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Online since: May 2013
Authors: Amit Sobti, R.K. Wanchoo
Singh, Thermal Conductivity of Nanofluids, Defence Science Journal 58 (2008) 600-607
Ai, Dependence of the thermal conductivity of nanoparticle-fluid mixture on the base fluid, Journal of Materials Science Letters 21 (2002) 1469-1471
Xu, A model of thermal conductivity of nanofluids with interfacial shells, Materials Chemistry and Physics 90 (2005) 298-301
, International Journal of Thermal Sciences 57 (2012) 152-162
Keblinski, Thermal transport in nanofluids, Annual Review of Materials Research 34 (2004) 219–246.
Ai, Dependence of the thermal conductivity of nanoparticle-fluid mixture on the base fluid, Journal of Materials Science Letters 21 (2002) 1469-1471
Xu, A model of thermal conductivity of nanofluids with interfacial shells, Materials Chemistry and Physics 90 (2005) 298-301
, International Journal of Thermal Sciences 57 (2012) 152-162
Keblinski, Thermal transport in nanofluids, Annual Review of Materials Research 34 (2004) 219–246.
Online since: August 2021
Authors: Dmitriy S. Manturov, Oleg V. Kudryakov, Valery N. Varavka
Varavka, Integrated indentation tests of metal-ceramic nanocomposite coatings, Inorganic Materials. 51(15) (2015) 1508-1515
Kim (Eds.), Physics, Mechanics of New Materials and Their Applications, ch. 1, Nova Science Publishers, New York, 2019, pp.1-12
Pharr An improved technique for determining hardness and elastic modulus using load and displacement sensing indentation experiments, Journal of materials research. 7 (1992) 1564-1583
Metallic Materials - Instrumented Indentation Test for Hardness and Materials Parameters - Part 1: Test Method, Standartinform, Moscow, 2013
Varavka: submitted to Journal of Friction and Wear (2020).
Kim (Eds.), Physics, Mechanics of New Materials and Their Applications, ch. 1, Nova Science Publishers, New York, 2019, pp.1-12
Pharr An improved technique for determining hardness and elastic modulus using load and displacement sensing indentation experiments, Journal of materials research. 7 (1992) 1564-1583
Metallic Materials - Instrumented Indentation Test for Hardness and Materials Parameters - Part 1: Test Method, Standartinform, Moscow, 2013
Varavka: submitted to Journal of Friction and Wear (2020).
Online since: July 2016
Authors: Akhmad Suryadi, Qomariah Qomariah, M. Sarosa
If the experimental results contain the relevant information about the material behavior, then the trained neural network will contain sufficient information about material’s behavior to qualify as a material model [6].
Materials The main purpose of the research evaluate the compressive strength of self compacting concrete (SCC) made with locally available materials, such as cement, aggregate, and fly ash using artificial neural network models.
The second phase involved determining if Self Compacting Concrete could be manufactured in large quantities for field applications using locally available materials.
[2] Okumura Hajime and Ouchi Masahiro, Self-Compacting Concrete, Journal of Advance Technology, Vol 1, No. 1, 2003, pp. 5-15
[5] Suryadi Akhmad, Predicting the Initial Setting Time of Self Compacting Concrete Using Artificial Neural Networks with the Various of Learning Rate Coefficient, Journal of Applied Sciences Research (JASR), Jordan, Vol. 7, number 3, February 2011, pp 314-320
Materials The main purpose of the research evaluate the compressive strength of self compacting concrete (SCC) made with locally available materials, such as cement, aggregate, and fly ash using artificial neural network models.
The second phase involved determining if Self Compacting Concrete could be manufactured in large quantities for field applications using locally available materials.
[2] Okumura Hajime and Ouchi Masahiro, Self-Compacting Concrete, Journal of Advance Technology, Vol 1, No. 1, 2003, pp. 5-15
[5] Suryadi Akhmad, Predicting the Initial Setting Time of Self Compacting Concrete Using Artificial Neural Networks with the Various of Learning Rate Coefficient, Journal of Applied Sciences Research (JASR), Jordan, Vol. 7, number 3, February 2011, pp 314-320
Online since: October 2013
Authors: D. Pincott, A.S. Blicblau
Penner, Canadian Journal of Physics, Vol. 80 (2002) p.931
Cochran, Journal of Sports Sciences, Vol. 20 (2002) p. 635
Yokoyama, Applied Mechanics and Materials Vol. 7-8 (2007) p. 237
Novak, in: Materials Science and Technology 2003 Meeting, Chicago, 2003, p. 397
Ujihashi, Proceedings of the Institution of Mechanical Engineers, Part P: Journal of Sports Engineering and Technology, 226 (2012) 96-106.
Cochran, Journal of Sports Sciences, Vol. 20 (2002) p. 635
Yokoyama, Applied Mechanics and Materials Vol. 7-8 (2007) p. 237
Novak, in: Materials Science and Technology 2003 Meeting, Chicago, 2003, p. 397
Ujihashi, Proceedings of the Institution of Mechanical Engineers, Part P: Journal of Sports Engineering and Technology, 226 (2012) 96-106.
Online since: January 2013
Authors: Fang Guo, Wei Gu, Jie Jun Tang, Ming Hai Murong
The structural equation is obtained as:
(3)
Where is a parameter related to the materials strength.
Acknowledgements This work was financially supported by the National Natural Science Foundation (51078042, 51278067), the Hunan Science and Technology Plan Project(2009003)and the Western Traffic Science and Technology Plan Project (2009 318 000 048).
Chinese Journal of Geotechnical Engineering, 1997,19(2):1-7
Chinese Journal of Rock Mechanics and Engineering, 2002, 21(9): 1397-1391
Journal of East China Geological Institute, 2002, 25(3):220-227.
Acknowledgements This work was financially supported by the National Natural Science Foundation (51078042, 51278067), the Hunan Science and Technology Plan Project(2009003)and the Western Traffic Science and Technology Plan Project (2009 318 000 048).
Chinese Journal of Geotechnical Engineering, 1997,19(2):1-7
Chinese Journal of Rock Mechanics and Engineering, 2002, 21(9): 1397-1391
Journal of East China Geological Institute, 2002, 25(3):220-227.
Online since: May 2011
Authors: Yu Liang Qiu, Xiao Yong Hu, Xiao Xu Zhang, Wei Hua Dong, Bao Wen Kou
Table 1 shows the mechanical parameters of rock, tunnel structure and backfill materials.
Acknowledgements This study is supported by Science and Technology Special Support of CCCC (KYHT2008-10).
Jiyang Fu, Jiu-rong Wu, An Xu: Journal of Hunan University (Natural Sciences), Vol. 35 (2008), P. 23-27, in Chinese
Guihong Chen: China Railway Science, Vol. 26 (2005), P. 93 -97, in Chinese
Journal of South China University of Technology: Natural Science, Vol. 27 (1999), P. 108-114, in Chinese.
Acknowledgements This study is supported by Science and Technology Special Support of CCCC (KYHT2008-10).
Jiyang Fu, Jiu-rong Wu, An Xu: Journal of Hunan University (Natural Sciences), Vol. 35 (2008), P. 23-27, in Chinese
Guihong Chen: China Railway Science, Vol. 26 (2005), P. 93 -97, in Chinese
Journal of South China University of Technology: Natural Science, Vol. 27 (1999), P. 108-114, in Chinese.
Online since: May 2011
Authors: Yuan Chen, Chang Bin Xia, Fan Gao, Ying Zhu, Chen Lin Dai, Jun Liu, Ling Zhang
Experimental materials and equipment
(1)Sludge is the original mud from sludge thickening tank at a sewage treatment plants in Changsha.
The microstructure shows that there are less colloidal material, porosity and larger, faster spin speed
Engineering Vol. 25 (In Chinese 2008), p. 19-22 [6] Li Gan, Zhaoping Meng and Jienan Pan: Journal of China University of Mining and Technology.
Vol. 14 (In Chinese 2004), p. 238-242 [7] Rongmei Shi, Ping Ning: Journal of Kunming University of Science and Technology.
Vol. 14 (In Chinese 2008), p. 65-85 [8] Junju Shen, Leilei Ren and Yuanyi Zhuang: Journal of Hazardous Materials.
The microstructure shows that there are less colloidal material, porosity and larger, faster spin speed
Engineering Vol. 25 (In Chinese 2008), p. 19-22 [6] Li Gan, Zhaoping Meng and Jienan Pan: Journal of China University of Mining and Technology.
Vol. 14 (In Chinese 2004), p. 238-242 [7] Rongmei Shi, Ping Ning: Journal of Kunming University of Science and Technology.
Vol. 14 (In Chinese 2008), p. 65-85 [8] Junju Shen, Leilei Ren and Yuanyi Zhuang: Journal of Hazardous Materials.
Online since: February 2015
Authors: Sufizar Ahmad, M.S.A. Bakar, A. Muchtar, H. Basri, Hamimah Abdul Rahman
Introduction
In order to increase the life-time of the cell as well as to reduce the cost of materials, research regarding solid oxide fuel cell (SOFC) was targeted to lower the operating temperature so it can feasible to be commercialized [1].
In this paper, perovskite-type La0.6Sr0.4Co0.2Fe0.8O3-δ (LSCF6428), a type of mixed ionic-electronic conductor material (MIEC) are combined with samarium doped cerium carbonated SDCC forming composite cathode LSCF-SDCC powder then applied as the cathode materials of LTSOFC [3].
Method The raw materials used were a commercial LSCF powder (LSCF6428; KCeracell, Korea) and self-fabricated of SDC carbonate (SDCC) powder.
EDS mapping shows that all the elements were distribute uniformly via wet milling method provide better composite powder for LTSOFC cathode materials.
Journal of Hydrogen Energy. 38 (2013) 14060-14066
In this paper, perovskite-type La0.6Sr0.4Co0.2Fe0.8O3-δ (LSCF6428), a type of mixed ionic-electronic conductor material (MIEC) are combined with samarium doped cerium carbonated SDCC forming composite cathode LSCF-SDCC powder then applied as the cathode materials of LTSOFC [3].
Method The raw materials used were a commercial LSCF powder (LSCF6428; KCeracell, Korea) and self-fabricated of SDC carbonate (SDCC) powder.
EDS mapping shows that all the elements were distribute uniformly via wet milling method provide better composite powder for LTSOFC cathode materials.
Journal of Hydrogen Energy. 38 (2013) 14060-14066
Online since: January 2013
Authors: Shu Ming Wen, Si Qing Liu, Li Kun Gao, Guo Dong Xu, Lu Zheng Chen
Fine hematite and ilmenite materials were used for the investigation.
The material is less than 74 μm, and has a particle size below 43 μm by 78.70%, accounting for 81.33% of the total iron in the material.
The materials were fully mixed at a solid concentration around 10% and evenly fed to the separator within 15-20 s.
Wen: submitted to International Journal of Mineral Processing. (2012)
Liu: Journal of Magnetism and Magnetic Materials. 311 (2), 481-488 (2007).
The material is less than 74 μm, and has a particle size below 43 μm by 78.70%, accounting for 81.33% of the total iron in the material.
The materials were fully mixed at a solid concentration around 10% and evenly fed to the separator within 15-20 s.
Wen: submitted to International Journal of Mineral Processing. (2012)
Liu: Journal of Magnetism and Magnetic Materials. 311 (2), 481-488 (2007).
Online since: February 2011
Authors: Chang Juan Jing, Da Li Liu, Qing Xi Hu, Yuan Yuan Liu, Qiang Gao Wang
Materials testing, which compares the quality of both materials of the construction scaffold with those in the two injectors, is made up of RP and electrospinning material testing.
[3] Subbiah T, Bhat G S, T ock R W, et al.: Applied Polymer Science Vol. 96(2005), p. 557–569
[4] He Ji huan, WuY,et al.: Journal of the Polymer Vol. 46(2005), p. 12637-12640
[6] Fallahi, Rafizaden, Mohammadi: Polymer Engineering and Science Vol.10 (2010), p. 1372–1376
[7] Zhu Ya-bin, Li Yuan-yuan, Liu Yu-xin: Journal of the Ningbo University Vol. 22 (2009), p. 408-413, in Chinese.
[3] Subbiah T, Bhat G S, T ock R W, et al.: Applied Polymer Science Vol. 96(2005), p. 557–569
[4] He Ji huan, WuY,et al.: Journal of the Polymer Vol. 46(2005), p. 12637-12640
[6] Fallahi, Rafizaden, Mohammadi: Polymer Engineering and Science Vol.10 (2010), p. 1372–1376
[7] Zhu Ya-bin, Li Yuan-yuan, Liu Yu-xin: Journal of the Ningbo University Vol. 22 (2009), p. 408-413, in Chinese.