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Glass and Ceramics
Published in: Glass and Ceramics 5-6/2018

10-09-2018

Determination of the Stiffness Characteristics of Composite Fiberglass Supports

Authors: V. V. Adishchev, A. S. Zubkov, A. I. Ivanov, V. V. Mal’tsev, A. Yu. Panichev

Published in: Glass and Ceramics | Issue 5-6/2018

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Abstract

An investigation of the stiffness characteristics of fiberglass supports with cone angle about 89° is presented. A method is proposed for determining the modulus of elasticity in tension and compression in longitudinal and transverse directions of a composite support. Experimental studies were performed for measuring the modulus of elasticity in longitudinal and transverse directions, and formulas and empirical methods for calculating the modulus of elasticity and Poisson’s ratio in the transverse direction are proposed. It is showing that the modulus of elasticity in tension exceeds the modulus of elasticity in compression.
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Literature
1.
T. K. Sørensen, J. Holbøll, and S. D. Mikkelsen, Composite Based EHV AC Overhead Transmission Lines, Technical University of Denmark, Department of Electrical Engineering (2010).
2.
J. P. Fanucci and J. J. Gorman, US Patent 6397545 B1, Energy-Absorbing Utility Poles and Replacement Components, 4 June 2002, Kazak Composites, Inc., USA (2002).
3.
G. S. Hosford, J. F. Boozer, III, R. A. Pollard, Jr., and J. R. Lewis, Jr., Composite Utility Pole, US Patent 5704187 A, 6 January 1998, Shakespeare Company, USA (1998).
4.
D. Polyzois and N. Ungkurapinan, Composite Wind Tower Systems and Methods of Manufacture, US Patent 7866121 B2, 11 January 2011, University of Manitoba, Canada (2011).
5.
S. J. Lim, C. D. Kong, and H. B. Park, “A Study on optimal design of filament winding composite tower for 2 MWclass horizontal axis wind turbine systems,” Int. J. Composite Materials, No. 3, 15 – 23 (2013).
6.
S. Ibrahim, D. Polyzois, and S. K. Hassan, “Development of glass fiber reinforced plastic poles for transmission and distribution lines,” Can. J. Civ. Eng., 27, 850 – 858 (2000).CrossRef
7.
H. Mohamed and R. Masmoudi, “Design optimization of GFRP pole structures using finite element analysis,” in: Proceedings of Composites & Polycon 2009, American Composites Manufacturers Association, 15 – 17 January 2009, Tampa, FL, USA (2009).
8.
Munusamy Selvaraj, “Structural assessment of a 66 kV overhead power transmission line tower built with polymer composite material,” in: Proceedings of the 2015 World Congress on Advances in Structural Engineering and Mechanics (ASEM15), 25 – 29 August 2015, Incheon, Korea (2015).
9.
Hsien-Yang Yeh and Hsien-Liang Yeh, “A simple failure analysis of the composite transmission tower,” J. Reinf. Plast. Comp., 20(12), 1054 – 1065 (2001).CrossRef
10.
Hsein-Yang Yeh and Samuel C. Yang, “Building of a composite transmission tower,” J. Reinf. Plast. Comp., 16(5), 414 – 424 (1997).CrossRef
11.
A. K. Malmester, V. P. Tamuzh, and G. A. Tetere, Resistance of Polymer and Composite Materials [in Russian], Zinatne, Riga (1980), 3rd edition.
12.
B. Conde, A. Villarino, M. Cabaleiro, and D. Gonzalez-Aguilera, “Geometrical issues on the structural analysis of transmission electricity towers thanks to laser scanning technology and finite element method,” Remote Sens., No. 7, 11,551 – 11,569 (2015).
13.
M. Selvaraj, S. M. Kulkarni, and R. R. Babu, “Structural evaluation of FRP pultruded sections in overhead transmission line towers,” Int. J. Civ. Struct. Eng., No. 2, 943 – 949 (2012).
14.
R. Masmoudi, H. Mohamed, and S. Metiche, “Finite element modeling for deflection and bending responses of GFRP poles,” J. Reinf. Plast. Comp., 27(6), 639 – 658 (2008).CrossRef
15.
A. C. Young, A. J. Goupee, H. J. Dagher, and A. M. Viselli, “Methodology for optimizing composite towers for use on floating wind turbines,” J. Renewable Sustainable Energy, No. 9, 033305–21 (2017).
16.
M. J. Cerny, “Eigenvalues of composite shells for television tower prague,” in: Proceedings of the International Conference on Composite Engineering (ICCE/1), 28 – 31 August 1994, New Orleans, LA, USA (1994).
17.
R. Hernández-Corona and I. Ramirez-Vázquez, “Structural performance of polymeric composite members in a transmission line tower,” in: Proceedings of the COMSOL Conference 2015, 7 – 9 October 2015, Boston, MA, USA (2015).
18.
Q. C. Yu, W. Y. Zhong, and L. L. Hu, “Influence of tension in T300/epoxy prepreg winding process on the performance of the bearing composites,” J. Reinf. Plast. Comp., 36, 1099 – 1115 (2017).CrossRef
19.
V. V. Vasil’ev, V. D. Protasov, V. V. Bolotin, et al., Handbook of Composite Materials [in Russian], Mashinostronie, Moscow (1990).
20.
Yu. M. Tarnopol’skii and A. M. Skudra, Structural Strength and Deformability of Fiberglass [in Russian], Zinatne, Riga (1966).
21.
N. N. Trofimov and M. Z. Kanovich, Fundamentals of the Development of Polymer Composites [in Russian], Nauka, Moscow (1999).
Metadata
Title
Determination of the Stiffness Characteristics of Composite Fiberglass Supports
Authors
V. V. Adishchev
A. S. Zubkov
A. I. Ivanov
V. V. Mal’tsev
A. Yu. Panichev
Publication date
10-09-2018
Publisher
Springer US
Published in
Glass and Ceramics / Issue 5-6/2018
Print ISSN: 0361-7610
Electronic ISSN: 1573-8515
DOI
https://doi.org/10.1007/s10717-018-0054-1

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