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Online since: September 2014
Authors: George Tarasov, Konstantin Gyrnik, Denis Leontev
Acknowledgments
The work was supported by the Ministry of education and science of Russian Federation (project 14.Y26.31.0003), the Russian Foundation for Basic Research (grants No. 14-01-90008-Bel_a), the Far Eastern Federal University, the Far-Eastern Branch of the Russian Academy of Sciences.
Lutsenko, Gas flow through a porous heat-releasing medium with allowance for the temperature dependence of gas viscosity, Journal of Engineering Physics and Thermophysics 79 (1) (2006) 33-39
Lutsenko, Numerical modeling of unsteady gas flow through porous heat-evolutional objects with partial closure of the object's outlet, International Journal of Heat and Mass Transfer 72 (2014) 602-608
Sorokova, Numerical Method for Investigation of 1D Processes in Porous Media with Heterogeneous Reactions when Flow Rate of Oxidant Regulates Itself, Advanced Materials Research 880 (2014) 115-120
Sorokova, Numerical Comparison of Heterogeneous Combustion Waves in Horizontal and Vertical Porous Objects under Free Convection, Advanced Materials Research 880 (2014) 109-114
Lutsenko, Gas flow through a porous heat-releasing medium with allowance for the temperature dependence of gas viscosity, Journal of Engineering Physics and Thermophysics 79 (1) (2006) 33-39
Lutsenko, Numerical modeling of unsteady gas flow through porous heat-evolutional objects with partial closure of the object's outlet, International Journal of Heat and Mass Transfer 72 (2014) 602-608
Sorokova, Numerical Method for Investigation of 1D Processes in Porous Media with Heterogeneous Reactions when Flow Rate of Oxidant Regulates Itself, Advanced Materials Research 880 (2014) 115-120
Sorokova, Numerical Comparison of Heterogeneous Combustion Waves in Horizontal and Vertical Porous Objects under Free Convection, Advanced Materials Research 880 (2014) 109-114
Online since: August 2016
Authors: Agnieszka Kułakowska, Radoslaw Patyk, Łukasz Bohdal, Marcin Kulakowski
Patyk, Three Dimensional Finite Element Simulation of Sheet Metal Blanking Process, Applied Mechanics and Materials 474 (2014) 430-435
Kukielka, Numerical Analysis and Simulation of Drawpiece Forming Process by Finite Element Method, Applied Mechanics and Materials 474 (2014) 153-158
R.SEM/EDX and XPS studies of niobium after electropolishing, Applied Surface Science, 2012, 263, 357-361 [6] J.
Bohdal, Possibility of Steering of Product Surface Layers Properties in Burnishing Rolling Process, Applied Mechanics and Materials 474 (2014) 442-447
Patyk, Problems Determining of the Mechanical Properties of Metallic Materials from the Tensile Test in the Aspect of Numerical Calculations of the Technological Processes, Applied Mechanics and Materials 474 (2014) 454-459
Kukielka, Numerical Analysis and Simulation of Drawpiece Forming Process by Finite Element Method, Applied Mechanics and Materials 474 (2014) 153-158
R.SEM/EDX and XPS studies of niobium after electropolishing, Applied Surface Science, 2012, 263, 357-361 [6] J.
Bohdal, Possibility of Steering of Product Surface Layers Properties in Burnishing Rolling Process, Applied Mechanics and Materials 474 (2014) 442-447
Patyk, Problems Determining of the Mechanical Properties of Metallic Materials from the Tensile Test in the Aspect of Numerical Calculations of the Technological Processes, Applied Mechanics and Materials 474 (2014) 454-459
Online since: March 2024
Authors: Chieko Narita, Kazushi Yamada
In recent years, great attention has been paid to the development of porous materials with excellent reactivity and absorbency.
Prussian blue nanoparticles are known to adsorb radioactive materials such as cesium, and are expected to be applied to the recovery of cesium diffused in the atmosphere and ocean.
Porous materials have a large surface area to volume ratio, and thus have a wide range of applications, such as absorbency and adsorption.
Compared to aerogels, sponges, and nanoporous films, fibrous materials have a wide range of forms and shapes that can be tailored to their respective applications.
Experimental Materials and sample preparation.
Prussian blue nanoparticles are known to adsorb radioactive materials such as cesium, and are expected to be applied to the recovery of cesium diffused in the atmosphere and ocean.
Porous materials have a large surface area to volume ratio, and thus have a wide range of applications, such as absorbency and adsorption.
Compared to aerogels, sponges, and nanoporous films, fibrous materials have a wide range of forms and shapes that can be tailored to their respective applications.
Experimental Materials and sample preparation.
Online since: July 2016
Authors: Antoni Świć, Arkadiusz Gola
Świć, Mathematical Models for Manufacturing Systems Capacity Planning and Expansion – an Overview, Applied Mechanics and Materials, 125-131, DOI: 10.4028/www.scientific.net/AMM.791.125
Shpitalni, Design of Reconfigurable Manufacturing Systems, Journal of Manufacturing Systems, 29 (2010) 130-141
Konczal, RMS – System of the Future or New Trend in Science, Advances in Science and Technology, 7, 20 (2013) 35-41
Arora, Reconfigurable Manufacturing System: An Overview, International Journal of Machine Intelligence, 1, 2 (2009) 38-46
Sobaszek, Computer Programming as a Tool for the Engineering Problems Analysis, Applied Computer Science, 9, 2 (2013) 57-71
Shpitalni, Design of Reconfigurable Manufacturing Systems, Journal of Manufacturing Systems, 29 (2010) 130-141
Konczal, RMS – System of the Future or New Trend in Science, Advances in Science and Technology, 7, 20 (2013) 35-41
Arora, Reconfigurable Manufacturing System: An Overview, International Journal of Machine Intelligence, 1, 2 (2009) 38-46
Sobaszek, Computer Programming as a Tool for the Engineering Problems Analysis, Applied Computer Science, 9, 2 (2013) 57-71
Online since: July 2011
Authors: Masumi Obara, Mitusgi Hamasaki, Kozo Obara, Hirotaka Manaka
These experimental facts suggest the effectiveness of the application of the excitation process of the inner core electron system as a new advanced material process.
These experimental facts suggest the effectiveness of the application of the excitation process of the inner core electron system as a new advanced material process.
Hatano of the Advance Science Research Center of Japan Atomic Energy Agency and emeritus Prof.
Brock:Nucleation, coarsening, and coalescence during layer-by-layer growth of complex oxides via pulsed laser deposition: time-resolved, diffuse x-ray Scattering studies: Materials Science & Engineering A (2010) [3] NIST Atomic Spectra Database levels Data http://physics.nist.gov/asd3 [4] N.
Stoneham, Materials Modification by Electronic Excitation, Cambridge, 2001 [5] A.
These experimental facts suggest the effectiveness of the application of the excitation process of the inner core electron system as a new advanced material process.
Hatano of the Advance Science Research Center of Japan Atomic Energy Agency and emeritus Prof.
Brock:Nucleation, coarsening, and coalescence during layer-by-layer growth of complex oxides via pulsed laser deposition: time-resolved, diffuse x-ray Scattering studies: Materials Science & Engineering A (2010) [3] NIST Atomic Spectra Database levels Data http://physics.nist.gov/asd3 [4] N.
Stoneham, Materials Modification by Electronic Excitation, Cambridge, 2001 [5] A.
Online since: January 2010
Authors: H. A. Cortéz, V. H. Jacobo, A. Ortiz, Rafael Schouwenaars
Properties of the rolled material.
This can be attributed to the use of materials of commercial purity, the fact that a three-dimensional experimental space was sampled over a fairly broad range and the complexity of the two-phase alloy under consideration.
Elsivier Science Publishers, 1983
Elsevier Science, Netherlands, 1995
Materials Science and Engineering A 409 (2005) 39-45 [14] Kuhlmann, D.
This can be attributed to the use of materials of commercial purity, the fact that a three-dimensional experimental space was sampled over a fairly broad range and the complexity of the two-phase alloy under consideration.
Elsivier Science Publishers, 1983
Elsevier Science, Netherlands, 1995
Materials Science and Engineering A 409 (2005) 39-45 [14] Kuhlmann, D.
Online since: August 2009
Authors: Yan Fei Xiong, Jiang Yu, Hao Lin, Shi Li Li
However, it's
dangerous use the dry grinding method to grind flammable and explosive materials by fluid energy.
As to combustible materials, the key is to avoid frying materials being contacted with oxygen.
Some experts from Najing University of Science represented by Liu Hongying have designed the new drying jet mill which can refine oxidant-style materials such as APC into less than 2um, and the degree of fineness is adjustable according to different requirements. 2.
Chinese Journal of Explosives & Propellants, 2002,12:12-13.
Ultrafine RDX Explosive Prepared by Pulse Ram -Type Pulverization M ethod[J],ENERGETIC MATERIALS,2005,13(5):321-322.
As to combustible materials, the key is to avoid frying materials being contacted with oxygen.
Some experts from Najing University of Science represented by Liu Hongying have designed the new drying jet mill which can refine oxidant-style materials such as APC into less than 2um, and the degree of fineness is adjustable according to different requirements. 2.
Chinese Journal of Explosives & Propellants, 2002,12:12-13.
Ultrafine RDX Explosive Prepared by Pulse Ram -Type Pulverization M ethod[J],ENERGETIC MATERIALS,2005,13(5):321-322.
Online since: July 2012
Authors: Feng Qin He, Hua Lin Wang, Yong Hong Tan, Jian Gang Wang, Ping Zhou, Chun K. Seong
Research Institute of Process Equipment and Pressure Vessels,East China University of Science and Technology, 200237, Shanghai, China
2.
State Key Laboratory of Chemical Engineering,East China University of Science and Technology, 200237, Shanghai, China 3.
The testing material was the suspensions of water and gypsum powder with different concentrations.
Acknowledgements This work was supported in part by the National Science Foundation of China under Grant 60971004 and Grant 61171088,Shanghai Scientific and Technological Innovation Project (10dz1201300), Natural Sciences Foundation of Shanghai (09zr1423600), Shanghai Municipal Education Commission Research Foundation (cl200935), National Science Foundation of China (No. 21076073), Shanghai Rising-Star Program (No. 10QA1401700), Innovation Program of Shanghai Municipal Education Commission (12ZZ055) and Natural Sciences Foundation of Shanghai (21106040).
Bai, Z.S., Wang, H.L., and Tu, S.T.: ‘Study of Air-Liquid Flow Patterns in Hydrocyclone Enhanced by Air Bubbles’, Chemical Engineering & Technology, 2009, 32, (1), pp. 55-63 [3] Zhang, Y.H., Qian, P., Liu, Y., and Wang, H.L.: ‘Experimental Study of Hydrocyclone Flow Field with Different Feed Concentration’, Industrial & Engineering Chemistry Research, 2011, 50, (13), pp. 8176-8184 [4] Yang, Q., Wang, H.L., Wang, J.G., Li, Z.M., and Liu, Y.: ‘The coordinated relationship between vortex finder parameters and performance of hydrocyclones for separating light dispersed phase’, Separation and Purification Technology, 2011, 79, (3), pp. 310-320 [5] Yang, Q.A., Wang, H.L., Liu, Y., and Li, Z.M.: ‘Solid/liquid separation performance of hydrocyclones with different cone combinations’, Separation and Purification Technology, 2010, 74, (3), pp. 271-279 [6] Karimi, M., Dehghani, A., Nezamalhosseini, A., and Talebi, S.: ‘Prediction of hydrocyclone performance using artificial neural networks’, Journal
State Key Laboratory of Chemical Engineering,East China University of Science and Technology, 200237, Shanghai, China 3.
The testing material was the suspensions of water and gypsum powder with different concentrations.
Acknowledgements This work was supported in part by the National Science Foundation of China under Grant 60971004 and Grant 61171088,Shanghai Scientific and Technological Innovation Project (10dz1201300), Natural Sciences Foundation of Shanghai (09zr1423600), Shanghai Municipal Education Commission Research Foundation (cl200935), National Science Foundation of China (No. 21076073), Shanghai Rising-Star Program (No. 10QA1401700), Innovation Program of Shanghai Municipal Education Commission (12ZZ055) and Natural Sciences Foundation of Shanghai (21106040).
Bai, Z.S., Wang, H.L., and Tu, S.T.: ‘Study of Air-Liquid Flow Patterns in Hydrocyclone Enhanced by Air Bubbles’, Chemical Engineering & Technology, 2009, 32, (1), pp. 55-63 [3] Zhang, Y.H., Qian, P., Liu, Y., and Wang, H.L.: ‘Experimental Study of Hydrocyclone Flow Field with Different Feed Concentration’, Industrial & Engineering Chemistry Research, 2011, 50, (13), pp. 8176-8184 [4] Yang, Q., Wang, H.L., Wang, J.G., Li, Z.M., and Liu, Y.: ‘The coordinated relationship between vortex finder parameters and performance of hydrocyclones for separating light dispersed phase’, Separation and Purification Technology, 2011, 79, (3), pp. 310-320 [5] Yang, Q.A., Wang, H.L., Liu, Y., and Li, Z.M.: ‘Solid/liquid separation performance of hydrocyclones with different cone combinations’, Separation and Purification Technology, 2010, 74, (3), pp. 271-279 [6] Karimi, M., Dehghani, A., Nezamalhosseini, A., and Talebi, S.: ‘Prediction of hydrocyclone performance using artificial neural networks’, Journal
Online since: September 2011
Authors: Jian Lan Zhou, Kun Li, Kai Chang Sun, Zhi Yu Sun
., Yichang 443002, China
2 Department of Control Science & Engineering, Huazhong University of Science and Technology, Wuhan, 430074, China
3 Department of Science & Environmental Protection, China Three Gorges Group.
Hence, human and material resources can focus on rectification of the problems which reflected by the factors.
Acknowledgements This work was financially supported by the National Natural Science Foundation of China (No.51079078).
Fuyang Teachers College Natural Science. 39 (1996) 47-50
[4] Qian Xinming, Chen Baozhi, On identification & control of major hazards, China Safety Science Journal. 4 (1994) 16-21
Hence, human and material resources can focus on rectification of the problems which reflected by the factors.
Acknowledgements This work was financially supported by the National Natural Science Foundation of China (No.51079078).
Fuyang Teachers College Natural Science. 39 (1996) 47-50
[4] Qian Xinming, Chen Baozhi, On identification & control of major hazards, China Safety Science Journal. 4 (1994) 16-21
Online since: September 2008
Authors: W.Joe Quadakkers, Gerald H. Meier, Lorenz Singheiser, J. Zurek, E. Essuman, Michael Hänsel
Caillet, Materials Science Forum, 231, 369-372 (2001)
[2] H.
Quadakkers, Materials Science and Engineering A, in press (2007) [4] J. śurek, E.
Quadakkers, Corrosion Science, 46/9, 2301 (2004) [5] R.J.
Nicholls, The Institute of Materials, London, ISSN 1354-5116, 178 (2001) [6] E.
Meussner, Journal of the Electrochemical Society, 110, 1195 (1963) [10] Wagner, Journal of the Electrochemical Society, 99, 369 (1956) [11] R.
Quadakkers, Materials Science and Engineering A, in press (2007) [4] J. śurek, E.
Quadakkers, Corrosion Science, 46/9, 2301 (2004) [5] R.J.
Nicholls, The Institute of Materials, London, ISSN 1354-5116, 178 (2001) [6] E.
Meussner, Journal of the Electrochemical Society, 110, 1195 (1963) [10] Wagner, Journal of the Electrochemical Society, 99, 369 (1956) [11] R.