Search results

According to the related theory of material mechanics, the displacement denotes the first derivative of the strain.
The material of beam is made up of steel Q345, Young’s modulus E=1.92×1011N/m2, density ρ=7800kg/m3, Poisson’s ratio μ= 0.3.
Acknowledgements This work was financially supported by the National Natural Science Foundation of China (No.50578018).
Sinou: European Journal of Mechanics A-Solid Vol.28 (2009), p. 75-85 [3] E.
Cremona: Journal of Sound and Vibration Vol.292 (2006), p. 179-202 [5] Youliang Ding, Aiqun Li and Changqing Miao: Engineering Mechanics Vol. 24 (2007), p. 99-103 [6] Yan Deng, Puchiang Yan: Journal of Tsinghua University Vol.40 (2000), p. 123-127 [7] Deqing Guan, Wei Pan: Journal of Transport Science and Engineering Vol. 25 (2009), p. 35-39 [8] Deqing Guan, Hongwei Ying and Xiaolin Zhong: Applied Mechanics and Materials Vol. 71-78 (2011), p. 4078-4081

About 50wt% of materials used in gas turbine compartment of an aerospace engine are nickel based super alloys [2].
Reference [1] E.O Ezugwu, I.R Pashby, “High speed milling of nickel based super alloys”, Journal of Materials processing technology, 33(1992) p429-437
Bonney, “An overview of aerospace engine alloys”, Journal of material processing technology, 134 (2003) p233-253
Teo “The Machinability of Inconel 718”, Journal of material processing technology, 63 (1997) 199-204
Daniel Kirby, “Surface roughness optimization in an end-milling operation using the Taguchi design method”, Journal of Materials Processing Technology, 184 (2007), p. 233

Production of specimens and test processes 2.1 Raw materials and equipments Aggregate frameworks used in FRPC are granites.
International Journal of Cement Composites and Lightweight Concrete. 2 (1985), p. 49 4.
International Journal of Cement Composites and Lightweight Concrete. 8 (1983), p. 203 5.
Ma Xingpeng: Modern Deteciton Technology ,(Higher Education Press, China, 2004) (in Chinese) Acknowledgements The work described in this paper is suported by Science and Technology Agency of Henan Province, the 2010 Science and Technology Development Plan of Henan Province (No. 102102210238).
Corresponding author: Wenfeng Bai (1980-), instructor in Huanghuai University, Ph.D. of Shandong University, majoring in composite materials.

Van Den Boogaard: Key Engineering Materials, Vol. 344 (2007), p. 519
Duflou: Key Engineering Materials, Vol. 410 (2009), p. 401
Habraken: Key Engineering Materials, 2007.
Van Houtte: submitted to International Journal of Material Forming (2008)
Vantomme: submitted to High Performance Structures and Materials III (2006)

Since 1980's, there is an exceedingly growing interest in physical understanding and numerical modeling of liquid-solid phase changes in multiconstituent materials of the metallic, ceramics and polymer types.
Stomp: Metallurgical and Materials Transactions A Vol. 29A (1998), p. 617
Mencinger: Journal of Computational Physics Vol. 198 (2003), p. 243-264
Shen: Computer Modelling in Engineering & Sciences Vol. 3 (2002), p. 11-52
Shen, The Meshless Method, Tech Science Press, Encino, 2002

Preface This is the proceedings of the selected papers presented at 12th IUMRS International Conference on Advanced Materials (IUMRS-ICAM2013) held in Qingdao, China, Sept. 22-28, 2013.
The IUMRS International Conference on Advanced Materials is one of the most important serial conferences of the International Union of Materials Research Societies (IUMRS).
IUMRS-ICAM 2013 had 33 Symposia covering five fields of Energy and environmental materials; Structural materials; Functional materials; Nano-scale and amorphous materials; and Materials processing and Genomic engineering.
By recommendation of symposium organizers and after peer reviewing 235 papers are published on the journal of "Materials Research Innovation", 308 papers are published in the present proceedings, which divided into three volumes of Part 1: Energy, Environment and Functional Materials Part 2: Structural Materials Part 3: Nano-Scale Materials, Materials Processing and Genomic Engineering This is the volume for Part 1 including 37 papers selected from 7 symposia of Area A (Energy and environmental materials) and 43 papers from 8 symposia of Area C (Functional materials).
Editors IUMRS-ICAM 2013 12th IUMRS International Conference on Advanced Materials September 22-28, 2013, Qingdao, China Organized by Chinese Materials Research Society(C-MRS) International Union of Materials Research Societies (IUMRS) Supported by Ministry of Science and Technology of China China Association for Science and Technology National Natural Science Foundation of China Chinese Academy of Sciences Chinese Academy of Engineering Government of Qingdao City, Shandong Province, China American Institute of Physics

The Effects of Nano Pt/Carbon Black Compound Coating on the Electro-catalysis Properties of the Graphite Electrode Lou Baiyanga, Zhou Hanb and Xu Binc Institute of Materials and Surface Engineering, Zhejiang University of Technology, Hangzhou 310014, P.R.
Introduction Direct alcohols fuel cells have become one of the hotspots of international materials and energy fields because of its merit of abundant resources, high theoretical energy density and convenience in storing and carrying [1-3], especially the direct methanol fuel cell and the direct ethanol fuel cell have been concerned and studied [4-6].
Experimental materials and methods The basic material of specimen is graphite electrode.
[2] Tian Jian-hua, Gao Peng-fei, Zhang Zhi-yuan, et al: International Journal of Hydrogen Energy Vol.33(2008),p.5686 [3] Zhenhai Wen, Qiang Wang et al: Electrochemistry Communications Vol.10 (2008), p.84 [4] B.
Williams: Journal of Power Sources Vol.83 (1999),p. 15 [5] Zhou W J, Li W Z, Song S Q, et al: Journal of Power Sources Vol.131 (2004),p.217 [6] Ribadeneira E E, Hoyos B A: Journal of Power Sources Vol.180 (2008),p.238 [7] Zheng Zhong, Xu Bo, Huang Lu, et al: Solid State Sciences, Vol.10 (2008),p.316

The geometry detail is shown in Fig. 3, and material properties in Table 1.
Acknowledgement This research was supported by the National Natural Science Foundation of China (50909021, 51169003), the Major Projects of Guangxi Natural Science Foundation (2012GXNSFEA053002), the Systematic Project of Guangxi Key Laboratory of Disaster Prevention and Structural Safety (2012ZDX05).
References [1] Don ZR, Zhao QF and Song CC: Journal of Pressure Vessel Technology, Vol. 112 (1990), p. 57-64
[2] Wei Zhang, Hegao Wu, Kai Su: Journal of Hydroelectric Engineering, Vol. 24(2005), p. 70-74, in Chinese
[3] Wei Zhang, Hegao Wu: Journal of Hydroelectric Engineering, 27(2008), p. 73-78, in Chinese

Thus, these heavy metals are introduced naturally through the modification of parent materials, and result from various anthropogenic activities, such as mining and smelting.
Materials and methods 2.1 Study area The study area is the gold site of the locality of Komabangou in Niger (14°01′41″ and 14°07′56″ North latitude and 01° 02′12″ and 01°10′00″ East longitude).
Badjo, « Contents of metallic trace elements and pollution parameters in the soils of the Komabangou gold mining area in Niger », Journal of Materials and Environmental Science, p. 15, 2022
Eren, « Removal of copper ions by modified Unye clay, Turkey », Journal of Hazardous Materials, vol. 159, no 2‑3, p. 235‑244, 2008
Varlikli et al., « Adsorption of dyes on Sahara desert sand », Journal of Hazardous Materials, vol. 170, no 1, p. 27‑34, 2009

Dargusch 2 , Jianye Han1 and Sen Yu1 1 Northwest Institute for Nonferrous Metal Research, Xi'an 710016, China 2 CAST CRC, School of Engineering, The University of Queensland, Brisbane, 4072, Australia a yzt@c-nin.com Keywords: bio-metal materials, type titanium alloys, surgical implants, stent Abstract The effects of alloy chemistry and heat treatment on the microstructure and mechanical properties of Ti-Nb-Zr-Mo-Sn near β type titanium alloys have been investigated.
Acknowledgements Authors would like to acknowledge the financial support of National Natural Science Foundation of China (30770586), "973" key foundation research project (2005CB623900), and the CAST CRC, established and supported by the Australian Government's Cooperative Research Centres Programme.
J. (1998) Titanium alloys in total joint replacement - a materials science perspective, Biomaterials 19,1621-1639 [2] Niinomi, M.(1998) Mechanical Properties of biomedical titanium alloys, Materials Science and Engineering A243, 231-236 [3] Daisuke, K., Niinomi, M., Morinaga, M., Kato, Y. and Yashiro, T. (1998) Design and mechanical properties of new β type titanium alloys for implant materials, Materials Science and Engineering A243, 244-249 [4] Rack, H.
J. and Qazi, J.I. (2006) Titanium alloys for biomedical applications, Materials Science and Engineering C26, 1269 - 1277 [5] Niinomi, M. (2008) Mechanical biocompatibilities of titanium alloys for biomedical applications, Journal of Mechanical Behavior of Biomedical Materials 1, 30-42 [6] Liu, X., Chu, P.
K. and Ding, C.(2004) Surface modification of titanium, titanium alloys, and related materials for biomedical application, Materials Science and Engineering R47, 49-121 [7] Hanada, S., Matsumoto, H. and Watanabe, W.(2005) Mechanical compatibility of titanium implants in hard tissues, International congress series 1284, 239-247 [8] Yu Z., Zhou L. and Wang, K. (2004) Designing and development of ß type titanium alloy for medical application, Rare Metal Letters, 23(1),5