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Energy Conversion Engineering Conf.
Mechanical Science and Technology for Aerospace Engineering, 2007,26(11): 1454-1457
Modern Manufacturing Engineering, 2010, (12): 91-94
AIAA Journal. 2007, 45 (5):1126–1137
Journal of sound and vibration. 2009,320:386-405

It is shown that such alloys have found application as III armor class materials, due to their higher strength compared to aluminum alloys (AMg5, B95, 1901), lower density than classical armored steels (77, 44S, Ts85, SPS-43) and less brittleness in comparison with ceramic materials based on oxides and carbides (Al2O3, SiC, B4C) [3-6].
[4] Mylnikov V V, Abrosimov A A, Romanov I D and Romanov A D 2014 Technical Science 9 pp 143 – 147 [5] Grinevich A V and Lavrov A V 2018 Proceedings of VIAM 3(63) pp 95-102 [6] Minhyung Lee, Sangwon Park, Ilguk Jo and Sangkwan Lee. 2017 Procedia Engineering 204 pp 100-107 [7] Ilyin A A, Skvortsova S V, Spector V S, Kudelina I M and Mamontova N A 2011 Light alloy technology 2 pp 37-41 [8] Mamonov A M, Safaryan A I, Agarkova E O, Zhilyakova M A 2018 Metal Science and Heat Treatment V 60 I 1-2 pp 80-88 [9] Senkevich K S, Skvortsova S V, Kudelina I M, Knyazev M I and Zasypkin V V 2014 Metals 1 pp 77-82 [10] Gvozdeva O N, Shalin A V and Stepushin A S 2020 IOP Conference Series Materials Science and Engineering V 889 I 1 A 012005 pp 1-7 [11] Gvozdeva O N, Shalin A V, Stepushin A S and Ovchinnikov A V 2020 IOP Conference Series Materials Science and Engineering V 971 I 1 A 052016 pp 1-5 [12] Skvortsova S V, Gvozdeva O N, Shalin A V, Sarychev S M and Stepushin A S 2020 Sixth interdisciplinary
scientific forum with international participation "New materials and advanced technologies" V I pp 81-86 [13] Lukina E A 2019 Journal of Physics: Conference Series. – IOP Publishing.
[14] Grushin I A, German M A and Kuzmina D A 2019 Journal of Physics: Conference Series, V 1396 A 012020 [15] Lenkovets A S, Lozovan A A, Betsofen S Ya, Bespalov A V, Grushin I A and Ivanov N A 2019 Journal of Physics: Conference Series V 1396 A 012028

Equivalent modeling for shape design of IPMC (Ionic Polymer-Metal Composite) as flapping actuator Hoon Cheol Park1,a, Sangki Lee 1,b and Kwang Jin Kim 2,c 1 Artificial Muscle Research Center, Department of Aerospace Engineering, Konkuk University, Seoul, South Korea 2 Active Materials and Processing Laboratory, Department of Mechanical Engineering, University of Nevada, NV, USA a hcpark@konkuk.ac.kr, blsk387@konkuk.ac.kr, ckwangkim@unr.edu Keywords: IPMC, equivalent bimorph beam model, actuation force, actuation displacement, thermal analogy, MSC/NASTRAN Abstract.
Acknowledgement This work was supported by the International Science and Technology Cooperation Research Program (2003), KISTEP, Ministry of Science in Korea and Korea Science and Engineering Foundation (KOSEF, 2003).
Kim: "An Equilibrium Circuit Model for Ionic Polymer-Metal Composites and Their Performance Improvement by a Clay-Based Polymer Nano-Composite Technique," Journal of Intelligent Materials Systems and Structures Vol. 14 (2003), pp. 633-642 [4] Q.
Cross: "Nonlinear piezoelectric behavior of ceramic bending mode actuators under strong electric fields," Journal of Applied Physics Vol. 86 (1999), pp. 3352-3360 [5] MSC/NASTARAN User's Guide (MSC 2003) [6] B.K.
Nemat-Nasser: "Micromechanics of actuation of ionic polymer-metal composites," Journal of Applied Physics Vol. 92 (2002), pp. 2899-2915

Rosso d 1 Institute of Engineering Materials and Biomaterials, Silesian University of Technology, ul.
Konarskiego 18a, 44-100 Gliwice, Poland 2 Department of Materials Science and Chemical Engineering, Politecnico di Torino -Alessandria Campus, Viale T.Michel 5, 15100 Alessandria, Italy a leszek.dobrzanski@polsl.pl, bzbigniew.brytan@polsl.pl, cmarco.actis@polito.it, d mario.rosso@polito.it Keywords: powder metallurgy, stainless steels, vacuum sintering.
Rosso, Proceedings of 12th International Scientific ConferenceAMME'03, pp.211-214, Gliwice-Zakopane, Poland 2003
Pallavicini, Journal of Materials Processing Technology, Vol. 157-158, pp. 312-316, 2004
Torralba, Journal of the European Ceramic Society Vol. 23, pp. 2813-2819, 2003.

Influence of Retarders on the Microstructure of Hardened Building Gypsum Paste and the Mechanism of Its Strength Loss Jindong Qu a, Baizhan Lib and Jiahui Pengc Faculty of Urban Construction & Environmental Engineering, Chongqing University, China 3 College of Materials Science and Engineering, Chongqing University, China aqjdmail@163.com, bbaizhanli@cqu.edu.cn, cpengjh@cqu.edu.cn Key words: gypsum；retarder；microstucture；crystal morphology；pore structure.
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Brockner: Zement-Kalk-Gips. 1990, (9): 219~220 [8] Manjit Singh and Mridul Garg: Cement and Concrete Research. 1997, 27 (6): 947~950 [9] Yuhe Deng，Jiayan Luo，Dexing Zai et al: Holzforschung, 2008, 62(3): 368-371 [10] N.Singh.: Journal of Thermal Analysis and Calorimetry, 2006, 86(3): 721-726 [11] M.H.H.
Abdel-Aal: Journal of Colloid and Interface Science, 2004, (270) :99–105 [12] Jiahui Peng, Jianxin Zhang, Mingfeng Chen : Journal of the Chinese Ceramic Society, 2008, 36(7): 896-900.

Piezoelectric performance analysis of the single-sided trapezoidal loop shaped piezoelectric cantilever beam JIANG Bing1,a*，CHEN Hong1,b，CHEN Lijuan2,c，CAO Kun1,d, YUAN Shuai1,e , WANG Qiang1,f 1 College of Automation, Nanjing University of Posts and Telecommunications, Nanjing, 210046, China 2 College of Electrical Engineering, Southeast University, Nanjing, 210096, China a jiangb@njupt.edu.cn b chenh19890216@163.com c chenlijuan19811219@163.com d 920754767@qq.com e yuanshuai5211314x@126.com f wangq19771218@163.com Keywords: single-sided trapezoidal loop; Strain distribution; Resonant frequency;Coupling voltage Abstract.
The design, fabrication and evaluation of a MEMS PZT cantilever with an integrated sip roof mass for vibration energy harvesting ［J］.Journal of Micromech Microeng,2008,18( 5) : 055017
Micro electron Journal,2008,39( 5) : 802 －806
Low frequency can spiral ere piezoelectric structure performance analysis[J] Journal of solid mechanics, 2007: 28(1): 87-92.
Alternative Geometries for Increasing Power Density in Vibration Energy Scavenging for Wireless Sensor Networks [J].International Energy Conversion Engineering Conf.2005,8:1-12

Bakanov, Modeling of temperature field distribution of the foam glass batch in terms of thermal treatment of foam glass, International Journal for Computational Civil and Structural Engineering. 3 (2017) 112-118
Nikishov, Variability of approaches to mathematical modeling of cellular glass charge stock thermal processing, Academic journal "Balletin of Belgorod technical university named after V.G.
Single bubbles, Ceramics – Silikáty. 47(3) (2003)81-87
Volkov et al., Mathematical Model of the Pore Formation Dynamics Owing to Heat Treatment of the Foam Glass Batch, Journal of Higher Educational Establishments.
Dissertation for a Doctor’s of Engineering Science Degree, Leningrad, 1987 (In Russian)

., Efficient mold manufacturing for precision glass molding, Journal of Vacuum Science Technology B 27, 1445, 2009 [2] Su, L.; Yi, A., Investigation of the effect of coefficient of thermal expansion on prediction of refractive index of thermally formed glass lenses using FEM simulation, Journal of Non-Crystalline Solids, Volume 357, pp. 3006-3012, 2011 [3] Bifano, T.G., Ductile regime grinding of brittle materials, PhD Thesis, North Carolina State University, 1988 [4] Brinksmeier et al., Dressing of Coarse-Grained Diamond Wheels for Ductile Machining of Brittle Materials, Towards Synthesis of Micro-/Nanosystems, pp. 305-307, 2007 [5] Liu, K.; Li, X.
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Introduction Fused silica glass is widely applied in modern analytical chemistry, laser engineering, and navigation systems due to it’s unique properties such as high resistance to heat and chemicals, large transmission range and low optical absorption; high electrical insulation and fine vibration property [1].
The spindle on the grinding experiment setup used ceramic bearing with a maximum rotational speed of 50000 r/min, and rotation accuracy of 0.1μm.
Zervos: International Journal of Machine Tools & Manufacture Vol. 46 (2006) , pp.1053-1063 [4] C.
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Gurskikh: Powder Metallurgy and Metal Ceramics, Vol. 48 (2009), pp. 11–17
Mynors: International Journal of Machine Tools and Manufacture, Vol. 49 (2009), pp. 916-923
Kara: Engineering Structures, Vol. 29 (2007), pp. 2262-2273
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Ludovico: Journal of Materials Processing Technology, Vol. 197 (2008), pp. 301–305