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A Remote Robot Control System Based on RIA and Flex Platform TAN Baohua1, 2,3, a, ZHU Qingbo 4,b 1 School of Science, Hubei University of Technology, Wuhan, Hubei, China 2 School of Automobile Engineering, Wuhan University of Technology, Wuhan, Hubei, China 3 Key Lab of Modern Manufacture Quality Engineering, Wuhan, Hubei, China 4 School of Mechanical Engineering, Hubei University of Technology, Wuhan, Hubei, China a tan_bh@126.com, b zhuqingbo@msn.com Keywords: Robot control; RIA; Flex; Web Service; Component.
Start the robot control program to receive and enforce the command as well as complete the real-time video collection, coding and sending tasks; the robot receives the command, and process it with application program, if the command is correct, the robot will act accordingly and will send the movement to the operator in the form of video materials to make sure the operator is well informed of the robot’s work conditions.
Journal of Hubei University of Technology,2007,22(4):45-47.
Beijing: University of Electronic Science and Technology, 2006,6.

Materials Science and Engineering B, 172 (2010) 43–49
[8] J.Y Lee, Boron Back Surface Field Using spin on dopants by rapid thermal processing, Journal of Korean Physical Society, 44-6 (2004) 1581-1586
Fath, Bifacial solar cells on multi-crystalline silicon, 15th International Photovoltaic Science and Engineering Conference (PVSEC-15), Shanghai, 2005, pp. 885-886

Experimental Research and Production of Heavy Gauge DNV 485FDU for Deep Water Trunkline Project Shaopo Li1, 2 ,3, a, Wenhua Ding2, 3, b and Lifeng Wang2, 3, c 1University of Science & Technology Beijing, 30 Xueyuan Road, Beijing, 100083, China. 2Shougang Research Institute of Technology, 69 Yangzhuang Street, Beijing, 100043, China. 3Beijing Energy Steel Engineering Technology Research Center, 69 Yangzhuang Street, Beijing, 100043, China.
Journal of Iron and Steel Research, 2008(10): 36-39
Ahn, “Correlation of Microstructure and Charpy Impact Properties in API X70 and X80 Line-pipe steels”, [J], Materials Science and Engineering, A458(2007)281-289

An Investigation of an Electromagnetic Induction Device for a Small-scale MR Damper Bogdan Sapiński 1, a 1 Department of Process Control - University of Science and Technology 30 Mickiewicz Ave., 30-059 Cracow, Poland a deep@agh.edu.pl Keywords: electromagnetic induction device, magnetorheological damper, vibration Abstract.
Smart Materials and Structures, 1, p. 707-714 (2005)
AGH University of Science and Technology Press, Cracow, Poland (2006)
Journal of Theoretical and Applied Mechanics (to be published 2008)

Acknowledgements This work was financially supported by Natural Science Foundation of China (51078306), Higher School Special Research Fund for the Doctoral Programs (20106120110004), Significant Technological Project Innovation Fund in Xi’an University of Architecture and Technology (ZX0901), Special Funds in Key Discipline Construction Projects in Shanxi Province (E01004), Talent and Technology Fund Projects of Xi’an University of Architecture and Technology (RC1027).
China Communications Press, 1999 (In Chinese) [3] Chengchuan Liu, Liling Chen: China Building Materials Science & Technology, 2009, (03), 100-101 (In Chinese) [4] Jingbo Liu, Xiuli Du: Dynamics of Structures [M].
China Machine Press, 2005 (In Chinese) [5] Zi Cao, Suduo Xue, Xuesheng Wang, Yinchun Liu: Spatial Structures, 2008, 14 (3), 3-8 (In Chinese) [6] Junchang Bai, Jinping Jin: Shanxi Architecture, 2007, 33(3), 62-63 (In Chinese) [7] Wenyuan Hu, Jinghua Zhou: Journal of Southern Institute of Metallurgy, 2003, 24 (4), 25-28 (In Chinese) [8] JTG/T B02-01-2008.

Kwun b Division of Materials Science and Engineering, Korea University, Seoul 136-701, Korea a gsystem@korea.ac.kr, bsookkwun@korea.ac.kr Keywords: ultra-fine grain, oxidation, ODS alloy, mechanical alloying Abstract.
Acknowledgement This work was supported by the 2003 Nuclear Basic Research Program of the Korea Institute of Science and Technology Evaluation and Planning.
Quadakkers : Journal de Physique Ⅲ .

Structural stiffness and damping of material is also constant.
Moving trainset, number: nA Standing trainset, number: nB nA+nB=n m2 m1 mnA mnA+1 mn-1 k1 c1 k2 c2 knA-1 c nA-1 knA c nA knA+1 c nA+1 kn-2 c n-2 x1 xnA x2 xn-1 xnA+1 mn kn-1 c n-1 xn Fig. 2 The relation of force and stroke between two vehicles Fi ∆xi vi>0 vi<0 k0 kcg ks k'0 f0 O A B C D E G k'cg k'cg In Fig. 2 and Eq.3, iF is the action force between two vehicles, ix∆ is the relative displacement between two vehicles, i.e. stroke of the buffer, 1i i ix x x +∆ = − , iv is the relative velocity, 0k is the stiffness of the buffer in compress course, cgk' is the stiffness of a coupler and vehicle, 0k' is the stiffness of the buffer in comeback course, cgk is the stiffness of spherical rubber jointer, sk is initial stiffness of the buffer when initial force 0f exists, ms is the maximum stroke of the buffer, es is the initial stroke of the buffer when initial force exists, gdc is the structural damping of material
Yang: Chinese Journal of Mechanical Engineering, Vol. 42 (2006) No. 1, pp. 212-216.
Wei: China Railway Science, Vol. 23 (2002) No.1, pp. 77-85.
Sun: Subway Vehicle Coupler-buffer Strength Analysis and Dynamics Analysis, (MS., Shaanxi University of Science and Technology, China 2008), pp. 26-32.

Introduction Microfluidic technology is a new branch of biotechnology over the past decade [1], it integrates the microchannels, pumps, valves, pool reservoirs and microdetection devices on the matrix materials by using MEMS (Micro-Electro-Mechanical Systems) technology, and the biochemical reaction and detection could be achieved through controlling the sample flow in the micro-channel, so it has been widely applied in biochemical analysis.
Acknowledgements This paper is supported by National Natural Science Fund of China (60574092).
[3] Zhaolun Fang: Micro Fluidic Chip (Science Press, Beijing 2003)
Ortis De Solorzano: Journal of Microscopy.

Acknowledgements This study was supported by State Key Laboratory of Shield Machine and Boring Technology, National High Technology Research and Development Program of China (Grant No. 2012AA041801) and National Natural Science Foundation of China (No. 11302146).
Zheng: Chinese Journal of Theoretical and Applied Mechanics, Vol 44(2012), p.861-868.
Wang: Advanced Science Letters, Vol. 4(2011), p. 2049-2053
Chen and F.Y Li: Applied Mechanics and Materials, Vol. 143(2011), p. 512-516

Advanced Treatment of Textile Wastewater for Reuse by Ozonation-Biological and Membrane Processes Xiaojun WANGa, Qikun XUb, Luqing QIc State key laboratory of Industrial belts pollution control and ecological restoration, School of Environmental Science and Engineering, South China University of Technology, Guangzhou 510006, China acexjwang@scut.edu.cn (corresponding author), bXuqikun1129@yahoo.cn, c qiluqingqlq@qq.com Keywords: Ozone; Biological aerated filter (BAF); Reverse osmosis (RO); Membrane Abstract.
Acknowledgements The study was supported by the National Natural Science Foundation (NSFC) of China, Grant No. 51078149, and the scientific management of technological planning projects of Guangzhou, Grant No. 2009Z1-E751.
[2] Nihel Ben Amar etc, Comparison of tertiary treatment by nanofiltration and reverse osmosis for water reuse in denim textile industry, Journal of Hazardous Materials. 170 (2009) 111-117