Sort by:
Publication Type:
Open access:
Publication Date:
Periodicals:
Search results
Online since: July 2012
Authors: Shi Lin Zhao, Qiang Du, Tian Tian Xu, Chu Rui Huang, Yuan Yuan Luo
These materials have shown strong adsorption capacity, but poor acid and alkali resistance and small tannins solid load.
But thanks to the high cost of materials, it is difficult to be adapted to industrial application.
Journal of Agricultural and Food Chemistry.
Journal of Applied Polymer Science.
Journal of the Chinese Society of Rare Earths.
But thanks to the high cost of materials, it is difficult to be adapted to industrial application.
Journal of Agricultural and Food Chemistry.
Journal of Applied Polymer Science.
Journal of the Chinese Society of Rare Earths.
Online since: August 2010
Authors: Wei Gou Dong, Hai Ling Song
Journal of Thermoplastic Composite Materials. 1998, 11(1): 22-56
Journal of Thermoplastic Composite Materials, 2000, 13(7):292-313
Journal of thermoplastic composite materials, 2005, 18(5):269-285
Journal of thermoplastic composite materials,. 2006, 19(1):97-112
Journal of thermoplastic composite materials, 1998, 33:4049-4058
Journal of Thermoplastic Composite Materials, 2000, 13(7):292-313
Journal of thermoplastic composite materials, 2005, 18(5):269-285
Journal of thermoplastic composite materials,. 2006, 19(1):97-112
Journal of thermoplastic composite materials, 1998, 33:4049-4058
Online since: April 2012
Authors: Ke Jun Zhu, Shao Hui Yin, Yong Jian Zhu, Dao Cheng Zhang
This can be modeled as a rigid-visco-plastic material in MSC.
Journal of Manufacturing Science and Engineering, 2006, 128(3): 683-690
Advanced Materials Research, 2010, 126(128), 564-569
Journal of Materials Processing Technology, 2008, 201: 751-754
Journal of Manufac- turing Science and Engineering, ASME, 2007, 129(2): 380–387
Journal of Manufacturing Science and Engineering, 2006, 128(3): 683-690
Advanced Materials Research, 2010, 126(128), 564-569
Journal of Materials Processing Technology, 2008, 201: 751-754
Journal of Manufac- turing Science and Engineering, ASME, 2007, 129(2): 380–387
Online since: April 2014
Authors: F. Pınar Gokdemir, Ece Yuzbasioglu, A. Evrim Saatci, Orhan Ozdemir, Kubilay Kutlu
Murafa, Materials Chemistry and Physics 114 (2009), p.217
Kanno, Journal of Material Processing Technology 209 (2009), p.2321
Padmanabhan, Materials Science and Engineering B 143 (2007), p.42
Ma, Materials Letters Vol. 62 12–13 (2008), p.1835
Granqvist, “Handbook of Inorganic Electrochromic Materials” (Elsevier, The Netherlands, 1995)
Kanno, Journal of Material Processing Technology 209 (2009), p.2321
Padmanabhan, Materials Science and Engineering B 143 (2007), p.42
Ma, Materials Letters Vol. 62 12–13 (2008), p.1835
Granqvist, “Handbook of Inorganic Electrochromic Materials” (Elsevier, The Netherlands, 1995)
Online since: May 2013
Authors: Zhi Rong Li, Hong Bing Wang, Chun Hua Sun
Introduction
EDM is a machining approach which electrically removes materials from all conductive product[1].
Ai,Study on technology of ultrasonic vibration aided electrical discharge machining in gas, Journal of Materials Processing Technology, 149 (1-3) (2004) 640-644 [2] H.
Zheng, Ultrasonic vibration assisted electro-discharge machining of microholes in Nitinol, Journal of Micromechanics and Microengineering, 13 (5) (2003) 693-700
Wei, Ultrasonic and EDM to deep and small hole on titanium alloy, Journals of Materials Processing Technology, 120 (1-3) (2002) 101-106
Lau, A study of Ultrasonic aided Wire Electrical Discharge Machining, Journals of Materials Processing Technology, 63 (1-3) (1997) 823-828
Ai,Study on technology of ultrasonic vibration aided electrical discharge machining in gas, Journal of Materials Processing Technology, 149 (1-3) (2004) 640-644 [2] H.
Zheng, Ultrasonic vibration assisted electro-discharge machining of microholes in Nitinol, Journal of Micromechanics and Microengineering, 13 (5) (2003) 693-700
Wei, Ultrasonic and EDM to deep and small hole on titanium alloy, Journals of Materials Processing Technology, 120 (1-3) (2002) 101-106
Lau, A study of Ultrasonic aided Wire Electrical Discharge Machining, Journals of Materials Processing Technology, 63 (1-3) (1997) 823-828
Online since: April 2013
Authors: Salwa Mahmood, Muhamad Zameri Mat Saman, Mohd Yusof Noordin
The Life Cycle Assessment (LCA) will be used to evaluate the environmental impacts of membrane system from raw materials, continues with product development and manufacturing, and finally ends when all materials are returned to earth.
A system boundary of this study begins from extraction materials, manufacturing process, transportation, usage and end of life.
Journal of Industrial Ecology, 3(2-3), 95-120
Journal of Membrane Science, 284[1-2] (2006) 214-226
Water Science and Technology, 50[2] (2004) 1-7
A system boundary of this study begins from extraction materials, manufacturing process, transportation, usage and end of life.
Journal of Industrial Ecology, 3(2-3), 95-120
Journal of Membrane Science, 284[1-2] (2006) 214-226
Water Science and Technology, 50[2] (2004) 1-7
Online since: September 2007
Authors: Lei Wu, Lian Sheng Ma
Thermal Vibration of Functionally Graded Circular Plates
Lei WU and Liansheng MAa
School of Sciences, Lanzhou University of Technology, Lanzhou, China
a
lsma@lut.cn
Keywords: Functionally graded materials (FGM); Circular plate; Thermal vibration; Shooting
method.
It is assumed that the mechanical and thermal properties of functionally graded materials vary continuously through the thickness of the plate and obey a simple power law related to the volume fraction of the constituents.
Introduction Due to the excellent property of functionally graded materials (FGM) to withstanding high temperature gradient environments, it is widely used in many important engineering structures, such as aerospace, nuclear reactors and chemical plants.
Acknowledgements This work was supported by the National Fundamental Science Foundation of China (10472039), the Natural Science Foundation of Gansu Province(ZS041-A25-007) and the Doctoral Foundation of Lanzhou University of Technology.
Huang: International Journal of Non-linear Mechanics Vol.8 (1973), p.445
It is assumed that the mechanical and thermal properties of functionally graded materials vary continuously through the thickness of the plate and obey a simple power law related to the volume fraction of the constituents.
Introduction Due to the excellent property of functionally graded materials (FGM) to withstanding high temperature gradient environments, it is widely used in many important engineering structures, such as aerospace, nuclear reactors and chemical plants.
Acknowledgements This work was supported by the National Fundamental Science Foundation of China (10472039), the Natural Science Foundation of Gansu Province(ZS041-A25-007) and the Doctoral Foundation of Lanzhou University of Technology.
Huang: International Journal of Non-linear Mechanics Vol.8 (1973), p.445
Online since: December 2010
Authors: Wan Zhen Wang, Xin Tang Wang, Ming Zhou
For the convenience of application, the EC3 constitutive model of the steel materials in fire is simplified with series expansion, and the suggested formula for each stage are unified.
It is noted that the materials of the structure studied here include common steel and the steel cables with high strength, and the EC3 constitutive model is used for the common steel.
Fig.3 Effect of model of materials on displacement of the structures in fire(Q235) It is shown that the fire response of the structure is affected obviously by the different model of material under the same fire conditions, and the critical temperature for four model of material is 314°C, 278°C, 350°C and 434°C, respectively.
Fig.4 Effect of model of materials on displacement of the structures in fire (Q345) The fire response of the structure under the same condition with the situation presented above is drawn in Fig.4 for steel material of Q345B.
References [1] Xintang Wang: Building Structure Vol. 32 (2) (2002), p.57 (In Chinese) [2] Guoqiang Li, Linhai Han, Guobiao Lou and Shouchao Jiang, in: Fire Resistance Design of Steel Structure and Composite Steel-Concrete Structures, edited by China Architecture and Building Press, Peking (2007) (In Chinese) [3] Zhi Yang, Qing-hua Han, Hui Jin and Lan Wang: Journal of Tianjin University Vol. 40(8) (2007), p.1007 (In Chinese) [4] Yin Bai, Yongjiu Shi and Yuanqing Wang: Science in China Series E: Technological Sciences Vol.52(8) (2009), p.2340(In Chinese) [5] Huanting Zhou, Guo-qiang Li and Shouchao Jiang: Journal of Sichuan University Vol. 40(5) (2008), p.106 (In Chinese)
It is noted that the materials of the structure studied here include common steel and the steel cables with high strength, and the EC3 constitutive model is used for the common steel.
Fig.3 Effect of model of materials on displacement of the structures in fire(Q235) It is shown that the fire response of the structure is affected obviously by the different model of material under the same fire conditions, and the critical temperature for four model of material is 314°C, 278°C, 350°C and 434°C, respectively.
Fig.4 Effect of model of materials on displacement of the structures in fire (Q345) The fire response of the structure under the same condition with the situation presented above is drawn in Fig.4 for steel material of Q345B.
References [1] Xintang Wang: Building Structure Vol. 32 (2) (2002), p.57 (In Chinese) [2] Guoqiang Li, Linhai Han, Guobiao Lou and Shouchao Jiang, in: Fire Resistance Design of Steel Structure and Composite Steel-Concrete Structures, edited by China Architecture and Building Press, Peking (2007) (In Chinese) [3] Zhi Yang, Qing-hua Han, Hui Jin and Lan Wang: Journal of Tianjin University Vol. 40(8) (2007), p.1007 (In Chinese) [4] Yin Bai, Yongjiu Shi and Yuanqing Wang: Science in China Series E: Technological Sciences Vol.52(8) (2009), p.2340(In Chinese) [5] Huanting Zhou, Guo-qiang Li and Shouchao Jiang: Journal of Sichuan University Vol. 40(5) (2008), p.106 (In Chinese)
Online since: August 2017
Authors: Yvan Bordiec, Benoit Grimault, Paul Lefèvre, Frédéric Chateau, Renaud Frappier
RS after different HFMI processes were extensively characterized by Nitschke-Pagel and co-workers in different welding configurations and materials [5-7].
Topper, High cycle fatigue behavior of impact treated welds under variable amplitude loading conditions, International Journal of Fatigue 81 (2015), 128-142 [20] Information on http://www.empowering-technologies.com/page-43-ultrasonic-impact-treatment-needle-peening.html [21] Fabien Lefebvre, et al., External reference samples for residual stress analysis by X-ray diffraction, Materials Science Forum 681 (2001), 215-222 [22] Y.
Fujiwara, On the diffraction plane dependency of X-ray elastic constants, Journal of the Society of Materials Science Japan 18 (1969), 1066-1071 [23] A.
Bocher, Computational quantification and correction of the errors induced by layer removal for subsurface residual stress measurements, International Journal of Mechanical Sciences 64 (2012), 184-195 [30] T.
Frydrysek, Report about the possibilities of FEM applied in the verification of X-Ray measurement of residual stress, MM Science Journal 178/179 (2010), 1-2 [34] E.
Topper, High cycle fatigue behavior of impact treated welds under variable amplitude loading conditions, International Journal of Fatigue 81 (2015), 128-142 [20] Information on http://www.empowering-technologies.com/page-43-ultrasonic-impact-treatment-needle-peening.html [21] Fabien Lefebvre, et al., External reference samples for residual stress analysis by X-ray diffraction, Materials Science Forum 681 (2001), 215-222 [22] Y.
Fujiwara, On the diffraction plane dependency of X-ray elastic constants, Journal of the Society of Materials Science Japan 18 (1969), 1066-1071 [23] A.
Bocher, Computational quantification and correction of the errors induced by layer removal for subsurface residual stress measurements, International Journal of Mechanical Sciences 64 (2012), 184-195 [30] T.
Frydrysek, Report about the possibilities of FEM applied in the verification of X-Ray measurement of residual stress, MM Science Journal 178/179 (2010), 1-2 [34] E.