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THE MINERALOGY OF THE COPPER – GOLD ORE DEPOSITS AT THE PHU KHAM, MINE, LAOS Vongsavanh Soysouvanh1,3,a, Kamar Shah Ariffin1,b, Koichiro Watanabe2,c, Nhinxay Visane3,d School of Materials and Mineral Resources Engineering, Universiti Sains Malaysia, 14300 Nibong Tebal Pulau Penang, Malaysia 2 Department of Earth Resources Engineering, Faculty of Engineering, Kyushu University,744 Motooka Nishi- Ku Fukuoka, 819 - 0395, Japan 3 Department of Mechanical Engineering, Faculty of Engineering, National University of Laos, Sokpaluang Rd, Sisattanak District P.O.BOX: 3166, Vientiane LAO PDR a Email: soysouvanh2007@hotmail.com / vongsoy@gmail.com Keywords: Phu Kham, Laos, porphyry copper - gold, skarn, intrusive rock Abstract : The Phu Kham “Mountain of Gold” copper - gold deposit is located in the Xaisomboun District in Vientiane Province in Lao PDR, approximately 100 km northeast of the capital city of Vientiane.
Finally, the authors wish to thank to the School of Materials and Mineral Resources Engineering, Universiti Sains Malaysia and Department of Earth Resources Engineering, Faculty of Engineering, Kyushu University for performing laboratory works and analyses.
Journal of Asia Earth Sciences 18:343-350 [2] Backhouse, D.J., 2004, Geological setting, alteration and nature of mineralization at the Phu Kham Copper- Gold Deposit Laos PDR, Unpublished Honors Thesis, Centre for Ore Deposit Research (CODES) – University of Tasmania, 141 p
Chronological and metallogenic framework of Cu-Au skarn deposits along Loei Fold Belt, Thailand and Lao PDR, in Williams P. et al. eds., Smart Science for Exploration and Mining: Proceedings of Tenth Biennial SGA Meeting Townsville, Australia, 17-20 August 2009, v. 1, p. 309–311

The Experimental Study on Consolidation of Acrylic Non-Aqueous Dispersion for Wet-Area Earthen Ruins in Southwest China Wu Yi1, a 1Civil Engineering and Architecture School, Southwest university of science and technology, Mianyang, 621010, Sichuan, China aw-em@163.com Keywords: Acrylic Non-Aqueous Dispersion; Consolidate; Earth Monument; Wet Abstract.
Introduction Earthen monuments, built mainly with earth, having low strength and directly contacted ground, is venerable to be destructed by groundwater, rains, wind, sand, sunlight, temperature, animals, plants and microbe, so developing anti-weathering materials for protecting them is the focus and difficulty in earthen monument preservation research[1].
Yang, Preliminary screening of consolidation and conservation materials for earthen sites in moist areas, In: China Relic Protection Technology Society, The proceedings of the 2nd conference by China relic protection technology society, China Relic Protection Technology Society, Beijing, 2002, p. 229-237
Comparison of consolidation effectiveness of acrylic non aqueous dispersion and other anti weathering consolidants for earthen architectures and monuments, SCIENCES OF CONSERVATION AND ARCHAEOLOGY, 2 (2003)40-48
Selection of Strengthening Medium for Archeological Site of Hongshan Culture at Niuheliang, Liaoliang Province, Chinese Journal of Geotechnical Engineering, 5 (2005) 567-570.

Materials and Methods Materials.
Acknowledgement This work has partially been supported by the National research Council of Thailand (NRCT) and the National Nanotechnology Center (NANOTEC), NSTDA, Ministry of Science and Technology, Thailand, through its program of Center of Excellence Network.
Mykkänen, Antioxidant phytochemicals against type 2 diabetes, British Journal of Nutrition. 99 (2008) 109-117
Harborne, Phytochemical Methods A Guide to Modern Techniques of Plant Analysis, Plant Sciences, 1998

Considering the boundary of two feature points of the SWCC, soils unsaturated stage can be illustrated as three phases (Figure.2): Capillary saturation zone, Desaturation zone and Residual saturation zone[8]. 2 Materials and methods In this study, saline soils in northwest China were selected for the test materials.
[9] Zhou J, and Yu J., Influences affecting the soil-water characteristic curve, Journal of Zhejiang University, Science, 2005, 6A(8):797–804
[11] Gardner W R., Some steady state solutions of the unsaturated moisture flow equation with application to evaporation from a water table, Soil Science, 1958, 85:228-232

Structure evaluation and microbial biomass determining of biological activated carbon Zhu Meng-fua, You Xiu-dong, Su Hong-bo, Deng Cheng, Chen Ping, Zhu Lu, Yuan Ying-hai Institute of Medical Equipment, Academy of Military Medical Sciences, Tianjin 300161, China azmf323@163.com Keywords: biological activated carbon; phospholipids (Lipid-P) analysis; microbial biomass; water treatment Abstract.
Materials and methods Major materials and equipments.
Beijing: Science press, 2007,1-2 [2] Zhang Xiaojian, Wang Zhansheng, Gu Xia-sheng.
Journal of harbin university of civil engineering and architecture, 2000,33(1):47-50 [4] Zhu Meng-fu, Wang Hai-yan, Su Hong-bo, et al.

In Eq.5, f is the axial feeding rate [mm/r], η the materials removal rate.
Acknowledgments This research was supported especially by Education Ministry of China as a key science and technology research project (Project No.: 104190).
Li: Materials Science Forum, Vol.532-533 (2006), pp.781-784
Cai,: Journal of Northeastern University, Vol.26 (2005) No.8, pp.770-773.

If compared to the involute helical-spur gear drive of the same size and material, the bearing capacity of the tooth surface would be 2~3 times higher.
ASME, Journal of Mechanisms, Transmissions, and Automation in Design, Vol. 111, pp.278-284, 1989
B., “Helical Gears with Circular Arc Tooth: Simulation of Conditions of Meshing and Bearing Contact,” ASME Journal of Mechanisms, Transmission, and Automation in Design, Vol. 107, pp. 556-564, 1985
[10] Cai, Zhong Biao, Characteristic Study and Stress Analysis of Helical Gears with Circular Arc Teeth, National Science Council Project, Project No.
[13] Sun, Da Dong, Cai, Chun Yuan, Double Circular-Arc Tooth Contact Analysis, Journal of Northeastern University, Vol. 94, pp. 77-80, 1992.

Mehta, “Characterization and simulation studies on high tilt ion implantation for precision halo implant applications”, Nuclear Instruments and Methods in Physics Research Section B: Beam Interactions with Materials and Atoms, 2002, Vol. 261, Issues 1-2
[6] H.Abdullah, J.Jurait, A.Lennie, Z.M.Nopiah, I.Ahmad, “Simulation of Fabrication Process VDMOSFET Transistor Using Silvaco Software”, European Journal of Scientific Research, 2009, ISSN 1450-216X, Vol.29 No.4, pp. 461-470 [7] Ugur Esme, “Application of Taguchi Method for the Optimization of Resistance Spot Welding Process”, The Arabian Journal for Science and Engineering, 2009, Vol. 34, No. 2B [8] Husam Ahmed Elgomati, Ibrahim Ahmad, “Optimization of Cobalt Silicide and Gate Dielectric Thickness in 65nm NMOS Using Taguchi Method”, International Conference on Modeling and Simulation, Coimbatore, 27-29 August 2007
[14] Kai Yang, Ee-Chon Teo, Franz Konstantin Fuss, “Application of Taguchi method in optimization of cervical ring cage”, International Journal of Biomechanics, 2007, Vol. 40, pp. 3251-3256.

Acknowledgements Supported by: Research Found for earthquake sponsored by Ministry of national science and technique(200808021) References [1] Fusheng Zhou, Xun Guo and Zhihua Zheng: Journal of Earthquake Engineering and Engineering Vibration.
Vol.22 (2002), p.58 (In Chinese) [2] Liqun Li and Weiqing Liu: Journal of Nanjing Architectural and Civil Engineering Institute, Vol.2 (2001), p.19(In Chinese) [3] Mehran Khoshbakht, Mark W.
Berman: Finite Elements in Analysis and Design, vol.42 (2006), p.414 [4] Liang Huang, Shengyun Chen, Chuxian Shiand Xiang Gao: Key Engineering Materials, Vol.400 (2001), p.911 [5] Code for seismic design of buildings in China (GB50011-2001), China Architecture & Building Press, Beijing (2001), in press
[6] Minzheng Zhang: Journal of Earthquake Engineering and Engineering Vibration.

Reverse validation in the robots control BOŽEK Pavol1,a *, PIVARČIOVÁ Elena2,b and KORSHUNOV Aleksander3,c 1 Slovak University of Technology, Faculty of Materials Science and Technology, Institute of Applied Informatics, Automation and Mechatronics, Hajdóczyho 1, 917 24 Trnava, Slovak Republic 2 Technical University in Zvolen, Faculty of Environmental and Manufacturing Technology, Department of Machinery Control and Automation Technology, Masarykova 24, 960 53 Zvolen, Slovak Republic 2 Kalashnikov Izhevsk State Technical University, 7 Studencheskaya St. 426069 Izhevsk Russia apavol.bozek@stuba.sk, belena.pivarciova@tuzvo.sk, ckai@istu.ru Keywords: inertial navigation system, robot, operation Abstract.
In: Journal of Electrical Engineering, 2014, vol. 65, no. 5, online, p. 277-282
In Journal of Electrical Engineering.
Virgala, Modeling of Dynamic Systems in Simulation Environment MATLABSimulink – SimMechanics, American Journal of Mechanical Engineering.