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Online since: September 2011
Authors: Ji Hong Zhu, J.S. Li, L. Xia, W.H. Zhang
and are the volume occupied by solid materials and its upper bound, respectively.
Here, suppose material properties are .
Paulino: International Journal for Numerical Methods in Engineering, Vol. 77(2009), p. 301 [2] N.
Saitou: Journal of Mechanical Design, Vol. 127(2005), p. 34 [3] W.H.
Beckers: International Journal for Numerical Methods in Engineering, Vol. 78(2009), p. 631 [5] J.H.
Here, suppose material properties are .
Paulino: International Journal for Numerical Methods in Engineering, Vol. 77(2009), p. 301 [2] N.
Saitou: Journal of Mechanical Design, Vol. 127(2005), p. 34 [3] W.H.
Beckers: International Journal for Numerical Methods in Engineering, Vol. 78(2009), p. 631 [5] J.H.
Online since: December 2011
Authors: Claudiu Bisu, Alain Gerard, Miron Zapciu, Olivier Cahuc
Independentei, sect.6, 060042 Bucharest.
2University Bordeaux 1, -I2M- Material, Processes, Interactions-CNRS, UMR 5295,
351 cours de la Liberation, 33405 Talence, France.
Adapting envelope analysis to characterize the milling tool materials is an important contribution to the qualitative and quantitative characterization of milling capacity and a step by modeling the three-dimensional cutting process.
Figure 2: Experimental device. 4 Measurement and analysis To increase the forces and to obtain a better response for the monitoring the test was performed on steel materials workpiece E24-2, the tool milling cutter were used here is 490-025C5-08M, with 25 mm diameter and 3 teeth.
Journal of Sound Vibration, 270, (4), 2004, pp. 61-73
Girardin, “Etude de l’usinage de matériaux performants et surveillance de l’usinage“, Thesis Institut National de Sciences Appliquées de Lyon, 2010
Adapting envelope analysis to characterize the milling tool materials is an important contribution to the qualitative and quantitative characterization of milling capacity and a step by modeling the three-dimensional cutting process.
Figure 2: Experimental device. 4 Measurement and analysis To increase the forces and to obtain a better response for the monitoring the test was performed on steel materials workpiece E24-2, the tool milling cutter were used here is 490-025C5-08M, with 25 mm diameter and 3 teeth.
Journal of Sound Vibration, 270, (4), 2004, pp. 61-73
Girardin, “Etude de l’usinage de matériaux performants et surveillance de l’usinage“, Thesis Institut National de Sciences Appliquées de Lyon, 2010
Online since: October 2016
Authors: Pelagia Glampedaki
Materials and Methods
Materials.
Luo, Journal of Materials Chemistry 21, (2011) p. 6113 [6] CMA Ashruf, Sensor Review 22, (2002) p. 322 [7] W.
Yuen, Journal of Applied Polymer Science 121, (2011) p. 267 [19] MC.
Bayane, Journal of Applied Polymer Science 115, (2010) p. 2479 [30] L.
Warmoeskerken, Journal of Materials Science 47(5), (2012) 2078–2087 [39] P.
Luo, Journal of Materials Chemistry 21, (2011) p. 6113 [6] CMA Ashruf, Sensor Review 22, (2002) p. 322 [7] W.
Yuen, Journal of Applied Polymer Science 121, (2011) p. 267 [19] MC.
Bayane, Journal of Applied Polymer Science 115, (2010) p. 2479 [30] L.
Warmoeskerken, Journal of Materials Science 47(5), (2012) 2078–2087 [39] P.
Online since: July 2010
Authors: Renaud Gantois, Jean Noel Félices, Nicolas Pirc, Fabrice Schmidt, Arthur Cantarel
The use of composite materials in large structures has increased in recent years.
Introduction Composite materials have been used in the aircraft industry over the past three decades for their excellent specific mechanical properties.
Acknowledgments This work was supported by DAHER-Socata and CRCC-Resource and Competencies Center for Composite Materials.
Composites Science and Technology 66, 1067-1080 (2006)
Journal of composite materials (2002)
Introduction Composite materials have been used in the aircraft industry over the past three decades for their excellent specific mechanical properties.
Acknowledgments This work was supported by DAHER-Socata and CRCC-Resource and Competencies Center for Composite Materials.
Composites Science and Technology 66, 1067-1080 (2006)
Journal of composite materials (2002)
Online since: January 2016
Authors: Kitipun Boonin, Jakrapong Kaewkhao, Patarawagee Yasaka
An alternative way is using luminescent materials excited by ultraviolet light and consequently emitting the white light [8].
Their physical, optical and luminescence properties for white emission materials development were investigated.
Yu , Luminescent properties of Sr2Al2SiO7:Ce3+,Eu2+ phosphors for near UV-excited white light-emitting diodes, Materials Letters 65 (2011 ) 3418-3420
Han, Eu/Dy ions co-doped white light luminescence zinc-aluminoborosilicate glasses for white LED, Optical Materials 31 (2008) 47-50
Yao, Luminescence properties of Dy3+-doped Li2SrSiO4 for NUV-excited white LEDs, Optical Materials 33 (2011) 1808-1812
Their physical, optical and luminescence properties for white emission materials development were investigated.
Yu , Luminescent properties of Sr2Al2SiO7:Ce3+,Eu2+ phosphors for near UV-excited white light-emitting diodes, Materials Letters 65 (2011 ) 3418-3420
Han, Eu/Dy ions co-doped white light luminescence zinc-aluminoborosilicate glasses for white LED, Optical Materials 31 (2008) 47-50
Yao, Luminescence properties of Dy3+-doped Li2SrSiO4 for NUV-excited white LEDs, Optical Materials 33 (2011) 1808-1812
Online since: November 2015
Authors: Peter Michalik, Gabriel Fedorko, Nikoleta Husáková, Peter Kačmáry, Ivica Ristović, Vieroslav Molnár
FEM is suitable for the analysis of hyper-elastic materials such as rubber or rubber-textile conveyor belt (Peng and Chang [12]; Novotný [13]).
Mazurkiewicz, Analysis of the ageing impact on the strength of the adhesive sealed joints of conveyor belts, Journal of Materials Processing Technology 208 (2008) 477-485
Chang, A compressible approach in finite element analysis of rubber-elastic materials, Computers & Structures 62 (3) (1997) 573–593
Yang, Parametric finite element analysis on key parts of the conveyor, Applied Mechanics and Materials 101–102 (2012) 755–758
Fen, Research on the idler spacing of belt conveyor, Applied Mechanics and Materials 127 (2012) 295–299.
Mazurkiewicz, Analysis of the ageing impact on the strength of the adhesive sealed joints of conveyor belts, Journal of Materials Processing Technology 208 (2008) 477-485
Chang, A compressible approach in finite element analysis of rubber-elastic materials, Computers & Structures 62 (3) (1997) 573–593
Yang, Parametric finite element analysis on key parts of the conveyor, Applied Mechanics and Materials 101–102 (2012) 755–758
Fen, Research on the idler spacing of belt conveyor, Applied Mechanics and Materials 127 (2012) 295–299.
Online since: January 2010
Authors: Francisco Manuel Braz Fernandes, Daniel P.L. Silva, Rui F. Martins
Shape Memory Alloys (SMA) belong to a special group of metallic materials, which are
capable of returning to a pre-determined shape or size when submitted to an appropriate thermal
cycle.
Introduction Ni-Ti alloys are a special group of metallic materials, also known as "Smart Materials", which have two very important characteristics: superelasticity and shape memory.
Hall: A computational model for shape memory alloys, International Journal of Solids and Structures Vol. 37 (2000), p. 735-760 [3] K.
Ren: "Physical metallurgy of Ti-Ni-based shape memory alloys", Progress in Materials Science Vol 50 (2005) p. 511-678 [4] C.M.
Barsoum: International Journal of Fracture Vol. 11 (1975), p.167-169 [6] J.P.
Introduction Ni-Ti alloys are a special group of metallic materials, also known as "Smart Materials", which have two very important characteristics: superelasticity and shape memory.
Hall: A computational model for shape memory alloys, International Journal of Solids and Structures Vol. 37 (2000), p. 735-760 [3] K.
Ren: "Physical metallurgy of Ti-Ni-based shape memory alloys", Progress in Materials Science Vol 50 (2005) p. 511-678 [4] C.M.
Barsoum: International Journal of Fracture Vol. 11 (1975), p.167-169 [6] J.P.
Online since: July 2013
Authors: Ke Fa Zhou, Yan Fang Qin, Li Sun, Ming Jun Liu, Qian Feng Wang
Materials and Methods
Site Description.
Zhao: submitted to Journal of Shanxi Agricultural Sciences (2010) [6] C.H.
Tong: submitted to Journal of Jilin University (Earth Science Edition) (2006)
Yu: submitted to Journal of Beijing Normal University (Natural Science) (2007) [17] A.N.
Cheng: submitted to Journal of Anhui Agricultural Science (2010) [23] H.
Zhao: submitted to Journal of Shanxi Agricultural Sciences (2010) [6] C.H.
Tong: submitted to Journal of Jilin University (Earth Science Edition) (2006)
Yu: submitted to Journal of Beijing Normal University (Natural Science) (2007) [17] A.N.
Cheng: submitted to Journal of Anhui Agricultural Science (2010) [23] H.
Online since: June 2010
Authors: Jing Bo Guo, Fang Ma, Chein Chi Chang, Li Wei
Zhao: Journal of Zhejiang University SCIENCE A, Vol. 8
(2007), p. 1831-1838
Mukherji: Journal of Hazardous Materials Vol. 154 (2008), p. 63-72
Lin: Biochemical Engineering Journal Vol. 27 (2005), p. 95-103
Hamoda: Water Science and Technology Vol. 43 (2001), p. 321-326
Wang: Water Science and Technology Vol. 24 (1991), p. 197-213
Mukherji: Journal of Hazardous Materials Vol. 154 (2008), p. 63-72
Lin: Biochemical Engineering Journal Vol. 27 (2005), p. 95-103
Hamoda: Water Science and Technology Vol. 43 (2001), p. 321-326
Wang: Water Science and Technology Vol. 24 (1991), p. 197-213
Online since: April 2012
Authors: Jian Xing Zhang
The review on 3D human body modeling [J].Journal of Henan Polytechnic University, 2001(20)
Review on human body modeling 3D in garment CAD[J], Journal of Wuhan University of Science and Engineering, 2004(17)
[8] Baiqing Qu, Xu Shejiao.computer graphics [M], first edition, Xi'an, Xi'an Electronic and Science University PublishingAgency, in 2003 June, 168
Dedicated 3D CAD for garment modeling [J], Journal of materials processing technology, 2000(10)
[12] Xiaoyu Ma. 3D garment simulation technology research progress [71, Textile journal,2004(8).
Review on human body modeling 3D in garment CAD[J], Journal of Wuhan University of Science and Engineering, 2004(17)
[8] Baiqing Qu, Xu Shejiao.computer graphics [M], first edition, Xi'an, Xi'an Electronic and Science University PublishingAgency, in 2003 June, 168
Dedicated 3D CAD for garment modeling [J], Journal of materials processing technology, 2000(10)
[12] Xiaoyu Ma. 3D garment simulation technology research progress [71, Textile journal,2004(8).