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Online since: July 2016
Authors: Bao Yan Chai, Shen Qi, Long Zhang, Xiao Jian Mao
Corbin, Journal of the European Ceramic Society, 1989. 5(3): p. 143-154
International Society for Optics and Photonics
Chen, Journal of the European Ceramic Society, 2015. 35(1): p. 23-28
Sun, Journal of the American Ceramic Society, 2012. 95(9): p. 2801-2807
Chu. in Ceramic Engineering and Science Proceedings. 2009
International Society for Optics and Photonics
Chen, Journal of the European Ceramic Society, 2015. 35(1): p. 23-28
Sun, Journal of the American Ceramic Society, 2012. 95(9): p. 2801-2807
Chu. in Ceramic Engineering and Science Proceedings. 2009
Online since: November 2012
Authors: David Gethin, Zawati Harun, Nazri Mohd Nawi, Mohd Faizal Batcha
Modeling of Layering Ceramic Shell Mould
Zawati Harun1, a, Nazri Mohd Nawi1, Mohd Faizal Batcha1andDavid Gethin2,b
1Faculty of Mechanical Engineering and Manufacturing
Universiti Tun Hussein Onn Malaysia (UTHM), Johor, Malaysia.
2C ivil and Computational Engineering Centre, University of Wales, Singleton Park, Swansea.
[3] Scherer, G.W., 1990, Theory of Drying, Journal America Ceramic Society, v. 73, p. 3-14
[7] Zawati Harun, D.T.Gethin, Drying Simulation of Ceramic Shell Build up Process, Second Asia International Conference on Modelling and Simulation (AMS 2008), 13-15 May 2008, Kuala Lumpur
International Journal heat Mass Transfer, 1988. 31(5): p. 957-967
[12] Zawati Harun David Gethin, Drying (Consolidation) Porous Ceramic by Considering the Microscopic Pore Temperature Gradient, Applied Mechanics and Materials, Vol. 147,2012, p 210-214, [13] Z.Harun, Gethin, D.T., Lewis, R.W., Combined Heat and Mass Transfer for Drying Ceramic(shell) Body, The International Journal of Multiphysics, Vol 2(1), 2008, p. 1-19.
[3] Scherer, G.W., 1990, Theory of Drying, Journal America Ceramic Society, v. 73, p. 3-14
[7] Zawati Harun, D.T.Gethin, Drying Simulation of Ceramic Shell Build up Process, Second Asia International Conference on Modelling and Simulation (AMS 2008), 13-15 May 2008, Kuala Lumpur
International Journal heat Mass Transfer, 1988. 31(5): p. 957-967
[12] Zawati Harun David Gethin, Drying (Consolidation) Porous Ceramic by Considering the Microscopic Pore Temperature Gradient, Applied Mechanics and Materials, Vol. 147,2012, p 210-214, [13] Z.Harun, Gethin, D.T., Lewis, R.W., Combined Heat and Mass Transfer for Drying Ceramic(shell) Body, The International Journal of Multiphysics, Vol 2(1), 2008, p. 1-19.
Online since: February 2016
Authors: Chen Guang Wei, Yuan Tian, Yi Wang Bao, Zhao Liu, Xue Qiang Cao
Materials Science & Engineering A 2013; 574: 25-30
[3] Y.W.
Ceramics International 2014; 40: 1263-1272 [5] X.Q.
Journal of the European Ceramic Society 2013; 33: 3085-3093 [7] Kaishi Wang, Jesse Unger, Jessica D.
Journal of the European Ceramic Society 2014 [8] Bradley T.
Materials Science and Engineering A 2007; 268-274 [13] Y.W.
Ceramics International 2014; 40: 1263-1272 [5] X.Q.
Journal of the European Ceramic Society 2013; 33: 3085-3093 [7] Kaishi Wang, Jesse Unger, Jessica D.
Journal of the European Ceramic Society 2014 [8] Bradley T.
Materials Science and Engineering A 2007; 268-274 [13] Y.W.
Online since: March 2015
Authors: Xiao Ping Zhou, Ying Ze Fang, Feng Xu
Preparation of nickel-based Al2O3-TiB2 composite ceramic powder
Feng Xua, Xiaoping Zhoub and Yingze Fangc
Hubei University of Technology College of Mechanical Engineering,
Hubei Provincial Key Laboratory of Green Materials for Light Industry,
Wuhan, Hubei, 430068, China
a24092575@qq.com, bzxp_zhn @163.com, c151224823@qq.com
Keywords: Mechanical alloying;Nickel-based ceramics;Al2O3-TiB2;Ceramic composites.
Materials engineering[J],2002(9):6-11.
Ceramics International[J],2006,16(5):19-23
Journal of Material Science and Technology[J], 2006,22(2):269-272
[8] Zhuang MA,Peng LIN,Shizhi DONG.Chinese Journal of Nonferrous Metals[J],2010,20(5), 908-913.
Materials engineering[J],2002(9):6-11.
Ceramics International[J],2006,16(5):19-23
Journal of Material Science and Technology[J], 2006,22(2):269-272
[8] Zhuang MA,Peng LIN,Shizhi DONG.Chinese Journal of Nonferrous Metals[J],2010,20(5), 908-913.
Online since: July 2015
Authors: Srithar Rajoo, Norhayati Ahmad, Muhammad Rabiu Abbas, Alias Mohd Noor, Uday M. Basheer, Muhammad Hanafi Md Sah
International journal of thermophysics. 27 (2006) 209-19
International Journal of Solids and Structures. 45 (2008) 3494-506
International Journal of Thermophysics. 30 (2009) 1357-71
International Journal of Engineering Science. 24 (1986) 1159-72
Advances in cryogenic engineering.
International Journal of Solids and Structures. 45 (2008) 3494-506
International Journal of Thermophysics. 30 (2009) 1357-71
International Journal of Engineering Science. 24 (1986) 1159-72
Advances in cryogenic engineering.
Online since: March 2019
Authors: Asma Perveen, Aydarkhan Sarsen, Azat Bilal, M. Ravi Sankar, Didier Talamona
Perveen1,e
1Nazarbayev University, Department of Mechanical Engineering, Republic of Kazakhstan
2IIT Guwahati, India,
aaydarkhan.sarsen@nu.edu.kz, bazat.bilal@nu.edu.kz, cevmrs@iitg.ac.in, ddidier.talamona@nu.edu.kz, easma.perveen@nu.edu.kz
Keywords: Assisted EDM, ceramics, Nano powder, silver coating
Abstract.
Journal of Ceramics, (2015)
Ceramics International, Vol. 41(3) (2015), p. 3490–3496
Proceedings of the 4th International Conference on Multi-Material Micro Manufacture, (2008), p. 161–166
Journal of the European Ceramic Society, Vol. 26(15), (2006).
Journal of Ceramics, (2015)
Ceramics International, Vol. 41(3) (2015), p. 3490–3496
Proceedings of the 4th International Conference on Multi-Material Micro Manufacture, (2008), p. 161–166
Journal of the European Ceramic Society, Vol. 26(15), (2006).
Online since: January 2014
Authors: Lourival Boehs, Manuel Alfredo Pereira, Jaime Domingos Teixeira, Vicente Cantavella, A. Pedro Novaes de Oliveira, Cristina Siligardi
Mauro Ramos, 950, centro - 88020-020 Florianópolis, SC, Brazil
2Department of Mechanical Engineering (EMC)
5Department of Materials and Environmental Engineering (DIMA)
University of Modena and Reggio Emilia (UNIMORE)
Via Vignolese 905, 41100 Modena, MO, Italy
6Institute of Ceramics Technology (ITC), Jaume I University,
Av.
:Journal of the American Ceramic Society Vol. 79 [4] (1996), p. 1092
Yan: Ceramics International Vol. 23 (1997), p. 457
:Ceramics International Vol. 33 (2007), p. 655
Beall: Glass-Ceramic Technology.
:Journal of the American Ceramic Society Vol. 79 [4] (1996), p. 1092
Yan: Ceramics International Vol. 23 (1997), p. 457
:Ceramics International Vol. 33 (2007), p. 655
Beall: Glass-Ceramic Technology.
Online since: August 2012
Authors: Antonio Pedro Novaes de Oliveira, Jaime Domingos Teixeira, Lourival Boehs, Francielly Roussenq Cesconeto, Manuel Alfredo Pereira, Cristina Siligardi
SINTERING BEHAVIOR OF LZS GLASS-CERAMICS
Jaime Domingos Teixeira1,a, Antonio Pedro Novaes de Oliveira1,2,b
Lourival Boehs2,c, Francielly Roussenq Cesconeto1,d, Cristina Siligardi3,e, Manuel Alfredo Pereira4,f
1Group of Ceramic and Glass Materials (CERMAT)
2Department of Mechanical Engineering (EMC)
Federal University of Santa Catarina (UFSC)
Campus Universitário – Trindade, 88040-900 Florianópolis, SC, Brazil
3Department of Materials and Environmental Engineering (DIMA)
University of Modena and Reggio Emilia (UNIMORE)
Via Vignolese 905, 41100, Modena, MO, Italy
4Federal Institute of Santa Catarina (IFSC)
Avenida Mauro Ramos, 950 – Centro, Florianópolis, SC, Brazil
ajaime@ifsc.edu.br, bpedronovaes@emc.ufsc.br, cboehs@emc.ufsc.br, dfranciellycesconeto@hotmail.com, ecristina.siligardi@unimore.it, fmalfredo@ifsc.edu.br
Keywords: ceramics, glass-ceramics, sintering, crystallization.
Pellacani: Journal of the American Ceramic Society Vol. 79 (4) (1996), p.1092
Leonelli: Journal of the American Ceramic Society Vol. 81 (3) (1998), p. 777
Journal of Materials Science Vol. (36) (2001), p.1
Yan: Ceramics International Vol. 23 (1997), p. 457.
Pellacani: Journal of the American Ceramic Society Vol. 79 (4) (1996), p.1092
Leonelli: Journal of the American Ceramic Society Vol. 81 (3) (1998), p. 777
Journal of Materials Science Vol. (36) (2001), p.1
Yan: Ceramics International Vol. 23 (1997), p. 457.
Online since: February 2020
Authors: Maya Etrekova, Konstantin Oblov, Anastasiya Gorshkova, Nikolay Samotaev, Denis Veselov
Parameter Studies of Ceramic MEMS Microhotplates Fabricated by Laser Micromilling Technology
Nikolay Samotaeva *, Konstantin Oblovb, Maya Etrekova c, Denis Veselovd and Anastasiya Gorshkovae
National Research Nuclear University MEPhI (Moscow Engineering Physics Institute), Russian Federation, 115409 Moscow, Kashirskoe highway 31
annsamotaev@mephi.ru, bkyoblov@mephi.ru, cmoetrekova@mephi.ru, ddsveselov@mephi.ru, enastyapzspb@mail.ru
Keywords: ceramic, MEMS, microhotplate, thick film technology, modeling
Abstract.
The results show possibility to fast fabrication of different topologies for ceramic MEMS microhotplate in form-factor of SOT-23 type SMD package.
Experimental The laser micromilling technology used for ceramic MEMS fabrication precisely described in works [9-10].
151 (1) article 012024 [5] Oblov K, Ivanova A, Soloviev S, Samotaev N, Vasiliev A and Sokolov A, Technology for fast fabrication of glass microhotplates based on the laser processing, 2015 Physics Procedia 72 465-469 [6] Karpov E, Karpov E, Suchkov A, Mironov S, Baranov A, Sleptsov V, Energy efficient planar catalytic sensor for methane measurement, 2013 Sensors and Actuators A: Physical 194 176-180 [7] Liu Q, Yao J, Wu Y, Wang Y, Ding G, Two operating modes of palladium film hydrogen sensor based on suspended micro hotplate, International Journal of Hydrogen Energy 44 11259-11265 [8] Monereo O, Casals O, Prades J D, Cirera A, Self-heating in pulsed mode for signal quality improvement: Application to carbon nanostructures-based sensors, Sensors and Actuators, B: Chemical 226 254-265 [9] Samotaev N, Oblov K, Pisliakov A, Volkov N, Ivanova A, Gorshkova A and Zibilyuk N, Technology of Rapid Prototyping SMD MOX Gas Sensors, 2018 Proceedings of 17th International Meeting on Chemical
Sensors - IMCS 2018 [10] Samotaev N, Oblov K and Ivanova A, Laser Micromilling Technology as a Key for Rapid Prototyping SMD ceramic MEMS devices, 2018 MATEC Web of Conferences 207 article 04003 [11] Biró F, Dücso C, Hajnal Z, Riesz F, Pap A E and Bársony I, Thermo-mechanical design and characterization of low dissipation micro-hotplates operated above 500°C, 2015 Microelectronics Journal 45 (12) 1822-1828
The results show possibility to fast fabrication of different topologies for ceramic MEMS microhotplate in form-factor of SOT-23 type SMD package.
Experimental The laser micromilling technology used for ceramic MEMS fabrication precisely described in works [9-10].
151 (1) article 012024 [5] Oblov K, Ivanova A, Soloviev S, Samotaev N, Vasiliev A and Sokolov A, Technology for fast fabrication of glass microhotplates based on the laser processing, 2015 Physics Procedia 72 465-469 [6] Karpov E, Karpov E, Suchkov A, Mironov S, Baranov A, Sleptsov V, Energy efficient planar catalytic sensor for methane measurement, 2013 Sensors and Actuators A: Physical 194 176-180 [7] Liu Q, Yao J, Wu Y, Wang Y, Ding G, Two operating modes of palladium film hydrogen sensor based on suspended micro hotplate, International Journal of Hydrogen Energy 44 11259-11265 [8] Monereo O, Casals O, Prades J D, Cirera A, Self-heating in pulsed mode for signal quality improvement: Application to carbon nanostructures-based sensors, Sensors and Actuators, B: Chemical 226 254-265 [9] Samotaev N, Oblov K, Pisliakov A, Volkov N, Ivanova A, Gorshkova A and Zibilyuk N, Technology of Rapid Prototyping SMD MOX Gas Sensors, 2018 Proceedings of 17th International Meeting on Chemical
Sensors - IMCS 2018 [10] Samotaev N, Oblov K and Ivanova A, Laser Micromilling Technology as a Key for Rapid Prototyping SMD ceramic MEMS devices, 2018 MATEC Web of Conferences 207 article 04003 [11] Biró F, Dücso C, Hajnal Z, Riesz F, Pap A E and Bársony I, Thermo-mechanical design and characterization of low dissipation micro-hotplates operated above 500°C, 2015 Microelectronics Journal 45 (12) 1822-1828
Online since: December 2013
Authors: Qing Suo Liu, Xu Ma, Xiao Yun Gao
The structure safety monitoring technology, which observe the status of cracks dynamically on-line and warn real time, attracts the attention of the international engineering [1~3].
CHINA CIVIL ENGINEERING JOURNAL. 2000, 33(4): 1-5.
State-of-the-Art review of the Structural health monitoring in civil engineering[J].
JOURNAL OF DISASTER PREVENTION AND MITIGATION ENGINEERING. 2003, 23(3): 92-98.
CHINA CIVIL ENGINEERING JOURNAL. 2006, 39(2): 46-52.
CHINA CIVIL ENGINEERING JOURNAL. 2000, 33(4): 1-5.
State-of-the-Art review of the Structural health monitoring in civil engineering[J].
JOURNAL OF DISASTER PREVENTION AND MITIGATION ENGINEERING. 2003, 23(3): 92-98.
CHINA CIVIL ENGINEERING JOURNAL. 2006, 39(2): 46-52.