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Online since: April 2016
Authors: Ming Long Ma, Yong Jun Li, Jia Wei Yuan, Guo Liang Shi, Chun Fang Lu, Xing Gang Li, Kui Zhang
Materials science and engineering: A. 125 (1990) 249-265
Research progress of advanced magnesium rare-earth alloys.
Materials for Mechanical Engineering. 34 (2010) 10-12
Journal of Jilin University (Engineering and Technology Edition). 39 (2009) 159-163
Materials for Mechanical Engineering. 35 (2011) 47-50
Research progress of advanced magnesium rare-earth alloys.
Materials for Mechanical Engineering. 34 (2010) 10-12
Journal of Jilin University (Engineering and Technology Edition). 39 (2009) 159-163
Materials for Mechanical Engineering. 35 (2011) 47-50
Online since: August 2023
Authors: Katerina Lebedeva, Anna Cherkashina, Tetyana Tykhomyrova, Vladimir Lebedev
Tanaka Designing smart biomaterials for tissue engineering, International Journal of Molecular Sciences. 19 (2018) 17
Lelkes, On the road to smart biomaterials for bone research: Definitions, concepts, advances, and outlook, Bone Research. 9 (2021):1–16
Alvarez, J.G Hardy., M.F Desimone, Stimuli-responsive materials for tissue engineering and drug delivery, International Journal of Molecular Sciences. 21 (2020) 4724
Ferguson, Reinforcement of mono- and bi-layer Poly(Ethylene Glycol) hydrogels with a fibrous collagen scaffold, Annals of Biomedical Engineering. 43 (2015) 2618–2629
Saimbetova, Design and Research of Eco-Friendly Polymer Composites, Materials Science Forum. 1006 (2020) 259–266
Lelkes, On the road to smart biomaterials for bone research: Definitions, concepts, advances, and outlook, Bone Research. 9 (2021):1–16
Alvarez, J.G Hardy., M.F Desimone, Stimuli-responsive materials for tissue engineering and drug delivery, International Journal of Molecular Sciences. 21 (2020) 4724
Ferguson, Reinforcement of mono- and bi-layer Poly(Ethylene Glycol) hydrogels with a fibrous collagen scaffold, Annals of Biomedical Engineering. 43 (2015) 2618–2629
Saimbetova, Design and Research of Eco-Friendly Polymer Composites, Materials Science Forum. 1006 (2020) 259–266
Online since: August 2004
Authors: Norikazu Ooka, Makoto Ebata
Norikazu Ooka
1,2, Makoto Ebata
2,3
1
Senior Technical Advisor, The Japan Welding Engineering Society
2
Working Group member for Promotion of Laboratory Accreditation,
The Japan Welding Engineering Society(JWES)
3
General Manager, Advanced Material Dept., Mitsui Engineering & Shipbuilding Co., Ltd.
However, it is also a fact that the scheme has such various subjects as improvement of clearness and impartiality, transition to an internationally acceptable accreditation scheme, expansion of applicable fields in addition to architectural steel structures, all-out adoption of quality system, and morals. [1][2] In response to such subjects, the Working Group for Promotion of Laboratory Accreditation of The Japan Welding Engineering Society has worked for establishing a new accreditation scheme for nondestructive testing organizations.
Abbreviations: IAF: International Accreditation Forum PAC: Pacific Accreditation Cooperation ILAC: International Laboratory Accreditation Cooperation MRA: Mutual Recognition Arrangement APLAC: Asia-Pacific Laboratory Accreditation Cooperation MS: Management System Figure 1.
Various schemes for conformity assessment Title of Publication (to be inserted by the publisher) The new laboratory accreditation scheme for nondestructive testing organizations (referred to as the Laboratory Accreditation Scheme) is to be co-managed by The Japan Accreditation Board for Conformity Assessment (referred to as JAB) which is a laboratory accreditation body in Japan and The Japan Welding Engineering Society (referred to as JWES) which is delegated by JAB for assessment of laboratories.
The Japan Accreditation Board for Conformity Assessment (JAB) The Japan Welding Engineering Society (JWES) Figure 3.
However, it is also a fact that the scheme has such various subjects as improvement of clearness and impartiality, transition to an internationally acceptable accreditation scheme, expansion of applicable fields in addition to architectural steel structures, all-out adoption of quality system, and morals. [1][2] In response to such subjects, the Working Group for Promotion of Laboratory Accreditation of The Japan Welding Engineering Society has worked for establishing a new accreditation scheme for nondestructive testing organizations.
Abbreviations: IAF: International Accreditation Forum PAC: Pacific Accreditation Cooperation ILAC: International Laboratory Accreditation Cooperation MRA: Mutual Recognition Arrangement APLAC: Asia-Pacific Laboratory Accreditation Cooperation MS: Management System Figure 1.
Various schemes for conformity assessment Title of Publication (to be inserted by the publisher) The new laboratory accreditation scheme for nondestructive testing organizations (referred to as the Laboratory Accreditation Scheme) is to be co-managed by The Japan Accreditation Board for Conformity Assessment (referred to as JAB) which is a laboratory accreditation body in Japan and The Japan Welding Engineering Society (referred to as JWES) which is delegated by JAB for assessment of laboratories.
The Japan Accreditation Board for Conformity Assessment (JAB) The Japan Welding Engineering Society (JWES) Figure 3.
Online since: April 2021
Authors: Igor A. Savin, Renat V. Gavariev, Ksenia N. Gavarieva
Series: Materials Science and Engineering 240 (2017)
Advanced casting methodologies: inert environment vacuum casting and solidification, die casting, compocasting, and roll casting, casting, semi-solid forming and hot metal forming, (2014) Comprehensive Materials Processing, vol. 5, Elsevier Ltd., pp. 3-37
Series: Materials Science and Engineering 570 (2019) 012072
IOP Conference Series: Materials Science and Engineering, 86 (1), 2015
International Journal of Engineering and Technology(UAE) 7(4), 2018, pp. 71-73/ [15] Gilman, V.
Advanced casting methodologies: inert environment vacuum casting and solidification, die casting, compocasting, and roll casting, casting, semi-solid forming and hot metal forming, (2014) Comprehensive Materials Processing, vol. 5, Elsevier Ltd., pp. 3-37
Series: Materials Science and Engineering 570 (2019) 012072
IOP Conference Series: Materials Science and Engineering, 86 (1), 2015
International Journal of Engineering and Technology(UAE) 7(4), 2018, pp. 71-73/ [15] Gilman, V.
Online since: February 2015
Authors: Mohd Hamdi Abdul Shukor, Sharifah Adzila Syed Abu Bakar, Iis Sopyan, Ramesh T. Subramaniam
Hamdi4d
1Department of Materials Engineering and Design, Faculty of Mechanical and Manufacturing
Engineering, Universiti Tun Hussein Onn Malaysia,
86400 Batu Pahat, Johor
2,4Centre of Advanced Manufacturing & Material Processing (AMMP), Department of
Mechanical Engineering, Faculty of Engineering, University of Malaya,
50603 Kuala Lumpur, Malaysia
3Department of Manufacturing and Materials Engineering, Faculty of Engineering, International
Islamic University Malaysia
aadzila@uthm.edu.my, bramesh79@um.edu.my, csopyan@iium.edu.my, dhamdi@um.edu.my
Keywords: Magnesium, Mechanochemical, Hydroxyapatite, X-ray Diffraction, Fourier Transform Infrared.
Forum. 694 (2011) 118-122
Forum. 694 (2011) 118-122
Online since: May 2012
Authors: Xiao Lei Zhang, Xiao Juan Li
2-D FLOOD ROUTING SIMULATION ON THE LOWER YELLOW RIVER FROM HUAYUANKOU TO JIAHETAN BASED ON MIKE21 SOFTWARE
Xiaolei Zhang1,2,a, Xiaojuan Li1,b
1College of Water Resources and Hydroelectric Engineering, Wuhan University, Wuhan, 430072, China
2North China University of Water Resources and Electric Power, Zhengzhou, 450011, China
azhangxiaolei@ncwu.edu.cn, b597724073@qq.com
Keywords: MIKE 21, 2-D mathematical model, the Lower Yellow River, boundary condition, flood routing.
According to the research tasks of numerical simulation, the characteristics of morphologies of river channels in the Lower Yellow River reaches and other factors such as controlling hydraulic engineering, production dikes and embankments, the model scope is selected.
[2] Hongtao Wan, Chenghu Zhou, Yingxiang Wu and et al. in: ADVANCES IN WATER SCIENCE, 2002, 13(2): p.215-p.222 (in Chinese)
Expert forum on a General Plan for Lower Yellow River Management[C].
According to the research tasks of numerical simulation, the characteristics of morphologies of river channels in the Lower Yellow River reaches and other factors such as controlling hydraulic engineering, production dikes and embankments, the model scope is selected.
[2] Hongtao Wan, Chenghu Zhou, Yingxiang Wu and et al. in: ADVANCES IN WATER SCIENCE, 2002, 13(2): p.215-p.222 (in Chinese)
Expert forum on a General Plan for Lower Yellow River Management[C].
Online since: May 2013
Authors: Abel Cherouat, Houman Borouchaki, Jie Zhang
The numerical results prove that the proposed methodology is helpful for advanced numerical simulation of metal milling in three dimensions.
[2] G.M.Pittala, M.Monno, A new approach to the prediction of temperature of the workpiece of face milling operations of ti-6al-4v, Applied Thermal Engineering 31 (2011) 173–180
[7] A.Cherouat, L.Moreau, H.Borouchaki, Advanced numerical simulation of metal forming processes using adaptive remeshing procedure, Material Science Forum 614 (2009) 27–33
Cook, Fracture characteristics of three metals subjected to various strains, strain rates, temperatures and pressure, Engineering Fracture Mechanics 21 (1985) 31-48
Caperaa, A 3D transient numericam model of milling, IMechE Journal of Engineering Manufacture, Part B, Vol 215(2001), pp. 1-4
[2] G.M.Pittala, M.Monno, A new approach to the prediction of temperature of the workpiece of face milling operations of ti-6al-4v, Applied Thermal Engineering 31 (2011) 173–180
[7] A.Cherouat, L.Moreau, H.Borouchaki, Advanced numerical simulation of metal forming processes using adaptive remeshing procedure, Material Science Forum 614 (2009) 27–33
Cook, Fracture characteristics of three metals subjected to various strains, strain rates, temperatures and pressure, Engineering Fracture Mechanics 21 (1985) 31-48
Caperaa, A 3D transient numericam model of milling, IMechE Journal of Engineering Manufacture, Part B, Vol 215(2001), pp. 1-4
Online since: November 2008
Authors: Yan Ching Jean, Hong Min Chen, L. James Lee, Jin Tao Yang, Xiao Hong Gu, Wei Song Hung, Kueir Rarn Lee, Juin Yih Lai, Yi Ming Sun, Chien Chieh Hu
James Lee
2,c
, Jintao Yang2,d, Xiaohong
Gu,1,3,e
, Wei-Song Hung4,f,, Kueir-Rarn Lee4,5,g
, Juin-Yih Lai4,5,h
, Yi-Ming
Sun4,6,i, Chien-Chieh Hu4,7,j
1
Department of Chemistry, University of Missouri-Kansas City, Kansas City, Missouri, 64110, USA
2
Department of Chemical and Biomolecular Engineering, The Ohio State University, Columbus,
Ohio 43210, USA
3Materials and Construction Research Division, National Institute of Standards and Technology,
Gaithersburg, MD 20899
4
R&D Center for Membrane Technology, Chung Yuan Christian
University, Chung-Li, 32023, Taiwan
5
Department of Chemical Engineering, Chung Yuan Christian University, Chung-Li, 32023, Taiwan
6
Department of Chemical Engineering and Materials Science, Yuan Ze
University, Chung-Li, 32023, Taiwan
7
Department of Chemical Engineering, Nanya Institute of Technology,
Chung-Li, 32023, Taiwan
a
jeany@umkc.edu,b chenho@umkc.edu, cleelj@chbmeng.ohio-state.edu, dyang.1119@osu.edu,
e
xiaohong.gu
Positron and Positronium chemistry has been pursued and advanced by many scientists and engineers in both fundamental understanding of Positronium atom and its applications to chemical and polymeric systems during the last decade.
Future perspectives of applying Positronium chemistry to membrane science and technology and other related disciplines of nanotechnology, chemical engineering, materials science, energy research, molecules with positrons, biological and medical sciences appear to be promising.
The success of these developments will benefit the application of PAS to other related disciplines of nanotechnology, chemical engineering, materials science, energy research, molecules with positrons, biological and medical sciences.
Jean, Materials Science Forum 445-446 (2004) p. 274 12.
Positron and Positronium chemistry has been pursued and advanced by many scientists and engineers in both fundamental understanding of Positronium atom and its applications to chemical and polymeric systems during the last decade.
Future perspectives of applying Positronium chemistry to membrane science and technology and other related disciplines of nanotechnology, chemical engineering, materials science, energy research, molecules with positrons, biological and medical sciences appear to be promising.
The success of these developments will benefit the application of PAS to other related disciplines of nanotechnology, chemical engineering, materials science, energy research, molecules with positrons, biological and medical sciences.
Jean, Materials Science Forum 445-446 (2004) p. 274 12.
Online since: November 2015
Authors: Denise Bellisario, Fabrizio Quadrini, Loredana Santo, Luigi Ciampoli
International Journal of Manufacturing, Materials and Mechanical Engineering. 1 (2011) 10-20
Polymer-Plastics Technology and Engineering. 51 (2012) 560-567
Santo, Recent Developments in the Field of Shape Memory Epoxy Foams, Materials Science Forum. 783 – 786 (2014) 2523-2530
Advanced Materials Research. 783-786 (2014) 2509-2516
Villadei, Shape Memory Composites for Self-Deployable Structures in Aerospace Applications, Procedia Engineering. 88, C (2014) 42-47.
Polymer-Plastics Technology and Engineering. 51 (2012) 560-567
Santo, Recent Developments in the Field of Shape Memory Epoxy Foams, Materials Science Forum. 783 – 786 (2014) 2523-2530
Advanced Materials Research. 783-786 (2014) 2509-2516
Villadei, Shape Memory Composites for Self-Deployable Structures in Aerospace Applications, Procedia Engineering. 88, C (2014) 42-47.
Online since: August 2011
Authors: Wen Tie Niu, Wei Guo Gao, Da Wei Zhang, Guang Li
An Adaptive Changeability Approach of Flow Path Feature in Hydraulic Manifold Blocks Design
Guang Li1,2, Wentie Niu1,a, Dawei Zhang1 and Weiguo Gao1
1School of Mechanical Engineering, Tianjin University, Tianjin 300072, China
2School of Packaging & Printing Engineering, Tianjin University of Science & Technology, Tianjin 300222, China
aCorresponding author, niuwentie@tju.edu.cn
Keywords: Hydraulic Manifold Blocks; Flow path feature pattern; Adaptive changeability; NSGA2
Abstract.
At present, feature technology is wildly used in production modeling for it can associate functions and rich engineering information with geometric models.
Wong: International Jounal of Advanced Manufacturing Technology, Vol. 16(3), (2000), p.182 [2] Ye Bing and Chen Ying: China Mechanical Engineering, Vol. 13(16), (2002), p.1364 (In Chinese) [3] W.G.
Zhang: Materials Science Forum, Vol. 628-629 (2009), p.275 [4] Ma Y.S. and Tong T.: Computers in Industry, Vol. 51(1), (2003), p.51 [5] Ruiyi Su, XuWang, Liangjin Gui and Zijie Fan: Structural and Multidisciplinary Optimization, Vol. 43, (2011), p.275 [6] Helen L.
At present, feature technology is wildly used in production modeling for it can associate functions and rich engineering information with geometric models.
Wong: International Jounal of Advanced Manufacturing Technology, Vol. 16(3), (2000), p.182 [2] Ye Bing and Chen Ying: China Mechanical Engineering, Vol. 13(16), (2002), p.1364 (In Chinese) [3] W.G.
Zhang: Materials Science Forum, Vol. 628-629 (2009), p.275 [4] Ma Y.S. and Tong T.: Computers in Industry, Vol. 51(1), (2003), p.51 [5] Ruiyi Su, XuWang, Liangjin Gui and Zijie Fan: Structural and Multidisciplinary Optimization, Vol. 43, (2011), p.275 [6] Helen L.