Research Article
Year 2016,
Volume: 8 Issue: 4, 87 - 98, 29.12.2016
Abstract
References
- [1] Xia M, Takayanagi H, Kemmochi K. Analysis of multi-layered filament-wound composite pipes under internal pressure. Compos Struct 2001;53:483-491.
- [2] Martens M, Ellyin F. Biaxial monotonic behavior of a multidirectional glass fiber epoxy pipe. Compos: Part A - Appl Sci Technol 2000;31:1001–1014.
- [3] Abdul Majid M S, Assaleh T A, Gibson A G, Hale J M, Fahrer A, Rookus C A P, Hekman M. Ultimate elastic wall stress (UEWS) test of glass fibre reinforced epoxy (GRE) pipe. Compos Part A - Appl Sci Technol 2011;42:1500–1508.
- [4] Wakayama Shuichi, Kobayashi Satoshi, Imai Takayuki, Matsumoto Takayuki. Evaluation of burst strength of FW-FRP composite pipes after impact using pitch-based low-modulus carbon fiber. Compos Part A - Appl Sci Technol 2006;37:2002–2010.
- [5] Onder Aziz, Sayman Onur, Dogan Tolga, Tarakcioglu Necmettin. Burst failure load of composite pressure vessels. Compos Struct 2009;89:159–166.
- [6] Kaynak Cevdet, Mat Onur. Uniaxial fatigue behavior of filament-wound glass-fiber/epoxy composite tubes. Compos Sci Technol 2001;61:1833–1840.
- [7] Rousseau J, Perreux D, VerdieÁre N. The influence of winding patterns on the damage behaviour of filament-wound pipes. Compos Sci Technol 1999;59:1439-1449.
- [8] Mertiny P, Ellyin F, Hothan A. An experimental investigation on the effect of multi-angle filament winding on the strength of tubular composite structures. Compos Sci Technol 2004;64:1–9.
- [9] Sayman Onur. Analysis of multi-layered composite cylinders under hygrothermal loading. Compos Part A - Appl Sci Technol 2005;36:923–933.
- [10] Zhao J H, Chen X, Dharani L R, Ji F S. Stress analysis of a multilayered composite cylinder with defects. Theoretical and Appl Fract Mech 2000;34:143-153.
- [11] Arjomandi Kaveh, Taheri Farid. Bending capacity of sandwich pipes. Ocean Eng 2012;48:17–31.
- [12] Tran Phuong, Ngo Tuan D., Ghazlan Abdallah. Numerical modelling of hybrid elastomeric composite panels subjected to blast loadings. Composite Structures 153 (2016) 108–122.
- [13] Ridzuan M.J.M., Majid M.S. Abdul, Afendi M., Mazlee M.N., Gibson A.G.. Thermal behaviour and dynamic mechanical analysis of Pennisetum purpureum/glass-reinforced epoxy hybrid composites. Composite Structures 152 (2016) 850–859.
- [14] Essabir Hamid, Boujmal Radouane, Bensalah Mohammed Ouadi, Rodrigue Denis, Bouhfid Rachid, Qaiss Abou el kacem. Mechanical and thermal properties of hybrid composites: Oil-palm fiber/clay reinforced high density polyethylene. Mechanics of Materials 98 (2016) 36–43.
- [15] Akpinar Salih, Aydin Murat Demir. 3-D non-linear stress analysis on the adhesively bonded composite joint under bending moment, International Journal of Mechanical Sciences, 81, 149–157(2014).
- [16] Daniel I. M., Abot, J. L.. Fabrication testing and analysis of composite sandwich beams, Composites Science and Technology, 60, 2455–63(2000).
- [17] Camponeschi E.T.. Compression response of thick-section composite materials, Annapolis, USA: David Taylor Research Center, (DTRC-SME-90/60)(1990).
- [18] Sülü İsmail Yasin, Temiz Şemsettin, Aydin Murat Demir. Layer effects of multi-layered face to face adhesively bonded composite pipes subjected to internal pressure, Academic Journal of Science, 04 (03);195–202 (2015).
Year 2016,
Volume: 8 Issue: 4, 87 - 98, 29.12.2016
Abstract
The stress analysis of multi-layered hybrid composite
pipes with symmetrical orientation angles, under internal pressure, was
investigated. The codes of numerical models were created in ANSYS software for
numerical analyses. Two inner surfaces
of first model are E-glass fiber/epoxy and two outer surfaces of its are carbon/epoxy
(AS4/3501-6). Inner surfaces of second model are carbon/epoxy (AS4/3501-6) and
outer surfaces of its are E-glass fiber/epoxy. The problem was studied using a computational tool based on the Finite
Element Method (FEM). Each layer of the composite pipes was examined
with different orientation angles. The
hoop and shear stresses were obtained numerically for each layer. Also, radial,
tangential, axial and shear stresses were determined in the thickness direction
of the composite pipes. The shear extension coupling was considered because the
lay-up angles with [+ θ, – θ]s layers were in the different radii.
References
- [1] Xia M, Takayanagi H, Kemmochi K. Analysis of multi-layered filament-wound composite pipes under internal pressure. Compos Struct 2001;53:483-491.
- [2] Martens M, Ellyin F. Biaxial monotonic behavior of a multidirectional glass fiber epoxy pipe. Compos: Part A - Appl Sci Technol 2000;31:1001–1014.
- [3] Abdul Majid M S, Assaleh T A, Gibson A G, Hale J M, Fahrer A, Rookus C A P, Hekman M. Ultimate elastic wall stress (UEWS) test of glass fibre reinforced epoxy (GRE) pipe. Compos Part A - Appl Sci Technol 2011;42:1500–1508.
- [4] Wakayama Shuichi, Kobayashi Satoshi, Imai Takayuki, Matsumoto Takayuki. Evaluation of burst strength of FW-FRP composite pipes after impact using pitch-based low-modulus carbon fiber. Compos Part A - Appl Sci Technol 2006;37:2002–2010.
- [5] Onder Aziz, Sayman Onur, Dogan Tolga, Tarakcioglu Necmettin. Burst failure load of composite pressure vessels. Compos Struct 2009;89:159–166.
- [6] Kaynak Cevdet, Mat Onur. Uniaxial fatigue behavior of filament-wound glass-fiber/epoxy composite tubes. Compos Sci Technol 2001;61:1833–1840.
- [7] Rousseau J, Perreux D, VerdieÁre N. The influence of winding patterns on the damage behaviour of filament-wound pipes. Compos Sci Technol 1999;59:1439-1449.
- [8] Mertiny P, Ellyin F, Hothan A. An experimental investigation on the effect of multi-angle filament winding on the strength of tubular composite structures. Compos Sci Technol 2004;64:1–9.
- [9] Sayman Onur. Analysis of multi-layered composite cylinders under hygrothermal loading. Compos Part A - Appl Sci Technol 2005;36:923–933.
- [10] Zhao J H, Chen X, Dharani L R, Ji F S. Stress analysis of a multilayered composite cylinder with defects. Theoretical and Appl Fract Mech 2000;34:143-153.
- [11] Arjomandi Kaveh, Taheri Farid. Bending capacity of sandwich pipes. Ocean Eng 2012;48:17–31.
- [12] Tran Phuong, Ngo Tuan D., Ghazlan Abdallah. Numerical modelling of hybrid elastomeric composite panels subjected to blast loadings. Composite Structures 153 (2016) 108–122.
- [13] Ridzuan M.J.M., Majid M.S. Abdul, Afendi M., Mazlee M.N., Gibson A.G.. Thermal behaviour and dynamic mechanical analysis of Pennisetum purpureum/glass-reinforced epoxy hybrid composites. Composite Structures 152 (2016) 850–859.
- [14] Essabir Hamid, Boujmal Radouane, Bensalah Mohammed Ouadi, Rodrigue Denis, Bouhfid Rachid, Qaiss Abou el kacem. Mechanical and thermal properties of hybrid composites: Oil-palm fiber/clay reinforced high density polyethylene. Mechanics of Materials 98 (2016) 36–43.
- [15] Akpinar Salih, Aydin Murat Demir. 3-D non-linear stress analysis on the adhesively bonded composite joint under bending moment, International Journal of Mechanical Sciences, 81, 149–157(2014).
- [16] Daniel I. M., Abot, J. L.. Fabrication testing and analysis of composite sandwich beams, Composites Science and Technology, 60, 2455–63(2000).
- [17] Camponeschi E.T.. Compression response of thick-section composite materials, Annapolis, USA: David Taylor Research Center, (DTRC-SME-90/60)(1990).
- [18] Sülü İsmail Yasin, Temiz Şemsettin, Aydin Murat Demir. Layer effects of multi-layered face to face adhesively bonded composite pipes subjected to internal pressure, Academic Journal of Science, 04 (03);195–202 (2015).
There are 18 citations in total.
Details
| Subjects | Engineering |
|---|---|
| Journal Section | Articles |
| Authors | |
| Publication Date | December 29, 2016 |
| Published in Issue | Year 2016 Volume: 8 Issue: 4 |