Sort by:
Publication Type:
Open access:
Publication Date:
Periodicals:
Search results
Online since: May 2020
Authors: Jia Lin Tsai, Po Ying Tseng, Wen Jie Ke
Chen: Journal of Applied Polymer Science Vol. 131 (2014), Article ID 40565
[7] Q.
Liu: Chemistry of Materials Vol. 26 (2014), pp. 4459-4465 [8] Y.
Tsai: Journal of Composite Materials Vol. 53 (2018), pp. 835-847 [15] S.
Zhang: Computational Materials Science Vol. 31 (2004), pp. 225-236 [24] Y.
Du: Computational Materials Science Vol. 143 (2018), pp. 240-247
Liu: Chemistry of Materials Vol. 26 (2014), pp. 4459-4465 [8] Y.
Tsai: Journal of Composite Materials Vol. 53 (2018), pp. 835-847 [15] S.
Zhang: Computational Materials Science Vol. 31 (2004), pp. 225-236 [24] Y.
Du: Computational Materials Science Vol. 143 (2018), pp. 240-247
Online since: October 2015
Authors: Mahani Yusoff, Ahmad Fauzi Mohd Noor, Razali Mohd Hasmizam
Arrighi: Journal of Hazardous Materials, Vol. 160 (2008), p. 265
Xua: Journal of Hazardous Materials, Vol. 161 (2009), p. 231
K., Wan Mohd Zain: Journal of Sustainability Science and Management, Vol. 8 (2013), p. 244
Frank: Journal of Materials Chemistry.
M., Rudin: Journal of Sustainability Science and Management, Vol. 4 (2009), p. 49
Xua: Journal of Hazardous Materials, Vol. 161 (2009), p. 231
K., Wan Mohd Zain: Journal of Sustainability Science and Management, Vol. 8 (2013), p. 244
Frank: Journal of Materials Chemistry.
M., Rudin: Journal of Sustainability Science and Management, Vol. 4 (2009), p. 49
Online since: November 2011
Authors: Wei Song, Hu Qiang Wang, Lei Yang, Gui Cheng Wang, Hong Jie Pei
Canarim: Journal of the Brazilian Society of Mechanical Sciences and Engineering Vol.31 (2009), pp. 47-51
Xia: Advanced Materials Science and Technology Vol.181-182 (2011), pp.1013-1017
Alpas: Journal of Materials Processing Technology Vol. 210 (2010), pp. 2142-2153
Malavolta: Journal of the Brazilian Society of Mechanical Sciences and Engineering Vol. 32 (2010), pp. 154-159
Takada: Key Engineering Materials Vol.257-258 (2004), pp. 559-564
Xia: Advanced Materials Science and Technology Vol.181-182 (2011), pp.1013-1017
Alpas: Journal of Materials Processing Technology Vol. 210 (2010), pp. 2142-2153
Malavolta: Journal of the Brazilian Society of Mechanical Sciences and Engineering Vol. 32 (2010), pp. 154-159
Takada: Key Engineering Materials Vol.257-258 (2004), pp. 559-564
Online since: August 2015
Authors: Aelita Nikulina, Pavel Komarov, Alexandra Chevakinskaya, Vadim Skeeba
Liu, Mechanism of forming interfacial intermetallic compounds at interface for solid state diffusion bonding of dissimilar materials, Materials Science and Engineering A. 437 (2006) 430-435
Baksan, Microstructure and strength of friction-welded Fe–28Al and 316 L stainless steel, Materials Science and Engineering A. 528 (2011) 8530– 8536
Mordike, Formation of a crack-free joint between Ti alloy and Al alloy by using a high-power CO2 laser, Journal of Materials Science, 32 (1997) 6191-6200
Venkata Ramana, Role of nickel as an interlayer in dissimilar metal friction welding of maraging steel to low alloy steel, Journal of Materials Processing Technology. 212 (2012) 66-77
Jouvard, Multiphysical modeling of dissimilar welding via interlayer, Journal of Materials Processing Technology. 211 (2011) 1796-1803
Baksan, Microstructure and strength of friction-welded Fe–28Al and 316 L stainless steel, Materials Science and Engineering A. 528 (2011) 8530– 8536
Mordike, Formation of a crack-free joint between Ti alloy and Al alloy by using a high-power CO2 laser, Journal of Materials Science, 32 (1997) 6191-6200
Venkata Ramana, Role of nickel as an interlayer in dissimilar metal friction welding of maraging steel to low alloy steel, Journal of Materials Processing Technology. 212 (2012) 66-77
Jouvard, Multiphysical modeling of dissimilar welding via interlayer, Journal of Materials Processing Technology. 211 (2011) 1796-1803
Online since: September 2015
Authors: S.G. Pandav, V.P. Deshmukh, M.R. Mohape, S. Deole, A.S. Tambavekar, V.R. Baviskar, S.R. Sable, M.M. Chitale, V.M. Nimbalkar
Sable2, M.M.Chitale2
1Naval Materials Research Laboratory, Shill–Badlapur Road, Ambernath–421506, India.
2G.V.Acharya Institute of Engineeing and Technology, Shelu, Karjat, 410101, India.
The value of δ (or the tangent of δ), is a measure of the damping capacity of a material and represents the ability of a material to absorb and dissipate mechanical vibrations.
[6] V.M.Nimbalkar, B.R.K.Rao , V.P.Deshmukh, and A.K.Shah, Wear behavior of aluminium alloy based composites containing in situ reinforced TiB2 particles, Metals Materials and Processes, 2004, vol 16, No 4.pp 391-396
[10] R.Keshavamurthy, Sadananda Mageri, Ganesh Raj, B.Naveenkumar, Prashant M Kadakol and K.Vasu, Microstructure and Mechanical Properties of Al7075-TiB2 in-situ composite, Research Journal of Material Sciences, Vol. 1(10), 6-10, November (2013)
Chung, Titanium Diboride reinforced aluminium with high wear resistance, journal of material science 31(1996) 5961-5973
The value of δ (or the tangent of δ), is a measure of the damping capacity of a material and represents the ability of a material to absorb and dissipate mechanical vibrations.
[6] V.M.Nimbalkar, B.R.K.Rao , V.P.Deshmukh, and A.K.Shah, Wear behavior of aluminium alloy based composites containing in situ reinforced TiB2 particles, Metals Materials and Processes, 2004, vol 16, No 4.pp 391-396
[10] R.Keshavamurthy, Sadananda Mageri, Ganesh Raj, B.Naveenkumar, Prashant M Kadakol and K.Vasu, Microstructure and Mechanical Properties of Al7075-TiB2 in-situ composite, Research Journal of Material Sciences, Vol. 1(10), 6-10, November (2013)
Chung, Titanium Diboride reinforced aluminium with high wear resistance, journal of material science 31(1996) 5961-5973
Online since: February 2018
Authors: C. Velmurugan, R.C. Mohan Kumar
Emad-Al-Momani et al [9], uses DOE technique for investigating the effect of parameters for two different materials.
Methodology The experimentation part involves two different materials AISI 1020 and AISI 304 and the following represents the methodology in which the experimentation was carried out.
A.B. (2014), “Geometrical Defect in Precision Blanking/Punching: A Comprehensive Review on Burr Formation,” Research Journal of Applied Sciences, Engineering and Technology, Vol.8, pp. 1139-1148
[11] Ridha Hambli, (June 2005), “Optimization of blanking process using neural network simulation”, The Arabian Journal for Science and Engineering, Vol 30, PP. 135-139
Batoz (2004), “Blank optimization in sheet metal forming using an evolutionary algorithm”, Journal of Materials Processing Technology, pp.183-191.
Methodology The experimentation part involves two different materials AISI 1020 and AISI 304 and the following represents the methodology in which the experimentation was carried out.
A.B. (2014), “Geometrical Defect in Precision Blanking/Punching: A Comprehensive Review on Burr Formation,” Research Journal of Applied Sciences, Engineering and Technology, Vol.8, pp. 1139-1148
[11] Ridha Hambli, (June 2005), “Optimization of blanking process using neural network simulation”, The Arabian Journal for Science and Engineering, Vol 30, PP. 135-139
Batoz (2004), “Blank optimization in sheet metal forming using an evolutionary algorithm”, Journal of Materials Processing Technology, pp.183-191.
Online since: April 2016
Authors: Qing Yi Liu, Chang Ping Wei, Li Dan Dong, Feng Ming Wang, Shuang Sun, Jing Li
Materials and Preparation
Raw Material.
The Performance Analysis of theSample The Sample of different Raw Materials Ratio had Effect on Clotting, Hemostatic Capability.
Fig. 3 The clotting capability test of the sample of different raw materials ratio Fig.4 The hemostatic performance test of the sample of different raw materials ratio m1:the weight of chitosan m2:the weight of baicalin Fig.3 and Fig.4 showed that with the increase of the quality ratio of chitosan and baicalin the effect of coagulation and hemostasis was gradually enhanced, but the effect of coagulation and hemostasis was enhanced more slowly when the quality ratio exceeded 1:0.8, so the best quality ratio of chitosan and baicalin was 1:0.8.
[4] I.Y.Kim, L.Eichel and R.Edwards: Journal of Endourology, Vol.21(2007)No.6,p.652
[11] R.S.Xu:Chemistry of Natural Product(science press,China,1993),p.588.
The Performance Analysis of theSample The Sample of different Raw Materials Ratio had Effect on Clotting, Hemostatic Capability.
Fig. 3 The clotting capability test of the sample of different raw materials ratio Fig.4 The hemostatic performance test of the sample of different raw materials ratio m1:the weight of chitosan m2:the weight of baicalin Fig.3 and Fig.4 showed that with the increase of the quality ratio of chitosan and baicalin the effect of coagulation and hemostasis was gradually enhanced, but the effect of coagulation and hemostasis was enhanced more slowly when the quality ratio exceeded 1:0.8, so the best quality ratio of chitosan and baicalin was 1:0.8.
[4] I.Y.Kim, L.Eichel and R.Edwards: Journal of Endourology, Vol.21(2007)No.6,p.652
[11] R.S.Xu:Chemistry of Natural Product(science press,China,1993),p.588.
Online since: December 2013
Authors: Xue Wen Lei, Zu Jia Zheng, Qing Ping Jin, Zhi Chen
Soil nailings were two type of materials, one was HRB335 steel, another was GFRP.Grouting cement was No.425, friction angle was 50°, GFRP bar’s elastic modulus was 45 GPa.The model consisted of 9600 zones, 11050 grid-points,832 structural-elements and 709 nodes.
Two different types of materials were applied as soil nailing, plastic zone distribution was obtained by numerical simulation, shown in Fig 2.
Journal of Structure Engnr, Oct. (2009), p.1164~1175
Chinese Journal of Solid Mechanics (2011), 2.32(1), p.88-93(In Chinese)
Engelhardt, ect.Journal of Bridge Engnr, Sept.
Two different types of materials were applied as soil nailing, plastic zone distribution was obtained by numerical simulation, shown in Fig 2.
Journal of Structure Engnr, Oct. (2009), p.1164~1175
Chinese Journal of Solid Mechanics (2011), 2.32(1), p.88-93(In Chinese)
Engelhardt, ect.Journal of Bridge Engnr, Sept.
Online since: November 2013
Authors: Marisa Masumi Beppu, Marina Salvarani Tonoli
Materials Science and Engineering C, v. 23, p. 651-658, 2003
Materials Science and Engineering C, v. 26, p. 78-86, 2006
Journal of Materials Chemistry, v.17, p. 3980-3986, 2007
Journal of Materials Science Materials in Medicine, v.8, 1993 [15] Jinlong, N.; Zhenxi, Z.; Dazong, J.
Journal of Materials Science Materials in Medicine, v.11, p. 155-162, 2000.
Materials Science and Engineering C, v. 26, p. 78-86, 2006
Journal of Materials Chemistry, v.17, p. 3980-3986, 2007
Journal of Materials Science Materials in Medicine, v.8, 1993 [15] Jinlong, N.; Zhenxi, Z.; Dazong, J.
Journal of Materials Science Materials in Medicine, v.11, p. 155-162, 2000.
Online since: September 2013
Authors: Ting Ping Chang, Te Fu Huang, Shyh Chour Huang, Thanh Phong Dao
Analysis of Cold Preforming Process for Hollow Fasteners with Thin Flange
Ting-Ping Chang1,a, Shyh-Chour Huang1,b, Te-Fu Huang2,c,
Thanh-Phong Dao1,d
1Department of Mechanical Engineering, National Kaohsiung University of Applied Sciences
Kaohsiung, Taiwan, R.O.C.
2Department of Mold and Die Engineering National Kaohsiung University of Applied Sciences
Kaohsiung, Taiwan, R.O.C.
Wang, Journal of Materials Processing Technology. 151 (2004) 321-327
Wu, International Journal of Machine Tools & Manufacture. 47 (2007) 168-174
Manach, Journal of Materials Processing Technology. 211 (2011) 1606-1613
Im, Journal of Materials Processing Technology. 184 (2007) 411-419.
Wang, Journal of Materials Processing Technology. 151 (2004) 321-327
Wu, International Journal of Machine Tools & Manufacture. 47 (2007) 168-174
Manach, Journal of Materials Processing Technology. 211 (2011) 1606-1613
Im, Journal of Materials Processing Technology. 184 (2007) 411-419.