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Online since: March 2010
Authors: Shi Ming Ji, Li Zhang, Xian Zhang, Guo Da Chen, Ming Sheng Jin, Qiao Ling Yuan
Khatri: Journal of Materials Processing Technology, Vol. 190
(2007), p. 282-290
[3] T.
Kawashima: Journal of Materials Processing Technology, Vols. 143-144 (2003), p. 682-686 [5] J.
Choi: Journal of Material Processing Technology, Vol. 53 (1995), p. 630-642 [6] J.
Raghuram: Journal of Materials Processing Technology, Vol. 149 (2004), p. 22-29 [12] D.K.
Yuan: Key Engineering Materials, Vols. 304-305 (2006), p. 113-117 [18] S.M.
Kawashima: Journal of Materials Processing Technology, Vols. 143-144 (2003), p. 682-686 [5] J.
Choi: Journal of Material Processing Technology, Vol. 53 (1995), p. 630-642 [6] J.
Raghuram: Journal of Materials Processing Technology, Vol. 149 (2004), p. 22-29 [12] D.K.
Yuan: Key Engineering Materials, Vols. 304-305 (2006), p. 113-117 [18] S.M.
Online since: October 2013
Authors: Wen Wu Yang, Jian Bo Wang, Peng Chen, Juan Ge
A green construction evaluation index system is established in this paper, which includes five-level aspects such as construction management, materials and material resource utilization, water conservation and utilization, energy efficiency and utilization, and land utilization and protection.
Table 1 Evaluation index system of green construction Indicators Factors Construction management B1 Compiling green construction management system, goal and plan B11 The attendance of green construction management staff B12 Dynamic management of the green construction B13 Self assessment and comprehensive assessment B14 Materials and material resource utilization B2 The use of commodities concrete and mortar B21 The use of high strength steel and high performance concrete B22 Scheme optimization of steel materials B23 Optimization of steel structure production and installation methods B24 Water conservation and utilization B3 Water saving measures in mixing and conserving water B31 Set up the water circulation device B32 Water quota, metrology management B33 The use of unconventional water and recycling water B34 Efficiency and energy utilization B4 Improvement of the equipment files and maintenance B41 Power and load match usage B42 The rationality of the process arrangement
Journal of Construction Technology, Vols. 36 No.11 (2007) 1
Huang, Green construction fuzzy comprehensive evaluation, Journal of Southwest Jiaotong University, Vols. 43 No. 2 (2008) 292
Duan, Construction projects green construction establishment of evaluation system, Journal of Architectural Science, Vols. 25 No. 10 (2009) 35-39
Table 1 Evaluation index system of green construction Indicators Factors Construction management B1 Compiling green construction management system, goal and plan B11 The attendance of green construction management staff B12 Dynamic management of the green construction B13 Self assessment and comprehensive assessment B14 Materials and material resource utilization B2 The use of commodities concrete and mortar B21 The use of high strength steel and high performance concrete B22 Scheme optimization of steel materials B23 Optimization of steel structure production and installation methods B24 Water conservation and utilization B3 Water saving measures in mixing and conserving water B31 Set up the water circulation device B32 Water quota, metrology management B33 The use of unconventional water and recycling water B34 Efficiency and energy utilization B4 Improvement of the equipment files and maintenance B41 Power and load match usage B42 The rationality of the process arrangement
Journal of Construction Technology, Vols. 36 No.11 (2007) 1
Huang, Green construction fuzzy comprehensive evaluation, Journal of Southwest Jiaotong University, Vols. 43 No. 2 (2008) 292
Duan, Construction projects green construction establishment of evaluation system, Journal of Architectural Science, Vols. 25 No. 10 (2009) 35-39
Online since: September 2011
Authors: Wei Kai Xu, Wei Wang
These frequency ranges are commonly called Bandgaps [1], and the periodic materials or structures are termed as Phononic Crystals (PCs) [2].
The metamaterials, firstly refers to Left-handed materials [6], now have been expanded to a broad area that included Double Negative (permittivity and permeability) Materials, Single-Negative (permittivity or permeability) Materials and other artificial materials which have novel properties differ from the naturally occurring materials.
The two component materials are PMMA and aluminum, respectively.
Schultz: Science, Vol. 292 (2001), p.77
Wu: Journal of Applied Physics, Vol. 97 (2005) No. 7, p.076105
The metamaterials, firstly refers to Left-handed materials [6], now have been expanded to a broad area that included Double Negative (permittivity and permeability) Materials, Single-Negative (permittivity or permeability) Materials and other artificial materials which have novel properties differ from the naturally occurring materials.
The two component materials are PMMA and aluminum, respectively.
Schultz: Science, Vol. 292 (2001), p.77
Wu: Journal of Applied Physics, Vol. 97 (2005) No. 7, p.076105
Online since: January 2013
Authors: Zi Ming Yang, Zheng Peng, Pu Wang Li, Min Zhou, Guang Wang, Guang Tao Han, Yu Xin Pang
The ratio of wall material to core material was 2: 1, and the complex condensation pH value was 4.5.
Chinese Journal of Information on TCM.16(2)(2009)
Patchoulicalcohol research summaries, Chinese Journal of Information on TCM. 19(1) (2012)
Journal of Controlled Release, 100(2004)5 –28
Polymer Materials Science and Engineering, 26(7)(2010)118-121
Chinese Journal of Information on TCM.16(2)(2009)
Patchoulicalcohol research summaries, Chinese Journal of Information on TCM. 19(1) (2012)
Journal of Controlled Release, 100(2004)5 –28
Polymer Materials Science and Engineering, 26(7)(2010)118-121
Online since: September 2011
Authors: De Gao Zou, Xian Jing Kong, Tao Gong, Jing Mao Liu
Idriss: Journal of Geotechnical Engineering, Vol. 112 (1986), No. 11, p.1016-1032
Han: Journal of Hydraulic Engineering, Vol. 8 (2001), p.20-25.
Cai: Chinese Journal of Geotechnical Engineering, Vol. 31 (2009), No. 12, p.1920-1924.
Xu: Hydraulic Science and Engineering, Vol. 2, (1996), p.143-150.
Han: Chinese Journal of Geotechnical Engineering, Vol. 23 (2001), p.32-37.
Han: Journal of Hydraulic Engineering, Vol. 8 (2001), p.20-25.
Cai: Chinese Journal of Geotechnical Engineering, Vol. 31 (2009), No. 12, p.1920-1924.
Xu: Hydraulic Science and Engineering, Vol. 2, (1996), p.143-150.
Han: Chinese Journal of Geotechnical Engineering, Vol. 23 (2001), p.32-37.
Online since: December 2010
Authors: Zhen Guo Wang, Sheng Li Lv, Cheng Long Xu, Fei Zhao, Xiao Yan Tong
Relying on "The data accumulation and laws of materials corrosion in the natural environment" - a major project of the National Natural Science Foundation of China, a lot of valuable data of typical metals subjected to long period of seawater corrosion have been collected and summarized.
Digital simulation system can also vividly describe service process of engineering structural materials acrossing time-scale domain.
The data retrieval modes have test places, test areas, test time, materials and corrosion types.
Li: Materials Science and Engineering A Vol.369 (2004), p.284 [5] D.M.
Hu: Journal of Ship Mechanics Vol.9 (2005), p.103 [8] R.E.
Digital simulation system can also vividly describe service process of engineering structural materials acrossing time-scale domain.
The data retrieval modes have test places, test areas, test time, materials and corrosion types.
Li: Materials Science and Engineering A Vol.369 (2004), p.284 [5] D.M.
Hu: Journal of Ship Mechanics Vol.9 (2005), p.103 [8] R.E.
Online since: May 2009
Authors: Y.T. Dai, Gang Xu, Wei Lai Li
Introduction
Deep-ultraviolet (DUV) laser is often applied to micro-fabrication of nonmetal materials because the
materials strongly absorb the laser beam.
Silica glass and diamond-like materials are representatives of the materials hard to machine.
However, development of 157nm laser technology opens new opportunities for micromachining those materials.
Conclusions Deep-UV laser with 157nm wavelength is conducted into micromachining of wide band-gap materials.
References [1] S.Harry,M.James,J.Peter et al:Journal of Photopolymer Science and Technology,Vol.15(2002), pp.569-576
Silica glass and diamond-like materials are representatives of the materials hard to machine.
However, development of 157nm laser technology opens new opportunities for micromachining those materials.
Conclusions Deep-UV laser with 157nm wavelength is conducted into micromachining of wide band-gap materials.
References [1] S.Harry,M.James,J.Peter et al:Journal of Photopolymer Science and Technology,Vol.15(2002), pp.569-576
Online since: March 2013
Authors: Sarabjeet Singh Sidhu, Sanjeev Kumar, Ajay Batish
Journal of Materials Processing Technology 1997, 63, 813-818
Journal of Materials Processing Technology 2004, 155, 1653-1657
Journal of Materials Processing Technology 2004, 153, 978-985
Journal of Materials Processing Technology 2007, 183, 122-126
Journal of Materials Science 2003, 38, 1679-1687
Journal of Materials Processing Technology 2004, 155, 1653-1657
Journal of Materials Processing Technology 2004, 153, 978-985
Journal of Materials Processing Technology 2007, 183, 122-126
Journal of Materials Science 2003, 38, 1679-1687
Online since: June 2011
Authors: B.T. Hang Tuah Baharudin, Shamsuddin Sulaiman, Mohd Khairol A. Arifin, Mohd Sayuti, S. Suraya, T.R. Vijayaram
Some manufacturers which use particulate and discontinuous fiber materials report that their costs were already competitive with those of conventional materials.
Rohatgi, Aluminium alloy-silica sand composites: preparation and properties, Journal of Materials Science, 21 (1986), pp 3413-3419 [9] K.H.W.
King, A Production Engineers View of Advanced Composite Materials, Materials & Design, Vol.3 (1982), pp.515-522
Journal of Materials Science. 29(4) (1994), pp 2541 – 2556
[13] F.L.Matthew and R.D.Rawlings, Composite Material; Engineering and Science, Imperial College of Science, UK (1999).
Rohatgi, Aluminium alloy-silica sand composites: preparation and properties, Journal of Materials Science, 21 (1986), pp 3413-3419 [9] K.H.W.
King, A Production Engineers View of Advanced Composite Materials, Materials & Design, Vol.3 (1982), pp.515-522
Journal of Materials Science. 29(4) (1994), pp 2541 – 2556
[13] F.L.Matthew and R.D.Rawlings, Composite Material; Engineering and Science, Imperial College of Science, UK (1999).
Online since: January 2015
Authors: Vladimir Lalin, Elizaveta Zdanchuk
Gravity flow of granular materials in Hoppers and bins in mines (1965) International Journal of Rock Mechanics and Mining Sciences & Geomechanics Abstracts, Volume 2, Issue 3, pp. 277–292
[7] Peijun Guo, Xubin Su, Shear strength, interparticle locking, and dilatancy of granular materials (2007) Canadian Geotechnical Journal, 44(5), pp. 579-591
Permeability of compacted granular materials (1984) Canadian Geotechnical Journal, 21(4), pp.726-729
Bio-Materials and Prototyping Applications in Medicine (2007) Bio-Materials and Prototyping Applications in Medicine, 227 p
Nonlinear thermodynamic model for reduced Cosserat continuum (2014) International Journal of Mathematical Models and Methods in Applied Sciences, V. 8, pp. 208-213
[7] Peijun Guo, Xubin Su, Shear strength, interparticle locking, and dilatancy of granular materials (2007) Canadian Geotechnical Journal, 44(5), pp. 579-591
Permeability of compacted granular materials (1984) Canadian Geotechnical Journal, 21(4), pp.726-729
Bio-Materials and Prototyping Applications in Medicine (2007) Bio-Materials and Prototyping Applications in Medicine, 227 p
Nonlinear thermodynamic model for reduced Cosserat continuum (2014) International Journal of Mathematical Models and Methods in Applied Sciences, V. 8, pp. 208-213