Search results

[11].Ma S K,Yang J,Wu B B.Effects of MPP on the Sound Absorptive Property of Porous Materials[J].Journal of Qingdao University(Natural Science Edition). 2016,29(3):79-82,88
Journal of Mechanical Engineering. 2016,52(13):68-78
Chinese Journal of Raremetals. 2015,39(1):49-54
Acoustic manual[M].Beijing Science Press,2004
Noise control[M].Beijing Science Press,1987.

Chen: A simple flow rule for characterizing nonlinear behavior of fiber composites, Journal of Composite Material, Vol. 23 (1989), pp.1009-1020
Sun: Characterization of elastic-viscoplastic properties of an AS4/PEEK thermoplastic composite, Journal of Composite Material, Vol. 25 (1991), pp.1277-1296
Sun: A plastic potential function suitable for anisotropic fiber composites, Journal of Composite Material, Vol. 27 (1993), pp.1379-1390
Shen, etc: Numerical analysis of interlaminar stresses of angle-ply AS4/PEEK laminate with a central hole, Journal of Thermoplastic Composite Materials, Vol. 22 (2009), pp.383-406
Shen: Numerical analysis and experimental validation of interlaminar stresses of quasi-isotropic APC-2/AS-4 laminate with a central hole loaded in tension, Journal of Thermoplastic Composite Materials, Vol. 23 (2010), pp.413-433.

Teaching of Materials and Welding Engineering to Today's Postgraduate Mechanical Engineers A.
Valiulis Department of Materials Science and Welding, Vilnius Gediminas Technical University, Basanaviciaus 28, LT-03227 Vilnius, Lithuania Algirdas.valiulis@adm.vtu.lt Keywords: materials engineering, welding engineering, modeling of physical processes.
A particular example is the combining in one study program, studies of different engineering and structural materials (including composite materials, ceramics, polymers, etc.) and methods and technologies of brazing, joining by welding, bonding by glue, etc of these materials.
Valiulis: Materials Science, Vol. 6, No 3, Kaunas, Technologija (2000), p. 163 [5] L.
Višniakov: Materials Science, Vol. 9, No 2, Kaunas, Technologija (2003), p. 164

Materials Science Forum Vols. *** (2004) pp.401-404 online at http://scientific.net  2004 Trans Tech Publications, Switzerland Research Status Quo of Simulation Design Methods for Ceramic Tool Materials L.Q.
With the development of material and computer science, the higher requirement of the industry on ceramic materials, the computer aided design of ceramic materials is highly imperative.
Currently, Advances in Materials Manufacturing Science and Technology 402 they are mainly used in the areas such as pattern recognition and classification, function approximation, data compressing and predicting etc.
Mukherjee: Computational Material Science Vol. 5 (1996), p. 307 [2] N.
He: Materials for Mechanical Engineering Vol. 26 (2002), p. 7 [4] J.Q.

At present, the most applications in surface modification of materials is type I collagen, future research will be a variety of surface modification of materials for composite materials, which will play complementary roles, as well as gene therapy and the development of nanometer materials, it will become a hot issue in the field of bone tissue engineering.
Therefore, selecting suitable materials for surface modification, targeted to the matrix scaffold materials for surface modification and surface modification of material surface, improve the cell adhesion and promotes cell proliferation is the scaffold materials for bone tissue engineering research important content.
The importance of bone tissue engineering materials for surface modification The bone tissue can be regarded as a cell of the multiphase composite material from the point of view of material science and engineering.
Ideal surface modification should take into consideration the surface topology, specific identification, hydrophilic and hydrophobic protein adsorption equilibrium, and other aspects of functional new tissues can be.Therefore, surface modification of biomaterials is a complex systems engineering, needs both material science and biological science needs, realize optimization.At present, most applications in surface modification of materials is of type I collagen, future research will be a variety of surface modification of materials for composite materials to play complementary roles, as well as gene therapy and the development of nanometer materials will become a hot issue in the field of bone tissue engineering.
Journal of Orthopaedic Research, Volume 20, Issue 5, September 2002, Pages 1009-1015.

Preparation PET Hybrided Materials by In Situ Polymerization for Delustered Fibers Mahgoub Osman Montasera, Jialiang Zhoub, Mohamed Nourreinc, Chong Lid, Hengxue Xiange, Bin Sunf*, Meifang Zhug* State Key Laboratory for Modification of Chemical Fibers and Polymer Materials, College of Materials Science and Engineering, Donghua University, Shanghai 201620, China amontaserali1987@gmail.com, bzjl19871217@126.com, cnourrein2000@hotmail.com, d897837544@qq.com, ehengxyexiang@163.com, fsunbin@dhu.edu.cn, gzhumf@dhu.edu.cn Keywords: Hybrid materials, PET, TiO2, Dull fiber, In Situ polymerization.
Experimental Materials.
Synthesis and non-isothermal crystallization behavior of PET/surface-treated TiO2 nanocomposites, Journal of Macromolecular Science, Part B, 2008, 47(6): 1117
Nucleation effect of surface treated TiO2 on Poly (trimethylene terephthalate)(PTT) nanocomposites, Journal of applied polymer science, 2013, 127(3): 1909
Crystallization behavior and UV‐protection property of PET‐ZnO nanocomposites prepared by in situ polymerization, Journal of applied polymer science, 2009, 114(2): 1303.

Materials Science Forum, 968 MSF, 361–367
In Materials Science Forum, 1006, pp. 55–61
Materials Science Forum, 1006, 47–54
Materials Science Forum, 1006 MSF, 47–54
Materials Science Forum, 1038, 33–39

Especially, it has put in a lot of efforts in R&D of new materials, changes in functions, and innovations in design, stepping into the service industry from the manufacturing industry.
Items of the same shapes and colors but different materials and costs may lead to different feelings.
Therefore, external elements such as forms, colors, materials, finishing, and interfaces of products become important elements for innovative design and development.
N1 N2 N3 N4 N5 N6 N7 N8 N9 N10 N11 N12 N13 N14 N15 N16 N17 Figure 1 Drawings of extended creative product designs with hosiery materials Conclusions In this study, the drawings of creative ideas were created according to the manufacturer’s demands regarding extended innovative product design with hosiery materials.
Jiang, Innovative Product Design: Beginning with Understanding Colors, Materials, and Finished Works, DrMaster Press Co., Ltd., Taipei (2011)

Permeability of Packaging Materials Sheng Zhang1, Wenchao Gu2, Zhengyong Cheng1, Wenjuan Gu1, a*, Ying Li1, 1Faculty of Mechanical and Electrical Engineering, Kunming University of Science and Technology, Chenggong, Kunming City, China 2School of Tourism and Geographical Science, Yunnan Normal University, Kunming City, China a*guwenjuan@whu.edu.cn Keywords: packaging material, permeability, barrier, food packaging Abstract.
Several commonly used packaging materials were researched in this paper.
Permeability of Packaging Materials The Gas Permeability.
The moisture-resistance property depends on the packaging materials.
[3] Oi-Wah Lau, Siu-Kay Wong, Contamination in food from packaging material, Journal of Chromatography A, 882 (2000) 255–270

Journal of Tongji University, 2008, 11(5) 5-8, in Chinese
Research on phase change energy storage wall materials[J].
Journal of Jiangsu University, 2011, 12 (3) 39-42, in Chinese
Journal of Hunan University, 2011, 38 (4), 11-16, in Chinese
New Building Materials, 2011，87（2），87-92, in Chinese.