Sort by:
Publication Type:
Open access:
Publication Date:
Periodicals:
Search results
Online since: October 2023
Authors: Jorge Salguero Gómez, Juan Manuel Vazquez Martinez, Rafael Bienvenido, Fermín Bañón-García
However, it may become an important technological challenge for the manufacturing and joining of these materials.
An operation of great interest for these materials is drilling.
Introduction Within the different ranges of materials used in industry. composite materials and especially those combining a polymeric matrix with a reinforcement have been widely used in industry in recent years.
Wottschel, Recent Developments for Laser Beam Joining of CFRP-aluminum Structures, Procedia Materials Science. 2 (2013) 250–258. https://doi.org/10.1016/j.mspro.2013.02.031
Fu, Experimental Research on Temperature of Drilling CFRP with Brazed Diamond Core Drill, Materials Science Forum. 800–801 (2014) 776–781. https://doi.org/10.4028/www.scientific.net/MSF.800-801.776
An operation of great interest for these materials is drilling.
Introduction Within the different ranges of materials used in industry. composite materials and especially those combining a polymeric matrix with a reinforcement have been widely used in industry in recent years.
Wottschel, Recent Developments for Laser Beam Joining of CFRP-aluminum Structures, Procedia Materials Science. 2 (2013) 250–258. https://doi.org/10.1016/j.mspro.2013.02.031
Fu, Experimental Research on Temperature of Drilling CFRP with Brazed Diamond Core Drill, Materials Science Forum. 800–801 (2014) 776–781. https://doi.org/10.4028/www.scientific.net/MSF.800-801.776
Online since: June 2012
Authors: Wei Chen, Jie Li, Yu Zhu Zhang, Hong Wei Xing, Yue Long, Gao Liang Li, Jin Hu Wu, Jian Fei Wu
(Natural Science Edition),2005, 4(37):450-454
Journal of Chemical Engineering of Chinese Universities, 2007, (1): 60-63
Journal of China University of Mining&Technology, 2000, 29(2):136-139
Chemical Engineering Science, 2002, 57(14): 2635-2640
Chemical Engineering Science, 2004, 59(2): 437- 447.
Journal of Chemical Engineering of Chinese Universities, 2007, (1): 60-63
Journal of China University of Mining&Technology, 2000, 29(2):136-139
Chemical Engineering Science, 2002, 57(14): 2635-2640
Chemical Engineering Science, 2004, 59(2): 437- 447.
Online since: May 2011
Authors: Ting Lei, Song Gu, Jun Lin Tao, Jian Jun Xie, Wen Jun Hu
So recycled concrete accord with the tide of development and has a broad development prospect as a new green material [1~4].
Experimental Design Experimental Materials Coarse Aggregate: Recycled coarse aggregate is from the waste concrete of basketball court at the Southwest University of Science and Technology and the natural coarse aggregate is from ordinary gravels, all of this is crushed by crusher and obtain continuous grading from 5mm to 20mm by artificially screening.
References [1] Liu Shuhua, Leng Faguang:Recycled Concrete Technology.Beijing(China building material industry press.
[2] China building materials science research institute:Green Building Materials and Building Materials Greenization(Chemical industry press.
[7] Lees JM, Winistorfer AU, MeierU: Journal of Composites for Construction, Vol.6(2002) , p.249-256 [8] Zhang Jiwen, Lu Zhitao, Teng Jinguang: Journal of Building Structures, Vol.22(2001) , p. 42-48,in Chinese
Experimental Design Experimental Materials Coarse Aggregate: Recycled coarse aggregate is from the waste concrete of basketball court at the Southwest University of Science and Technology and the natural coarse aggregate is from ordinary gravels, all of this is crushed by crusher and obtain continuous grading from 5mm to 20mm by artificially screening.
References [1] Liu Shuhua, Leng Faguang:Recycled Concrete Technology.Beijing(China building material industry press.
[2] China building materials science research institute:Green Building Materials and Building Materials Greenization(Chemical industry press.
[7] Lees JM, Winistorfer AU, MeierU: Journal of Composites for Construction, Vol.6(2002) , p.249-256 [8] Zhang Jiwen, Lu Zhitao, Teng Jinguang: Journal of Building Structures, Vol.22(2001) , p. 42-48,in Chinese
Online since: July 2012
Authors: Li Zhen Ma, Bao Hua Kong, Pei Jun Li, Xin Li, Yuan Tao
Andersen, Journal of Meat Science, 89,111 (2011)
Bertram, Journal of Meat Science, 72, 34 (2006)
Andersen, Journal of Meat Science, 66, 301 (2004)
Karlsson, Journal of Meat Science, 66, 437 (2004)
Aaslyng, Journal of Meat Science, 77, 190 (2007)
Bertram, Journal of Meat Science, 72, 34 (2006)
Andersen, Journal of Meat Science, 66, 301 (2004)
Karlsson, Journal of Meat Science, 66, 437 (2004)
Aaslyng, Journal of Meat Science, 77, 190 (2007)
Online since: July 2014
Authors: Gao Feng Wei, Yan Xu, Hai Yan Chen
Journal of composite Materials, 1989, 23(9): 890-911
Journal of composite Materials, 1995, 26(6): 785-819
Journal of Material Science, 1982, 17: 3211-3220
Journal of composite Materials, 1986, 20(9): 472-484
The structure of knitting yarn braided perform, Journal of composite Materials. 2000, 17(3): 1-5
Journal of composite Materials, 1995, 26(6): 785-819
Journal of Material Science, 1982, 17: 3211-3220
Journal of composite Materials, 1986, 20(9): 472-484
The structure of knitting yarn braided perform, Journal of composite Materials. 2000, 17(3): 1-5
Online since: November 2020
Authors: Vitalii Kapitan, Konstantin Nefedev, Konstantin Nefedev, Yuriy Shevchenko, Dmitrii Kapitan, Alexey Rybin, Alexander Perzhu, Roman Volotovskiy, Konstantin Soldatov, Alexander Makarov, Vladislav Strongin, Alena Korol, Egor V. Vasiliev
The search
ing of magnetic systems and materials in which skyrmions exist in a wider range of internal factors
and external influences is one of the urgent tasks in the study of magnetic materials and topological
phenomena in them.
Thomas, Magnetic domainwall racetrack memory, Science 320 (5873) (2008) 190-194
Dyachenko, Concentration of magnetic transitions in dilute magnetic materials, Journal of Physics: Conference Series 490 (1) (2014) 012165
Piskunova, Influence of anisotropy on magnetoresistance in magnetic multilayer structures, Journal of Magnetism and Magnetic Materials 482 (2019) 201-205
Vasiliev, Thermodynamic properties of heisenberg spin systems, in: Key Engineering Materials, Vol. 806, 2019, pp. 142-154
Thomas, Magnetic domainwall racetrack memory, Science 320 (5873) (2008) 190-194
Dyachenko, Concentration of magnetic transitions in dilute magnetic materials, Journal of Physics: Conference Series 490 (1) (2014) 012165
Piskunova, Influence of anisotropy on magnetoresistance in magnetic multilayer structures, Journal of Magnetism and Magnetic Materials 482 (2019) 201-205
Vasiliev, Thermodynamic properties of heisenberg spin systems, in: Key Engineering Materials, Vol. 806, 2019, pp. 142-154
Online since: February 2011
Authors: Zhao Qun Du, Tian Xian Zhou, Gang Zheng, Weidong Yu
In-situ Complex Testing of Fabrics Stiffness and Properties by A Senor
DU ZhaoQun1, a, ZHOU TianXian1, Gang ZHENG1 and YU WeiDong2,1
1 Key Laboratory of Textile Science & Technology, Ministry of Education, College of Textiles, Donghua University, Shanghai 201620, China
2 College of Clothing and Art Design, Jiaxing University, Jiaxing, Zhejiang 314001, China
aduzq@dhu.edu.cn
Keywords: Testing; In-situ complex; Force sensor; Fabrics; Stiffness.
The multiple properties through single test in principle is up-to-date technology of measurement science, which is an assembled measuring technology in-situ and measure multiple functions on the same part of a sample.
(6) By measuringand, the bending rigidity of a fabric or a yarn can be obtained through the Eq.6. 2 Materials and Methods 19 fabrics with warp×weft length by 15 cm×2 cm were selected and their specifications were listed in Table 1.
References [1] Kawabata S, in: The Standardization and Analysis of Hand Evaluation [M], 2nd ed., Osaka Japan, The Textile Machinery Society of Japan, 1980: 9-88 [2] Ly N.G, Tester, D.H and Buckenham P, in: Simple Instruments for Quality Control by Finishers and Tailors, Textile Research Journal, 1991, 61: 402-406 [3] Pan N and Yen K.C, in:Physical Interpretations of Curves Obtained Through The Fabric Extraction Process for Handle Measurement, Textile Research Journal, 1992, 62: 279-290 [4] Wang G, Postle R and Zhang W, in: The Tailorability of Lightweight Wool and Wool-blended Fabrics, Journal of the Textile Institute, 2003, 94: 212-222 [5] Strazdiene E, Martisiute G and Gutauska M, in: Textile Hand A New Method for Textile Objective Evaluation, Journal of the Textile Institute, 2003, 94: 245-255 [6] Du Z.Q and Yu W.D, in: A Comprehensive Handle Evaluation System for Fabrics: I.
Measurement and Characterization of Mass and Bending Properties, Measurement Science and Technology, 2007, 18: 3547-3554
The multiple properties through single test in principle is up-to-date technology of measurement science, which is an assembled measuring technology in-situ and measure multiple functions on the same part of a sample.
(6) By measuringand, the bending rigidity of a fabric or a yarn can be obtained through the Eq.6. 2 Materials and Methods 19 fabrics with warp×weft length by 15 cm×2 cm were selected and their specifications were listed in Table 1.
References [1] Kawabata S, in: The Standardization and Analysis of Hand Evaluation [M], 2nd ed., Osaka Japan, The Textile Machinery Society of Japan, 1980: 9-88 [2] Ly N.G, Tester, D.H and Buckenham P, in: Simple Instruments for Quality Control by Finishers and Tailors, Textile Research Journal, 1991, 61: 402-406 [3] Pan N and Yen K.C, in:Physical Interpretations of Curves Obtained Through The Fabric Extraction Process for Handle Measurement, Textile Research Journal, 1992, 62: 279-290 [4] Wang G, Postle R and Zhang W, in: The Tailorability of Lightweight Wool and Wool-blended Fabrics, Journal of the Textile Institute, 2003, 94: 212-222 [5] Strazdiene E, Martisiute G and Gutauska M, in: Textile Hand A New Method for Textile Objective Evaluation, Journal of the Textile Institute, 2003, 94: 245-255 [6] Du Z.Q and Yu W.D, in: A Comprehensive Handle Evaluation System for Fabrics: I.
Measurement and Characterization of Mass and Bending Properties, Measurement Science and Technology, 2007, 18: 3547-3554
Online since: February 2011
Authors: Zhen Xing Zheng, Cheng Qiu, Zhao Yao Zhou, Wei Xia
Materials Science and Engineering A, 1998, 258(1-2): 249-257
[2] Tetsuya Hirohata, Saiji Masaki, Susumu Shima.
Journal of Materials Processing Technology 2001,111: 113-117 [3] Guigon P,Simon O.Powder Technology,2003,130 (1):41-48
International Journal of Mechanical Sciences. 2005,47: 94-109 [6] K.T.
Material Science and Engineering. 2003, 130(1) :41-48
Journal of Mechanical and Sciences. 2002, 44: 1295-1308 [8] Roman.
Journal of Materials Processing Technology 2001,111: 113-117 [3] Guigon P,Simon O.Powder Technology,2003,130 (1):41-48
International Journal of Mechanical Sciences. 2005,47: 94-109 [6] K.T.
Material Science and Engineering. 2003, 130(1) :41-48
Journal of Mechanical and Sciences. 2002, 44: 1295-1308 [8] Roman.
Online since: May 2017
Authors: Jantip Setthayanond, Potjanart Suwanruji, Supakit Achiwawanich, Thipchanok Bowornhathai, Sutasinee Kityakarn
SEM images illustrated highly ordered macroporous structure which was a characteristic for 3DOM materials.
These properties make 3DOM materials a great candidate as photodegradation catalytic application. [1] TiO2 is considered to be an important material for photocatalyst because due to its chemical stability, nontoxic, low cost and low band gap energy.
Results and Discussion Characterization of 3DOM TiO2 Materials.
Achiwawanich: Advanced Materials Research Vol. 634-638 (2013), p.620-623
Wang: Journal of Porous Material Vol. 21 (2014), p. 939-945
These properties make 3DOM materials a great candidate as photodegradation catalytic application. [1] TiO2 is considered to be an important material for photocatalyst because due to its chemical stability, nontoxic, low cost and low band gap energy.
Results and Discussion Characterization of 3DOM TiO2 Materials.
Achiwawanich: Advanced Materials Research Vol. 634-638 (2013), p.620-623
Wang: Journal of Porous Material Vol. 21 (2014), p. 939-945
Online since: February 2014
Authors: He Li Ma, Ren Chen, Jia Meng Guo, Lei Yi, Ke Wu Peng
Experimental
Experiment Materials.
The CeO2 raw materials are offered by Baotou Steel Rare-Earth Hi-Tech Co.
The grain size of CeO2 is 10μm, and the purity of the CeO2 raw materials is 99.9wt%.
Materials Review,1994,(4):69~72 [2] Thevenot F.
Journal of Material Science Letter, 2002, 21: 703~706
The CeO2 raw materials are offered by Baotou Steel Rare-Earth Hi-Tech Co.
The grain size of CeO2 is 10μm, and the purity of the CeO2 raw materials is 99.9wt%.
Materials Review,1994,(4):69~72 [2] Thevenot F.
Journal of Material Science Letter, 2002, 21: 703~706