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Online since: August 2013
Authors: Bhupendra Singh Chauhan, Haeng Muk Cho, Naveen Kumar, Amrita Pandey, Ashutosh Kumar Rai
South Korea
3Department of Applied Science, DSITM, Ghaziabad (UP).
Material such as rags impregnated with linseed oil may spontaneously combust after a long induction period due to gradual exothermic reaction with oxygen.
Journal of Mechanical Science and Technology vol.24(2) (2010), p. 529-535
Biomass (renewable) resources for production of material.
Material such as rags impregnated with linseed oil may spontaneously combust after a long induction period due to gradual exothermic reaction with oxygen.
Journal of Mechanical Science and Technology vol.24(2) (2010), p. 529-535
Biomass (renewable) resources for production of material.
Online since: March 2006
Authors: X.C. Xu, Tsutomu Yamaguchi, Quan Sheng Liu, Chong Ge Wang
Xu
1,c and Tsutomu Yamaguchi3,d
1
Institute of Rock and Soil Mechanics, CAS, Wuhan, Hubei, China
2
Shandong University of Science and Technology, Taian, Shandong, China
3
Institute for Geo-Resources and Environment, AIST, Tsukuba West, Ibaraki, Japan
a
liuqs@whrsm.ac.cn,b chgewang@163.com,cxcxu@whrsm.ac.cn,d t-yamaguchi@aist.go.jp
Keywords: Time-temperature equivalence, rock, thermodynamics, experiment
Abstract.
(1) where ψ is the Helmholtz's free energy function, 'ijb are linear coefficients in Onsager's principle considered as material constants, jq are state variables in the system concerning strain components, temperatures and non-observable inner variables, and iQ are generalized forces.
(19) where D1 and D2 are material constants of rock, h is the free-volume fraction, VVh f /= , V is the whole volume of rock and Vf is the free volume after subtracting micro voids volume between grains.
Acknowledgements This study was supported by the Chinese Natural Science Foundation (Grant No.: 40172098) and Innovation Foundation Project of Institute of Rock and Soil Mechanics, CAS( Grant No.
Phys., Vol.25 (1954), p.1385 [7] Liu, Q., Wang, C.: Chinese Journal of Rock Mechanics and Engineering Vol.22 (2002), p.193 [8] Liu, Q., Xu, X., Yamaguchi, T.: Proc.
(1) where ψ is the Helmholtz's free energy function, 'ijb are linear coefficients in Onsager's principle considered as material constants, jq are state variables in the system concerning strain components, temperatures and non-observable inner variables, and iQ are generalized forces.
(19) where D1 and D2 are material constants of rock, h is the free-volume fraction, VVh f /= , V is the whole volume of rock and Vf is the free volume after subtracting micro voids volume between grains.
Acknowledgements This study was supported by the Chinese Natural Science Foundation (Grant No.: 40172098) and Innovation Foundation Project of Institute of Rock and Soil Mechanics, CAS( Grant No.
Phys., Vol.25 (1954), p.1385 [7] Liu, Q., Wang, C.: Chinese Journal of Rock Mechanics and Engineering Vol.22 (2002), p.193 [8] Liu, Q., Xu, X., Yamaguchi, T.: Proc.
Online since: September 2014
Authors: Chung Ching Lee, Ying Chieh Lin, Chia Hsien Li, Heng Sheng Lin
Micro Rotary Plunge-Swaging of Stainless Pipes
Heng-Sheng Lina, Chung-Ching Leeb, Ying-Chieh Linc, Chia-Hsien Lid
Department of Mold and Die Engineering, National Kaohsiung University of Applied Sciences, Kaohsiung 807, Taiwan
ahslin@kuas.edu.tw, bcclee@kuas.edu.tw, cyclin@mail.mirdc.org.tw, dmike020425@hotmail.com
Keywords: Micro Rotary Plunge-Swaging, Micro Piping.
Methods Materials and Experimental Procedures.
Acknowledgements The authors thank the research fund NSC 99-2221-E-151-070-MY2 granted by the National Science Council, Taiwan.
Hartl, Experimental and numerical investigation of localized thinning in hydroforming of micro-tubes, European Journal of Mechanics A/Solids 31 (2012) 67-76
Methods Materials and Experimental Procedures.
Acknowledgements The authors thank the research fund NSC 99-2221-E-151-070-MY2 granted by the National Science Council, Taiwan.
Hartl, Experimental and numerical investigation of localized thinning in hydroforming of micro-tubes, European Journal of Mechanics A/Solids 31 (2012) 67-76
Online since: August 2019
Authors: Daniel V. Oliveira, Rui A. Silva, Els Verstrynge, Antonio Romanazzi, Michiel Van Gorp
Materials and Structures, 47 (2014) 2021-2037
Materials, 9 (2016) 1-17
Materials and Structures, 46 (2013) 203-219
Materials and Structures, 38 (2005) 781-785
Materials and Structures, 48 (2015) 3443-3456
Materials, 9 (2016) 1-17
Materials and Structures, 46 (2013) 203-219
Materials and Structures, 38 (2005) 781-785
Materials and Structures, 48 (2015) 3443-3456
Online since: February 2009
Authors: C.S. Okoli
Low soil temperature retards the growth of seedlings and
absorption of materials.
MATERIALS A(D METHODS Description of Study Area: The experiment was conducted at the Agricultural Engineering experimental Farm of the Federal University of Technology, Akure between December and March 2006.
Journal of Horticultural Science & Biotechnology, 73(1), p. 125. 4.
Agronomy Journal Vol. 92, p. 1221. 16.
Agronomy Journal, Vol. 92, p. 821. 18.
MATERIALS A(D METHODS Description of Study Area: The experiment was conducted at the Agricultural Engineering experimental Farm of the Federal University of Technology, Akure between December and March 2006.
Journal of Horticultural Science & Biotechnology, 73(1), p. 125. 4.
Agronomy Journal Vol. 92, p. 1221. 16.
Agronomy Journal, Vol. 92, p. 821. 18.
Online since: October 2009
Authors: Mark Easton, David H. StJohn, Lisa Sweet
[5] Easton, M.A. and StJohn, D.H. (2008) Improved prediction of the grain size of aluminium
alloys that includes the effect of cooling rate, Materials Science and Engineering A, 486(1-2):
8-13
Kearns, M.A., Boothroyd, C.B. and Greer, A.L. (1999) Grain Refinement by Al-Ti-B Alloys in Aluminium Melts: A Study of the Mechanisms of Poisoning by Zirconium, Materials Science and Technology, 15: 1115-1123
[24] Spittle, J.A. and Brown, S.G. (2005) Numerical modelling of permeability variation with composition in aluminium alloy systems and its relationship to hot tearing, Materials Science and Technology, 21(9): 1-7
-M and Gremaud, M. (1999) A New Hot-Tearing Criterion, Metallurgical and Materials Transactions A, 30A: 449-455
Whiteley, Editor. 2001, The Minerals, Metals and Materials Society, Warrendale USA. p. 213-219.
Kearns, M.A., Boothroyd, C.B. and Greer, A.L. (1999) Grain Refinement by Al-Ti-B Alloys in Aluminium Melts: A Study of the Mechanisms of Poisoning by Zirconium, Materials Science and Technology, 15: 1115-1123
[24] Spittle, J.A. and Brown, S.G. (2005) Numerical modelling of permeability variation with composition in aluminium alloy systems and its relationship to hot tearing, Materials Science and Technology, 21(9): 1-7
-M and Gremaud, M. (1999) A New Hot-Tearing Criterion, Metallurgical and Materials Transactions A, 30A: 449-455
Whiteley, Editor. 2001, The Minerals, Metals and Materials Society, Warrendale USA. p. 213-219.
Online since: September 2003
Authors: Cheng Yong Wang, C. Rolf
Citation & Key Engineering Materials Vols
Schwartz: Advances in Ultra Hard Materials Application Technology Vol. 2 (1982), p. 127 [10] H.H.
Clausen: International Journal of Machine Tools and Manufacture Vol. 42(9) (2002), p. 1045 [16] R.
Clausen: International Journal of Machine Tools and Manufacture (to be published) [21] M.
Clausen: Key Engineering Materials Vol. 202-203 (2001), p. 61 [25] R.
Schwartz: Advances in Ultra Hard Materials Application Technology Vol. 2 (1982), p. 127 [10] H.H.
Clausen: International Journal of Machine Tools and Manufacture Vol. 42(9) (2002), p. 1045 [16] R.
Clausen: International Journal of Machine Tools and Manufacture (to be published) [21] M.
Clausen: Key Engineering Materials Vol. 202-203 (2001), p. 61 [25] R.
Online since: February 2026
Authors: Ruslan Sabah Abdulrahman, Farah Ibrahim Abdalsalam, Safaa Hameed Faisal, Tahseen A. Jabbar
It is also important for materials processing and crystal growth, particularly because convection affects the material microstructure as well as the physical properties of the material.
Channapattanac, Natural convection heat transfer inside trapezoidal enclosure using Cu-water nanofluid with heat source at various positions, Al-Nahrain Journal for Engineering Sciences 26 (2023) 175–185
Farsi, Numerical simulation of heat transfer and entropy generation in a trapezoidal enclosure with sinusoidal temperature wall using nanofluid, Applications in Engineering Science 19 (2024) 100186
Faisal, Numerical simulation of natural convection in a trapezoidal enclosure with inner rotating cylinder and magnetic field, Scientific Review Engineering and Environmental Sciences 32 (2023) 135–154
Faisel, Numerical analysis of natural convection heat transfer in a trapezoidal enclosure using water-based nanofluid, International Journal of Heat and Technology 38 (2020) 925–932
Channapattanac, Natural convection heat transfer inside trapezoidal enclosure using Cu-water nanofluid with heat source at various positions, Al-Nahrain Journal for Engineering Sciences 26 (2023) 175–185
Farsi, Numerical simulation of heat transfer and entropy generation in a trapezoidal enclosure with sinusoidal temperature wall using nanofluid, Applications in Engineering Science 19 (2024) 100186
Faisal, Numerical simulation of natural convection in a trapezoidal enclosure with inner rotating cylinder and magnetic field, Scientific Review Engineering and Environmental Sciences 32 (2023) 135–154
Faisel, Numerical analysis of natural convection heat transfer in a trapezoidal enclosure using water-based nanofluid, International Journal of Heat and Technology 38 (2020) 925–932