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Online since: October 2014
Authors: Min Qi, Wei Qiang Wang, Juan Wang
Microstructure and in vitro biodegradable properties of Fe-Zn alloys prepared by electroforming
Weiqiang Wang*, Juan Wang, Min Qi*
School of Materials Science and Engineering, Dalian University of Technology, Dalian 116024, China
*Corresponding author: wangwq@dlut.edu.cn (W.Q.
Moreover, electroforming can produce fine-grained metallic materials with improved mechanical properties [11].
Materials and Methods Specimen fabrication by electroforming.
According to the EDS results, there is no element of oxygen existing in the electroformed materials.
[9] Okamoto H: Journal of Phase Equilibria and Diffusion Vol. 28 (2007), p. 317
Moreover, electroforming can produce fine-grained metallic materials with improved mechanical properties [11].
Materials and Methods Specimen fabrication by electroforming.
According to the EDS results, there is no element of oxygen existing in the electroformed materials.
[9] Okamoto H: Journal of Phase Equilibria and Diffusion Vol. 28 (2007), p. 317
Online since: January 2012
Authors: Xiao Juan Li, Jian Lian, Rong Hua Wang, Ya Qing Li
References
[1] Price J C, “Comparing MODIS and ETM+ Data For Regional and Global Land Classification,” Remote Sensing of Environment, Elsevier Science, New York,Vol.86, pp. 1335-1853, Apr. 2003
[3] Gu Juan, Li Xin, and Huang Chunlin, “Land Cover Classification Based on Time-series MODIS NDVI Data in Heihe River Basin,” Advances in Earth Science, Lanzhou, Vol. 25, pp.317-326, Mar. 2010
[8] Lin Hui, Xiong Yujiu, Wan Lingfeng, Mo Dengkui, and Sun Hua, “Temporal and Spatial Variation of MODIS Vegetation Indices in Hunan Province,” Chinese Journal of Applied Ecology, Ecological Society of China, Shenyang, Liaoning Province, Vol. 18, pp. 581-585, Mar. 2007
[9] Zhang Shuyu, Li Dengke, Jing Yigang, Li Xingmin, and Gao Bei, “Analysis of Seasonal Dynamics of Vegetation Change in Shaanxi Province Based MODIS NDVI Time Series Data,” Chinese Journal of Agrometeorology, Chinese Academy of Agricultural Sciences Institute of Agricultural Environment and Sustainable Development, Beijing, Vol. 18, pp. 88-92, Jan. 2007
Science Press, Beijing, 2001.
[3] Gu Juan, Li Xin, and Huang Chunlin, “Land Cover Classification Based on Time-series MODIS NDVI Data in Heihe River Basin,” Advances in Earth Science, Lanzhou, Vol. 25, pp.317-326, Mar. 2010
[8] Lin Hui, Xiong Yujiu, Wan Lingfeng, Mo Dengkui, and Sun Hua, “Temporal and Spatial Variation of MODIS Vegetation Indices in Hunan Province,” Chinese Journal of Applied Ecology, Ecological Society of China, Shenyang, Liaoning Province, Vol. 18, pp. 581-585, Mar. 2007
[9] Zhang Shuyu, Li Dengke, Jing Yigang, Li Xingmin, and Gao Bei, “Analysis of Seasonal Dynamics of Vegetation Change in Shaanxi Province Based MODIS NDVI Time Series Data,” Chinese Journal of Agrometeorology, Chinese Academy of Agricultural Sciences Institute of Agricultural Environment and Sustainable Development, Beijing, Vol. 18, pp. 88-92, Jan. 2007
Science Press, Beijing, 2001.
Online since: August 2014
Authors: Jin Jiang Cui, Man Zhao, He Nan Wu, Guang Yang, Da Yong Jiang
Linear Target Feature Extraction Applied in Target Identification
Man Zhao1,2,a, Jinjiang Cui 3,a, Henan Wu1,a, Guang Yang 1,a, Dayong Jiang 4,a,*
1Special Service Department, Aviation University of Air Force, Changchun 130022, China
2School of Science, Changchun University of Science and Technology, Changchun 130022, China
3Suzhou Institute of Biomedical Engineering and Technology Chinese Academy of Sciences,
Suzhou 215000, China
4School of Materials Science and Engineering, Changchun University of Science and Technology,
Changchun 130022, China
axman82@126.com
Corresponding author: Tel.:+86 431 85583016; fax: +86 431 85583015
E-mail address: xman82@126.com
Keywords: Linear target extraction; Target recognition; Hough transform
Abstract.
Acknowledgements This work is supported by the National Natural Science Foundation of China (Grant Nos. 61106050, 21201022), Jiangsu Provincial Natural Science Foundation of China (BK2012188).
References [1] Roushdy, M., “Comparative study of edge detection algorithms applying on the grayscale noisy image using morphological filter”, the International Journal on Graphics, Vision, and Image Processing, 6(4), 17-23 (2006) [2] Z.
Acknowledgements This work is supported by the National Natural Science Foundation of China (Grant Nos. 61106050, 21201022), Jiangsu Provincial Natural Science Foundation of China (BK2012188).
References [1] Roushdy, M., “Comparative study of edge detection algorithms applying on the grayscale noisy image using morphological filter”, the International Journal on Graphics, Vision, and Image Processing, 6(4), 17-23 (2006) [2] Z.
Online since: August 2013
Authors: Yan Zuo, Sheng Shu Ai, Qing Kai Ren, Xi Tian, Zhong Yan Xie
Materials and methods
Sewage sources.
Acknowledgements This work was supported by National Science Foundation of China (Research Project 51078067), Science and technology development project of Jilin province (No. 201101089), Jilin Science and Technology Department of Education funded research project (guitar UNESCO co-word [2009] No. 254) and science and technology development plan of Jilin province (20122112).
(China Environmental Science Press, Beijing 1999)
Wang, Environmental Protection Science Vol. 4-27(2001), P 14 [4] T.
Jiao, Journal of Jilin Architectural and Civil Engineer ing Institute Vol. 24-2 (2007), P 29
Acknowledgements This work was supported by National Science Foundation of China (Research Project 51078067), Science and technology development project of Jilin province (No. 201101089), Jilin Science and Technology Department of Education funded research project (guitar UNESCO co-word [2009] No. 254) and science and technology development plan of Jilin province (20122112).
(China Environmental Science Press, Beijing 1999)
Wang, Environmental Protection Science Vol. 4-27(2001), P 14 [4] T.
Jiao, Journal of Jilin Architectural and Civil Engineer ing Institute Vol. 24-2 (2007), P 29
Online since: June 2011
Authors: Yuri N. Gornostyrev, Pavel A. Korzhavyi, Andrei V. Ruban, Oleg I. Gorbatov
Gornostyrev1,3,d
1Institute of Quantum Materials Science, Ekaterinburg 620107, Russia
2Royal Institute of Technology (KTH), SE-100 44 Stockholm, Sweden
3Institute of Metal Physics, Ural Division RAS, Ekaterinburg 620041, Russia
aoleg.gorbatov@iqms.ru, bpavel@mse.kth.se, ca.v.ruban@gmail.com, dyug@imp.uran.ru
Key words: magnetism, defects, diffusion, vacancy-solute interactions.
Introduction Studies of interactions between vacancies and solute atoms (alloying elements or impurities) in crystalline materials are motivated by the significance of such interactions for our understanding of many important physical phenomena (such as diffusion, ordering, or decomposition) which occur in the materials during ageing or due to irradiation.
Iron-based alloys are undoubtedly the most important construction materials of our industrial society.
Steels have been used as nuclear materials, for example, for making pressure vessels of fission reactors.
Journal of Nuclear Materials 371, 37 (2007) ]; therefore they are considered as promising construction materials for the next-generation fission reactors as well as for the future fusion reactors.
Introduction Studies of interactions between vacancies and solute atoms (alloying elements or impurities) in crystalline materials are motivated by the significance of such interactions for our understanding of many important physical phenomena (such as diffusion, ordering, or decomposition) which occur in the materials during ageing or due to irradiation.
Iron-based alloys are undoubtedly the most important construction materials of our industrial society.
Steels have been used as nuclear materials, for example, for making pressure vessels of fission reactors.
Journal of Nuclear Materials 371, 37 (2007) ]; therefore they are considered as promising construction materials for the next-generation fission reactors as well as for the future fusion reactors.
Online since: August 2012
Authors: Zhi Wen Xu, Wan Zhu Guo, Feng Qin Li, Yue Yi, Cheng Dong Wang, De Sheng Li, Ling Zhu, Feng Gu, Cheng Dong Wang, De Sheng Li
Materials and methods
A.
Li, "The saving of giant panda," Published by Sichuan Science and Technology Publishing Company, pp. 113-129, 2000.
FIERS, "Cloning and expression of the canine interferon-γ gene," Journal of interferon research, vol. 12, pp. 95-102, 1992
[22] G. von Heijne, "The signal peptide," Journal of Membrane Biology, vol. 115, pp. 195-201, 1990
," Toxicological Sciences, vol. 55, p. 235, 2000
Li, "The saving of giant panda," Published by Sichuan Science and Technology Publishing Company, pp. 113-129, 2000.
FIERS, "Cloning and expression of the canine interferon-γ gene," Journal of interferon research, vol. 12, pp. 95-102, 1992
[22] G. von Heijne, "The signal peptide," Journal of Membrane Biology, vol. 115, pp. 195-201, 1990
," Toxicological Sciences, vol. 55, p. 235, 2000
Online since: October 2015
Authors: Mark Jermy, Tze How New, Tim Flint, Wei Hua Ho
References
x
[1]
Y X Chan, G C Koh, M C Hoang, S Shi, and TH New, "Effects of Corrugate Aerofoil Surface Features on Flow-Separation Control," AIAA Journal, vol. 52, no. 1, pp. 206-211, 2014.
[2]
F R Menter, Best Practice: Scale-Resolving Simulations in ANSYS CFD Version 1.02.
Gemany: ANSYS, 2012, vol. 32. [3] F R Menter and Y Egorov, "Scale-Adaptive Simulation Method for Unsteady Flow Predictions Part 1: Theory and Model Description," Flow, Turnulence and Combustion, vol. 85, no. 1, pp. 113-138, 2010. [4] Jiri Vondal and Jiri Hajek, "Comparison of SAS turbulence model to the SST K-w in non-premixed combustion simulation," in 14th European Turbulence Conference, Lyon, 2013. [5] T H New, Y X Chan, G C Koh, H M Chung, and S Shi, "Effects of Corrugate Aerofoil Surface Features on Flow-Separation Control," AIAA Journal, vol. 52, no. 1, pp. 206-211, 2014. [6] J C Nawroth et al., "A tissue-engineered jellyfish with biomimetic propulsion," Nature Biotechnology, no. 30, pp. 792-797, 2012. [7] D E Alexander, "Unusual Phase Relationships Between The Forewings and Hindwings in Flying Dragonflies," Journal of Experimental Biology, vol. 109, pp. 379-383, 1984. [8] C Hefler, H Qiu, and W Shyy, "The Interaction of Wings in Different Flight Modes of a Dragonfly," in 17th International
Kinematics and Aerodynamics.," in Swimming and Flying in Nature.: 763-781, 1975. [12] C J C Rees, "Form and Function in Corrugated Insect Wings," Nature, vol. 256, pp. 200-203, 1975. [13] G Ruppell, "Kinematic Analysis of Symmetrical Flight Manoeuvres of Odonata," Journal of Experimental Biology, vol. 144, pp. 13-42, 1989. [14] A L R Thomas, G K Taylor, R B Srygley, R L Nudds, and R J Bomphrey, "Dragonfly Flight: Free-Flight and Tethered Flow Visualizations Reveal a Diverse Array of Unsteady Lift-Generating Mechanisms, Controlled Primarily via Angle of Attack," Journal of Experimental Biology, vol. 207, pp. 4299-4323, 2004. [15] J M Wakeling and C P Ellington, "Dragonfly Flight I Gliding Flight and Steady-State Aerodynamics," Journal of Experimental Biology, vol. 200, pp. 543-556, 1997. [16] J M Wakeling and C P Ellington, "Dragonfly Flight III Lift and Power Requirements," Journal of Experimental Biology, vol. 200, pp. 583-600, 1997. [17] Z J Wang, "Dragonfly Flight," Physics Today, vol
. 61, no. 10, pp. 74-75, 2008. [18] D-E Levy and A Seifert, "Simplified dragonfly airfoil aerodynamics at Reynolds numbers below 8000," Physics of Fluids, vol. 21, 2009. [19] Z Zhou, C Li, J B Nie, and Y Chen, "Effect of oscillation frequency on wind turbine airfoil dynamic stall," Materials Science and Engineering, vol. 52, pp. 1-5, 2013. [20] K Lu, Y H Xie, D Zhang, and J B Lan, "Numerical investigations into the asymmetric effects on the aerodynamic response of a pitching airfoil," Journal of Fluids and Sturctures, no. 76-86, p. 39, 2013. [21] J Panda and K B M Q Zaman, "Experimental Investigation of the flowfield of an oscillating airfoil," in 10th AIAA Applied Aerodynamics Conference, 1992. [22] T Lee, "Flow past two in-tandem airfoils undergoing sinusoidal oscillations," Experiments in Fluids, vol. 51, no. 6, pp. 1605-1621, 2011. [23] Hui Hu and Masatoshi Tamai, "Bioinspired corrugated airfoil at low Reynolds numbers," Journal of Aircraft, vol. 45, no. 6, pp. 2068-2077, 2008. [24]
Michelle Kwok and Rajat Mittal, "Experimental Investigation of the Aerodyanmics of a Modeled Dragonfly Wing Section," in AIAA region I-MA Student Conference Charlottesville, Virginia, 2005. [25] Jeffrey Murphy and Hui Hu, "An Experimental Investigation on a Bio-inspired Corrugated Airfoil," in 47th AIAA Aerospace Sciences Meeting and Exhibit, Orlando, 2009. x
Gemany: ANSYS, 2012, vol. 32. [3] F R Menter and Y Egorov, "Scale-Adaptive Simulation Method for Unsteady Flow Predictions Part 1: Theory and Model Description," Flow, Turnulence and Combustion, vol. 85, no. 1, pp. 113-138, 2010. [4] Jiri Vondal and Jiri Hajek, "Comparison of SAS turbulence model to the SST K-w in non-premixed combustion simulation," in 14th European Turbulence Conference, Lyon, 2013. [5] T H New, Y X Chan, G C Koh, H M Chung, and S Shi, "Effects of Corrugate Aerofoil Surface Features on Flow-Separation Control," AIAA Journal, vol. 52, no. 1, pp. 206-211, 2014. [6] J C Nawroth et al., "A tissue-engineered jellyfish with biomimetic propulsion," Nature Biotechnology, no. 30, pp. 792-797, 2012. [7] D E Alexander, "Unusual Phase Relationships Between The Forewings and Hindwings in Flying Dragonflies," Journal of Experimental Biology, vol. 109, pp. 379-383, 1984. [8] C Hefler, H Qiu, and W Shyy, "The Interaction of Wings in Different Flight Modes of a Dragonfly," in 17th International
Kinematics and Aerodynamics.," in Swimming and Flying in Nature.: 763-781, 1975. [12] C J C Rees, "Form and Function in Corrugated Insect Wings," Nature, vol. 256, pp. 200-203, 1975. [13] G Ruppell, "Kinematic Analysis of Symmetrical Flight Manoeuvres of Odonata," Journal of Experimental Biology, vol. 144, pp. 13-42, 1989. [14] A L R Thomas, G K Taylor, R B Srygley, R L Nudds, and R J Bomphrey, "Dragonfly Flight: Free-Flight and Tethered Flow Visualizations Reveal a Diverse Array of Unsteady Lift-Generating Mechanisms, Controlled Primarily via Angle of Attack," Journal of Experimental Biology, vol. 207, pp. 4299-4323, 2004. [15] J M Wakeling and C P Ellington, "Dragonfly Flight I Gliding Flight and Steady-State Aerodynamics," Journal of Experimental Biology, vol. 200, pp. 543-556, 1997. [16] J M Wakeling and C P Ellington, "Dragonfly Flight III Lift and Power Requirements," Journal of Experimental Biology, vol. 200, pp. 583-600, 1997. [17] Z J Wang, "Dragonfly Flight," Physics Today, vol
. 61, no. 10, pp. 74-75, 2008. [18] D-E Levy and A Seifert, "Simplified dragonfly airfoil aerodynamics at Reynolds numbers below 8000," Physics of Fluids, vol. 21, 2009. [19] Z Zhou, C Li, J B Nie, and Y Chen, "Effect of oscillation frequency on wind turbine airfoil dynamic stall," Materials Science and Engineering, vol. 52, pp. 1-5, 2013. [20] K Lu, Y H Xie, D Zhang, and J B Lan, "Numerical investigations into the asymmetric effects on the aerodynamic response of a pitching airfoil," Journal of Fluids and Sturctures, no. 76-86, p. 39, 2013. [21] J Panda and K B M Q Zaman, "Experimental Investigation of the flowfield of an oscillating airfoil," in 10th AIAA Applied Aerodynamics Conference, 1992. [22] T Lee, "Flow past two in-tandem airfoils undergoing sinusoidal oscillations," Experiments in Fluids, vol. 51, no. 6, pp. 1605-1621, 2011. [23] Hui Hu and Masatoshi Tamai, "Bioinspired corrugated airfoil at low Reynolds numbers," Journal of Aircraft, vol. 45, no. 6, pp. 2068-2077, 2008. [24]
Michelle Kwok and Rajat Mittal, "Experimental Investigation of the Aerodyanmics of a Modeled Dragonfly Wing Section," in AIAA region I-MA Student Conference Charlottesville, Virginia, 2005. [25] Jeffrey Murphy and Hui Hu, "An Experimental Investigation on a Bio-inspired Corrugated Airfoil," in 47th AIAA Aerospace Sciences Meeting and Exhibit, Orlando, 2009. x
Online since: April 2024
Authors: Heyran Abbasova, Nizami Yusubov
Yusubov, Elements of the matrix theory of multi-tool machining accuracy in spatial adjustments,” Technical journal "Bulletin of mechanical engineering. 9 (2013) 13-17
Abbasova, Models for Machining Accuracy in Multi-Tool Adjustment, International Journal of Automative and Mechanical Engineering. 17 (2020) 8067–8085.
Abbasova, Full-factor matrix model of accuracy of dimensions performed on multi-purpose CNC machines, Metal Working and Material Science. 23 (2021) 6-20. doi: 10.17212/1994-63092021-23.4-6-20
Dadashov, Theoretical basis for the development of an algorithmic unified complex of mathematical models of cutting forces, Machine science 1 (2023) 55-60
Huseynov, Matrix models of machining errors in multi-toolmulti-carriage adjustments, nternational Journal on “Technical and Physical Problems of Engineering” (IJTPE). 15 (2023) 309-315
Abbasova, Models for Machining Accuracy in Multi-Tool Adjustment, International Journal of Automative and Mechanical Engineering. 17 (2020) 8067–8085.
Abbasova, Full-factor matrix model of accuracy of dimensions performed on multi-purpose CNC machines, Metal Working and Material Science. 23 (2021) 6-20. doi: 10.17212/1994-63092021-23.4-6-20
Dadashov, Theoretical basis for the development of an algorithmic unified complex of mathematical models of cutting forces, Machine science 1 (2023) 55-60
Huseynov, Matrix models of machining errors in multi-toolmulti-carriage adjustments, nternational Journal on “Technical and Physical Problems of Engineering” (IJTPE). 15 (2023) 309-315
Online since: January 2019
Authors: Chao Sheng Wang, Dan Qin, Hua Ping Wang, Shan Shan Liu, Ji Yue Hu, Ye Chen, Fu You Ke, Ling Ling Gao
These emissions may be strongly influenced by the raw materials and manufacturing techniques of the recycled PET.
Introduction Polyethylene terephthalate (PET) enjoys wide applications in textile, package materials by virtue of its excellent wear, chemical resistance, durability and mechanical properties coupled with its low market price.
One of the attractive chemical recycling methods to regenerate PET is glycolysis reaction into the bis(2-hydroxyethyl) terephthalate, and then obtained monomer BHET is used in the synthesis of polymeric materials[4].
Experiments Materials.
Journal of Polymer Science, 2017 1-13.
Introduction Polyethylene terephthalate (PET) enjoys wide applications in textile, package materials by virtue of its excellent wear, chemical resistance, durability and mechanical properties coupled with its low market price.
One of the attractive chemical recycling methods to regenerate PET is glycolysis reaction into the bis(2-hydroxyethyl) terephthalate, and then obtained monomer BHET is used in the synthesis of polymeric materials[4].
Experiments Materials.
Journal of Polymer Science, 2017 1-13.
Online since: October 2022
Authors: Wen Hui Yang, Gao Feng Tian, De Lin Liu, Ren De Mu
Effect of Co and Al Contents on Hot Corrosion Resistance of Powder Metallurgy Aeroengine Disk Superalloys
Wen-Hui Yang1,a, Gao-Feng Tian2,b*, De-Lin Liu1,c, Yang Chen2,d, Ren-De Mu1,e
1Aviation Key Laboratory of Science and Technology on Advanced Corrosion and Protection for Aviation Material, Beijing Institute of Aeronautical Materials, Beijing 100095, China
2Science & Technology on Advanced High Temperature Structural Materials Laboratory, Beijing Institute of Aeronautical Materials, Beijing 100095, China
aywh930315@126.com, bgftian2008@163.com, cliudelin19800722@163.com, dfengli9572@sina.com, emurende@163.com
Keywords: Powder metallurgy superalloy; hot corrosion; oxidation; molten Na2SO4-NaCl salts; sulfuration
Abstract.
Therefore, it is very necessary to carry out research on hot corrosion resistance of the key materials.
Annual Revies of Materials Science 1977;7: 477-509
Materials, 2019, 12: 2934
Material Science Engineering, 1986, 2: 194-200
Therefore, it is very necessary to carry out research on hot corrosion resistance of the key materials.
Annual Revies of Materials Science 1977;7: 477-509
Materials, 2019, 12: 2934
Material Science Engineering, 1986, 2: 194-200