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Online since: March 2010
Authors: Long Liang Pang, Shu Fang Wu, Zong Yan Wang
By controlling the distance between layers, the
dimensions are clearly arranged.
3) Adjusting the bill of materials.
Bill of materials is the inventory of all the parts (components) in the assembly, reflecting the number and relevant properties of the parts and standard-parts in the assembly.
Wang: Journal of Machine Design, (2004), p.1-3 [3] Y.L.
Qi: Journal of Tianjin University(Science and Technology), (2002), p. 744-748 [4] W.D.
Xu: Mechanical Science and Technology, (2002), p.832-835 [6] Y.H.
Bill of materials is the inventory of all the parts (components) in the assembly, reflecting the number and relevant properties of the parts and standard-parts in the assembly.
Wang: Journal of Machine Design, (2004), p.1-3 [3] Y.L.
Qi: Journal of Tianjin University(Science and Technology), (2002), p. 744-748 [4] W.D.
Xu: Mechanical Science and Technology, (2002), p.832-835 [6] Y.H.
Online since: December 2012
Authors: Gang Lu, Yue Huang
Experiment Section
Experimental materials and Apparatus.
Materials and Apparatus: PSI was synthesized by thermal polycondensation of maleic acid and ammonia.
Journal of Macromolecular Science , Part A: Pure and Applied Chemistry, 2005, 42: 1299-1315
Journal of Macromolecular Science , Part A: Pure and Applied Chemistry, 2005, 42: 1299-1315
“Synthese and application of green polymer polyaspartic acid,” Hebei Journal of Industrial Science Technaology, Vol. 22, pp. 33-35, January, 2005
Materials and Apparatus: PSI was synthesized by thermal polycondensation of maleic acid and ammonia.
Journal of Macromolecular Science , Part A: Pure and Applied Chemistry, 2005, 42: 1299-1315
Journal of Macromolecular Science , Part A: Pure and Applied Chemistry, 2005, 42: 1299-1315
“Synthese and application of green polymer polyaspartic acid,” Hebei Journal of Industrial Science Technaology, Vol. 22, pp. 33-35, January, 2005
Online since: June 2015
Authors: R. Zakaria, K. Nazir, A.F. Aziz, A.M.M. Ali, Muhd Zu Azhan Yahya, Siti Fadzilah Ayub
Ali1,2,b
1Faculty of Applied Sciences Universiti Teknologi MARA,40450 Shah Alam,Malaysia.
2Institute of Science, Universiti Teknologi MARA,40450 Shah Alam,Malaysia.
3Physics department, Universiti Pertahanan Nasional Malaysia,Kem Sungai Besi, 57000 Kuala Lumpur, Malaysia.
Rahman and M.S.Su’ait “Morphological, Infrared, and ionic Conductivity Studies of Poly(ethylene oxide)- 49% poly(methyl methacrylate) grafted natural rubber- Lithium Perchlorate Salt Based Solid Polymer Electrolytes” Journal of Applied Polymer Science, 4222-4229,2011
Wang, S.Dong, “Plasticizer effect on the ionic conductivity of PEO-based polymer electrolyte” Materials Chemistry and Physics, Vol 74, pp. 98-103, 2002
Hamzah, M.Y.A Rahman, “Preparation and characterization of PMMA-MG30-LiCLO4 solid polymeric electrolyte” Journal of Physics D: Applied Physics,Vol.42, 2009
Yahya, “Frequency dependent conductivity studies on PMMA-LiCF3SO3 polymer electrolytes” Materials Research Innovations, Vol. 13, pp. 217-219, 2009
Rahman and M.S.Su’ait “Morphological, Infrared, and ionic Conductivity Studies of Poly(ethylene oxide)- 49% poly(methyl methacrylate) grafted natural rubber- Lithium Perchlorate Salt Based Solid Polymer Electrolytes” Journal of Applied Polymer Science, 4222-4229,2011
Wang, S.Dong, “Plasticizer effect on the ionic conductivity of PEO-based polymer electrolyte” Materials Chemistry and Physics, Vol 74, pp. 98-103, 2002
Hamzah, M.Y.A Rahman, “Preparation and characterization of PMMA-MG30-LiCLO4 solid polymeric electrolyte” Journal of Physics D: Applied Physics,Vol.42, 2009
Yahya, “Frequency dependent conductivity studies on PMMA-LiCF3SO3 polymer electrolytes” Materials Research Innovations, Vol. 13, pp. 217-219, 2009
Online since: June 2010
Authors: Ke Qin Yan, Ming Gu, Xuan Yi Zhou
Due to the
complexity of the special material, only few researchers get the data from field investigation though
lots of job carried out in simulating.
Acknowledgement The work described in this paper was supported by the National Natural Science Foundation for Innovative Research Groups in Science (50621062); State Key Laboratory of Science and Technology Basic Research Grant (SLDRCE08-A-03); The National Natural Science Foundation of China for Surface Project (50608060). 6.
Journal of Wind Engineering and Industrial Aerodynamics, 2003. 91: p. 551-569. 2.
Gamble, S.L., Finite Area Element Snow Loading Prediction Applications and Advancements Journal of Wind Engineering and Industrial Aerodynamics, 1992. 41-44: p. 1537-1548. 4.
Key Engineering Materials 2010. accepted. 6.
Acknowledgement The work described in this paper was supported by the National Natural Science Foundation for Innovative Research Groups in Science (50621062); State Key Laboratory of Science and Technology Basic Research Grant (SLDRCE08-A-03); The National Natural Science Foundation of China for Surface Project (50608060). 6.
Journal of Wind Engineering and Industrial Aerodynamics, 2003. 91: p. 551-569. 2.
Gamble, S.L., Finite Area Element Snow Loading Prediction Applications and Advancements Journal of Wind Engineering and Industrial Aerodynamics, 1992. 41-44: p. 1537-1548. 4.
Key Engineering Materials 2010. accepted. 6.
Online since: May 2012
Authors: Bei Zhang, Cheng Chao Guo, Wen Kui Peng, Yan Hui Zhong
In numerical analysis, material of the rock is different in the various areas and subarea method can deal with this problem by been given different values to various material property.
The material of each area is considered as Moore-Coulomb plastic body.
Specific materials parameters are in Table 1.
Journal of Chang-an university (natural science edition), Vol. 24 (2004), p. 2.
Journal of rock mechanics and engineering, Vol. 11(2008), p. 27.
The material of each area is considered as Moore-Coulomb plastic body.
Specific materials parameters are in Table 1.
Journal of Chang-an university (natural science edition), Vol. 24 (2004), p. 2.
Journal of rock mechanics and engineering, Vol. 11(2008), p. 27.
Online since: July 2014
Authors: Yan Ling Xiong, Lei Zhao, Zhao Hui Luan, Li Juan He
Athermalization Design of Wide Field Medium Wave Infrared Optical System
Lei Zhao1,a, ZhaoHui Luan1,b YanLing Xiong1,c and LiJuan He1,d
1School of Applied Science, Harbin University of Science and Technology, China
azhaoleiwm@163.com, blzhmj5@126.com, cxyling1964@163.com, dhlj6607@163.com
Keywords: athermalization, optical design, wide field, infrared optical system
Abstract.
For the high optical-thermal expansion coefficients of the infrared materials, the refractive index, radius of curvature and center thickness of the optical element will have the corresponding change when the infrared optical system works under the different temperatures.
Principle of Passive Optical Athermalization Passive optical athermalization is a method using the different optical materials with different optical-thermal expansion coefficients to allocate the focal power, and make the image plane drift close to the length change of lens cone due to the hot-expansion and cold-contraction.
The materials of the lenses respectively are Silicon, Germanium, Silicon, Germanium and Silicon.
References [1] Yaguang Geng and Mingqian Zhang: submitted to Infrared and Laser Engineering (2007) in Chinese [2] Jinqiu Xiao and Shumei Xu: submitted to Journal of Electronic Measurement and Instrument (2004) in Chinese [3] Yanlong Qi and Meng Duan: submitted to Infrared Technology (2009) in Chinese [4] Yan Li and Bao Zhang: submitted to Journal of Applied Optics (2013) in Chinese [5] Xingqiao Ai and Bo Liu: submitted to Proc. of SPIE (2010) [6] Yang Jiang and Qiang Sun: submitted to Acta Photonica Sinica (2013) in Chinese [7] Le Yang and Qiang Sun: submitted to Acta Photonica Sinica (2011) in Chinese
For the high optical-thermal expansion coefficients of the infrared materials, the refractive index, radius of curvature and center thickness of the optical element will have the corresponding change when the infrared optical system works under the different temperatures.
Principle of Passive Optical Athermalization Passive optical athermalization is a method using the different optical materials with different optical-thermal expansion coefficients to allocate the focal power, and make the image plane drift close to the length change of lens cone due to the hot-expansion and cold-contraction.
The materials of the lenses respectively are Silicon, Germanium, Silicon, Germanium and Silicon.
References [1] Yaguang Geng and Mingqian Zhang: submitted to Infrared and Laser Engineering (2007) in Chinese [2] Jinqiu Xiao and Shumei Xu: submitted to Journal of Electronic Measurement and Instrument (2004) in Chinese [3] Yanlong Qi and Meng Duan: submitted to Infrared Technology (2009) in Chinese [4] Yan Li and Bao Zhang: submitted to Journal of Applied Optics (2013) in Chinese [5] Xingqiao Ai and Bo Liu: submitted to Proc. of SPIE (2010) [6] Yang Jiang and Qiang Sun: submitted to Acta Photonica Sinica (2013) in Chinese [7] Le Yang and Qiang Sun: submitted to Acta Photonica Sinica (2011) in Chinese
Online since: June 2019
Authors: Armen Atynian, Kateryna Bukhanova, Roman Tkachenko, Volodymyr Manuilenko, Dmytro Borodin
Energy Efficient Building Materials with Vermiculite Filler
A.
They belong to the ecological fireproof materials and provide the good heat insulation.
One of the extension ways of the heat insulation materials production as well as the light aggregates for them is the usage of vermiculite and vermiculite based materials because this material is a local raw one.
Rodrigues, “Characterization of Natural Clay Vermiculite, Expanded by Indirect Method for Energy and Microwave“, Materials Science Forum, 820, 36-39 (2015)
Advanced Materials Research, 178, 53-58 (2011)
They belong to the ecological fireproof materials and provide the good heat insulation.
One of the extension ways of the heat insulation materials production as well as the light aggregates for them is the usage of vermiculite and vermiculite based materials because this material is a local raw one.
Rodrigues, “Characterization of Natural Clay Vermiculite, Expanded by Indirect Method for Energy and Microwave“, Materials Science Forum, 820, 36-39 (2015)
Advanced Materials Research, 178, 53-58 (2011)
Online since: June 2010
Authors: Steven P. Knight, A.J. Davenport, Anthony R. Trueman, Graham Clark
Stampanoni: Materials Sci. and
Technology, 22, 9, (2006), p. 1076
[6] F.
Jackson: British Corrosion Journal, 34, 1, (1999), p. 45 [10] K.T.
Hrivnaková: Materials and Corrosion, 55, 6, (2004), p. 437 [12] B.
Gao: Metallurgical and Materials Transactions, 29A, 4, (1998), p. 1153 [16] S.P.
Kinnear: Materials Science Forum, vol. 217-222, (1996), p. 1587 [18] D.J.
Jackson: British Corrosion Journal, 34, 1, (1999), p. 45 [10] K.T.
Hrivnaková: Materials and Corrosion, 55, 6, (2004), p. 437 [12] B.
Gao: Metallurgical and Materials Transactions, 29A, 4, (1998), p. 1153 [16] S.P.
Kinnear: Materials Science Forum, vol. 217-222, (1996), p. 1587 [18] D.J.
Online since: July 2012
Authors: Ji Hu Wang, Shao Guo Wen, Shi Gao Song, Yan Shen
Application of new emulsifier on acrylic emulsion polymerization
Shigao Song1,a,Shaoguo Wen1,b,*,Jihu Wang1,c,Yan Shen1,d,
1College of Chemistry and Chemical Engineering, Shanghai University of
Engineering Science, Shanghai 201620, P.
Journal of Hubei University.
Green materials research and application.
Shanghai University of Engineering Science.
Journal of North China University of Science and Technology.
Journal of Hubei University.
Green materials research and application.
Shanghai University of Engineering Science.
Journal of North China University of Science and Technology.
Online since: December 2013
Authors: Fei Lu, Guo Feng Zhang, Chao Liu, Xiu Jie Ji, Bo Wen Cheng, Jun Song, Ran Ran Fu, Jie Ru Huang, Peng He Su, Xiao Rong Gou, Lu Yang Chen
A Green Procedure for the Ionic Liquid Catalyzed Oxidation of Benzylic Alcohols to Aldehydes or Ketones in Aqueous Media
Guo-feng Zhang1, a, Xiu-jie Ji1,b,*, Bo-wen Cheng1, Jun Song1, Fei Lu1, Ran-ran Fu1, Jie-ru Huang1, Peng-he Su1, Xiao-rong Gou1 and Lu-yang Chen1, Chao Liu2,c,*
1State Key Laboratory of Hollow Fiber Membrane Materials and Processes, Tianjin Polytechnic University,Tianjin 300160, People’s Republic of China
2School of Materials Science and Engineering, Hebei University of Technology, Tianjin 300130,
P.R.
Acknowledgements: This work is supported by National Natural Science Foundation of China (21104057 and 51076174), Tianjin Municipal Education Foundation(2009ZD02), Tianjin Municipal Natural Science Foundation (10JCZDJC22200 and 09JCZDJC22700) and the National Training Programs of Innovation and Entrepreneurship for Undergraduates (201210058027).
Tandon: Journal of Catalysis,Vol.230 (2005),No.2, p.436-439
Tian: Journal of Shenyang Normal University, Vol. 29 (2011) No.2 p.249-251.
Acknowledgements: This work is supported by National Natural Science Foundation of China (21104057 and 51076174), Tianjin Municipal Education Foundation(2009ZD02), Tianjin Municipal Natural Science Foundation (10JCZDJC22200 and 09JCZDJC22700) and the National Training Programs of Innovation and Entrepreneurship for Undergraduates (201210058027).
Tandon: Journal of Catalysis,Vol.230 (2005),No.2, p.436-439
Tian: Journal of Shenyang Normal University, Vol. 29 (2011) No.2 p.249-251.