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Online since: December 2010
Authors: Zi Yang Cao, Hua Li
Li: Journal of Microfabrication Technology, Vol. 11 (2006) No.3, p.1-5
[2] J.
Kapoor: Journal of Manufacturing Science and Engineering, Vol. 126 (2004) No. 3, p.666-678 [4] M.
Fischer, and M.Vos: Journal. of Nanotechnology, Vol. 192 (1997) No. 8, p.145-148 [5] T.
Schaller: Journal of Precision Engineering, Vol. 23 (1999) No. 2, p.229-235 [11] Y.
Mishima, Journal of Manufacturing Science and Engineering, Vol. 126 (2004) No. 5, p.837-844 [13] W.
Kapoor: Journal of Manufacturing Science and Engineering, Vol. 126 (2004) No. 3, p.666-678 [4] M.
Fischer, and M.Vos: Journal. of Nanotechnology, Vol. 192 (1997) No. 8, p.145-148 [5] T.
Schaller: Journal of Precision Engineering, Vol. 23 (1999) No. 2, p.229-235 [11] Y.
Mishima, Journal of Manufacturing Science and Engineering, Vol. 126 (2004) No. 5, p.837-844 [13] W.
Online since: March 2015
Authors: Qi Qiao, Yue Zhang, Yang Yao
The concept of EIP by Cote & Hall (1995) [1] include:
(1) Conservation of natural and financial resources
(2) Reduced production, material, energy, insurance and treatment costs and liabilities
(3) Improved operating efficiency, quality, population health and public image
(4) Potential income through the sale of waste materials.
In addition, PCSD experts also proposed another definition of EIP: “An industrial system of planned materials and energy exchanges that seeks to minimize energy and raw materials use, minimize waste, and build sustainable economic, ecological and social relationships.”
The construction mode of EIP was that enterprises cooperated with each other and efficiently shared resources (information, materials, water, energy, infrastructure and natural habitat).
The purpose of the EIP was to minimize energy and raw materials use, minimize waste, and build sustainable economic, ecological and social relationships.
The flow of materials on the eco-industry chains are the by-product or waste resources, and the products chains are the material flow on the general industrial chains [16].Third, the different physical forms.
In addition, PCSD experts also proposed another definition of EIP: “An industrial system of planned materials and energy exchanges that seeks to minimize energy and raw materials use, minimize waste, and build sustainable economic, ecological and social relationships.”
The construction mode of EIP was that enterprises cooperated with each other and efficiently shared resources (information, materials, water, energy, infrastructure and natural habitat).
The purpose of the EIP was to minimize energy and raw materials use, minimize waste, and build sustainable economic, ecological and social relationships.
The flow of materials on the eco-industry chains are the by-product or waste resources, and the products chains are the material flow on the general industrial chains [16].Third, the different physical forms.
Online since: December 2010
Authors: Feng Xiang You
Example 1 For graphite / epoxy materials , we set
The restrict condition is four simply supported edges, laying angles are respectively
a/h=10, introducing dimensionless inherent frequency, calculation results see Table 1 .
The material density is 1600kg/m3, ply angle are .
[2]Jones R M.Mechanics of composite materials[M].
Journal of composite materials,1990,7(2):99-109
Journal of composite materials,1986.3(2):64-73 [18] Reddy J .
The material density is 1600kg/m3, ply angle are .
[2]Jones R M.Mechanics of composite materials[M].
Journal of composite materials,1990,7(2):99-109
Journal of composite materials,1986.3(2):64-73 [18] Reddy J .
Online since: October 2011
Authors: Jing Zhang, Chao Feng Yang, Ke Yuan
(Xi’an, China), and the purity of them was above 98%.
2.2 Plant materials
The plant materials of Taxus media were collected from Mianyang city, Sichuan province and Changshan city of Zhejiang province from 18, April, 2010 to 22, April, 2010 and the voucher specimens were deposited at our laboratory.
Journal of Guizhou Normal University (Natural Science), 1999, 17(4): 19-21
Study on Extraction and Sepration of the Taxol [J].Journal of Yanbian University(Natural Science), 1998, 24(1): 42
Chinese Journal of New Drugs, 2006, 15(13): 1084
Wang, “Correlation Analysis on 6 Kinds of Taxanes in Branches and Leaves of Taxus wallichiana, ” Journal of West China Forestry Science, volumn 37, 2008, pp. 1-4.
Journal of Guizhou Normal University (Natural Science), 1999, 17(4): 19-21
Study on Extraction and Sepration of the Taxol [J].Journal of Yanbian University(Natural Science), 1998, 24(1): 42
Chinese Journal of New Drugs, 2006, 15(13): 1084
Wang, “Correlation Analysis on 6 Kinds of Taxanes in Branches and Leaves of Taxus wallichiana, ” Journal of West China Forestry Science, volumn 37, 2008, pp. 1-4.
Online since: September 2011
Authors: Yu Rong Yan, Yao Ming Zhao, Peng Zhang, Wei Pan, Rui Tian Zhu
Journal of Biomedical Materials Research Part A, Vol 95A, No. 3(2010), p.828-836
[5] Liu S.
Journal of Biomaterials Science-Polymer Edition, Vol 22, No.7(2011), p.945-955 [6] Chang S.
Journal of Biomedical Materials Research Part A, Vol 95A, No. 1(2010), p.276-282 [9] Panzavolta S., Gioffrè M., Focarete M.
Journal of Materials Science: Materials in Medicine, Vol 19, No.1(2008), p.95-102 [11] Zhao Y.
Journal of South China University of Technology(Natural Science Edition) , Vol 36, No.11(2008), p.157-161 [12] C.
Journal of Biomaterials Science-Polymer Edition, Vol 22, No.7(2011), p.945-955 [6] Chang S.
Journal of Biomedical Materials Research Part A, Vol 95A, No. 1(2010), p.276-282 [9] Panzavolta S., Gioffrè M., Focarete M.
Journal of Materials Science: Materials in Medicine, Vol 19, No.1(2008), p.95-102 [11] Zhao Y.
Journal of South China University of Technology(Natural Science Edition) , Vol 36, No.11(2008), p.157-161 [12] C.
Online since: September 2013
Authors: Cheng Zhao, Long Tao, Jin Wang, Li Hua Li
Study on the ISF Procedure of the Throttle Pedal Fixed Plate
Based on the Numerical Simulation
Lihua Li 1,2,3, Long Tao4,Jin Wang 2,3,a, Cheng Zhao1
1Surface Engineering Laboratory, Qingdao University of Science and Technology, Qingdao, 266061, China
2Department of Mechanical Engineering, Qingdao Technological University, Qingdao, 266033, China
3 State Key Laboratory of Materials Processing and Die & Mould Technology, Huazhong University of Science and Technology, Wuhan 430047, China
4Qingdao Choho industrial Co., Ltd, Qingdao 266000, China
ajinwangqtech@163.com
Keywords: incremental sheet forming, numerical simulation, practical production
Abstract.
Steel sheet of ST12 with 0.64mm thickness was chosen in this experiment, the material property is shown in Table1 .
Acknowledgements This work was financially supported by the the National Science Foundation of China (51205217), the State Key Laboratory of Materials Processing and Die & Mould Technology Foundation of Huazhong University of Science and Technology (2011-P07) and the Project of Shandong Province Higher Educational Science and Technology Program (J10LD13).
Michel, Experimental investigations and numerical analysis for improving knowledge of incremental sheet forming process for sheet metal parts, Journal of Materials Processing Technology 210 (2010) 363–369 [3]Y.H.
Park, Effect of Process Parameters on Formability in Incremental Forming of Sheet Metal, Journal of Materials Processing Technology 130–131 (2002) 42–46 [4]Study on the Formability and Numerical Simulation in Sheet Incremental Forming, Tao Long, MSc Thesis, P45, in Chinese.
Steel sheet of ST12 with 0.64mm thickness was chosen in this experiment, the material property is shown in Table1 .
Acknowledgements This work was financially supported by the the National Science Foundation of China (51205217), the State Key Laboratory of Materials Processing and Die & Mould Technology Foundation of Huazhong University of Science and Technology (2011-P07) and the Project of Shandong Province Higher Educational Science and Technology Program (J10LD13).
Michel, Experimental investigations and numerical analysis for improving knowledge of incremental sheet forming process for sheet metal parts, Journal of Materials Processing Technology 210 (2010) 363–369 [3]Y.H.
Park, Effect of Process Parameters on Formability in Incremental Forming of Sheet Metal, Journal of Materials Processing Technology 130–131 (2002) 42–46 [4]Study on the Formability and Numerical Simulation in Sheet Incremental Forming, Tao Long, MSc Thesis, P45, in Chinese.
Online since: August 2013
Authors: Hui Jie Liu, Li Zhou
Zielinski: Journal of Materials Processing Technology Vol. 109 (2001), p. 206
[5] O.N.
Olson: Materials Science and Engineering A Vol. 289 (2000), p. 41 [8] D.
Froes: Materials Science and Engineering A Vol. 280 (2000), p. 220 [9] F.H.
Li: Materials Science and Engineering A Vol. 500 (2009), p. 1 [11] T.K.
Froes: Materials Science and Engineering A Vol. 359 (2003), p. 137 [14] H.
Olson: Materials Science and Engineering A Vol. 289 (2000), p. 41 [8] D.
Froes: Materials Science and Engineering A Vol. 280 (2000), p. 220 [9] F.H.
Li: Materials Science and Engineering A Vol. 500 (2009), p. 1 [11] T.K.
Froes: Materials Science and Engineering A Vol. 359 (2003), p. 137 [14] H.
Online since: December 2015
Authors: Rozana Mohd Dahan, Mohamad Hafiz Mohd Wahid, Adillah Nurashikin Arshad, Muhamad Naiman Sarip, Mohamad Rusop Mahmood
Materials and Method
Materials.
Advanced Materials Research, 2013. 626: p. 311-316
Journal of Membrane Science, 2009. 345(1-2): p. 13-20
Journal of Polymer Science Part B: Polymer Physics, 1994. 32(5): p. 859-870
Journal of Applied Polymer Science, 2006. 100(4): p. 3272-3279
Advanced Materials Research, 2013. 626: p. 311-316
Journal of Membrane Science, 2009. 345(1-2): p. 13-20
Journal of Polymer Science Part B: Polymer Physics, 1994. 32(5): p. 859-870
Journal of Applied Polymer Science, 2006. 100(4): p. 3272-3279
Online since: June 2017
Authors: Yu Liu, Yan Qiong Sun, Su Ping Cui
As one of the energy-extensive consumption industry in China, the building materials, especially the wall and roof materials is recognized as causing 70% of energy loss of the entire building materials.
New building materials,2013,11:56-59
Journal of Chongqing College of Electronic Engineering,2015,04:148-151
New building materials, 2006, 06:58-60
Process in Materials Science and Engineering. 2006.
New building materials,2013,11:56-59
Journal of Chongqing College of Electronic Engineering,2015,04:148-151
New building materials, 2006, 06:58-60
Process in Materials Science and Engineering. 2006.
Online since: October 2010
Authors: Song Bi, Yu Dong Zhang, Xun Jia Su, Gen Liang Hou, Feng Guo, Zhen Xing Mei
Experimental
Materials and preparation.
References [1] Lin Zhou, Wenzhong Wang et al: Journal of Molecular Catalysis A: Chemical, 252, (2006), p. 120–124 [2] Meng Shang,WenzhongWang et al: Journal of Hazardous Materials, 172, (2009), p. 338–344
[8] Satoshi Yoda, Katsuto Ohtake et al: Journal of Sol-Gel Science and Technology, 19, (2000), p.719–723
Mohamed: Journal of materials processing technology, 209, (2009), p.577–583
[13] Hai-qing Jiang, Hiromitsu Endo: Materials Research Bulletin, 44, (2009), p.700–706
References [1] Lin Zhou, Wenzhong Wang et al: Journal of Molecular Catalysis A: Chemical, 252, (2006), p. 120–124 [2] Meng Shang,WenzhongWang et al: Journal of Hazardous Materials, 172, (2009), p. 338–344
[8] Satoshi Yoda, Katsuto Ohtake et al: Journal of Sol-Gel Science and Technology, 19, (2000), p.719–723
Mohamed: Journal of materials processing technology, 209, (2009), p.577–583
[13] Hai-qing Jiang, Hiromitsu Endo: Materials Research Bulletin, 44, (2009), p.700–706