocity of adsorption.
Table 2 showed maximum adsorption capacity of three granular carbons made from different materials such as coal, coconut shell and jujube seed.
:Environmental pollution & control,Vol.28 (2006), p.631 [7] MA Xiao-yan,GAO Nai-yun,LI Qing-song etc.: Journal of instrumental analysis, Vol.26(2007), p.267 [8] Ye Zhenhua, Chemical Separation Engineering (China Petrochemical Press Publications, China,1992) [9] Gao Naiyun, Yan Min, Le Linsheng: Enhanced Treatment of Potable Water(Chemical Industry Press Publications, China, 2005), [10] Xu Jianhua: Special Treatment for Water(Tongji University, China,2000) [11] Anna Bembnowska, Robert Pelech, and Eugeniusz Milchert: Journal of Colloid and Interface Science, Vol.265 (2000), p.276
Online since: September 2013
Authors: Ju Li Deng, Guo Rong Chen
Internet of things (IoT) is an important part of the new generation of information technology; the name suggests that IoT is the internet of material connecting to material.
The clients exchange their information and communication between materials to any other materials.
Journal of Intelligent Manufacturing, 2003,14, (1) :59-82
Journal of Control Theory and Applications,2008,6(3): 267-272
Journal of Network and Systems Management,2000,8(4): 499-525
The clients exchange their information and communication between materials to any other materials.
Journal of Intelligent Manufacturing, 2003,14, (1) :59-82
Journal of Control Theory and Applications,2008,6(3): 267-272
Journal of Network and Systems Management,2000,8(4): 499-525
Online since: August 2013
Authors: Ai Jun Tang, Zhan Qiang Liu, Hai Long Ma
Elastic-plastic Deformation of Milling Thin Wall Part
Aijun Tang1,2, a, Hailong Ma2,b and Zhanqiang Liu3,c
1 School of Material Science & Engineering, Shandong University, Jinan, China
2 College of Mechanical and Electronic Engineering, Shandong Jianzhu University, Jinan, China
3School of Mechanical Engineering, Shandong University, Jinan, Shandong Province, China
atajsmile@sdjzu.edu.cn, bmahailong@sdjzu.edu.cn, cmelius@sdu.edu.cn
Keywords: Elastic-plastic deformation; Thin wall part; Milling
Abstract.
The material of the workpiece is aluminum alloy with a shear modulus (i.e. shearing stress ratio strain) of 26GPa and a Poisson’s ratio of 0.33.
Acknowledgement The authors are grateful to the National Science and Technology Major Project (No.2012ZX04003-041), National Natural Science Foundation of China (No.51105233), National Post-doctoral Foundation (No. 2011M501126), Special Fund for Shandong Provincial Post-doctoral Innovative Programs (No.201003074), University Scientific Research Development Plan of Shandong Province (No.J12LB06, No.J11LD09).
Ratchev, S.Liu, A.A.Becker: Error compensation strategy in milling flexible thin-wall parts, Journal of Materials Processing Technology, 162-163(2005): 673–681
[3] He Ning, Wang Zhigang, Jiang Chengyu, et al: Finite element method analysis and control stratagem for machining deformation of thin-walled components, Journal of Materials Processing Technology, 139(2003): 332–336
The material of the workpiece is aluminum alloy with a shear modulus (i.e. shearing stress ratio strain) of 26GPa and a Poisson’s ratio of 0.33.
Acknowledgement The authors are grateful to the National Science and Technology Major Project (No.2012ZX04003-041), National Natural Science Foundation of China (No.51105233), National Post-doctoral Foundation (No. 2011M501126), Special Fund for Shandong Provincial Post-doctoral Innovative Programs (No.201003074), University Scientific Research Development Plan of Shandong Province (No.J12LB06, No.J11LD09).
Ratchev, S.Liu, A.A.Becker: Error compensation strategy in milling flexible thin-wall parts, Journal of Materials Processing Technology, 162-163(2005): 673–681
[3] He Ning, Wang Zhigang, Jiang Chengyu, et al: Finite element method analysis and control stratagem for machining deformation of thin-walled components, Journal of Materials Processing Technology, 139(2003): 332–336
Online since: January 2011
Authors: Xing Ai, Zhan Qiang Liu, Yang Qiao
Wang: Journal of Aeronautical Materials, Vol. 26 (2006), p. 244-250
[2] S.F.
Yan: Journal of Aeronautical Materials, Vol. 23 (2003), p. 233-238 [3] W.M.
Ridgway: Journal of Materials Processing Technology, Vol. 200 (2008), p. 424-432 [5] A.
Thomas: Materials Science and Engineering A, Vol. 458 (2007), p. 195-201 [8] R.
Yang: Journal of Materials Processing Technology, Vol. 207 (2008), p. 180-186
Yan: Journal of Aeronautical Materials, Vol. 23 (2003), p. 233-238 [3] W.M.
Ridgway: Journal of Materials Processing Technology, Vol. 200 (2008), p. 424-432 [5] A.
Thomas: Materials Science and Engineering A, Vol. 458 (2007), p. 195-201 [8] R.
Yang: Journal of Materials Processing Technology, Vol. 207 (2008), p. 180-186
Online since: August 2014
Authors: Farid Nasir Ani
The future trend in thermo-conversion processing of the biomass is the utilization of microwave energy into renewable bio-fuels, materials and chemicals.
The potential of uses of bio-oils and bio-chars from oil palm solid wastes for biofuels, materials and chemicals are given.
The applications of these renewable sources to produce biofuels, materials and chemicals have been applied in some countries around the world.
The oil palm shell char could be used to make activated carbon for water treatment and gas adsorbent materials, nano-materials for gas separation and storage (ANG), microwave absorbent materials.
Plasma Sources Science and Technology, 15 :S26-S34
The potential of uses of bio-oils and bio-chars from oil palm solid wastes for biofuels, materials and chemicals are given.
The applications of these renewable sources to produce biofuels, materials and chemicals have been applied in some countries around the world.
The oil palm shell char could be used to make activated carbon for water treatment and gas adsorbent materials, nano-materials for gas separation and storage (ANG), microwave absorbent materials.
Plasma Sources Science and Technology, 15 :S26-S34