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Materials Science Forum Vols. *** (2004) pp.201-205 online at http://scientific.net  2004 Trans Tech Publications, Switzerland Three-dimensional Finite Element Analysis of Metal Powder Compaction P.Q.
Li1,a 1 College of Mechanical Engineering, South China University of Technology, Guangzhou 510640, P.R.
Since Advances in Materials Manufacturing Science and Technology 202 the yield surface shouldn't exceed von Mises yield surface, δ should be no larger than A/3.
Materials Science Forum Vols. *** 203 The above constitutive relation was implemented into user subroutines of MSC.Marc.
Acknowledgements The authors are grateful for the financial support from National Advanced Technology Research and Development Project (863 project, 2001AA337010), National Natural Science Foundation of China (Key Project, 50135020), and the Natural Science Foundation of Guangdong Province (Research Group Project, 003019).

Finite element analysis of optimum back pressure during equal channel angular pressing Feng-jian SHI1, 2, a ， Lei-gang WANG 2, b 1 Provincial Key Lab of Advanced Welding Technology, Jiangsu University of Science and Technology, Zhenjiang 212003, PR China 2 School of Material Science and Engineering, Jiangsu University, Zhenjiang 212013, PR China a shifengjian@126.com, b lgwang@ujs.edu.cn Keywords: equal channel angular pressing; finite element analysis; back pressure; strain distribution.
Forum Vol. 357-359 (2001), p. 489 [3] S.H.
Forum Vol. 539-543 (2007), p. 86 [4] T.L.
Forum Vol. 503-504 (2006), p. 37 [12] P.B.
Forum Vol. 519-521 (2006), p. 1215 [16] Y.

The series of NOCMAT Conferences have proven to be a leading forum where scholars, governmental and non-governmental agencies, practitioners exchange innovations of low energy cement technologies, new materials and systems, and innovative material/structural technologies such as bamboo, natural fibers, etc. towards costeffective, durable, environment-friendly, energy efficient and sustainable construction.
The 15th NOCMAT provided an international forum for information dissemination and exchange, discussions and debates on research and practice related to innovative construction materials and technologies with objectives for sustainable development.
The conference attracted a wide range of academics, scientists, researchers, students, builders, designers, NGOs, policy makers and other industrialists from a wide variety of backgrounds, including fields of architecture, engineering, materials, sustainable and ecological technologies, biomaterials, materials sciences, environmental engineering and government agencies, etc.
Specific conference themes included: lower carbon cements and concretes; advanced vegetal fibre composites in construction; innovative use of plant based materials such as bamboo, straw, hemp, curaua, sisal; timber materials and engineering; lime based materials; stone, unfired clay and earthen architecture.

Leaded by social and technological problems in the modern stage of e-learning systems the authors propose a low cost prototype based on an advanced collaboration architecture that provides the lecturers and learners with educational services in different domains such as engineering, or sciences.
Section III is dedicated to the advanced approaches to be implemented for special forms of education.
The collaborative learning cloud has been quickly adopted for engineering, especially electrical engineering, applied electronics, telecommunications and computer science.
Manseur, A Synchronous Distance Learning Program Implementation in Engineering and Mathematics, Proceedings of the 39th ASEE/IEEE Frontiers in Education Conference, San Antonio, Texas, (2009) 1-6
Chen, A Problem-based Learning Approach to Teaching an Advanced Software Engineering Course, Proceedings of the 2nd International Workshop on Education Technology and Computer Science, (2011) 252-255

Preface The international conference on advanced design and manufacturing engineering series provides a forum for accessing to the most up-to-date and authoritative knowledge from both industrial and academic worlds, sharing best practice in the field of advanced design and manufacturing engineering.
Following the success of the previous conferences, the 3rd International Conference on Advanced Design and Manufacturing Engineering (ADME 2013) was taken place in Anshan, China, in July, 2013.
This conference successfully brought together scientists and engineers from industry and academia and provided a forum for exchange of ideas, cooperation and future directions by means of keynote speeches, regular presentations and a round-table discussion.
Studies presented in this book cover these topics: Advanced Manufacturing Technology, Advanced Equipment Manufacture, Fluid and Flow Engineering, Dynamic Systems and Analysis, Machinery Dynamics and Dynamic Modelling, Advanced Computer-Aided Design and Modelling Technologies in Mechanical Engineering and Mechanisms, System Analysis and Industrial Engineering, Innovative Design Methodology and Product Design, Intelligent Optimization Design and Reverse Engineering, Mechatronics, Automation and Control, Detection Technologies, Industrial Robotics and Machine Vision, Navigation and GPS Technology, Sensor Technologies, Measurement and Monitoring Technologies, Power, Energy, Microelectronic Technology and Embedded System.
The editors The 3rd International Conference on Advanced Design and Manufacturing Engineering (ADME 2013) Organized by: University of Science and Technology Liaoning, China Co-organized by: Metal association of Liaoning, China Anshan Iron and Steel Group Corporation, China Saitama Institute of Technology, Japan NanyangTechnological University, Singapore Chinese University of Hongkong, HK National Formosa University, Taiwan Conference Organization Chairman Prof.

The state investment in low carbon Tourism far below the policy investment, science and technology is the first productivity, excellent environmental protection technology plays an important role in promoting a low carbon economy, guarantee and no application of advanced technology, will not have the production and consumption of carbon emission reduction.
In addition, scenic construction still mainly traditional construction methods and building materials, the lack of advanced environmentally friendly materials Tourists' cognitive degree is not deep.
Second, increasing capital investment in low carbon advanced technologies and the tilt of the policy, to establish the tourism enterprises as the main body, combining the economic model, speed up the transformation of low carbon Tourism technology. [4] Third, to strengthen scientific and technological cooperation between international, actively introduce foreign advanced low-carbon technology and management experience, to promote the innovation of energy saving technology in our country, the formation of good technical support for the development of low carbon tourism.
Conclusions Low-carbon tourism is a guarantee for achieving sustainable development, the development of low-carbon tourism is a long-term system engineering, not overnight, you need to go through the whole long-term exploration of tourism and related industries, although many of the problems now facing, we believe China must embark on a suitable low-carbon development, tourism into the tourism industry in the true sense, to achieve harmony between man and nature, and contribute to the Chinese low carbon economy.
Forum Vol. 1(2014), p. 240-241 [3] Yu Zhang: Dajiang weekly forum .Forum Vol. 2(2011), p. 3 [4] Ping Sun : Japan's low-carbon economy Experience and Inspiration, edtied by Chinese Market (2011), In Chinese

In accordance with the requirements of materials science and engineering course, the undergraduate graduation design of the materials professional is implemented.
For the engineering students, the best topics of graduation project are the engineering design, experimental research and actual operation.
The students may learn more use of advanced testing techniques to solve practical problems in production.
Zang: Chemical Engineering & Equipment Vol 10 (2008), p.186 [4] X.
Tan: Higher Education Forum Vo, 11 (2009), p. 40 [7] C.

Padding, Non-spherical particles in a pseudo-2D fluidised bed: modelling study, Chemical Engineering Science, 192 (2018) 1105-1123
Archives of Materials Science and Engineering, 94 2 (2018) 49–54
Schott, Replicating cohesive and stress-history-dependent behavior of bulk solids: feasibility and definiteness in DEM calibration procedure, Advanced Powder Technology, 32 (2021) 1532-1548
IOP Conference Series: Materials Science and Engineering, 907 1 (2020) № 012060
ARPN Journal of Engineering and Applied Sciences, 15 15. (2020) 1657–1665

The objective of ICAMR 2012 was to provide a forum for the discussion of new developments, recent progress and innovations in the field of Materials Science.
The papers are divided into twenty-two sections, covering such topics as materials behaviour, casting and solidification, coatings and surface engineering, composites, machining technology, nanomaterials, biomedical manufacturing, sustainable manufacturing processes, manufacturing planning and scheduling, modelling and simulation, computer-aided design and engineering, semiconductor materials engineering, laser-based manufacturing and mechanical and electronic engineering control.

Preface The Japanese-Mediterranean Workshop on Applied Electromagnetic Engineering for Magnetic, Superconducting and Nanomaterials (JAPMED), constituting a landmark in the development of materials, manufacturing and electrical engineering, is held every two years, jointly organized by the National Technical University of Athens (Laboratory of Manufacturing Technology and Laboratory of Electrical Machines) and the Japan Society of Applied Electromagnetics and Mechanics.
It provided a forum for specialists from universities, research centers and industry of various countries worldwide to establish cooperation, to share knowledge and experience and the cross-fertilization of new ideas and developments in the design, analysis, new materials utilization and optimisation techniques in the areas of applied electromagnetics and manufacturing of advanced materials from macro-, micro- to nanoscale and their industrial applications in modern technologies in nanotechnology, electricity/electronics, transportation, bioengineering, energy and environment.
Furthermore, modern advanced research areas, like nanotechnology/nanomaterials, ultraprecision engineering and bioengineering, are also included in order to enhance cooperation towards these advanced technologies, which may greatly affect our lives in the future.