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Online since: November 2014
Authors: Tadeusz Łagoda, Ewelina Böhm, Marta Kurek
Introduction
THE FATIGUE OF MATERIALS HAS BEEN WIDELY DESCRIBED IN LITERATURE.
Table 1 presents chemical composition of chosen materials.
The basic mechanical properties of analyzed materials.
[2] Kurek M., Łagoda T., Katzy D.: Comparison of fatigue characteristics of some selected materials, Materials Testing (Materialprufung), Vol.56, No. 2, 2014, pp.92-95
[8] Böhm E., Kurek M., Junak G., Cieśla M., Łagoda T.: Accumulation of Fatigue Damage Using Memory of the Material, Procedia Materials Science, Vol. 3, pp. 2–7, 2014 [9] Junak G., Cieśla M., Low-cycle fatigue of P91 and P92 steels used in the Power engineering industry, Archives of Materiale Science and Engineering, Vol.48, 2011, pp.19-24
Table 1 presents chemical composition of chosen materials.
The basic mechanical properties of analyzed materials.
[2] Kurek M., Łagoda T., Katzy D.: Comparison of fatigue characteristics of some selected materials, Materials Testing (Materialprufung), Vol.56, No. 2, 2014, pp.92-95
[8] Böhm E., Kurek M., Junak G., Cieśla M., Łagoda T.: Accumulation of Fatigue Damage Using Memory of the Material, Procedia Materials Science, Vol. 3, pp. 2–7, 2014 [9] Junak G., Cieśla M., Low-cycle fatigue of P91 and P92 steels used in the Power engineering industry, Archives of Materiale Science and Engineering, Vol.48, 2011, pp.19-24
Online since: August 2013
Authors: Zheng Zhang, Xing Quan Liu, Wei Wang, Ling Zhao
The raw materials were mixed stoichiometrically in a planetary ball mill and ground at a speed of 400 r/m for 8 hours[8].
Delmas, Chemistry of Materials 2002, 15, 348-354
Julien, Journal of Power Sources 2013, 232, 357-369
Garche, Journal of Power Sources 2010, 195, 2419-2430
Tirado, Materials Science and Engineering: R: Reports 2003, 40, 103-136
Delmas, Chemistry of Materials 2002, 15, 348-354
Julien, Journal of Power Sources 2013, 232, 357-369
Garche, Journal of Power Sources 2010, 195, 2419-2430
Tirado, Materials Science and Engineering: R: Reports 2003, 40, 103-136
Online since: March 2013
Authors: Li Yun Yi, Shi Liang Wang
Exploration of goaf of colliery area with engineering materials in a highway tunnel
Shiliang Wang 1, a, Liyun Yi 2, b
1 Sichuan College of Architecture Technology, 618000 Deyang City, P.R.
Material application on the tunnel waterproof grouting Waterproof grouting materials used in underground construction mainly include neat cement grout, chemically true soluble grout and cement-soluble glass grout.
China Railway Science.
Environmental Earth Sciences.
SHANXI SCIENCE&TECHNOLOGY of COMMUNICATIONS.
Material application on the tunnel waterproof grouting Waterproof grouting materials used in underground construction mainly include neat cement grout, chemically true soluble grout and cement-soluble glass grout.
China Railway Science.
Environmental Earth Sciences.
SHANXI SCIENCE&TECHNOLOGY of COMMUNICATIONS.
Online since: August 2017
Authors: Jun Wang, Rong Guo Hou, Chuan Zhen Huang, Hong Tao Zhu, Huan Yang
As for the velocity, the maximum deformation and stress of solid materials are increased with an increase in the velocity, especially in the high speed range.
Acknowledgements The work is financially supported by National Natural Science Foundation of China (51375276 and 51405274) and Independent Innovation Science Foundation of Shandong University.
Journal of Engineering Materials and Technology, ASME.,1989, 111: 221-228 [2] Wang J.Particle velocity models for ultra high pressure abrasive waterjets.
Journal of Materials Processing Technology,2009(9): 2314—2320 [3] M.
A, Dynamic elastic-plastic analysis of 3-D deformation in abrasive water jet machining, Journal of Materials Process technology, 2001,113: 337-341
Acknowledgements The work is financially supported by National Natural Science Foundation of China (51375276 and 51405274) and Independent Innovation Science Foundation of Shandong University.
Journal of Engineering Materials and Technology, ASME.,1989, 111: 221-228 [2] Wang J.Particle velocity models for ultra high pressure abrasive waterjets.
Journal of Materials Processing Technology,2009(9): 2314—2320 [3] M.
A, Dynamic elastic-plastic analysis of 3-D deformation in abrasive water jet machining, Journal of Materials Process technology, 2001,113: 337-341
Online since: March 2012
Authors: Hamimah Abdul Rahman, Hasan Zuhudi Abdullah, Siti Alwani Binti Ab. Aziz, Shahrin Hisham Amirnordin, Hariati Taib
The application of electrophoretic deposition (EPD) technique for deposition of thick and thin film deposition has been extended not only on to electrically conducting materials but also to non-conducting material.
Introduction EPD processing method has been used for the processing and fabrication of a wide variety of advanced ceramic materials and because of the high versatility of use with different materials and their combinations as well as its cost-effectiveness [1] and its ability to produce films on substrate of complex shapes and large dimensions [2].
Liu : Progress in Material Science (2006) [8] F.
Lu and X.S Zhao: Nanoporous Material–Science and Engineering, Chapter 1, (2004) p.1 [20] R.
Haubelt: Journal of the European Ceramic Society 30 (2010) p. 1159 [23] Luque, Antonio, Hegedus and Steven: Handbook of Photovoltaic Science and Engineering (2nd Edition) (2011) [24] K.Yamaji, H.
Introduction EPD processing method has been used for the processing and fabrication of a wide variety of advanced ceramic materials and because of the high versatility of use with different materials and their combinations as well as its cost-effectiveness [1] and its ability to produce films on substrate of complex shapes and large dimensions [2].
Liu : Progress in Material Science (2006) [8] F.
Lu and X.S Zhao: Nanoporous Material–Science and Engineering, Chapter 1, (2004) p.1 [20] R.
Haubelt: Journal of the European Ceramic Society 30 (2010) p. 1159 [23] Luque, Antonio, Hegedus and Steven: Handbook of Photovoltaic Science and Engineering (2nd Edition) (2011) [24] K.Yamaji, H.
Online since: August 2012
Authors: Zeng Gang Li, Zeng Yong Chu, Yong Jiang Zhou, Hai Feng Cheng
Preparation of La1-xSrxMnO3 materials
by high temperature solid phase method
LI Zenggang, CHU Zengyong, ZHOU Yongjiang, CHENG Haifeng
National Key Laboratory of Science and Technology on Advanced Ceramic Fibers and Composites, National University of Defense Technology, Changsha 410073,China
wsnlzg@qq.com
Keywords: high temperature solid phase method; perovskite type structure; LSMO
Abstract.
Lofland and S.M.Bhagat: Journal of Applied Physics Vol. 83 (1998), p. 2866-2868 [2] J.
Wong: Journal of Applied Physics Vol. 79 (1996), p. 1910-1812 [3] Soma Das and T.
[10] Jiang S P: Journal of Power Sources Vol. 124(2003), p. 390-420 [11] LI Daguang, ZHANG Hongyi and ZHANG Hefeng: Materials Science Vol. 20(2006), p. 296-299 [12] ZHU Baojun, GONG Tao and TANG Yuanhong: Materials Science and Engineering of Powder Metallurgy Vol. 10(2005), p.264-267 [13] Hammouche A, Siebert E and Hammou A: Electrochem Soc Vol. 138(1991), p. 1212-1218 [14] Szabo V, Bassir M and Van Neste A: Environm Vol. 37(2002), p. 175 [15] Wang W and Jiang S P: Solid State Ionies Vol. 177(2006), p.1361-1369
[16] ZHU Baojun, GONG Tao and TANG Yuanhong: Materials Science and Engineering of Powder Metallargy Vol. 10(2005), p. 264-267 [17] LEI Liwen: Wuhan University of Technology Vol. 5(2006), p.7-11
Lofland and S.M.Bhagat: Journal of Applied Physics Vol. 83 (1998), p. 2866-2868 [2] J.
Wong: Journal of Applied Physics Vol. 79 (1996), p. 1910-1812 [3] Soma Das and T.
[10] Jiang S P: Journal of Power Sources Vol. 124(2003), p. 390-420 [11] LI Daguang, ZHANG Hongyi and ZHANG Hefeng: Materials Science Vol. 20(2006), p. 296-299 [12] ZHU Baojun, GONG Tao and TANG Yuanhong: Materials Science and Engineering of Powder Metallurgy Vol. 10(2005), p.264-267 [13] Hammouche A, Siebert E and Hammou A: Electrochem Soc Vol. 138(1991), p. 1212-1218 [14] Szabo V, Bassir M and Van Neste A: Environm Vol. 37(2002), p. 175 [15] Wang W and Jiang S P: Solid State Ionies Vol. 177(2006), p.1361-1369
[16] ZHU Baojun, GONG Tao and TANG Yuanhong: Materials Science and Engineering of Powder Metallargy Vol. 10(2005), p. 264-267 [17] LEI Liwen: Wuhan University of Technology Vol. 5(2006), p.7-11
Online since: March 2016
Authors: Ireneusz Dominik, Stanisław Flaga
Design and pre-implementation of micro-movements sensor with magnetic shape memory material
FLAGA Stanisław 1, a *, DOMINIK Ireneusz1,b
1AGH University of Science and Technology, Building B2, Al.
During the last twenty years the rapid development in smart materials, which are also known as active materials, is observed.
The smart materials are sensitive to the changes of physical quantities such as light intensity, temperature, current intensity, electric and magnetic field which as a result change material properties.
Among smart materials which can undergo shape transformation, temperature-controlled shape memory alloys (SMA) [1,2,3,4], electrically-controlled piezoelectric materials [5], magnetic field controlled magnetostrictive materials and magnetic shape memory alloy (MSMA or FSMA) can be found.
[7] Ullakko K., Magnetically Controlled Shape Memory Alloys: A New Class of Actuator Materials, Journal of Material Engineering and Performance, Vol. 5/1996 [8] Flaga S., Kata D. and Sapiński B., Microstructure evaluation of Ni-Mn-Ga alloy, Mechanics and Control, no. 1/2010, AGH University of Science and Technology, Krakow
During the last twenty years the rapid development in smart materials, which are also known as active materials, is observed.
The smart materials are sensitive to the changes of physical quantities such as light intensity, temperature, current intensity, electric and magnetic field which as a result change material properties.
Among smart materials which can undergo shape transformation, temperature-controlled shape memory alloys (SMA) [1,2,3,4], electrically-controlled piezoelectric materials [5], magnetic field controlled magnetostrictive materials and magnetic shape memory alloy (MSMA or FSMA) can be found.
[7] Ullakko K., Magnetically Controlled Shape Memory Alloys: A New Class of Actuator Materials, Journal of Material Engineering and Performance, Vol. 5/1996 [8] Flaga S., Kata D. and Sapiński B., Microstructure evaluation of Ni-Mn-Ga alloy, Mechanics and Control, no. 1/2010, AGH University of Science and Technology, Krakow
Online since: October 2014
Authors: Yan Song Zhang, Ang Ding, Jing Hui Huang, Kun Ming Qian, Song Ji, Jie Hao, Chun Yang Qian, Zu Jun Zhang
Phase component materials
No
Comp.
Materials Science ang Engineering 1995, B3: 4204-4209
Materials Science and Technology. 1992. 3
Materials Science and Technology. 2013, 29(11): 1324-1327
Advanced Materials Research. 2013, 716: 276-280
Materials Science ang Engineering 1995, B3: 4204-4209
Materials Science and Technology. 1992. 3
Materials Science and Technology. 2013, 29(11): 1324-1327
Advanced Materials Research. 2013, 716: 276-280
Online since: March 2017
Authors: Krzysztof Jan Kurzydlowski, Tomasz Wejrzanowski, Jarosław Milewski, Karol Cwieka
This can only be achieved by defining the relationships between structure and properties of materials for MCFC.
Materials and methods Preparation of a slurry is the first and the most important stage in the process of MCFC materials fabrication.
Kurzydlowski, Structure of foams modeled by Laguerre-Voronoi tesselations, Computational Materials Science Vol. 67 (2013), p. 216-221
Redenbach, Microstructure models for cellular materials, Computational Materials Science Vol. 44 (2009), p. 1397-1407
Kurzydlowski, Image based analysis of complex microstructures of engineering materials, International Journal of Applied Mathematics and Computer Science, Vol. 18, No. 1 (2008), p. 33-39
Materials and methods Preparation of a slurry is the first and the most important stage in the process of MCFC materials fabrication.
Kurzydlowski, Structure of foams modeled by Laguerre-Voronoi tesselations, Computational Materials Science Vol. 67 (2013), p. 216-221
Redenbach, Microstructure models for cellular materials, Computational Materials Science Vol. 44 (2009), p. 1397-1407
Kurzydlowski, Image based analysis of complex microstructures of engineering materials, International Journal of Applied Mathematics and Computer Science, Vol. 18, No. 1 (2008), p. 33-39
Online since: July 2015
Authors: Gerhard Hirt, Markus Bambach, Johannes Lohmar, Alexander Kraemer
Accurate simulations are achieved by materials characterization in extensive laboratory test and subsequent fitting, i.e. by determining all free parameters of the material models used in process modelling [3,4,5].
Pietrzyk, Through-process modelling of microstructure evolution in hot forming of steels, Journal of Materials Processing Technology 125-126, 2002, pp. 53-62
Kasiviswanathan, Constitutive equations to predict high temperature flow stress in a Ti-modified austenitic steel, Materials Science and Engineering A 500, 2009, pp. 114-121 [9] S.
Karhausen, Identification of Parameters in Physically Based Material Models, Steel research Journal, 2012, pp. 955-958 [10] L.P.
Karjalainen, Stress relaxation method for investigations of softening kinetics in hot deformed steels, Materials Science and Technology Vol. 11, 1995, pp. 557-565 [11] G.
Pietrzyk, Through-process modelling of microstructure evolution in hot forming of steels, Journal of Materials Processing Technology 125-126, 2002, pp. 53-62
Kasiviswanathan, Constitutive equations to predict high temperature flow stress in a Ti-modified austenitic steel, Materials Science and Engineering A 500, 2009, pp. 114-121 [9] S.
Karhausen, Identification of Parameters in Physically Based Material Models, Steel research Journal, 2012, pp. 955-958 [10] L.P.
Karjalainen, Stress relaxation method for investigations of softening kinetics in hot deformed steels, Materials Science and Technology Vol. 11, 1995, pp. 557-565 [11] G.