Sort by:
Publication Type:
Open access:
Publication Date:
Periodicals:
Search results
Online since: February 2014
Authors: Wen Sheng Linghu, Jia Ming Cui
Kwak: Journal of Membrane Science Vol. 448 (2013), p. 125
[4] D.
Hota: Journal of hazardous Materials Vol. 258-259 (2013), p. 116 [6] O.
Bagheri: Journal of hazardous Materials Vol. 181 (2010), p. 836 [9] X.
Abe: Journal of Hazardous Materials Vol. 217–218 (2012), p. 85 [13] N.
Alacabey: Journal of Hazardous Materials Vol. 193 (2011), p. 27
Hota: Journal of hazardous Materials Vol. 258-259 (2013), p. 116 [6] O.
Bagheri: Journal of hazardous Materials Vol. 181 (2010), p. 836 [9] X.
Abe: Journal of Hazardous Materials Vol. 217–218 (2012), p. 85 [13] N.
Alacabey: Journal of Hazardous Materials Vol. 193 (2011), p. 27
Online since: March 2015
Authors: Quan Jiang, Ping Zhao, Ying Wang, Li Ping Ma, Chun Zhi Zhao
How to select building materials to be more conducive to building energy conservation?
Direct (1) Indirect Where, EDirect- the energy contained in a unit product of a building material, also known as direct energy consumption, MJ/kg building materials; EIndirect-building operation energy saving brought in the service process of a unit of building materials product, also known as indirect energy consumption, MJ/kg building materials.
Two of the national 12th Five-year Plan Science and Technology Support Plan Projects - " Research and Application of Full Life Cycle Evaluation Technology of Building Materials in Typical Areas" (No. : 2011 BAJ 04B06) and "Research of Technology Integration Service System in Building Materials Industry" ( No. 2014BAH25F05) References [1] Jiang Quan Green Building Material Evaluation - Evaluation · Certification [M] Beijing: Chemical Industry Press, July, 2012 [2] National Standard of The People's Republic Of China.
Journal of Environmental Science. 2010, 30(10): 2136-2144
Building Science, 2014.
Direct (1) Indirect Where, EDirect- the energy contained in a unit product of a building material, also known as direct energy consumption, MJ/kg building materials; EIndirect-building operation energy saving brought in the service process of a unit of building materials product, also known as indirect energy consumption, MJ/kg building materials.
Two of the national 12th Five-year Plan Science and Technology Support Plan Projects - " Research and Application of Full Life Cycle Evaluation Technology of Building Materials in Typical Areas" (No. : 2011 BAJ 04B06) and "Research of Technology Integration Service System in Building Materials Industry" ( No. 2014BAH25F05) References [1] Jiang Quan Green Building Material Evaluation - Evaluation · Certification [M] Beijing: Chemical Industry Press, July, 2012 [2] National Standard of The People's Republic Of China.
Journal of Environmental Science. 2010, 30(10): 2136-2144
Building Science, 2014.
Online since: June 2013
Authors: Qiang Shen, Xiao Juan Jiang, Guo Qiang Luo, Mei Juan Li, Lian Meng Zhang
Graphene-based nanocomposite materials show promising properties in many fields.
Experimental section Materials.
Graphite was obtained from Nanjing XFNANO Materials Tech Co, Ltd.
Zhu: Journal of Colloid and Interface Science.
Wang: Materials Chemistry and Physics.
Experimental section Materials.
Graphite was obtained from Nanjing XFNANO Materials Tech Co, Ltd.
Zhu: Journal of Colloid and Interface Science.
Wang: Materials Chemistry and Physics.
Online since: April 2023
Authors: Emad K. Al-Shakarchi, Zaid K. Alkaabi
Bismuth strontium calcium copper oxide (BSCCO) system of high temperature superconductor is one of the materials that attracts the attention of researchers in materials science [2,3].
Such materials are difficult to prepare and it requires great care and great handling.
Materials Science Forum. 1039, 269-273 [2] H.
Phase formation and microstructure of gamma irradiated Bi-2223 Superconductor Materials Science and Engineering 298 012021 [5] V.Grnier,R.caillard,G.desgardin,(2001) (Bi−Pb)2Sr2Ca2Cu3O10+6 ceramic synthesized using a polymer matrix method, Journal of the European Ceramic Society 21, 1139−1142 [6] N.
Journal of aerosol science 22.5 (1991): 585-599
Such materials are difficult to prepare and it requires great care and great handling.
Materials Science Forum. 1039, 269-273 [2] H.
Phase formation and microstructure of gamma irradiated Bi-2223 Superconductor Materials Science and Engineering 298 012021 [5] V.Grnier,R.caillard,G.desgardin,(2001) (Bi−Pb)2Sr2Ca2Cu3O10+6 ceramic synthesized using a polymer matrix method, Journal of the European Ceramic Society 21, 1139−1142 [6] N.
Journal of aerosol science 22.5 (1991): 585-599
Online since: January 2013
Authors: Jung Hwan Ahn, Yong Sik Cho, Hwa Young Kim, Hyo Ryeol Lee
AWJ is used to obtain cutting quality of various materials such as metal, ceramics, glass and composite materials within a short manufacturing time because of the characteristics of heatless and noncontact processing.
The traditional methods have become ineffective for machining of hard and brittle materials such that productivity cannot be achieved.
In addition, the plastically deformed material rolls over at the bottom of the kerf forming burrs at the jet exit side when cutting ductile materials.[4] The kerf taper angle for each cut was calculated using the measured values of the top and bottom width for each cut based on the equation.[5] Taper angle = tan-1(WT-WB/2T) (1) Fig.4.
References [1] Mahabalesh Palleda, “A study of taper angles and material removal rates of drilled holes in the abrasive water jet machining process”, Journal of Materials Processing Technology, Vol.189 (2007), p. 292-295 [2] D.K.
Ahn, "Computational fluid analysis of abrasive waterjet cutting head", Journal of Mechanical Science and Technology, Vol. 24 (2010), p. 249-252 [4] J.
The traditional methods have become ineffective for machining of hard and brittle materials such that productivity cannot be achieved.
In addition, the plastically deformed material rolls over at the bottom of the kerf forming burrs at the jet exit side when cutting ductile materials.[4] The kerf taper angle for each cut was calculated using the measured values of the top and bottom width for each cut based on the equation.[5] Taper angle = tan-1(WT-WB/2T) (1) Fig.4.
References [1] Mahabalesh Palleda, “A study of taper angles and material removal rates of drilled holes in the abrasive water jet machining process”, Journal of Materials Processing Technology, Vol.189 (2007), p. 292-295 [2] D.K.
Ahn, "Computational fluid analysis of abrasive waterjet cutting head", Journal of Mechanical Science and Technology, Vol. 24 (2010), p. 249-252 [4] J.
Online since: November 2007
Authors: Qiu Sheng Yan, Jia Bin Lu, Wei Qiang Gao, Juan Yu, Hong Tian
Volkova: Journal of Magnetism and Magnetic Materials,
Vol.252 (2002), pp.224-228
Zhang: Materials Science Forum, Vols.532-533 (2006), pp.145-148
Gao: International Journal of Materials and Product Technology, in press
Park: Journal of Colloid and Interface Science, Vol.240 (2001), pp.349-354
Zhao: Optical Materials, Vol.22 (2003), pp.39-44.
Zhang: Materials Science Forum, Vols.532-533 (2006), pp.145-148
Gao: International Journal of Materials and Product Technology, in press
Park: Journal of Colloid and Interface Science, Vol.240 (2001), pp.349-354
Zhao: Optical Materials, Vol.22 (2003), pp.39-44.
Online since: February 2014
Authors: Manja Kitek Kuzman, Srečko Vratuša, Petra Grošelj
Sustainability also governs decisions concerning building materials.
Embodied energy in building materials represents the non-renewable energy consumed in the acquisition of raw materials, their processing, manufacturing, transportation to site, and construction – it represents the relationship between building materials, construction processes, and their environmental impacts.
Acknowledgements This study was a part of the Research Program “Wood and lignocellulosic materials” supported by the Ministry of Higher Education, Science and Technology of the Republic of Slovenia.
[5] Joseph, P., Tretsiakova-McNally, S.: Sustainable Non-Metallic Building Materials.
World Applied Sciences Journal 3(4): 609-613, (2008)
Embodied energy in building materials represents the non-renewable energy consumed in the acquisition of raw materials, their processing, manufacturing, transportation to site, and construction – it represents the relationship between building materials, construction processes, and their environmental impacts.
Acknowledgements This study was a part of the Research Program “Wood and lignocellulosic materials” supported by the Ministry of Higher Education, Science and Technology of the Republic of Slovenia.
[5] Joseph, P., Tretsiakova-McNally, S.: Sustainable Non-Metallic Building Materials.
World Applied Sciences Journal 3(4): 609-613, (2008)
Online since: September 2008
Authors: Alberto Carpinteri, Pietro Cornetti, Alberto Sapora, Nicola Maria Pugno
Gao: International Journal of Fracture 138 (2006), 101
Wienkamer: Progress in Materials Science 52 (2007), 1263
Carpinteri: Mechanics of Materials, 18 (1994), 89
Pugno: Nature Materials 4 (2005), 421
Gurland: Materials science and engineering 33 (1978), 125.
Wienkamer: Progress in Materials Science 52 (2007), 1263
Carpinteri: Mechanics of Materials, 18 (1994), 89
Pugno: Nature Materials 4 (2005), 421
Gurland: Materials science and engineering 33 (1978), 125.
Online since: July 2011
Authors: Peng Dong, Hai Liang Wang, Xin Lei Yang, Quan Chang Ren
Tang Ming et al used the BF as reinforced materials to explore the BF in enhancing effect.
The purpose of this paper is to arouse the domestic bridge workers’ attention of the importance of the BF and make this new, high performance fiber materials can be widely used as soon as possible in the construction of the bridge.
Wang: Progress in Textile Science & Technology, 2010 (1):40-41.
Li: Journal of Hebei Institute of Architecture and Civil Engineering, 2008, 26(3):7-8.
Yang: Journal of Huaqiao University (Natural Science). 2010, 31(4):443-447.
The purpose of this paper is to arouse the domestic bridge workers’ attention of the importance of the BF and make this new, high performance fiber materials can be widely used as soon as possible in the construction of the bridge.
Wang: Progress in Textile Science & Technology, 2010 (1):40-41.
Li: Journal of Hebei Institute of Architecture and Civil Engineering, 2008, 26(3):7-8.
Yang: Journal of Huaqiao University (Natural Science). 2010, 31(4):443-447.
Online since: May 2020
Authors: Michal Petrů, Pavel Srb
Although an alternative solution is currently being developed to replace polyurethane foam by different materials [5].
Banik [14] determined the effects of various cellulosic fibrous materials on the formation of foam structure.
Journal of Polymer Science Part A: Polymer Chemistry, 2005, Vol 44, Issue 1, ISSN 1099-0518 [12] Gu, R. et al.
Water-blown soy polyol based polyurethane foams modified by cellulosic materials obtained from different sources.
Journal of Applied Polymer Science, 2009, Vol 112, Issue 4, pp 1974-1987, ISSN 1097-4628 [15] Chiang, C.C.
Banik [14] determined the effects of various cellulosic fibrous materials on the formation of foam structure.
Journal of Polymer Science Part A: Polymer Chemistry, 2005, Vol 44, Issue 1, ISSN 1099-0518 [12] Gu, R. et al.
Water-blown soy polyol based polyurethane foams modified by cellulosic materials obtained from different sources.
Journal of Applied Polymer Science, 2009, Vol 112, Issue 4, pp 1974-1987, ISSN 1097-4628 [15] Chiang, C.C.