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Online since: November 2012
Authors: Zoltán Gácsi, József Tóth, Judit Pázmán, Viktor Mádai
The Materials International Society, ASM International, ISBN: 0-87170-703-9 (2001)
Materials Science and Engineering A 303, (2001) 292-301
Journal of Materials Processing Technology Vols. 164-165, (2005) 924–929
Colloids and Surfaces A: Physicochemical and Engineering Aspects 235 (2004) (1-3) , 45-55
Journal of Alloys and Compounds, (2008) 85–91
Materials Science and Engineering A 303, (2001) 292-301
Journal of Materials Processing Technology Vols. 164-165, (2005) 924–929
Colloids and Surfaces A: Physicochemical and Engineering Aspects 235 (2004) (1-3) , 45-55
Journal of Alloys and Compounds, (2008) 85–91
Online since: July 2012
Authors: Lili Widarti Zainuddin, Norlida Kamarulzaman
Zahoor: Journal of Power Sources 165 (2007) 393-397
Natarajan, and V.Ravi: Ceramics International 34 (2008) p. 669-670.
Ke: Ceramics International 35 (2009) p. 949-952
Natarajan, and V.Ravi, Ceramics International 34 (2008) 669-670
Macdonald: Annals of Biomedical Engineering, Vol. 20 (1992) p. 289-305
Natarajan, and V.Ravi: Ceramics International 34 (2008) p. 669-670.
Ke: Ceramics International 35 (2009) p. 949-952
Natarajan, and V.Ravi, Ceramics International 34 (2008) 669-670
Macdonald: Annals of Biomedical Engineering, Vol. 20 (1992) p. 289-305
Online since: March 2012
Authors: Zhen Qing Wang, Hong Qing Lv, Miao Qun Liu
Numerical Analysis of Thermal Response of UHTCs
under Aerodynamic Heating
Miaoqun Liu 1,a, Hongqing lv 1,b and Zhenqing Wang 1,c
1College of Aerospace and Civil Engineering, Harbin Engineering University,
Harbin 150001, China
aliumiaoqun@hrbeu.edu.cn, blvhq251@163.com, cwangzhenqing@hrbeu.edu.cn
Keywords: Numerical analysis, Aerodynamic heating, Ultrahigh temperature ceramics(UHTCs), Thermal response.
This paper takes the combination of numerical and engineering computation to predict heating flux [1][2].
The heat flux estimated accurately is a prerequisite for the above work, this paper uses numerical calculation combined with engineering calculation[3,4] to solve the Euler equations for the external inviscid flow field, thus the outer parameters of boundary layer are determined, then the Surface heat flux is calculated by the engineering method.
The contours of pressure, density and temperature at symmetry is shown in Fig.2. and the surface heating flux of wall as shown in Fig.3 is calculated by using engineering method.
The 2nd International Symposium on Systems and Control in Aeronautics and Astronautics,(2008)
This paper takes the combination of numerical and engineering computation to predict heating flux [1][2].
The heat flux estimated accurately is a prerequisite for the above work, this paper uses numerical calculation combined with engineering calculation[3,4] to solve the Euler equations for the external inviscid flow field, thus the outer parameters of boundary layer are determined, then the Surface heat flux is calculated by the engineering method.
The contours of pressure, density and temperature at symmetry is shown in Fig.2. and the surface heating flux of wall as shown in Fig.3 is calculated by using engineering method.
The 2nd International Symposium on Systems and Control in Aeronautics and Astronautics,(2008)
Online since: June 2011
Authors: J.P. Chevalier, Frédéric Bonnet, E. Bayraktar, F. Ayari, D. Katundi
Bonnet3
1Supmeca -Paris, School of Mechanical and Manufacturing Engineering, France
2Chair of Industrial Materials, CNAM, Arts et Métiers, 75141 Paris 03 –France
3ARCELOR – Research, Paris, France
*bayraktar@supmeca.fr; emin.bayraktar@cnam.fr
Key words: Steel matrix composites; Ceramic particles-TiB2; Crash test; Welding; Weldability
Abstract.
Introduction Metal Matrix Composites (MMCs) have recently received considerable attention in manufacturing engineering as potential structural materials due to their high specific strength and stiffness [1-2, 3-6, 7-12].
While most work on MMCs is directed towards producing novel and lightweight engineering materials, there is also considerable interest in developing iron and steel matrix composites.
-The weldability of this new steel family gives it great potential in manufacturing engineering.
Okamoto (Eds.), Handbook of Ternary Alloy Phase Diagrams, vol. 5, ASM International, 1997
Introduction Metal Matrix Composites (MMCs) have recently received considerable attention in manufacturing engineering as potential structural materials due to their high specific strength and stiffness [1-2, 3-6, 7-12].
While most work on MMCs is directed towards producing novel and lightweight engineering materials, there is also considerable interest in developing iron and steel matrix composites.
-The weldability of this new steel family gives it great potential in manufacturing engineering.
Okamoto (Eds.), Handbook of Ternary Alloy Phase Diagrams, vol. 5, ASM International, 1997
Online since: July 2012
Authors: Ramesh Singh, Chou Yong Tan, Lai Kuan Lee Samuel, Mahdi Amiriyan, Ranna Tolouei, Boon Kar Yap
Owing to its excellent biocompatibility and its potential as a bioactive ceramic, HA has long been the focus of scientists and researchers worldwide as the material of choice for bone tissue engineering.
Nonetheless, the desire for a suitable bone tissue engineering material plus the attractive biological property of HA (bioactive) continues to fuel the determination of researchers and scientists worldwide.
Ramesh: Ceramics International Vol. 26 (2000), p. 221 – 230
Victoria: Ceramics International Vol. 35 (2009), p. 2373 – 2380
Sevostianov: Materials Science and Engineering A Vol. 431 (2006), p. 218 – 227
Nonetheless, the desire for a suitable bone tissue engineering material plus the attractive biological property of HA (bioactive) continues to fuel the determination of researchers and scientists worldwide.
Ramesh: Ceramics International Vol. 26 (2000), p. 221 – 230
Victoria: Ceramics International Vol. 35 (2009), p. 2373 – 2380
Sevostianov: Materials Science and Engineering A Vol. 431 (2006), p. 218 – 227
Online since: September 2013
Authors: Hong Yan Liu, Ping Zhao, Rohit Sharma, Chen Feng
In this paper, preliminary investigation of a new cement-sand based piezoelectric composite was conducted for potential structural engineering applications.
In this study, PZT powder mixed with cement and sand, which is more realistic in civil engineering applications.
Through a series of MTS compression tests, feasibility of using cement-sand based PZT composite materials in civil engineering is evaluated.
The studies of the applications for the piezoelectric materials in civil engineering have been done as well.
-N., Vibration control of civil structures using piezoceramic smart materials: A review, Engineering Structures, 28 (2006) p 1513-1524
In this study, PZT powder mixed with cement and sand, which is more realistic in civil engineering applications.
Through a series of MTS compression tests, feasibility of using cement-sand based PZT composite materials in civil engineering is evaluated.
The studies of the applications for the piezoelectric materials in civil engineering have been done as well.
-N., Vibration control of civil structures using piezoceramic smart materials: A review, Engineering Structures, 28 (2006) p 1513-1524
Online since: September 2012
Authors: Young Jae Choi, Seok Woo Lee, Hon Jong Choi, Kyeong Tae Kim, Yun Hyuck Hong, Kyung Hee Park
Ho11, "Ultrasonic Assisted Grinding of Ceramics", Journal of Materials Processing Technology 62 (1996) 287-293
[2] Javad Akbari, Hassan Borzoie, Mohammad Hossein Mamduhi, "Study on Ultrasonic Vibration Effects on Grinding Process of Alumina Ceramic (Al2O3)", World Academy of Science, Engineering and Technology 41 (2008) 785-789
Guo, "UVAG of Brittle Materials : DoE with a Cutting Force Model" Proceedings of the 2010 Industrial Engineering Research Conference [6] Q.
Jia "The Mechanism of Material Removal in Ultrasonic Drilling of Engineering Ceramics" Technical note IMechE 2000 [7] H.
Kang, " A Study of the Design of Ultrasonic Vibration Cutting Tool Horn" Journal of the Korean Society of Precision Engineering Vol. 8, No. 3 (1991.9)
[2] Javad Akbari, Hassan Borzoie, Mohammad Hossein Mamduhi, "Study on Ultrasonic Vibration Effects on Grinding Process of Alumina Ceramic (Al2O3)", World Academy of Science, Engineering and Technology 41 (2008) 785-789
Guo, "UVAG of Brittle Materials : DoE with a Cutting Force Model" Proceedings of the 2010 Industrial Engineering Research Conference [6] Q.
Jia "The Mechanism of Material Removal in Ultrasonic Drilling of Engineering Ceramics" Technical note IMechE 2000 [7] H.
Kang, " A Study of the Design of Ultrasonic Vibration Cutting Tool Horn" Journal of the Korean Society of Precision Engineering Vol. 8, No. 3 (1991.9)
Online since: July 2020
Authors: Xiang Li, Liang Zhao, Qian Huang, Hua Yin Sun
Corrosion Resistance of Partially Stabilized Zirconia Materials to Alkaline Steel Slag
Liang Zhao1,a, Qian Huang1,b*, Huayin Sun1,c, Xiang Li2,d
1School of Civil and Architectural Engineering, Yangtze Normal University, Chongqing 408100, China.
2Qingdao Zircool High-temperature Ceramics Co., Ltd, Qiangdao 266000, China.
Highly Porous Zirconia Ceramic Foams with Low Thermal Conductivity from Particle‐Stabilized Foams, Journal of the American Ceramic Society, 2016, 99(11): 3512-3515
Development of Zirconia Composite Ceramics and Study on their Corrosion Resistance up to 1600°C, Key Engineering Materials, 2004, 264-268: 1739-1742
Mechanical and Dielectric Properties of Partially Stabilized Zirconia Ceramic, Journal of the Chinese Ceramic Society, 2008, 36(3): 306-310
Thermal Stability and Ionic Conductivity of Calcia‐Stabilized Zirconia with Alumina Addition, International Journal of Applied Ceramic Technology, 2016, 13(4): 697-701
Highly Porous Zirconia Ceramic Foams with Low Thermal Conductivity from Particle‐Stabilized Foams, Journal of the American Ceramic Society, 2016, 99(11): 3512-3515
Development of Zirconia Composite Ceramics and Study on their Corrosion Resistance up to 1600°C, Key Engineering Materials, 2004, 264-268: 1739-1742
Mechanical and Dielectric Properties of Partially Stabilized Zirconia Ceramic, Journal of the Chinese Ceramic Society, 2008, 36(3): 306-310
Thermal Stability and Ionic Conductivity of Calcia‐Stabilized Zirconia with Alumina Addition, International Journal of Applied Ceramic Technology, 2016, 13(4): 697-701
Online since: April 2018
Authors: Song He Meng, Jin Ping Li, Cheng Yang, Yu Han Li
Then the ceramic blocks were compacted by cold isostatic pressing under 200MPa for two minutes.
Obviously the theoretical density of WO3 is much higher than that of the other two ceramics.
Thermal expansion of ZrO2- ZrW2O8 composites prepared using co-precipitation route, International Journal of Modern Physics B 23 (2009) 1449-1454
Preparation of ZrO2/ ZrW2O8 composites and study of its thermal expansion, Journal of Luoyang Institute of Science and Technology (Natural Science Edition) 24(3) (2014) 82-86 (in Chinese)
Study on the preparation processes of the ZrO2/ ZrW2O8 ceramic composites, Rare metal materials and Engineering 44 (S1) (2015) 311-315 (in Chinese)
Obviously the theoretical density of WO3 is much higher than that of the other two ceramics.
Thermal expansion of ZrO2- ZrW2O8 composites prepared using co-precipitation route, International Journal of Modern Physics B 23 (2009) 1449-1454
Preparation of ZrO2/ ZrW2O8 composites and study of its thermal expansion, Journal of Luoyang Institute of Science and Technology (Natural Science Edition) 24(3) (2014) 82-86 (in Chinese)
Study on the preparation processes of the ZrO2/ ZrW2O8 ceramic composites, Rare metal materials and Engineering 44 (S1) (2015) 311-315 (in Chinese)
Online since: January 2016
Authors: Irina Hussainova, Der Liang Yung, Rainer Traksmaa, Miguel A. Rodríguez
Materials Science and Engineering: A. 597: (2014) p. 75-81
[2] S.E.
Key Engineering Materials. 527: (2012) p. 20-25 [6] S.E.
Materials Science and Engineering: A. 497(1-2): (2008) p. 79-86 [8] X.
Ceramics International. 41(5): (2015) p. 7103-7108 [10] S.
Ceramics International. 40(7): (2014) p. 10517-10522 [11] D.
Key Engineering Materials. 527: (2012) p. 20-25 [6] S.E.
Materials Science and Engineering: A. 497(1-2): (2008) p. 79-86 [8] X.
Ceramics International. 41(5): (2015) p. 7103-7108 [10] S.
Ceramics International. 40(7): (2014) p. 10517-10522 [11] D.