Sort by:
Publication Type:
Open access:
Publication Date:
Periodicals:
Search results
Online since: February 2011
Authors: Alexander Gorin, Moola Mohan Reddy, Khaled A. Abou El Hossein
Abou-El-Hossein2,c
1Mechanical Engineering Department, Curtin University of Technology (Malaysia Campus), CDT 250, Miri, Sarawak, 98009, Malaysia,
2Mechanical & Aeronautical Department of Mechatronics Engineering, Nelson Mandela Metropolitan University, Port Elezebeth, 6031, South Africa.
[2] Malkin S.Ritter JE, Grinding mechanisms and strength degration for ceramics ASME, Journal of engineering for Industry 1989; 111:2111-18
[3] Malkin S.Ritter JE, Grinding mechanisms and strength degration for ceramics ASME, Journal of engineering for Industry 1989; 111:2111-18
[7] Hwang.H, Liu.Y.C, Experimental investigation of machining characteristics and removal mechanisms of advanced ceramics in high speed grinding, International Journal of Machine Tools and Manufacture 43, 2003, 811-823
[9] Rajurkar.K.P, Wang.Z.Y, Kuppattan.A, Micro removal of ceramic material (AL2O3) in the precision ultrasonic machining, Precision Engineering 23, 1999, 73-78
[2] Malkin S.Ritter JE, Grinding mechanisms and strength degration for ceramics ASME, Journal of engineering for Industry 1989; 111:2111-18
[3] Malkin S.Ritter JE, Grinding mechanisms and strength degration for ceramics ASME, Journal of engineering for Industry 1989; 111:2111-18
[7] Hwang.H, Liu.Y.C, Experimental investigation of machining characteristics and removal mechanisms of advanced ceramics in high speed grinding, International Journal of Machine Tools and Manufacture 43, 2003, 811-823
[9] Rajurkar.K.P, Wang.Z.Y, Kuppattan.A, Micro removal of ceramic material (AL2O3) in the precision ultrasonic machining, Precision Engineering 23, 1999, 73-78
Online since: October 2014
Authors: Alberto Ortona, Ehsan Rezaei
Advanced Engineering Materials, 2012. 14(12): p. 1074-1081
Proceedings of the Asme International Mechanical Engineering Congress and Exposition (Imece 2010), Vol 9, 2012: p. 575-579
International Journal of Solids and Structures, 2008. 45(6): p. 1754-1765
Advances in Bioceramics and Porous Ceramics III: Ceramic Engineering and Science Proceedings, Volume 31, 2010: p. 93-104
Advanced Engineering Materials, 2012: p. n/a-n/a
Proceedings of the Asme International Mechanical Engineering Congress and Exposition (Imece 2010), Vol 9, 2012: p. 575-579
International Journal of Solids and Structures, 2008. 45(6): p. 1754-1765
Advances in Bioceramics and Porous Ceramics III: Ceramic Engineering and Science Proceedings, Volume 31, 2010: p. 93-104
Advanced Engineering Materials, 2012: p. n/a-n/a
Structural Analysis and Dielectric Properties of Oxygen Non-Stoichiometry 5% Fe-Doped BaTiO3 Ceramic
Online since: September 2022
Authors: Mohd Sobri Idris, Rozana Aina Maulat Osman, Domingo Arturo Ruiz León, Nur Izzati Muhammad Nadzri, Ku Noor Dhaniah Ku Muhsen
The Structural Analysis and Dielectric Properties of Oxygen
Non-Stoichiometry 5% Fe-Doped BaTiO3 Ceramic
Ku Noor Dhaniah KU MUHSEN1,2,a, Rozana Aina MAULAT OSMAN1,2,b*, Mohd Sobri IDRIS2,3,c, Nur Izzati MUHAMMAD NADZRI2,3,d
and RUIZ León Domingo Arturo4,e
1Faculty of Electronic Engineering Technology, Universiti Malaysia Perlis, 02600 Arau, Perlis, Malaysia
2Materials Engineering Programme, Faculty of Chemical Engineering Technology, Universiti Malaysia Perlis, 02600 Arau, Perlis, Malaysia
3Center of Excellence Frontier Materials Research, Universiti Malaysia Perlis, 01000 Kangar, Perlis, Malaysia
4Chemistry Materials Department, Universidad de Santiago de Chile, Av.
Ceramics International, 41(6), 7713-7722
Ceramics International, 47(9), 13107-13117
Ceramics International, 42(7), 8010-8016
International Journal of Applied Ceramic Technology, 10, E122-E133
Ceramics International, 41(6), 7713-7722
Ceramics International, 47(9), 13107-13117
Ceramics International, 42(7), 8010-8016
International Journal of Applied Ceramic Technology, 10, E122-E133
Online since: September 2015
Authors: Luboš Náhlík, Pavel Hutař, Kateřina Štegnerová
Martin: International Journal of Fracture, Vol. 179 (2013), pp. 157-167
Danzer: Engineering Fracture Mechanics, Vol. 77 (2010), pp. 2126-2135
Lube: Key Engineering Materials, Vol. 290 (2005), pp. 191-198
Sih: International Journal of Fracture, Vol. 10 (1974), pp. 305-321
Bermejo: Engineering Fracture Mechanics, Vol. 77 (2010) p. 2192
Danzer: Engineering Fracture Mechanics, Vol. 77 (2010), pp. 2126-2135
Lube: Key Engineering Materials, Vol. 290 (2005), pp. 191-198
Sih: International Journal of Fracture, Vol. 10 (1974), pp. 305-321
Bermejo: Engineering Fracture Mechanics, Vol. 77 (2010) p. 2192
Online since: April 2012
Authors: Lei Shi, Da Zhi Jin, Guo Liang Zhang
Residual Stresses Distributions within Thin-walled Ceramic-Metal Seal
Guoliang Zhang a, Lei Shi b and Dazhi Jin c
Institute of Electronic Engineering, China Academy of Engineering Physics, Mianyang 621900, China
a zhglkx123@163.com, b 513shi@163.com, c Jindazhi@sohu.com
Keywords: Thin-walled ceramic-metal seal, Thermal expansion, Residual stresses distributions, FEM simulation, X-ray diffractometer.
Joviano: International Journal of Solids and Structures Vol. 47 (2010), p. 3131-3140
Xu: Journal of Materials Processing Technology Vol. 129 (2002), p. 446-450
Lii et al: Journal of Alloys and Compounds Vol. 470 (2009), p. 117-122
Takashi: International Journal of Solids and Structures Vol. 37 (2000), p. 4737-4762.
Joviano: International Journal of Solids and Structures Vol. 47 (2010), p. 3131-3140
Xu: Journal of Materials Processing Technology Vol. 129 (2002), p. 446-450
Lii et al: Journal of Alloys and Compounds Vol. 470 (2009), p. 117-122
Takashi: International Journal of Solids and Structures Vol. 37 (2000), p. 4737-4762.
Online since: May 2021
Authors: Igor V. Bessonov, Alexey D. Zhukov, I.I. Popov, S.P. Chernukhin
The thermal conductivity of classical ceramic products does not allow the manufacture of structures with thermal resistance required by modern heat engineering standards.
Therefore, the main direction in the development of technologies for ceramic wall materials has become the optimization of their heat engineering metrics.
The thermal resistance of such structure along the smooth surface of the wall is at least 2.8 m2°C/W with thermal engineering uniformity of at least 0.98 (due to the presence of masonry joints).
Nikbakht, Incorporation of waste materials in the manufacture of masonry, Journal of Building Engineering. 21 (2019) 37-54.
Drossou, Fired ceramics 100% from lignite fly ash waste glass cullet mixtures, Journal of Building Engineering. 14 (2017) 1–6.
Therefore, the main direction in the development of technologies for ceramic wall materials has become the optimization of their heat engineering metrics.
The thermal resistance of such structure along the smooth surface of the wall is at least 2.8 m2°C/W with thermal engineering uniformity of at least 0.98 (due to the presence of masonry joints).
Nikbakht, Incorporation of waste materials in the manufacture of masonry, Journal of Building Engineering. 21 (2019) 37-54.
Drossou, Fired ceramics 100% from lignite fly ash waste glass cullet mixtures, Journal of Building Engineering. 14 (2017) 1–6.
Online since: January 2017
Authors: Shi Hua Liu, Qing Dan Yuan, Peng Chen, Dan Hua Xu
Ceramics international, 1995, 21(3): 187-193
Ceramics International, 2002, 28(2): 123-130
Properties of Silica Ceramic Made from Amorphous Silica[C]//Key Engineering Materials. 2010, 434: 838-839
Materials Science and Engineering, 1975, 20: 83-88
Ceramics international, 1992, 18(1): 65-68
Ceramics International, 2002, 28(2): 123-130
Properties of Silica Ceramic Made from Amorphous Silica[C]//Key Engineering Materials. 2010, 434: 838-839
Materials Science and Engineering, 1975, 20: 83-88
Ceramics international, 1992, 18(1): 65-68
Online since: February 2022
Authors: Galina Voronkova, Sergey Rekunov, Oleg Dushko
Rekunov, Proceedings of the 4th International Conference on Industrial Engineering (ICIE 2018) Cham (Switzerland): Springer.
Chen, Indentation induced lateral crack in ceramics with surface hardening, Materials Science and Engineering.
Haber, Grain boundary engineering of silicon carbide by means of coprecipitation, Ceramic Engineering and Science Proceedings. 29 6, (2009) 141-152 [8] R.
Solodovnikov, Estimation of operational properties of lubricant coolant liquids by optical methods, International Journal of Applied Engineering Research. 12 19, (2017) 8380-8391 [10] M.
Slavin, International Conference on Industrial Engineering (ICIE 2017) Procedia Engineering 206, (2017) 228–231 [13] J.
Chen, Indentation induced lateral crack in ceramics with surface hardening, Materials Science and Engineering.
Haber, Grain boundary engineering of silicon carbide by means of coprecipitation, Ceramic Engineering and Science Proceedings. 29 6, (2009) 141-152 [8] R.
Solodovnikov, Estimation of operational properties of lubricant coolant liquids by optical methods, International Journal of Applied Engineering Research. 12 19, (2017) 8380-8391 [10] M.
Slavin, International Conference on Industrial Engineering (ICIE 2017) Procedia Engineering 206, (2017) 228–231 [13] J.
Online since: August 2011
Authors: Khaled A. Abou-El-Hossein, Alexander Gorin, Moola Mohan Reddy
Materials Science and Engineering A 496, 2008: 269-272.
3.
ELID grinding characteristics and surface modifying effects of aluminum nitride (AlN) ceramic, International Journal of Machine Tools & Manufacture 45 2005: 891-896. 4.
Liao, Surface/subsurface damage and the fracture strength of ground ceramics, Journal of Materials Processing Technology 57, 1996, 207–220. 7.
Part 1: analytical cutting force model, International Journal of Machine tools & Manufacture 40(2000) 2155-2173. 21.
Chee Keong Ng,Shreyes Melkote.NW.Y, Rahman.M, Senthil Kumar, Experimental study of micro-and nano-scale cutting of aluminum 7075-T6, International Journal of Machine tools & Manufacture 46(2006) 929-936. 22.
ELID grinding characteristics and surface modifying effects of aluminum nitride (AlN) ceramic, International Journal of Machine Tools & Manufacture 45 2005: 891-896. 4.
Liao, Surface/subsurface damage and the fracture strength of ground ceramics, Journal of Materials Processing Technology 57, 1996, 207–220. 7.
Part 1: analytical cutting force model, International Journal of Machine tools & Manufacture 40(2000) 2155-2173. 21.
Chee Keong Ng,Shreyes Melkote.NW.Y, Rahman.M, Senthil Kumar, Experimental study of micro-and nano-scale cutting of aluminum 7075-T6, International Journal of Machine tools & Manufacture 46(2006) 929-936. 22.
Online since: June 2011
Authors: Khaled A. Abou-El-Hossein, Alexander Gorin, Moola Mohan Reddy
[2] Malkin S.Ritter JE, Grinding mechanisms and strength degration for ceramics ASME, Journal of engineering for Industry 1989; 111:2111-18
[8] Hwang.H, Yin.L, High speed grinding performance and material removal mechanism of silicon nitride, Yokohama, Japan, 18-20 July, proceedings of 10th International conference on precision engineering, 2001, 416-420
[9] Hwang.H, Liu.Y.C, Experimental investigation of machining characteristics and removal mechanisms of advanced ceramics in high speed grinding, International Journal of Machine Tools and Manufacture 43, 2003, 811-823
[11] Daudin.B, Martin.PN, Mega-electronvolt ion beam polishing of anodically grown alumina, Materials Science and Engineering, 1989; A:63-6
[13] Rajurkar.K.P, Wang.Z.Y, Kuppattan.A, Micro removal of ceramic material (AL2O3) in the precision ultrasonic machining, Precision Engineering 23, 1999, 73-78
[8] Hwang.H, Yin.L, High speed grinding performance and material removal mechanism of silicon nitride, Yokohama, Japan, 18-20 July, proceedings of 10th International conference on precision engineering, 2001, 416-420
[9] Hwang.H, Liu.Y.C, Experimental investigation of machining characteristics and removal mechanisms of advanced ceramics in high speed grinding, International Journal of Machine Tools and Manufacture 43, 2003, 811-823
[11] Daudin.B, Martin.PN, Mega-electronvolt ion beam polishing of anodically grown alumina, Materials Science and Engineering, 1989; A:63-6
[13] Rajurkar.K.P, Wang.Z.Y, Kuppattan.A, Micro removal of ceramic material (AL2O3) in the precision ultrasonic machining, Precision Engineering 23, 1999, 73-78