Experimental and Simulation Investigation of Bending Moment Effect on Hollow Columns of Multi-layers of Hybrid Materials
Keywords:
Experimental study, Simulation study, AUTODYN, Bending load, Hybrid materials, Hollow columnsAbstract
This paper presented the effect of bending on multi-layer of hollow columns of Hybrid materials (Carbon-Glass /epoxy-Alumina) composite this effect occurred and volume fraction of fibers. An experimental procedure was developed to study the performance of these effects under bending load using a hydraulic bending device type (MATEST. SRL) testing machine. This study has three forms through the selection of columns hollows width to thickness (a/b) (0.5, 1 and 2) with three types of layers of samples (2,4 and8) layers. The ultimate load of failure for each Hybrid/epoxy-Al2O3 had been determined and specified the optimum volume fraction (Vf) due to the effect of mixing 50% and 60% were low in the case for compared 55% volume fraction. To simulate this problem the researcher used Explicit Mesh for AUTODYN under ANSYS-15 software, it was found that maximum bending load for Hybrid/ Epoxy-Al2O3 Specimens, the maximum load of specimens increased with increasing number of layers from 2L to 8L. The results also identified that the maximum load capacity by 55% volume fraction and a/b=0.5 of all composite specimens was highest from the others types of (50% and 60%) volume fractions and (a/b=1 and a/b=2) .Also, the Increasing ratio of stress capacity for specimens have 4 to 2 layers (4/2) and 8 to 4 (8/4) for experimental results have maximum value with increasing by 48.19% and 46.84% at (Sp.4#8/Sp.2#4) and (Sp.8#6/Sp.4#6) respectively.
Downloads
References
. popular science and technology series, composite materials ,DESIDOC, ministry of defense, metcalfoe house ,(1990).
. Bryan Harris. engineering composite materials, the institute of materials, London, (1999).
. Raif Sakinand IrfanAY. statistical analysis of bending fatigue life data using weibull distribution in glass- fiber reinforced polyester composites, materials and design, 29, issu.6, (2008), p.p 170-1181.
. Limin Bao , Natsuki Kamada , Danna Qian , Tomohiro Shirayi , Sotomi Gotou & Kiyoshi Kemmochi .Improvement of the Bending Characteristics of Thin FRP Cylinders by Imitating Nodes of Bamboo. Advanced Composite Materials., 19, 2 (2010), p.157-p.170.
. Palmer SO, Nettles AT and Poe Jr, CC.An experimental study of a stitched composite with a notch subjected to combined bending and tension loading. NASA Report No. NASA/TM-1999-209511, National Technical Information Service, (1999).
. Wisnom MR. The relationship between tensile and flexural strength of unidirectional composites. J Comp Mater, 26, (1992), p.1173–p.1180..
. Khashaba UA. On the mechanical behavior of [0/_45/ 90]s woven composites subjected to combined bending and tension loading, In: Proceedings of the 4th International Engineering Conference, Mansoure University, Egypt, 1, (2004), p.527–p.539.
. Khashaba UA and Seif MA. Effect of different loading conditions on the mechanical behavior of [0/_45/90]s woven composites. J Compos Struct, 74, (2006), 440–448.
. Liu XY and Yu WD.Bending fatigue properties of single aramid fibers. Chem Fibers Int, 54(3), (2004), 173–175.
. Gu BH. Bending fatigue properties of single wool fibers. J Text Res, 14(4), (1992), 157–159.
. Burgoyne CJ, Hobbs RE and Strzemiecki J.Tension bending and sheave bending fatigue of parallel lay aramid ropes. In Proceedings of 8th international conference on offshore mechanics and arctic engineering. The Hague, Netherlands, March, (1989) p.691–692.
. Mower TM. Sheave-bending and tensile fatigue of aramid-fiber strength members for communications cables. Int J Fatigue, 22, (2000), 121–135.
. Kohji M, Yoshihiro M and Kenjiro K.The influence of vacuum on fracture and fatigue behavior in a single aramid fiber. Int J Fatigue, 22, (2000), 757–765.
. Kollar LP and Springer GS. Mechanics of composite structures. Cambridge, UK: Cambridge University Press, 2003.
. Barbero EJ. Introduction to composite materials design. Boca Raton, FL: CRC Press, 2010.
. Agarwal BD, Broutman LJ and Chandrashekhara K.. Analysis and performance of fiber composites. Hoboken, New Jersey: John Wiley and Sons Inc.2006.
. Mallick PK. Fiber reinforced composites: Materials, manufacturing and design. Boca Raton, FL: CRC Press, 2008.
. Kaw AK.. Mechanics of composite materials. Boca Raton, FL: CRC Press, 2006.
. Bank LC. Composites for construction. Hoboken, New Jersey: John Wiley and Sons Inc, 2006.
. Vinson JR and Sierakowski RL. The behavior of structures composed of composite materials. Dordrecht, The Netherlands: Springer Science & Business Media, 2008.
. Muhammad AM Qureshi, Hota V GangaRao, Nasir Hayat and Praveen Majjigapu. Response of closed Glass Fiber Reinforced Polymer sections under combined bending and torsion. Journal of Composite Materials, 51(2), (2017), p.241–p.260
. Phan, N.D. and Reddy, J.N. Analyses of Laminated Composite Plates using a Higherorder Deformation Theory, Int. J. Num. Meth. Engg., 21(12), (1985), p.2201–p.2219.
. IdIbi, A., Karama, M. and Touratier, M. Comparison of Various Laminated Plate, 1997.
. Karama, M., Afaq, K.S. and Mistou, S. Mechanical Behavior of Laminated Composite Beam by New Multi-layered Laminated Composite Structures Model with Transverse Shear Stress Continuity, Int. J. Solids Struct., 40(6), (2003), p.1525–p.1546,
. Librescu L and Song O. Thin-walled composite beams. Dordrecht, The Netherlands: Springer, 2006.
. Salim HA and Davalos JF. Torsion of open and closed thin-walled laminated composite sections. J Compos Mater, 39, (2005), p.497–p.524.
. Roberts TM and Al-Ubaidi H. Flexural and torsional properties of pultruded fiber reinforced plastic I-profiles. J Compos Construct, 6, (2002), 28–34,
. Lekhnitski SG. Anisotropic plates. Gordon and Breach, 1968.
. Whitney JM. Structural analysis of laminated anisotropic plates. Technomic Publishing Company, 1987.
. ASCE LRFD manual for pultruded Fiber Reinforced Polymer (FRP) structures (Draft). ASCE-ACMA Joint Publication, Draft Version,
. Eurocode No. 3. Design of steel structures Part I – General rules and rules for buildings (Draft). Commission of the European Communities,1988.
. Creative Pultrusions Inc. The Pultex pultrusion design manual. Vol. 4, Revision 6. Available at: http://www.readbag. com/creativepultrusions-litlibrary-designmanualdmv4r6, 2004.
. F.C.Campbell., structural composite materials , ASM international, 2010.
. Bhas Kark., static analyses of portal axel outpot shaft using composite materials , international journal of research in engineering and technology, e issn:2319-1163/p issn: 2321-7308, vol.03, special issue:03, may, india, (2014).
. Niharika Mohanta and S.K.Acharya. “ investigation of mechanical properties of luffa cylindrical fiber reinforced epoxy hybrid composite”, international journal of engineering science and technology, 7(1), (2015), pp1-10.
. Hani Aziz., Mechanical properties of composite materials using natural rubber with epoxy resin, engineering and technology, 26(2), (2008).
Published
How to Cite
Issue
Section
Copyright (c) 2019 Ayad A. Ramadhan
This work is licensed under a Creative Commons Attribution 4.0 International License.