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Online since: November 2020
Authors: Sergey L. Sinebryukhov, Sergey V. Gnedenkov, Valentin I. Sergienko, Anton I. Neumoin, Denis P. Opra, Alexander A. Sokolov, Valery G. Kuryavyi
Against this background, the design of new electrode-active materials with an improved Li+ storage performance is an urgent task for materials scientists and battery engineers.
It is well-known, that creation of hybrids and nanocomposites, having properties that are not typical for microscale materials, is a promising way to design an advanced electrodes for LIBs.
Materials and Methods To synthesize the material, a high-voltage pulse generator [13] was used.
Carbon nanotubes in Li-ion batteries: A review // Materials Science and Engineering B. 2016.
High-capacity anode materials for lithium-ion batteries: Choice of elements and structures for active particles // Particle & Particle Systems Characterization. 2014.
It is well-known, that creation of hybrids and nanocomposites, having properties that are not typical for microscale materials, is a promising way to design an advanced electrodes for LIBs.
Materials and Methods To synthesize the material, a high-voltage pulse generator [13] was used.
Carbon nanotubes in Li-ion batteries: A review // Materials Science and Engineering B. 2016.
High-capacity anode materials for lithium-ion batteries: Choice of elements and structures for active particles // Particle & Particle Systems Characterization. 2014.
Online since: December 2013
Authors: Petr Konvalinka, Pavel Reiterman, Ondřej Holčapek
Introduction
Significant advances in the field of building materials leads to increasingly frequent enforcement these high performance materials in real constructions.
The increasing the cost of input materials will significantly reduce the total volume and weight of structures.
We can also use some secondary raw materials like ground brick dust to complete the composition of composite.
In the context of global efforts to substitute the energy-intensive building materials by secondary raw materials is discussed the possibility of using ground bricks dust.
Kodur, High-Temperature Properties of Concrete for Fire Resistance Modeling of Structures, ACI Materials Journal/September-October, (2008)
The increasing the cost of input materials will significantly reduce the total volume and weight of structures.
We can also use some secondary raw materials like ground brick dust to complete the composition of composite.
In the context of global efforts to substitute the energy-intensive building materials by secondary raw materials is discussed the possibility of using ground bricks dust.
Kodur, High-Temperature Properties of Concrete for Fire Resistance Modeling of Structures, ACI Materials Journal/September-October, (2008)
Online since: November 2010
Authors: Li Yan, Li Li Yu, Jin Zhen Cao, Zhen Zhong Tang
Properties of Blue-Stain Masson Pine after Compression and Thermal Modification
Lili Yu1, a, Zhenzhong Tang2, b, Jinzhen Cao3, c and Li Yan4, d
1 College of Packaging & Printing Engineering; Tianjin University of Science & Technology; 300222; P.R.China;
2 Timber Value Promotion and Sustainable Development Center;100834; P.R.China;
3 College of Material Science and Technology; Beijing Forestry University; 100083; P.R.China;
4 College of mechanical and Electronic Engineering; Northwest A&F University; 712100; P.R.China.
As wood is one of the viscoelastic materials, if wood is compressed under some certain conditions, the density, the surface hardness and the abrasion resistance would be improved significantly, as a result , the mechanical and physical properties of wood-based material could be improved and increase the value of these materials.
Material and Methods eferencesohu. after compressed ________________________________________________________________________________________________Materials.
Forest Products Journal, Vol.58-6(2008), p.88-93 [9] C.R.Welzbacher, J.Wehsener, A.O.Rapp, P.Haller.
Joumal of Wood Science, Vol. 46-1(2000) , p.8-15
As wood is one of the viscoelastic materials, if wood is compressed under some certain conditions, the density, the surface hardness and the abrasion resistance would be improved significantly, as a result , the mechanical and physical properties of wood-based material could be improved and increase the value of these materials.
Material and Methods eferencesohu. after compressed ________________________________________________________________________________________________Materials.
Forest Products Journal, Vol.58-6(2008), p.88-93 [9] C.R.Welzbacher, J.Wehsener, A.O.Rapp, P.Haller.
Joumal of Wood Science, Vol. 46-1(2000) , p.8-15
Online since: October 2011
Authors: Hui Ping Ren, Zi Li Jin, Rong Wang
Texture evolution during the cold rolled low carbon steel
sheet under CSP technology
Zili JIN 1,a , Huiping REN1 ,Rong Wang 2,b
1Inner Mongolia University of Science and Technology Institute for Materials
and Metallurgy Baotou 014010,China
2Baotou Iron & Steel (Group) Co.
[2] Hao Yu ,Yonglin.Kang., Journal of Univenrlty of Science and Technology Beljing. , 2008,15,(2),138
Materials Characterization., 2001, 46, 45
P-D, International Materials Reviews, 2003, 48, 86
Computational Materials Science.2005,34(4):299~313
[2] Hao Yu ,Yonglin.Kang., Journal of Univenrlty of Science and Technology Beljing. , 2008,15,(2),138
Materials Characterization., 2001, 46, 45
P-D, International Materials Reviews, 2003, 48, 86
Computational Materials Science.2005,34(4):299~313
Online since: November 2013
Authors: Chun Lan Mo, Wei Guan, Guan Yan Huang, Yong Juan Lu, Wen Zhong
The frame material is Q235 carbon steel.
Procedia Earth and Planetary Science,2011,(2):133~138
Applied Mechanics and Materials,2012:78~81
Journal of Liaoning University of Technology(Natural Science Edition),2008,28(6):399~402
Mechanical Science and Technology for Aerospace Engineering,2002,21 ( 3) : 380-383,386
Procedia Earth and Planetary Science,2011,(2):133~138
Applied Mechanics and Materials,2012:78~81
Journal of Liaoning University of Technology(Natural Science Edition),2008,28(6):399~402
Mechanical Science and Technology for Aerospace Engineering,2002,21 ( 3) : 380-383,386
Online since: November 2014
Authors: Zi Qin Ma, Li Sun, Xiu Ling Sun, Qiang Cheng, Peng Zhang, Jiang Wei
Before assembly, the axle journal diameter fitting wheel, the wheel center inner diameter, and the wheel rolling circle diameter are measured and recorded by manual work.
The system obtains material information of axle, wheel and wheelset, and obtains command of conveying, machining, and measuring from ERP.
Journal Diameter Fitting Wheel Wheel No.
Journal Diameter Fitting Wheel Wheel No.
Chinese: Science Press, Peijing, (2009).
The system obtains material information of axle, wheel and wheelset, and obtains command of conveying, machining, and measuring from ERP.
Journal Diameter Fitting Wheel Wheel No.
Journal Diameter Fitting Wheel Wheel No.
Chinese: Science Press, Peijing, (2009).
Online since: May 2014
Authors: Markus Bambach
Material data.
Jonas, Prediction of steel flow stresses at high temperatures and strain rates, Metallurgical and Materials Transactions A 22 (1991) 1545–1558
Ortner, Recrystallization in Hot Working and Creep, Metal Science Journal 8 (1974) 161–167
Bambach, Conditions for Consistent Implementation of Flow Stress Models Incorporating Dynamic Recrystallization into Finite Element Simulation Codes, Materials Science Forum 762 (2013) 325–330
Part 1: The recovery technique, International Journal for Numerical Methods in Engineering 33 (1992) 1331–1364
Jonas, Prediction of steel flow stresses at high temperatures and strain rates, Metallurgical and Materials Transactions A 22 (1991) 1545–1558
Ortner, Recrystallization in Hot Working and Creep, Metal Science Journal 8 (1974) 161–167
Bambach, Conditions for Consistent Implementation of Flow Stress Models Incorporating Dynamic Recrystallization into Finite Element Simulation Codes, Materials Science Forum 762 (2013) 325–330
Part 1: The recovery technique, International Journal for Numerical Methods in Engineering 33 (1992) 1331–1364
Online since: February 2011
Authors: Xiao Ping Luo, Lan Ting Xia, Ming Gang Zhang
Comparison of Different Content of Cd and Sb Element on the Microstructure, Mechanical Properties of As-Cast AZ31 Magnesium Alloy
Xiaoping Luo a, Lanting Xiab and Minggang Zhangc
School of Materials Science and Engineering, Taiyuan University of Science and Technology, Taiyuan 030024, PR China
alxpsyx@tom.com, bxlting@126.com, cam_lab@yeah.net
Keywords: Cd,Sb; AZ31 Magnesium Alloy; Microstructure; Mechanical Properties
Abstract.
Commercial high pure magnesium, aluminum, zinc (>99.9%), antimony (99.99%) and pure cadmium were used as the experimental materials.
Ebert: Materials Science and Engineering,VOL.302 (2001), p.37
Pan and S.Li: Journal of Chongqing Institute of Technology,VOL.21 (2007),p.10. ( In Chinese) [3] Y.Z.Lu,Q.D.Wang and Z.Xiao: Materials Science and Engineering, VOL.278 (2000), p.66 [4] G.F.Yuan,Y.S.Sun and W.J.Ding: Materials Science and Engineering, VOL.43 (2000), p.1009 [5] S.J, Chang,W.X.
B.Hamua,D.Eliezer,K.S.Shin: Materials Science and Engineering, VOL.447 (2007), p.35 [7] Z.S.Li, F.S.
Commercial high pure magnesium, aluminum, zinc (>99.9%), antimony (99.99%) and pure cadmium were used as the experimental materials.
Ebert: Materials Science and Engineering,VOL.302 (2001), p.37
Pan and S.Li: Journal of Chongqing Institute of Technology,VOL.21 (2007),p.10. ( In Chinese) [3] Y.Z.Lu,Q.D.Wang and Z.Xiao: Materials Science and Engineering, VOL.278 (2000), p.66 [4] G.F.Yuan,Y.S.Sun and W.J.Ding: Materials Science and Engineering, VOL.43 (2000), p.1009 [5] S.J, Chang,W.X.
B.Hamua,D.Eliezer,K.S.Shin: Materials Science and Engineering, VOL.447 (2007), p.35 [7] Z.S.Li, F.S.
Online since: October 2014
Authors: Hai Feng Liu, Zhan Yi Cao, X. Sun, W. Jiang, L.P. Liu
It consumes fewer materials, and could obtain high quality castings with higher density.
Lee, Dependence of tensile properties of AM60 magnesium alloy on microporosity and grain size, Materials Science and Engineering: A, 454-455 (2007) 575-580
Allison, In situ observation of tensile deformation of high-pressure die-cast specimens of AM50 alloy, Materials Science and Engineering: A, 520 (2009) 197-201
Kuczyński, Limit strains in the processes of stretch-forming sheet metal, International Journal of Mechanical Sciences, 9 (1967) 609-620
Horstemeyer, Quantitative fractographic analysis of variability in the tensile ductility of high-pressure die-cast AE44 Mg-alloy, Materials Science and Engineering: A, 427 (2006) 255-262.
Lee, Dependence of tensile properties of AM60 magnesium alloy on microporosity and grain size, Materials Science and Engineering: A, 454-455 (2007) 575-580
Allison, In situ observation of tensile deformation of high-pressure die-cast specimens of AM50 alloy, Materials Science and Engineering: A, 520 (2009) 197-201
Kuczyński, Limit strains in the processes of stretch-forming sheet metal, International Journal of Mechanical Sciences, 9 (1967) 609-620
Horstemeyer, Quantitative fractographic analysis of variability in the tensile ductility of high-pressure die-cast AE44 Mg-alloy, Materials Science and Engineering: A, 427 (2006) 255-262.
Online since: November 2013
Authors: Hong Xu, Wei Wei Zhang
The model parameters of 1Cr-0.5Mo-0.25V stainless steel bolting material at 500°C have been determined, and the creep and stress relaxation behaviors have been calculated.
The relationship between the residual stress and time during stress relaxation of various different materials has been derived from the creep equations.
(3) where E is Young’s modulus, A, σ0, n, α, β are material parameters, H is the strain hardening function.
References [1] Jinquan Guo: Research on the Analysis and Prediction Methodology of High Temperature Stress Relaxation(Dissertation, East China University of Science and Technology, China, 2010) [2] M.
Price: Journal for Global Optimization Vol. 11(1997), p.341 [9] NRIM Creep Data Sheet No. 44, National Research Institute for Metals, Tokyo (1997).
The relationship between the residual stress and time during stress relaxation of various different materials has been derived from the creep equations.
(3) where E is Young’s modulus, A, σ0, n, α, β are material parameters, H is the strain hardening function.
References [1] Jinquan Guo: Research on the Analysis and Prediction Methodology of High Temperature Stress Relaxation(Dissertation, East China University of Science and Technology, China, 2010) [2] M.
Price: Journal for Global Optimization Vol. 11(1997), p.341 [9] NRIM Creep Data Sheet No. 44, National Research Institute for Metals, Tokyo (1997).