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Online since: February 2016
Authors: Anatoly Druzhinin, Valery Yerokhov, Stepan Nichkalo, Yevhen Berezhanskyi
Nichkalo, Formation of ordered Si nanowires arrays on Si substrate, Advanced Materials Research 854 (2014) 83-88
Khoverko, High sensitive active MOS photodetector on local 3D SOI-structure, Advanced Materials Research, 854 (2014) 45-47
Panek, Cost-effective methods of texturing for silicon solar cells, Solar Energy Materials and Solar Cells 72 No1-4 (2002) 291-298
Skryshevsky, Hydrogen in porous silicon — A review, Materials Science and Engineering B 178(15) (2013) 942-955
Lipinski, Macroporous texturing of multicrystalline silicon for solar cells, Archives of Metallurgy and Materials 53 No1 (2008) 185-187
Khoverko, High sensitive active MOS photodetector on local 3D SOI-structure, Advanced Materials Research, 854 (2014) 45-47
Panek, Cost-effective methods of texturing for silicon solar cells, Solar Energy Materials and Solar Cells 72 No1-4 (2002) 291-298
Skryshevsky, Hydrogen in porous silicon — A review, Materials Science and Engineering B 178(15) (2013) 942-955
Lipinski, Macroporous texturing of multicrystalline silicon for solar cells, Archives of Metallurgy and Materials 53 No1 (2008) 185-187
Online since: March 2012
Authors: Ante Agić
Introduction
The incorporation of CNTs in a polymer fiber matrix by electrospinning provides structural materials with wide range multi-functionality [1].
A carbon nanotube with a length , radii is embedded at the center of matrix materials with a radii and length 2.
Materials, 2003, 15, 1161
P., Dispersion and alignment of carbon nanotubes in polymer matrix: A review, Material science and Engineering R , 2005, 49, 89
C., Computational materials: Multi-scale modeling and simulation of nanostructured materials, Composite Science and Technology, 2005, 65, 2416
A carbon nanotube with a length , radii is embedded at the center of matrix materials with a radii and length 2.
Materials, 2003, 15, 1161
P., Dispersion and alignment of carbon nanotubes in polymer matrix: A review, Material science and Engineering R , 2005, 49, 89
C., Computational materials: Multi-scale modeling and simulation of nanostructured materials, Composite Science and Technology, 2005, 65, 2416
Online since: August 2012
Authors: Dilinaer Mahemuti, Gulbahar Tohti, Mamatjan Tursun
material is 16MnL.
Acknowledgement: This research was sponsored by National Natural Science Fund of China No.81160458.
Du: Journal of Special Purpose Automobiles.
Maeng: Key Engineering Materials.Vol.16~18 (2000).pp361~366
(In Chinese) [4] Nijat Yusup and Mamtimin Geni: Journal of Xin Jiang University.
Acknowledgement: This research was sponsored by National Natural Science Fund of China No.81160458.
Du: Journal of Special Purpose Automobiles.
Maeng: Key Engineering Materials.Vol.16~18 (2000).pp361~366
(In Chinese) [4] Nijat Yusup and Mamtimin Geni: Journal of Xin Jiang University.
Online since: May 2011
Authors: Cai Liu, Jun Hui Li
Model of slab pressing finite element
In order to get the real “dog-bone deformation” of the slab pressed by the SSP anvils, different widths, pressing values and materials are considered in the finite model.
The simulated result with different materials is showed in the Fig.5 which show the width of the new pinch roll should be longer than 560mm and shorter than 880mm.
Roll shape of the back pinch roll Acknowledgements The authors would like to gratefully acknowledge the support of the He Bei Province Natural Science Foundation Project (No.
Kim et al.: Journal of Materials Processing Technology Vol. 187(2007),p. 738-746
[8] Xianzhang Feng, Lihong Wang, Jinfeng Wang et al.: JOURNAL OF PLASTICITY ENGINEERING Vol. 12(2005), p. 98-101, in Chinese.
The simulated result with different materials is showed in the Fig.5 which show the width of the new pinch roll should be longer than 560mm and shorter than 880mm.
Roll shape of the back pinch roll Acknowledgements The authors would like to gratefully acknowledge the support of the He Bei Province Natural Science Foundation Project (No.
Kim et al.: Journal of Materials Processing Technology Vol. 187(2007),p. 738-746
[8] Xianzhang Feng, Lihong Wang, Jinfeng Wang et al.: JOURNAL OF PLASTICITY ENGINEERING Vol. 12(2005), p. 98-101, in Chinese.
Online since: August 2013
Authors: Fei Ming Chen, Xian Zhong Zhu, Hui Xia Yang
Superabsorbent fiber is a new functional high polymer material.
Its bibulous rate can be up to tens or even thousands of times larger than conventional fibers, so it is widely applied in medical and sanitary materials, sealing materials, , etc [6].
Our results can provide a new approach to compare the absorption ability of two fiber materials.
It is also a natural science fund project in jiangsu province (BK2012869).
Zhou and W.G.Zhang: Superabsorbent Materials and its Prospect of Application in Textile Industry, Journal of China Textile University. 1994, 20 (4): 80-86
Its bibulous rate can be up to tens or even thousands of times larger than conventional fibers, so it is widely applied in medical and sanitary materials, sealing materials, , etc [6].
Our results can provide a new approach to compare the absorption ability of two fiber materials.
It is also a natural science fund project in jiangsu province (BK2012869).
Zhou and W.G.Zhang: Superabsorbent Materials and its Prospect of Application in Textile Industry, Journal of China Textile University. 1994, 20 (4): 80-86
Online since: July 2011
Authors: Wen Hui Mo
It is important to note that material properties, geometry parameters and applied loads of the structure are assumed to be normal random variables.
When geometry parameters, material properties and applied loads are subject to normal random variables, reliability optimization design of the gear box is presented.
It is defined as f(x)=πb1(mz–d)ρ+πb1(mz– d)ρ +πb2(mz– d)ρ+πb2(mz– d)ρ +πb2(mz– d)ρ+πb2(mz– d)ρ +πb2(mz– d)ρ+πb2(mz– d)ρ +πb3(mz– d)ρ+πb3(mz– d)ρ +πb4(mz– d)ρ+πb4(mz– d)ρ +πdl1ρ+πdl2ρ+πdl3ρ+πdl4ρ (1) where, The is the material density.
Journal of Mechanical Design, Transactions of the ASME,0210101-02101011(2)132,2010
Mechanical Science and Technology, 957-958, (6)17,1998.
When geometry parameters, material properties and applied loads are subject to normal random variables, reliability optimization design of the gear box is presented.
It is defined as f(x)=πb1(mz–d)ρ+πb1(mz– d)ρ +πb2(mz– d)ρ+πb2(mz– d)ρ +πb2(mz– d)ρ+πb2(mz– d)ρ +πb2(mz– d)ρ+πb2(mz– d)ρ +πb3(mz– d)ρ+πb3(mz– d)ρ +πb4(mz– d)ρ+πb4(mz– d)ρ +πdl1ρ+πdl2ρ+πdl3ρ+πdl4ρ (1) where, The is the material density.
Journal of Mechanical Design, Transactions of the ASME,0210101-02101011(2)132,2010
Mechanical Science and Technology, 957-958, (6)17,1998.
Online since: March 2025
Authors: Jia Hang Zhao, Yong Hao Zhang, Jun Wu, Jun Gang Nan, Yan Hui Yang, Dong Liu, Jian Guo Wang
Salischev: Journal of Materials Processing Technology Vol. 135(2-3) (2003), p. 324
Ma: Journal of Materials Processing Technology Vol. 187-188 (2007), p. 486
Gao: Journal of Materials Processing Technology Vol. 310 (2022)
Xiong: Journal of Materials Processing Technology Vol. 121(1)(2002), p.1
Lv: Journal of Materials Processing Technology Vol. 209(4) (2009), p. 1988.
Ma: Journal of Materials Processing Technology Vol. 187-188 (2007), p. 486
Gao: Journal of Materials Processing Technology Vol. 310 (2022)
Xiong: Journal of Materials Processing Technology Vol. 121(1)(2002), p.1
Lv: Journal of Materials Processing Technology Vol. 209(4) (2009), p. 1988.
Online since: February 2020
Authors: Shao Yi Hsia
General strength of materials was based on the maximum shearing stress theory of Tresca, and machine design was referred to the distortion energy theory of Von Mises.
(2) To predict the quality of material, such as mechanical properties, formability, product appearance, and basic size
Weroñski, Head forging aspects of new forming process of screw spike, Journal of Materials Processing Technology. 153 (2004) 736-740
Wei, The preform design for self-drilling screws, National Kaohsiung University of Applied Sciences, Taiwan, Master's thesis (2010)
Hsia, Yu-Tuan Chou and Guan-Fan Lu, Analysis of Sheet Metal Tapping Screw Fabrication Using a Finite Element Method, Applied Sciences. 6 (2016) 300; doi:10.3390/app6100300.
(2) To predict the quality of material, such as mechanical properties, formability, product appearance, and basic size
Weroñski, Head forging aspects of new forming process of screw spike, Journal of Materials Processing Technology. 153 (2004) 736-740
Wei, The preform design for self-drilling screws, National Kaohsiung University of Applied Sciences, Taiwan, Master's thesis (2010)
Hsia, Yu-Tuan Chou and Guan-Fan Lu, Analysis of Sheet Metal Tapping Screw Fabrication Using a Finite Element Method, Applied Sciences. 6 (2016) 300; doi:10.3390/app6100300.
Online since: November 2010
Authors: Yong Shao, Zheng Liang Wang, En Yu Jiang, Xiao Jin Zhu
* Corresponding Author
This research is supported by program of National Nature Science Foundation of China (No.90716027), and Shanghai Talent Development Fund (No.2009020)
Introduction
As the application of flexible structure in aircraft and spacecraft increases, it is stringently required that the vibration should be controlled.
The current research mostly uses smart composite material structure with shape memory alloy embedded in the body structure [4-5].
A 2.5mm thick epoxy plate is chosen as the base material, and the size is shown in Fig. 1.
The improvement of SMA material is still a key aspect for the engineering application of the smart structures.
Journal of Vibration, Measurement & Diagnosis, 28(01), 2008, pp50-54 [2] Dong Junhui, Xue Suduo, Zhou Qian, Application of Shape Memory Alloy in Structural Vibration Control, World Earthquake Engineering, 03(18), 2002, pp123-129 [3] Gangbing Song, Brian Kelly, Brij N Agrawal, Active position control of a shape memory alloy wire actuated composite beam, Smart Material and Structures, 9, 2000, pp711-716 [4] Jeanette Epps, Ramesh Chandra, Shape Memory Alloy Actuation for Active Tuning of Composite Beams, Smart Material and Structures, 6, 1997, pp251-264 [5] Victor Birman, Shape Memory Elastic Foundation and Supports for Passive Vibration Control of Composite Plates, International Journal of Solids and Structures, 12(45), 2008, pp320-335 [6] ZuO Xiaobao, Li Aiqun, Ni Lifeng, Chen Qingfu, Investigation and Application of Intelligent Seismic-Reduced Structure Using Shape Memory Alloy, Noise and Vibration Control, 4(2), 2003, pp10-13 [7] Zhou Bo, The Constitutive Modle of Shape Memory Alloys
The current research mostly uses smart composite material structure with shape memory alloy embedded in the body structure [4-5].
A 2.5mm thick epoxy plate is chosen as the base material, and the size is shown in Fig. 1.
The improvement of SMA material is still a key aspect for the engineering application of the smart structures.
Journal of Vibration, Measurement & Diagnosis, 28(01), 2008, pp50-54 [2] Dong Junhui, Xue Suduo, Zhou Qian, Application of Shape Memory Alloy in Structural Vibration Control, World Earthquake Engineering, 03(18), 2002, pp123-129 [3] Gangbing Song, Brian Kelly, Brij N Agrawal, Active position control of a shape memory alloy wire actuated composite beam, Smart Material and Structures, 9, 2000, pp711-716 [4] Jeanette Epps, Ramesh Chandra, Shape Memory Alloy Actuation for Active Tuning of Composite Beams, Smart Material and Structures, 6, 1997, pp251-264 [5] Victor Birman, Shape Memory Elastic Foundation and Supports for Passive Vibration Control of Composite Plates, International Journal of Solids and Structures, 12(45), 2008, pp320-335 [6] ZuO Xiaobao, Li Aiqun, Ni Lifeng, Chen Qingfu, Investigation and Application of Intelligent Seismic-Reduced Structure Using Shape Memory Alloy, Noise and Vibration Control, 4(2), 2003, pp10-13 [7] Zhou Bo, The Constitutive Modle of Shape Memory Alloys
Online since: October 2011
Authors: Xin Gui Zhang, De Jian Wei
The expansive soil is widely distributed in Guangxi province and mainly formed in three types: the third system muddy rock and its weathered materials, swell-shrink damic earth and alluvial face expansive soil.
The electron transport inside material also can cause heat transportation.
The Range of l : metal solid:101~102 W/(m·K)),building material: 10-1~100 W/(m·K), insulating material: 10-2~10-1 W/(m·K)),fluid:10-1 W/(m·K),gas: 10-2~10-1 W/(m·K).
Chinese Journal of scientific and technical periodicals, 1994, 22(1):44~48
Chinese Journal of geotechnical engineering, 2004, 26(5):715~718
The electron transport inside material also can cause heat transportation.
The Range of l : metal solid:101~102 W/(m·K)),building material: 10-1~100 W/(m·K), insulating material: 10-2~10-1 W/(m·K)),fluid:10-1 W/(m·K),gas: 10-2~10-1 W/(m·K).
Chinese Journal of scientific and technical periodicals, 1994, 22(1):44~48
Chinese Journal of geotechnical engineering, 2004, 26(5):715~718