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Online since: July 2014
Authors: Zhi Jie Sun
The primary support of sprayed concrete is elastic material.
All material parameters are shown in Tab.1[3,4].
Acknowledgements This work was financially supported by the Shanxi Traffic Science and Research Project (Research and Application of Supporting Structure Mechanical Properties of Large Section of Loess Tunnel), (2012-1-1).
References [1] Jinwen Li: Shanxi Science & Technology of Communications.
[2] Hongyue Zhan and Qicai Wang: Journal of Water Resources Architectural Engineering.
All material parameters are shown in Tab.1[3,4].
Acknowledgements This work was financially supported by the Shanxi Traffic Science and Research Project (Research and Application of Supporting Structure Mechanical Properties of Large Section of Loess Tunnel), (2012-1-1).
References [1] Jinwen Li: Shanxi Science & Technology of Communications.
[2] Hongyue Zhan and Qicai Wang: Journal of Water Resources Architectural Engineering.
Online since: January 2024
Authors: Guan Hua Wu, Сhao Bo Chen, Bin Bin Zhang, Song Gao
Ryan J et al. introduced the application advantages and prospects of machine learning in materials science [10].
Energetic Materials, 2021, 29(09): 819-826
High Temperature Materials and Processes, 2022, 41(1)
Deep learning object detection in materials science: Current state and future directions[J].
Computational Materials Science, 2022, 211
Energetic Materials, 2021, 29(09): 819-826
High Temperature Materials and Processes, 2022, 41(1)
Deep learning object detection in materials science: Current state and future directions[J].
Computational Materials Science, 2022, 211
Online since: December 2012
Authors: Cong Li, Wei Zhang
Landscape ecology plays a role as a bridge between biological ecology and human ecology, which also works for natural science and humanities.
Cover way affects the connectivity of the landscape greatly and also the flow and exchange of species, materials and energy between patches.
Gao: Landscape Ecology(Science Press, China 2003)(In Chinese)
(The Chinese Journal Of Mechanics 2005)(In Chinese) [4] H.Q.
(The Chinese Journal of Mechanics 2008)(In Chinese)
Cover way affects the connectivity of the landscape greatly and also the flow and exchange of species, materials and energy between patches.
Gao: Landscape Ecology(Science Press, China 2003)(In Chinese)
(The Chinese Journal Of Mechanics 2005)(In Chinese) [4] H.Q.
(The Chinese Journal of Mechanics 2008)(In Chinese)
Online since: February 2013
Authors: Jin Ming Wang, Pei Yong Guo, Ding Lu, Xiu Fu Hou
Materials and Methods
Sample collection
Study area.
This work was supported by the National Natural Science Foundation of China (No.20777021), the Natural Science Foundation of Fujian Province of China (No.2010J01043, D0610012), Ministry of Education, Key Research Project of Science and Technology (No. 210253) References [1] J.M.
Chisholm:Science Vol.268 (1995),p.1480 [4] P.Y.
Demers: Journal of Experimental Marine Biology and Ecology Vol.406 (2011), p.95 [8] M.B.
Kudela: Journal of Microbiological Methods Vol.89 (2012),p.209 [9] J.M.
This work was supported by the National Natural Science Foundation of China (No.20777021), the Natural Science Foundation of Fujian Province of China (No.2010J01043, D0610012), Ministry of Education, Key Research Project of Science and Technology (No. 210253) References [1] J.M.
Chisholm:Science Vol.268 (1995),p.1480 [4] P.Y.
Demers: Journal of Experimental Marine Biology and Ecology Vol.406 (2011), p.95 [8] M.B.
Kudela: Journal of Microbiological Methods Vol.89 (2012),p.209 [9] J.M.
Online since: September 2015
Authors: M.H. Aliabadi, Corrado Di Pisa
The material considered is an aluminium with Young’s modulus 73 GPa and Poisson’s ratio of 0.3, for skin, spare and stingers.
References: [1]MH Aliabadi, et al The Journal of Strain Analysis for Engineering Design 22 (4), 203-207, 1997 [2] I.Benedetti, et al Int J Numer Methods Eng, 80(10), (2009) 1356-78
[5] I Benedetti, MH Aliabadi, Computational Materials Science 67, (2013b) 249-260
Elements, (2015)56, 162-175 [34] DP Rooke, et al Fatigue & Fracture of Eng Materials & Structures (1992) 15 (5), 441-461 [35] X Huang, et al CMES: Computer Modeling in Eng & Sciences (2014), 102 (4), 291-330
References: [1]MH Aliabadi, et al The Journal of Strain Analysis for Engineering Design 22 (4), 203-207, 1997 [2] I.Benedetti, et al Int J Numer Methods Eng, 80(10), (2009) 1356-78
[5] I Benedetti, MH Aliabadi, Computational Materials Science 67, (2013b) 249-260
Elements, (2015)56, 162-175 [34] DP Rooke, et al Fatigue & Fracture of Eng Materials & Structures (1992) 15 (5), 441-461 [35] X Huang, et al CMES: Computer Modeling in Eng & Sciences (2014), 102 (4), 291-330
Online since: September 2013
Authors: Hong Ru Li, Zhi Bin Jiang, Nan Kang, Jun Tian Qu
Introduction
Tension controls are widely used in web-material transport systems such as papers, textiles, composites, polymers and metals.
Due to the unwind or rewind roller releases or accumulates material, their radii and inertia are time-varying.
and are the lengths of the web span between the process roller and unwind/rewind rollers; is the web thickness, is the web width and is the density of the web material; A is the area of cross-section of the web; E is the modulus of elasticity of the web material; is the constant tension of the unwind roller.
Acknowledgment This work was supported by the National Natural Science Foundation of China (No. 61074098).
Journal of Dynamic Systems, Measurement, and Control 116.2 (1994): 293-304
Due to the unwind or rewind roller releases or accumulates material, their radii and inertia are time-varying.
and are the lengths of the web span between the process roller and unwind/rewind rollers; is the web thickness, is the web width and is the density of the web material; A is the area of cross-section of the web; E is the modulus of elasticity of the web material; is the constant tension of the unwind roller.
Acknowledgment This work was supported by the National Natural Science Foundation of China (No. 61074098).
Journal of Dynamic Systems, Measurement, and Control 116.2 (1994): 293-304
Online since: October 2011
Authors: Qing Zhang, Zhong Qiu Liu
And the deformation-dependant permeability for the concrete material is used [3] (Eq. (4))
The material parameters of grouting zone (GZ) are adjusted according to the surrounding rock mass which using a Druker-Prager failure criterion, which is shown in Table 1.
Table 1: Material Properties for Coupled Analysis Material Dry Specific Weight Compression Strength Tensile Strength Initial Void Ratio Initial Hydraulic Conductivity Rock Mass 27.5 kN/m3 1.5e+05 kPa / 0.01 0.04 m/d Concrete 25.0 kN/m3 2.5e+04 kPa 2.17e+3kPa 0.005 0.0008 m/d Rebar 78.0 kN/m3 3.1e+05 kPa 3.1e+05 kPa / / Results Seepage from outside to inside.
Acknowledgements This work was financially supported by the National Natural Science Foundation of China (10972072) and Young Scholars Science and Technology Innovation Project of Shandong Agricultural University (23698).
Wong, in: The Transition from Brittle Faulting to Cataclastic Flow: Permeability Evolution, Journal of Geophysical Research, 102(B2), 3027~3041 (1997).
The material parameters of grouting zone (GZ) are adjusted according to the surrounding rock mass which using a Druker-Prager failure criterion, which is shown in Table 1.
Table 1: Material Properties for Coupled Analysis Material Dry Specific Weight Compression Strength Tensile Strength Initial Void Ratio Initial Hydraulic Conductivity Rock Mass 27.5 kN/m3 1.5e+05 kPa / 0.01 0.04 m/d Concrete 25.0 kN/m3 2.5e+04 kPa 2.17e+3kPa 0.005 0.0008 m/d Rebar 78.0 kN/m3 3.1e+05 kPa 3.1e+05 kPa / / Results Seepage from outside to inside.
Acknowledgements This work was financially supported by the National Natural Science Foundation of China (10972072) and Young Scholars Science and Technology Innovation Project of Shandong Agricultural University (23698).
Wong, in: The Transition from Brittle Faulting to Cataclastic Flow: Permeability Evolution, Journal of Geophysical Research, 102(B2), 3027~3041 (1997).
Online since: September 2013
Authors: Yuan Wang, Shou Cheng Wang, He Nan Chen
Finite Element Analysis on Key Components of Horizontal Refuse Compactor
Henan Chen1, a, Shoucheng Wang1, b and Yuan Wang1,c
1Chinesisch-Deutsche Technische Fakultät, Qingdao University of Science and Technology, Qingdao, China, 266061
a315357886@qq.com, b wscwn@163.com, cwangkatze@126.com
Key words: horizontal refuse compactor, structural design, statics analysis, Finite Element Analysis
Abstract.
Fig. 4 The locking mechanism FEA of block, push head and the clamp Definition of the nature of materials.
The material nature of refuse is defined as, with flexibility modulus, Poisson’s ratio.
By doing so, when block meets the requirements, the structure could be maximally optimized, thus materials and manufacturing cost could be saved. 2.
References [1] Courant R.Variational methods for the solution of problems of equilibrum and vibration,Bulletin of American Mathematical Society. 49(1943) 1-23 [2] Turner M J,Clough R W,Martin H C,Topp L J.Stiffness and defection anslysis of complex structures,Journal of Aeronautical Sciences. 23(1956) 805-824
Fig. 4 The locking mechanism FEA of block, push head and the clamp Definition of the nature of materials.
The material nature of refuse is defined as, with flexibility modulus, Poisson’s ratio.
By doing so, when block meets the requirements, the structure could be maximally optimized, thus materials and manufacturing cost could be saved. 2.
References [1] Courant R.Variational methods for the solution of problems of equilibrum and vibration,Bulletin of American Mathematical Society. 49(1943) 1-23 [2] Turner M J,Clough R W,Martin H C,Topp L J.Stiffness and defection anslysis of complex structures,Journal of Aeronautical Sciences. 23(1956) 805-824
Online since: August 2013
Authors: Yong Qi Zhang, Xiao Chu Wang, Peng Niu, Chun Fu Jin
Its ultimate state of bearing capacity is usually determined by the loss of overall stability of the member, and it gives mainly the elastic-plastic buckling on the plastic material.
Beijing: Science Press,(2003).
Key Engineering Materials .Vols. 452-453 (2011) ,p.485-488
Journal of Huazhong University of Science and Techenology, Vol.25 (2008) , p.128.
Key Engineering Materials.
Beijing: Science Press,(2003).
Key Engineering Materials .Vols. 452-453 (2011) ,p.485-488
Journal of Huazhong University of Science and Techenology, Vol.25 (2008) , p.128.
Key Engineering Materials.
Online since: April 2014
Authors: Dong Jia Yin, Xiong Jun He, De Quan You, Bing Kai Liu
Influence of Tensioning Stress to Web Cracking of
Rigid Frame Bridge in Cantilever Construction
Dongjia Yin 1, a, Xiongjun He2,b,Dequan You3,c , Bingkai Liu4
1School of Transportation,Wuhan University of Technology, Wuhan 430063,China
2 School of Transportation,Wuhan University of Technology, Wuhan 430063,China
3Fujian Research Institute Communications Science and Technology,Fuzhou 350004
4School of Transportation,Wuhan University of Technology, Wuhan 430063,China
ayindongjia1230@163.com, bhxjwhut@163.com, c dequan1990@hotmail.com
Keywords: web cracks;cantilever construction;FEA
Abstract.
During the analysis, the slipping between concrete and tendons is ignored, but two points of basic assumption are taken in account: Small deformation and Material nonlinearity.
The parameters of materials can consult relevant norms.
The materials are as follows: (1) Concrete: C50 , standard tensile strength is 2.65Mpa; (2) Prestressed steel: Φs15.2 steel strand; (3) Vertical steel: Φs32 finish rolling deformed steel.
References [1]Reseach Institute of High Ministry of Transport,The Research of Causes and Treatment Technical of Crack on Prestressed Concrete Continuous Beam and Continuous Rigid-frame Box Girder[R],2007.in Chinese [2]LIU Fangping, ZHOU Jianting, Song Jun, Wu Heng, Analysis of Formation Causes of Diagonal Cracks in Box Girder Web During Cantilever Construction[J], Construction Technology,2012.12(41):47-50,in Chinese [3]ZHU han-hua, CHEN meng-chong,YUAN ying-jie, Analysis and Prevention of Crack on Prestressed Concrete Continuous Rigid-frame Box Girder[M], Beijing: China Communication Press, 2006,in Chinese [4] Okeil Ayman M,Allowable tensile stress for webs of prestressed segmental concrete bridges,ACI stryctural Journal,v103,n4,p488-495,July/August 2006 [5] WU Lang, FANG Shuiping, WAN Ni, Experimental research of early tensile strength of concrete[J], Jiangxi Science, 2007.4(25):175-177,in Chinese
During the analysis, the slipping between concrete and tendons is ignored, but two points of basic assumption are taken in account: Small deformation and Material nonlinearity.
The parameters of materials can consult relevant norms.
The materials are as follows: (1) Concrete: C50 , standard tensile strength is 2.65Mpa; (2) Prestressed steel: Φs15.2 steel strand; (3) Vertical steel: Φs32 finish rolling deformed steel.
References [1]Reseach Institute of High Ministry of Transport,The Research of Causes and Treatment Technical of Crack on Prestressed Concrete Continuous Beam and Continuous Rigid-frame Box Girder[R],2007.in Chinese [2]LIU Fangping, ZHOU Jianting, Song Jun, Wu Heng, Analysis of Formation Causes of Diagonal Cracks in Box Girder Web During Cantilever Construction[J], Construction Technology,2012.12(41):47-50,in Chinese [3]ZHU han-hua, CHEN meng-chong,YUAN ying-jie, Analysis and Prevention of Crack on Prestressed Concrete Continuous Rigid-frame Box Girder[M], Beijing: China Communication Press, 2006,in Chinese [4] Okeil Ayman M,Allowable tensile stress for webs of prestressed segmental concrete bridges,ACI stryctural Journal,v103,n4,p488-495,July/August 2006 [5] WU Lang, FANG Shuiping, WAN Ni, Experimental research of early tensile strength of concrete[J], Jiangxi Science, 2007.4(25):175-177,in Chinese