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Online since: March 2010
Authors: Li Yun Li, Fu Quan Cao, Jie Zhang, An Ping Zhao, Lu Lu Tian
Bi-materials Fracture Experiment
Specimen preparation.
(a) Sketch photo of bi-materials specimen.
(b) σ1 of bi-materials specimen for α=45°.
On the other hand, KI in single-materials specimens are slightly greater than ones in bi-materials, while KI (KI<0) is the main resistance to the crack propagation.
Sic., Vol. 40 (2003), p.355 [2] Liyun Li, Fengguang Xu, Heping Xie and Ning Wei: Key Engineering Materials, Vol. 324 (2006), p.1217 [3] Liyun Li, Zhenzi Li, Zonqi Sun: Chinese Journal of Rock Mechanics and Engineering, Vol.13 (1994), p.134 [4] R.H.C.Wong, M.L.Huang, M.R.Jiao and C.A.Tang: Key Engineering Materials, Vol. 261 (2004), p. 214 [5] T.
(a) Sketch photo of bi-materials specimen.
(b) σ1 of bi-materials specimen for α=45°.
On the other hand, KI in single-materials specimens are slightly greater than ones in bi-materials, while KI (KI<0) is the main resistance to the crack propagation.
Sic., Vol. 40 (2003), p.355 [2] Liyun Li, Fengguang Xu, Heping Xie and Ning Wei: Key Engineering Materials, Vol. 324 (2006), p.1217 [3] Liyun Li, Zhenzi Li, Zonqi Sun: Chinese Journal of Rock Mechanics and Engineering, Vol.13 (1994), p.134 [4] R.H.C.Wong, M.L.Huang, M.R.Jiao and C.A.Tang: Key Engineering Materials, Vol. 261 (2004), p. 214 [5] T.
Online since: August 2011
Authors: Yun Wei Zhao, Zhuo Yang, Lei Zhang
The material removal is investigated in electrorheological (ER) fluid-assisted polishing of conductive materials.
This paper attempts to set up an analytical model for material removal in ER fluid-assisted polishing of conductive materials.
Principle of ER fluid-assisted polishing The principle of the ER fluid-assisted polishing of conductive materials is schematically shown in Fig.1.
Lee, Journal of Materials Processing Technology. 155-156 (2004) 1293-1299
Kong, Journal of Materials Processing Technology. 209 (2009) 4954-4957
This paper attempts to set up an analytical model for material removal in ER fluid-assisted polishing of conductive materials.
Principle of ER fluid-assisted polishing The principle of the ER fluid-assisted polishing of conductive materials is schematically shown in Fig.1.
Lee, Journal of Materials Processing Technology. 155-156 (2004) 1293-1299
Kong, Journal of Materials Processing Technology. 209 (2009) 4954-4957
Online since: January 2014
Authors: Antonio Ferreira Miguel
Modelling of Mass Transport in Porous Materials: Analytical Solutions and Analysis
Antonio F.
In this paper approximate analytical solutions to mass transport equations in porous materials with both constant and non-constant diffusion coefficients are presented.
Many problems of practical importance related with mass transport in finite porous materials take place under periodic boundary conditions being the period being of few minutes to several months and years [2].
Journal Thermal Sciences 44 (2005) 720-725 [5] A.
Miguel, Effect of air humidity on the evolution of permeability and performance of a fibrous filter during loading with hygroscopic and non-hygroscopic particles, Journal of Aerosol Science 34 (2003) 783-799 [9] A.
In this paper approximate analytical solutions to mass transport equations in porous materials with both constant and non-constant diffusion coefficients are presented.
Many problems of practical importance related with mass transport in finite porous materials take place under periodic boundary conditions being the period being of few minutes to several months and years [2].
Journal Thermal Sciences 44 (2005) 720-725 [5] A.
Miguel, Effect of air humidity on the evolution of permeability and performance of a fibrous filter during loading with hygroscopic and non-hygroscopic particles, Journal of Aerosol Science 34 (2003) 783-799 [9] A.
Online since: March 2024
Authors: Vlastimil Bilek, Lukáš Prochazka, Kateřina Matyskova, Radka Hedlova, Marie Hornakova
This includes waste generated in the production of building materials.
One of the waste materials obtained during the board processing is a fine powder.
Fine waste material from the production of CETRIS board. 3 Materials 3.1 Basic properties of the raw waste material First, the density of the dry raw material must be determined.
The density of finely ground materials is determined using a pycnometer according to ČSN EN 1097-6 [18].
World Journal of Science, Technology and Sustainable Development, 12(3), 233–242. https://doi.org/10.1108/WJSTSD-03-2015-0016 [2] Bonoli, A., Zanni, S., & Serrano-Bernardo, F. (2021).
One of the waste materials obtained during the board processing is a fine powder.
Fine waste material from the production of CETRIS board. 3 Materials 3.1 Basic properties of the raw waste material First, the density of the dry raw material must be determined.
The density of finely ground materials is determined using a pycnometer according to ČSN EN 1097-6 [18].
World Journal of Science, Technology and Sustainable Development, 12(3), 233–242. https://doi.org/10.1108/WJSTSD-03-2015-0016 [2] Bonoli, A., Zanni, S., & Serrano-Bernardo, F. (2021).
Online since: August 2023
Authors: Svitlana Shvydka, Atabala M. Babayev, Anton Chernukha, Olena Tarakhno, Olga Skorodumova
Emen, Formation of fire retardant properties in elastic silica coatings for textile materials, Materials Science Forum, 1006 (2020) 25–31
Savchenko, Thermodynamic study of fireprotective material, Materials Science Forum. 1038 (2021) 486–491
Kurska, Investigation of the processes of formation of a fire retardant coating, Materials Science Forum, 1038 (2021) 480–485
Obizhenko, Colloid-chemical regularities of reagent wastewater treatment of dairies, Materials Science Forum, 1038 (2021) 235–241
Romanova, Co-Мo-W galvanochemical alloy application as cathode material in the industrial wastewater treatment processes, Materials Science Forum, 1038 (2021) 251–257
Savchenko, Thermodynamic study of fireprotective material, Materials Science Forum. 1038 (2021) 486–491
Kurska, Investigation of the processes of formation of a fire retardant coating, Materials Science Forum, 1038 (2021) 480–485
Obizhenko, Colloid-chemical regularities of reagent wastewater treatment of dairies, Materials Science Forum, 1038 (2021) 235–241
Romanova, Co-Мo-W galvanochemical alloy application as cathode material in the industrial wastewater treatment processes, Materials Science Forum, 1038 (2021) 251–257
Online since: July 2011
Authors: Zhi Ming Du, Shui Sheng Xie, Gang Chen, Jun Liu, Qi Cao, Hai Meng Jia
If the testing position is on reinforcement materials, hardness is higher than the one in which the position is on based materials.
References [1] J.W.Kaczmar, K.Pietrzak, W.Wlosinski.: Journal of Materials Processing Technology.
Wlosinski.W.: Journal of materials processing technology.
Velasco. : Journal of Materials Processing Technology.
Vol.133(2003), p. 203 [6] Lu, Yi-Zhong, Wang Bao-Shun, Cui Yan etal.: Journal of Aeronautical Materials.
References [1] J.W.Kaczmar, K.Pietrzak, W.Wlosinski.: Journal of Materials Processing Technology.
Wlosinski.W.: Journal of materials processing technology.
Velasco. : Journal of Materials Processing Technology.
Vol.133(2003), p. 203 [6] Lu, Yi-Zhong, Wang Bao-Shun, Cui Yan etal.: Journal of Aeronautical Materials.
Online since: February 2014
Authors: Nurul Atikah Mohd Mokhtar, Kelimah Elong, Azira Azahidi, Nurhanna Badar, Norlida Kamarulzaman
Kamarulzaman2*
1 Faculty of Applied Science, Universiti Teknologi MARA, 40000 Shah Alam, Malaysia
2 Centre of Nanomaterial Research, Institute Of Science, Level 3 Block C, Universiti Teknologi Mara, 40450 Shah Alam, Malaysia
*norlyk @salam.uitm.edu.my (corresponding author)
Keywords: Li-ion battery, LiNi0.8Co0.2O2, cathode material
Abstract.
Kawamoto (2000) Journal of Power Sources 90:82–88 [6] J.
Chen (2012) Journal of Power Sources 205:385– 393 [8] X.
Doeff (2009) journal of the electrochemical society 156(3): A192-A198 [13] N.
Kalaiselvi (2005) Science and Technology of Advanced Materials 6:689–703 [15] X.
Kawamoto (2000) Journal of Power Sources 90:82–88 [6] J.
Chen (2012) Journal of Power Sources 205:385– 393 [8] X.
Doeff (2009) journal of the electrochemical society 156(3): A192-A198 [13] N.
Kalaiselvi (2005) Science and Technology of Advanced Materials 6:689–703 [15] X.
Online since: April 2012
Authors: Yong Lin Kang, Yu Dong Zheng, Xin Liang, Qiao Li Wang, Ying Ling, Kun Qiao, Guo Ming Zhu
The Analysis of the Interface States of Low-density Materials in the Forming Process
Qiaoli Wang1, a, Yudong Zheng1, b*, Xin Liang2, c,
Ying Ling2, d, Kun Qiao1, e, Yonglin Kang1, f, Guoming Zhu1, g
1School of Materials Science and Engineering, University of Science and Technology Beijing, Beijing 100083, China
2Institute of Aerospace Materials and Technology Beijing, Beijing, China
awangqiaoli@163.com, bzhengyudong@mater.ustb.edu.cn, cliangxbj@163.com,
dkuangslian@vip.sina.com, e12208374@qq.com, fkangylin@mater.ustb.edu.cn
*Corresponding author.
The interface of two low-density materials is bent in the forming process, which decreases the performance of materials.
The decay rates of frictional force of these two materials are △fa, △fb .
Adam: Journal of Materials Processing Technology Vol. 107(2000), p. 267 [7] A.
Ebrahimi: Materials and Design Vol. 31(2010), p. 493
The interface of two low-density materials is bent in the forming process, which decreases the performance of materials.
The decay rates of frictional force of these two materials are △fa, △fb .
Adam: Journal of Materials Processing Technology Vol. 107(2000), p. 267 [7] A.
Ebrahimi: Materials and Design Vol. 31(2010), p. 493
Online since: October 2014
Authors: Cun Wei Zhang, Xiang Mei Li, Rong Jie Yang, Peng Xiang Wang
Study on Fire Prevention of Wall Insulation Organic Materials
Wang Pengxiang1, Zhang Cunwei2, Li Xiangmei3, Yang Rongjie3
School of Materials Science &Engineering, Beijing Institute of Technology
National Engineering Research Center of Flame Retardant Materials,100081,Beijing
Keywords: Organic, Wall Insulation Materials, Fire Prevention, Development
Abstract: This article described the technical progress of the wall insulation organic materials and analyzed other relevant factors in recent years about the insulation materials policies changes and market changes.
The second type of wall insulation materials are composite materials, such as phenolic foam insulation materials, reaching flame retardant materials B1 level (fire).
They belong to the combustible materials (B2 fire).
A: incombustible materials.
B2: combustible construction materials.
The second type of wall insulation materials are composite materials, such as phenolic foam insulation materials, reaching flame retardant materials B1 level (fire).
They belong to the combustible materials (B2 fire).
A: incombustible materials.
B2: combustible construction materials.
Online since: May 2015
Authors: Adrian Stere Paris, Constantin Târcolea
Similar materials were selected using both techniques.
Andrew Cantrell stated only as a brief outline to demonstrate the need for material science in bicycle technology [17].
Voicu, Principal Component Analysis Applied to Agricultural Equipments, Tarım Makinaları Bilimi Dergisi (Journal of Agricultural Machinery Science) Istanbul 7 (3) (2011) 305-308
Ashby, Materials Selection in Mechanical Design, Third Edition, Ed.
Demetrescu –Târcolea, Statistical methods applied for materials selection The International Conference DGDS-2008 & MENP-5, 2008, Mangalia, Romania, Applied Sciences, Geometry Balkan Press, Vol.11, (2009) 145-150
Andrew Cantrell stated only as a brief outline to demonstrate the need for material science in bicycle technology [17].
Voicu, Principal Component Analysis Applied to Agricultural Equipments, Tarım Makinaları Bilimi Dergisi (Journal of Agricultural Machinery Science) Istanbul 7 (3) (2011) 305-308
Ashby, Materials Selection in Mechanical Design, Third Edition, Ed.
Demetrescu –Târcolea, Statistical methods applied for materials selection The International Conference DGDS-2008 & MENP-5, 2008, Mangalia, Romania, Applied Sciences, Geometry Balkan Press, Vol.11, (2009) 145-150