Sort by:
Publication Type:
Open access:
Publication Date:
Periodicals:
Search results
Online since: June 2011
Authors: Jin Quan Sun, Qing Kun He, Shao Hua Huang, Hong Guang Yang, Yong Feng Li, Hongzhi Cui
Laser Cladding of Ni-based Alloy on Mg alloy with Brass Transition
He Qingkun1, a, Cui Hongzhi1, b, Huang Shaohua2, Sun Jinquan1,
Yang Hongguang1 and Li Yongfeng1
1School of Materials Science and Engineering, Shandong University of Science and Technology, Qingdao 266510, China
2General Electromechanical Factory, China University of Petroleum, Dongying 257061, China
aqingkunhe@sina.com, bcuihongzhi1965@163.com
Keywords: Laser cladding; Magnesium alloy; Brass transition; Ni-based Alloy
Abstract.
In addition, the corrosion potential (Ecorr) of the sample was much higher than that of untreated materials.
Wear resistance and corrosion potential of the treated materials are greatly improved.
The corrosion potential (Ecorr) of the laser-clad Ni60 sample was much higher than that of brass transition and untreated materials.
Journal, Vol. 35 (2008), p. 1766
In addition, the corrosion potential (Ecorr) of the sample was much higher than that of untreated materials.
Wear resistance and corrosion potential of the treated materials are greatly improved.
The corrosion potential (Ecorr) of the laser-clad Ni60 sample was much higher than that of brass transition and untreated materials.
Journal, Vol. 35 (2008), p. 1766
Online since: October 2010
Authors: Jun Zhao, Shi Bo Ma, Jin Ma
Experimental material and method
The substrate materials is alloy structure steel 4140, coating material is even mixture which consists of WC and two kinds of binding phase powder (A , B) ground by ball milling separately, each mass rate is 3 to 1, the graininess of the powder is 5~15μm, A is Fe60 (C,0.5-1wt%.
Agren: Materials Science and Engineering A 452–453 (2007), p. 37-45 [2] Z.X Wang, A.X Yang, T Zang, D.Y He: Materials Engineering (2008), p. 56-59 [3] T Li, Q.F Li, J.Y.H.
Fuh: Materials Science and Engineering A 430 (2006), p. 113–119 [4] Bilge Yaman, Hasan Mandal: Materials Letters.
New carbide base materials for sparying.
Thermal spray 2003: Advancing the Science&Applying the Technology.
Agren: Materials Science and Engineering A 452–453 (2007), p. 37-45 [2] Z.X Wang, A.X Yang, T Zang, D.Y He: Materials Engineering (2008), p. 56-59 [3] T Li, Q.F Li, J.Y.H.
Fuh: Materials Science and Engineering A 430 (2006), p. 113–119 [4] Bilge Yaman, Hasan Mandal: Materials Letters.
New carbide base materials for sparying.
Thermal spray 2003: Advancing the Science&Applying the Technology.
Online since: March 2016
Authors: Miriam Kupková, Monika Hrubovčáková, Martin Kupka
What remains is to seek metallic materials which can do the job well.
Composition Porosity [%] CIP-based materials WAIP-based materials Fe 11.6 17.1 Fe-25Mn 20.9 28.4 Fe-30Mn 25.1 28.5 Fe-35Mn 25.5 31.9 Obtained sintered materials were inherently inhomogeneous, their properties varied significantly from point to point within a micro-length scale.
Morovská Turoňová, Sintering behaviour, graded microstructure and corrosion performance of sintered Fe-Mn biomaterials, International Journal of Electrochemical Science, 10 (2015) 9256-9268
Soboyejo, Mechanical Properties of Engineered Materials, Marcel Dekker, New York, 2003
Conference on Information Science, Machinery, Materials and Energy, Atlantis Press, Curran Associates, Inc, Chongquing, 2015, 1840-1850
Composition Porosity [%] CIP-based materials WAIP-based materials Fe 11.6 17.1 Fe-25Mn 20.9 28.4 Fe-30Mn 25.1 28.5 Fe-35Mn 25.5 31.9 Obtained sintered materials were inherently inhomogeneous, their properties varied significantly from point to point within a micro-length scale.
Morovská Turoňová, Sintering behaviour, graded microstructure and corrosion performance of sintered Fe-Mn biomaterials, International Journal of Electrochemical Science, 10 (2015) 9256-9268
Soboyejo, Mechanical Properties of Engineered Materials, Marcel Dekker, New York, 2003
Conference on Information Science, Machinery, Materials and Energy, Atlantis Press, Curran Associates, Inc, Chongquing, 2015, 1840-1850
Online since: September 2012
Authors: Jacques Desbrieres, Stephanie Reynaud, Pierre Marcasuzaa, Francis Ehrenfeld
Beppu, Evaluation of batch adsorption of chromium ions on natural and crosslinked chitosan membranes, Journal of Hazardous Materials 152 (2008) 1155-1163
[13] I.
Arvanitoyannis, Totally and partially biodegradable polymer blends based on natural and synthetic macromolecules: Preparation, physical properties, and potential as food packaging materials, Journal of Macromolecular Science – Reviews in macromolecular chemistry and Physics 39C (1999) 205-271 [14] C.
Adhikari, Polyaniline as a gas-sensor material, Materials and Manufacturing Processes 21 (2006) 263-270 [25] J.
Chen, Self-assembly of polyaniline-grafted chitosan/glucose oxidase nanolayered films for electrochemical biosensor applications, Journal of Materials Science 41 (2006) 4974-4977 [32] S.R.
Kim, Surprising shrinkage of expanding gels under an external load, Nature Materials 5 (2006) 48-51
Arvanitoyannis, Totally and partially biodegradable polymer blends based on natural and synthetic macromolecules: Preparation, physical properties, and potential as food packaging materials, Journal of Macromolecular Science – Reviews in macromolecular chemistry and Physics 39C (1999) 205-271 [14] C.
Adhikari, Polyaniline as a gas-sensor material, Materials and Manufacturing Processes 21 (2006) 263-270 [25] J.
Chen, Self-assembly of polyaniline-grafted chitosan/glucose oxidase nanolayered films for electrochemical biosensor applications, Journal of Materials Science 41 (2006) 4974-4977 [32] S.R.
Kim, Surprising shrinkage of expanding gels under an external load, Nature Materials 5 (2006) 48-51
Online since: June 2012
Authors: Ye Long Xiao, Ping Ping Yao, Hai Bing Zhou, Zong Xiang Jin
Experimental
Preparation of Materials.
Table 2 The mechanical performances of materials for space docking Materials Density (g/cm3) Porosity Apparent hardness Friction material 5.58 3.7% 58 HRF Counterpart material — — 37~42 HRC The Running-in Characteristics of Materials for Space Docking.
This process is defined as the running-in of materials.
Junkins: Journal of guidance, control, and dynamics Vol.29 No.4 (2006), p. 892
Deng: Advanced Materials Research No.284-286 (2011), p. 479
Table 2 The mechanical performances of materials for space docking Materials Density (g/cm3) Porosity Apparent hardness Friction material 5.58 3.7% 58 HRF Counterpart material — — 37~42 HRC The Running-in Characteristics of Materials for Space Docking.
This process is defined as the running-in of materials.
Junkins: Journal of guidance, control, and dynamics Vol.29 No.4 (2006), p. 892
Deng: Advanced Materials Research No.284-286 (2011), p. 479
Online since: June 2018
Authors: Tomasz Tański, Krzysztof Labisz
Tański2
1Department of Railway Transport, Faculty of Transport, Silesian University of Technology, Krasińskiego Str. 8, 40-019 Katowice, Poland
2Division of Materials Processing Technology, Management and Computer Techniques in Materials Science, Institute of Engineering Materials and Biomaterials, Silesian University of Technology, ul.
Klimpel, Structure and Properties of the 32CrMoV12-28 Steel alloyed with WC Powder using HPDL Laser, Materials Science Forum 530-531 (2006) 334-339
Collins, Review of the use of high power diode lasers in surface hardening, Journal of Materials Processing Tech 155-156 (2004) 1855-1860
Archives of Materials Science and Engineering 32 (2008) 5-12
Janicki, Effect of laser feeding on heat-treated light alloys, International Journal of Materials Research 108/2 (2017) 126-132 [17] G.
Klimpel, Structure and Properties of the 32CrMoV12-28 Steel alloyed with WC Powder using HPDL Laser, Materials Science Forum 530-531 (2006) 334-339
Collins, Review of the use of high power diode lasers in surface hardening, Journal of Materials Processing Tech 155-156 (2004) 1855-1860
Archives of Materials Science and Engineering 32 (2008) 5-12
Janicki, Effect of laser feeding on heat-treated light alloys, International Journal of Materials Research 108/2 (2017) 126-132 [17] G.
Online since: March 2018
Authors: Ali Esmaeili, Abdel Magid S. Hamouda
First of all, FSP may change material properties over the thickness and material behavior is the same as functionally graded materials [5-7].
A lot of researchers work on analyzing crack through the functionally graded materials analytically or semi-analytically [8-9].
In the case of the second tool, volume of the materials which undergoes severe plastic deformation increases drastically.
Science and Technology of Welding and Joining. 539-543 [5] S.
Mechanics of Advanced Materials and Structures, 1-14, 2017
A lot of researchers work on analyzing crack through the functionally graded materials analytically or semi-analytically [8-9].
In the case of the second tool, volume of the materials which undergoes severe plastic deformation increases drastically.
Science and Technology of Welding and Joining. 539-543 [5] S.
Mechanics of Advanced Materials and Structures, 1-14, 2017
Online since: July 2015
Authors: Martin Bednarik, Miroslav Manas, David Manas, Martin Ovsik, Michal Stanek, Pavel Stoklasek, Ales Mizera
The process of radiation crosslinking helps to improve some mechanical properties of polymer materials.
Pharr: Journal of Materials Research 19 (1), (2004), p. 1564 – 1583
Michalik: Archives of Materials Science and Engineering 36 (2), (2009), p. 89-95
Manas, : International Journal of Mathematics and Computers in Simulation [online] Issue 1, Volume 7, (2013), p. 9-16
Krzyzak, : Advanced Materials Research 1001, (2014) pp. 194-198.
Pharr: Journal of Materials Research 19 (1), (2004), p. 1564 – 1583
Michalik: Archives of Materials Science and Engineering 36 (2), (2009), p. 89-95
Manas, : International Journal of Mathematics and Computers in Simulation [online] Issue 1, Volume 7, (2013), p. 9-16
Krzyzak, : Advanced Materials Research 1001, (2014) pp. 194-198.
Online since: February 2012
Authors: Dong Sheng Chen, Ying Jin Gan, Xiao Hong Yuan, Yuan Jing Ye
Experimental procedures
Experimental materials and conditions.
Experimental materials: Lotus fiber, cotton fiber, and viscose fiber.
Progress in Textile Science & Technology. 6 (2006) 17-19.
Plant Fiber Sciences in China. 28 (2006) 249-253.
Journal of Cellulose Science and Technology. 17(2008)57-60.
Experimental materials: Lotus fiber, cotton fiber, and viscose fiber.
Progress in Textile Science & Technology. 6 (2006) 17-19.
Plant Fiber Sciences in China. 28 (2006) 249-253.
Journal of Cellulose Science and Technology. 17(2008)57-60.
Online since: February 2006
Authors: Michael I. Friswell, Paul D. Wilcox, M.R. Wisnom, Jonathan J. Scholey, C.K. Lee
As the use of composite materials in such
systems increases, so does the complexity of the damage modes present.
In this paper, practical issues of AE testing in wide composite materials are addressed.
For isotropic materials, dispersion curves are independent of angular direction, however this is not the case for anisotropic materials.
The propagation of elastic waves through plate materials differs from those in bulk materials.
This is expected, since the propagation of Lamb waves in isotropic materials is well understood.
In this paper, practical issues of AE testing in wide composite materials are addressed.
For isotropic materials, dispersion curves are independent of angular direction, however this is not the case for anisotropic materials.
The propagation of elastic waves through plate materials differs from those in bulk materials.
This is expected, since the propagation of Lamb waves in isotropic materials is well understood.