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Online since: January 2012
Authors: Jun Yang
This has much to do with the properties of the roof materials and the way of roofing construction.
It is the important resource of new antibacterial materials in biology [2].
Colloids in seaweed increase the wholeness of the roof The French materials experts, P.
Russian Journal of Marine Biology, 2007, Vol. 33, No. 3, p204–206
Journal of Materials Science,2007,43,(13),p4805-4857
It is the important resource of new antibacterial materials in biology [2].
Colloids in seaweed increase the wholeness of the roof The French materials experts, P.
Russian Journal of Marine Biology, 2007, Vol. 33, No. 3, p204–206
Journal of Materials Science,2007,43,(13),p4805-4857
Online since: September 2020
Authors: Shi Rong Li, Da Fu Cao, Peng Xiong
Acknowledgements
This work was supported by the Natural Science Foundation of China (No. 11672260).
Zhang, Thermoelastic damping in asymmetric three-layered microbeam resonators, Journal of Applied Mechanics. 83(2016): 061002-1
Mechanical Science, 106(2016): 128-137
Mechanics and Materials in Design,11(2015): 357–369
Xiong, Thermoelastic damping in functionally graded material circular micro plates, Journal of Thermal Stresses 41(2018): 1396-1412.
Zhang, Thermoelastic damping in asymmetric three-layered microbeam resonators, Journal of Applied Mechanics. 83(2016): 061002-1
Mechanical Science, 106(2016): 128-137
Mechanics and Materials in Design,11(2015): 357–369
Xiong, Thermoelastic damping in functionally graded material circular micro plates, Journal of Thermal Stresses 41(2018): 1396-1412.
Online since: March 2016
Authors: Jian Guo Gao, Shuai Zhang, Qian Qian Zhang, Fu Wen Zhao, Xiao Yun Song, Chun Ping Li, Jian Gao, Zhuo Jun Sun
Experiment
Materials.
Journal of inspection and quarantine, 2011, 21(2):46-49
Journal of inspection and quarantine, 24(1):38-40
Chinese Journal of food hygiene, 2013,25(1):12-15
Science ang Technology of Food Industry, 2011,32(11):457-458
Journal of inspection and quarantine, 2011, 21(2):46-49
Journal of inspection and quarantine, 24(1):38-40
Chinese Journal of food hygiene, 2013,25(1):12-15
Science ang Technology of Food Industry, 2011,32(11):457-458
Online since: December 2010
Authors: De Bin Shan, Yu Kui Wang, Zhen Long Wang, X.S. Geng
Shan
2
1
School of Mechanical Engineering, Harbin Institute of Technology, Harbin, China
2
School of materials science and engineering, Harbin Institute of Technology, Harbin, China
a
gengxs8457@163.com, bwangyukui@hit.edu.cn, cwangzl@hit.edu.cn
Keywords: Micro-WEDM, Thin wire electrode, Micro girder, Micro-electrode array
Abstract.
The axle journal's limiting width of micro girder.
Acknowledgment This research work is funded by Natural Science Foundation in China (No.50835002), Natural Science Foundation of Heilongjiang Province in China (No.E200901), and the Fundamental Research Funds for the Central Universities (No.HIT.NSRIF.2009018).
Gianchandani: Journal of Microelectromechanical Systems, Vol. 4 (2002) ,p.102
Journal of Micro mechanics and Micro engineering.
The axle journal's limiting width of micro girder.
Acknowledgment This research work is funded by Natural Science Foundation in China (No.50835002), Natural Science Foundation of Heilongjiang Province in China (No.E200901), and the Fundamental Research Funds for the Central Universities (No.HIT.NSRIF.2009018).
Gianchandani: Journal of Microelectromechanical Systems, Vol. 4 (2002) ,p.102
Journal of Micro mechanics and Micro engineering.
Online since: March 2023
Authors: R. Suresh, H.R. Basavaraju, S.S Manjunatha
Hence these are regarded as difficult-to-cut materials.
Journal of Materials Processing Technology Vol 105, p 327-332
Materials Science and Engineering A, Vol 378, p 180-184
Beela Satyanarayan, 2010, A Prediction of Material removal rate for Aluminum BIS-24345 Alloy in wire-cut EDM, International Journal of Engineering Science and Technology Vol. 2 (12), 7729-7739 [18] S.
Materials and Manufacturing Processes, 23: 174-181, 2008 [19] A.
Journal of Materials Processing Technology Vol 105, p 327-332
Materials Science and Engineering A, Vol 378, p 180-184
Beela Satyanarayan, 2010, A Prediction of Material removal rate for Aluminum BIS-24345 Alloy in wire-cut EDM, International Journal of Engineering Science and Technology Vol. 2 (12), 7729-7739 [18] S.
Materials and Manufacturing Processes, 23: 174-181, 2008 [19] A.
Online since: February 2022
Authors: Sergei Koryagin, Nikolay Velikanov, Oleg Sharkov
Investigation of the Effect of Vibration on the Bearing Capacity of Composite Materials
Sergei Koryagin1,a, Oleg Sharkov1*,b and Nikolay Velikanov1,c
1Immanuel Kant Baltic Federal University, Kaliningrad, 236016, Russia
askoryagin@kantiana.ru, bosharkov@kantiana.ru, cnvelikanov@kantiana.ru
Keywords: polymer coatings, composite structures, vibration, strength, deformation.
One of the effective methods for reducing the effect of shock and vibration loads on the bearing capacity of mechanical structures is the use of structural elements made of composite materials [11, 14–18].
Materials and Methods Test bench.
References [1] Gvozdkova S I and Shvartsburg L E 2017 Procedia Engineering 206 958–964 [2] Dong R G, Welcome D E, Xu X S and McDowell T W 2020 International Journal of Industrial Ergonomics 77 102946 [3] Vieler H, Karim A and Lechler A 2017 Robotics and Computer-Integrated Manufacturing 47 117–122 [4] Dubrovskiy A, Aliukov S, Dubrovskiy S and Alyukov A 2017 Lecture Notes in Engineering and Computer Science 2 679–684 [5] Moheimani S O R, Halim D and Fleming A J 2003 Spatial Control of Vibration: Theory and Experiments (Singapore World Scientific Publishing) p 236 [6] Munoa J, Beudaert X, Erkorkmaz K, Iglesias A, Barrios A and Zatarain M 2015 CIRP Annals 64(1) 385–388 [7] Hosseinabadi A H H and Altintas Y 2014 CIRP Journal of Manufacturing Science and Technology 7(3) 246–257 [8] Guoa Z, Cao Y, Feng K, Guan H and Zhang T 2019 Mechanical Systems and Signal Processing 133 106271 [9] Duan P and Ding X 2015 Journal of University of Shanghai for Science and Technology 37(6) 583–588 [
10] Chen Y, Wu H, Zhai J, Chen H, Zhu Q and Han Q 2019 Aerospace Science and Technology 84 1049–1058 [11] Koryagin S I, Sharkov O V and Velikanov N L 2018 Materials Science Forum 938 46–53 [12] Limarga A M, Duong T L, Gregori G and Clarke D R 2007 Surface and Coatings Technology 202(4–7) 693–697 [13] Kirpichnikov V Y, Koshcheev A P and Syatkovskii A I 2020 Journal of Applied Mechanics and Technical Physics 61(6) 968–971 [14] Kulíšek V, Růžička M, Vrba P, Smolík J and Janota M 2019 Materials Today: Proceedings 12(2) 288–297 [15] Fantuzzi N, Bacciocchi M, Benedetti D and Agnelli J 2021 Composites Part C: Open Access 4 100096 [16] Bigdeli M and Monfared V 2021 International Journal of Engineering, Transactions B: Applications 34(2) 556–563 [17] Cao Y, Zuo D, Zhao Y, Cao Z, Zhi J, Zheng G and Tay T E 2021 Composite Structures 261 13565 [18] Yang M, Gui L, Hu Y, Ding G and Song C 2018 Results in Physics 8 1110–1118 [19] Thomson W T 1996 Theory of vibration with applications (Boca Raton
One of the effective methods for reducing the effect of shock and vibration loads on the bearing capacity of mechanical structures is the use of structural elements made of composite materials [11, 14–18].
Materials and Methods Test bench.
References [1] Gvozdkova S I and Shvartsburg L E 2017 Procedia Engineering 206 958–964 [2] Dong R G, Welcome D E, Xu X S and McDowell T W 2020 International Journal of Industrial Ergonomics 77 102946 [3] Vieler H, Karim A and Lechler A 2017 Robotics and Computer-Integrated Manufacturing 47 117–122 [4] Dubrovskiy A, Aliukov S, Dubrovskiy S and Alyukov A 2017 Lecture Notes in Engineering and Computer Science 2 679–684 [5] Moheimani S O R, Halim D and Fleming A J 2003 Spatial Control of Vibration: Theory and Experiments (Singapore World Scientific Publishing) p 236 [6] Munoa J, Beudaert X, Erkorkmaz K, Iglesias A, Barrios A and Zatarain M 2015 CIRP Annals 64(1) 385–388 [7] Hosseinabadi A H H and Altintas Y 2014 CIRP Journal of Manufacturing Science and Technology 7(3) 246–257 [8] Guoa Z, Cao Y, Feng K, Guan H and Zhang T 2019 Mechanical Systems and Signal Processing 133 106271 [9] Duan P and Ding X 2015 Journal of University of Shanghai for Science and Technology 37(6) 583–588 [
10] Chen Y, Wu H, Zhai J, Chen H, Zhu Q and Han Q 2019 Aerospace Science and Technology 84 1049–1058 [11] Koryagin S I, Sharkov O V and Velikanov N L 2018 Materials Science Forum 938 46–53 [12] Limarga A M, Duong T L, Gregori G and Clarke D R 2007 Surface and Coatings Technology 202(4–7) 693–697 [13] Kirpichnikov V Y, Koshcheev A P and Syatkovskii A I 2020 Journal of Applied Mechanics and Technical Physics 61(6) 968–971 [14] Kulíšek V, Růžička M, Vrba P, Smolík J and Janota M 2019 Materials Today: Proceedings 12(2) 288–297 [15] Fantuzzi N, Bacciocchi M, Benedetti D and Agnelli J 2021 Composites Part C: Open Access 4 100096 [16] Bigdeli M and Monfared V 2021 International Journal of Engineering, Transactions B: Applications 34(2) 556–563 [17] Cao Y, Zuo D, Zhao Y, Cao Z, Zhi J, Zheng G and Tay T E 2021 Composite Structures 261 13565 [18] Yang M, Gui L, Hu Y, Ding G and Song C 2018 Results in Physics 8 1110–1118 [19] Thomson W T 1996 Theory of vibration with applications (Boca Raton
Online since: August 2015
Authors: Konstantin Naumenko, Holm Altenbach, Frank Laengler, Mykola Ievdokymov
Fatigue and Fracture of Engineering Materials, 19
(9):1143 - 1151, 1996
Materials at High Temperatures, 24(1):1 - 26, 2007
Skrzypek, editors, Creep and Damage in Materials and Structures, pages 285 - 348.
Materials Science and Engineering, A510- A511:169 - 174, 2009.[13] M.H.J.
Deformation and life assessment of high temperature materials under creep fatigue loading.
Materials at High Temperatures, 24(1):1 - 26, 2007
Skrzypek, editors, Creep and Damage in Materials and Structures, pages 285 - 348.
Materials Science and Engineering, A510- A511:169 - 174, 2009.[13] M.H.J.
Deformation and life assessment of high temperature materials under creep fatigue loading.
Online since: September 2017
Authors: Pi Hua Wen, J. Li, C. Shi
Numerical Analysis for Cracked Functionally Graded Materials
by Finite Block Method
J.
Wen2,c 1School of Mathematics and Statistics, Changsha University of Science and Technology, China 2School of Engineering and Materials Science, Queen Mary University of London, London, UK alijingnew@126.com, bc.shi@qmul.ac.uk, cp.h.wen@qmul.ac.uk Keywords: functionally graded materials, finite block method, stress intensity factors Abstract.
The finite block method (FBM) is developed to determine stress intensity factors with orthotropic functionally graded materials under static and dynamic loads in this paper.
The relationship between stress and strain anisotropic materials gives (1) where are the elastic compliances of the FGMs.
Wu: ASME Journal of Applied Mechanics 64 (1997), 449-456.
Wen2,c 1School of Mathematics and Statistics, Changsha University of Science and Technology, China 2School of Engineering and Materials Science, Queen Mary University of London, London, UK alijingnew@126.com, bc.shi@qmul.ac.uk, cp.h.wen@qmul.ac.uk Keywords: functionally graded materials, finite block method, stress intensity factors Abstract.
The finite block method (FBM) is developed to determine stress intensity factors with orthotropic functionally graded materials under static and dynamic loads in this paper.
The relationship between stress and strain anisotropic materials gives (1) where are the elastic compliances of the FGMs.
Wu: ASME Journal of Applied Mechanics 64 (1997), 449-456.
Online since: August 2022
Authors: Ripul Mehrotra, Satyendra N. Shukla, Pratiksha Gaur
Journal of Materials Chemistry, 22 (2012) 3710 – 23725
Gowda, Morphology structural and photoluminescence properties of shaping triple semiconductor Y x CoO: ZrO 2 nanostructures Journal of Materials Science: Materials in Electronics 32(9) (2021) 2164 – 12181
Journal of Materials Chemistry A, 3 (2015) 6742 – 6746
Berginc, Optical properties of nanostructured materials: a review, Journal of Nanophotonics, 5 (2011) 052502 – 0525020
Material Science Engineering B, 177 (2012) 581 – 587
Gowda, Morphology structural and photoluminescence properties of shaping triple semiconductor Y x CoO: ZrO 2 nanostructures Journal of Materials Science: Materials in Electronics 32(9) (2021) 2164 – 12181
Journal of Materials Chemistry A, 3 (2015) 6742 – 6746
Berginc, Optical properties of nanostructured materials: a review, Journal of Nanophotonics, 5 (2011) 052502 – 0525020
Material Science Engineering B, 177 (2012) 581 – 587
Online since: November 2012
Authors: Yu Ping Tong, Ji Lin Wu, Ze Yu Wu, Pei Rong Du
Acknowledgments
This work was supported by the Science and Technology Fund of Training the High-level Talents of North China University of Water Resources and Electric Power.
Journal of Numerical Methods and Computer Applications, 3 (1980) 163-172.
Zhang, An algorithm for tracking interfaces in two-dimensional Eulerian code, Journal of Numerical Methods and Computer Applications, 3 (2000) 161-170.
China Safety Science Journal, 2 (1994) 1-6.
Zhao, et al, Study on the flow of the explosive shock wave around the wall numerical simulation, Journal of Beijing Institute of Technology, 5 (1999) 543-547.
Journal of Numerical Methods and Computer Applications, 3 (1980) 163-172.
Zhang, An algorithm for tracking interfaces in two-dimensional Eulerian code, Journal of Numerical Methods and Computer Applications, 3 (2000) 161-170.
China Safety Science Journal, 2 (1994) 1-6.
Zhao, et al, Study on the flow of the explosive shock wave around the wall numerical simulation, Journal of Beijing Institute of Technology, 5 (1999) 543-547.