Free vibration and buckling analysis of polymeric composite beams reinforced by functionally graded bamboo fibers

doi:10.1007/s10483-024-3090-8

Abstract

Abstract:

Natural fibers have been extensively researched as reinforcement materials in polymers on account of their environmental and economic advantages in comparison with synthetic fibers in the recent years. Bamboo fibers are renowned for their good mechanical properties, abundance, and short cycle growth. As beams are one of the fundamental structural components and are susceptible to mechanical loads in engineering applications, this paper performs a study on the free vibration and buckling responses of bamboo fiber reinforced composite (BFRC) beams on the elastic foundation. Three different functionally graded (FG) layouts and a uniform one are the considered distributions for unidirectional long bamboo fibers across the thickness. The elastic properties of the composite are determined with the law of mixture. Employing Hamilton's principle, the governing equations of motion are obtained. The generalized differential quadrature method (GDQM) is then applied to the equations to obtain the results. The achieved outcomes exhibit that the natural frequency and buckling load values vary as the fiber volume fractions and distributions, elastic foundation stiffness values, and boundary conditions (BCs) and slenderness ratio of the beam change. Furthermore, a comparative study is conducted between the derived analysis outcomes for BFRC and homogenous polymer beams to examine the effectiveness of bamboo fibers as reinforcement materials, demonstrating the significant enhancements in both vibration and buckling responses, with the exception of natural frequencies for cantilever beams on the Pasternak foundation with the FG-◇ fiber distribution. Eventually, the obtained analysis results of BFRC beams are also compared with those for carbon nanotube reinforced composite (CNTRC) beams found in the literature, indicating that the buckling loads and natural frequencies of BFRC beams are lower than those of CNTRC beams.

Key words: bamboo fiber, free vibration, buckling analysis, functionally graded (FG) beam, elastic foundation, generalized differential quadrature method (GDQM)

2010 MSC Number:

74H45

H.M. FEIZABAD, M.H. YAS. Free vibration and buckling analysis of polymeric composite beams reinforced by functionally graded bamboo fibers. Applied Mathematics and Mechanics (English Edition), 2024, 45(3): 543-562.

TrendMD

Figures/Tables 24

Fig. 1

Table 1

Table 2

Table 3

Table 4

Table 5

Table 6

Table 7

Fig. 2

Fig. 3

Fig. 4

Fig. 5

Table 8

Table 9

Table 10

Table 11

Table 12

Table 13

Table 14

Table 15

Table 16

Table 17

Table 18

Table 19

References 48

1	MAHMUD, S., HASAN, K. F., JAHID, M. A., MOHIUDDIN, K., ZHANG, R., and ZHU, J. Comprehensive review on plant fiber-reinforced polymeric biocomposites. Journal of Materials Science, 56, 7231- 7264 (2021)
2	KALUSURAMAN, G., KUMARAN, S. T., BALAMURUGAN, K., SIVASHANMUGAM, N., SIVAPRAKASAM, P., KURNIAWAN, R., and EZHILMARAN, V. Vibration studies on fiber reinforced composites — a review. Journal of Natural Fibers, 20 (1), 2157361 (2023)
3	RADZI, A., ZAKI, S. A., HASSAN, M. Z., ILYAS, R., JAMALUDIN, K. R., DAUD, M. Y. M., and AZIZ, S. A. A. Bamboo-fiber-reinforced thermoset and thermoplastic polymer composites: a review of properties, fabrication, and potential applications. Polymers, 14 (7), 1387 (2022)
4	DIVYA, D., INDRAN, S., and BHARATH, K. N. Bamboo: a potential natural material for bio-composites. Bamboo Fiber Composites: Processing, Properties and Applications, Springer, Singapore, 15–37 (2021)
5	HASAN, K. F., AL HASAN, K. N., AHMED, T., GYÖRGY, S. T., PERVEZ, M. N., BEJÓ, L., SÁNDOR, B., and ALPÁR, T. Sustainable bamboo fiber reinforced polymeric composites for structural applications: a mini review of recent advances and future prospects. Case Studies in Chemical and Environmental Engineering, 8, 100362 (2023)
6	GAO, X., ZHU, D., FAN, S., RAHMAN, M. Z., GUO, S., and CHEN, F. Structural and mechanical properties of bamboo fiber bundle and fiber/bundle reinforced composites: a review. Journal of Materials Research and Technology, 19, 1162- 1190 (2022)
7	LOKESH, P., KUMARI, T. S., GOPI, R., and LOGANATHAN, G. B. A study on mechanical properties of bamboo fiber reinforced polymer composite. Materials Today: Proceedings, 22, 897- 903 (2020)
8	NURIHAN, O., HISHAM, M., RASID, Z., HASSAN, M., and NOR, A. M. The elastic properties of unidirectional bamboo fibre reinforced epoxy composites. International Journal of Recent Technology and Engineering, 8, 7187- 7193 (2019)
9	CHIN, S. C., TEE, K. F., TONG, F. S., ONG, H. R., and GIMBUN, J. Thermal and mechanical properties of bamboo fiber reinforced composites. Materials Today Communications, 23, 100876 (2020)
10	CUI, J., FU, D., MI, L., LI, L., LIU, Y., WANG, C., HE, C., ZHANG, H., CHEN, Y., and WANG, Q. Effects of thermal treatment on the mechanical properties of bamboo fiber bundles. Materials, 16 (3), 1239 (2023)
11	SÁNCHEZ, M. L., PATINO, W., and CARDENAS, J. Physical-mechanical properties of bamboo fibers-reinforced biocomposites: influence of surface treatment of fibers. Journal of Building Engineering, 28, 101058 (2020)
12	YANG, M., WANG, F., ZHOU, S., LU, Z., RAN, S., LI, L., and SHAO, J. Thermal and mechanical performance of unidirectional composites from bamboo fibers with varying volume fractions. Polymer Composites, 40 (10), 3929- 3937 (2019)
13	BANSAL, S., RAMACHANDRAN, M., and RAICHURKAR, P. Comparative analysis of bamboo using jute and coir fiber reinforced polymeric composites. Materials Today: Proceedings, 4 (2), 3182- 3187 (2017)
14	GETU, D., NALLAMOTHU, R. B., MINAYE, G., FENTAW, G., and KASSA, E. Experimental investigation on mechanical and physical properties of bamboo and sisal fiber reinforced hybrid polyester composite. IOP Conference Series: Materials Science and Engineering, 1057, 012007 (2021)
15	SATHISH, S., KUMARESAN, K., PRABHU, L., and VIGNESHKUMAR, N. Experimental investigation on volume fraction of mechanical and physical properties of flax and bamboo fibers reinforced hybrid epoxy composites. Polymers and Polymer Composites, 25 (3), 229- 236 (2017)
16	YU, Y., HUANG, Y., ZHANG, Y., LIU, R., MENG, F., and YU, W. The reinforcing mechanism of mechanical properties of bamboo fiber bundle-reinforced composites. Polymer Composites, 40 (4), 1463- 1472 (2019)
17	CHEN, C., LI, H., DAULETBEK, A., SHEN, F., HUI, D., GAFF, M., LORENZO, R., CORBI, I., CORBI, O., and ASHRAF, M. Properties and applications of bamboo fiber — a current-state-of-the art. Journal of Renewable Materials, 10 (3), 605- 624 (2022)
18	VAN TUYEN, B. Vibration response of bamboo-reinforced composite beams. Journal of Vibration Engineering & Technologies, (2023) doi: 10.1007/s42417-023-00998-2
19	KASIM, F. M., ROSLAN, S., RASID, Z., YAKUB, F., HASSAN, M., and YAHAYA, H. Post-buckling of bamboo reinforced composite plates. IOP Conference Series: Materials Science and Engineering, 1051, 012040 (2021)
20	JENA, P. C. Free vibration analysis of short bamboo fiber based polymer composite beam structure. Materials Today: Proceedings, 5, 5870- 5875 (2018)
21	SENTHILKUMAR, K., PULIKKALPARAMBIL, H., SENTHIL MUTHU KUMAR, T., JEROLD JOHN BRITTO, J., PARAMESWARANPILLAI, J., SIENGCHIN, S., KARTHIKEYAN, S., and RAJINI, N. Free vibration analysis of bamboo fiber-based polymer composite. Bamboo Fiber Composites: Processing, Properties and Applications, Springer, Singapore, 97–110 (2021)
22	ISMAIL, A. S., JAWAID, M., and NAVEEN, J. Void content, tensile, vibration and acoustic properties of kenaf/bamboo fiber reinforced epoxy hybrid composites. Materials, 12 (13), 2094 (2019)
23	SINGH, S. P., DUTT, A., and HIRWANI, C. K. Experimental and numerical analysis of different natural fiber polymer composite. Materials and Manufacturing Processes, 38 (3), 322- 332 (2023)
24	SANTHOSH, N., PRAVEENA, B., SRIKANTH, H., ANGADI, S., GUNGE, A., RUDRA NAIK, M., SHANKAR, G., RAMESHA, K., and RAVICHANDRAN, G. Experimental investigations on static, dynamic, and morphological characteristics of bamboo fiber-reinforced polyester composites. International Journal of Polymer Science, 2022, 1916877 (2022)
25	TAKAGI, H., MORI, H., and NAKAOKA, M. Damping performance of bamboo fibre-reinforced green composites. WIT Transactions on Engineering Sciences, 90, 243- 249 (2015)
26	SINHA, G. P., and KUMAR, B. Review on vibration analysis of functionally graded material structural components with cracks. Journal of Vibration Engineering & Technologies, 9, 23- 49 (2021)
27	SWAMINATHAN, K., NAVEENKUMAR, D., ZENKOUR, A., and CARRERA, E. Stress, vibration and buckling analyses of FGM plates — a state-of-the-art review. Composite Structures, 120, 10- 31 (2015)
28	ZHANG, N., KHAN, T., GUO, H., SHI, S., ZHONG, W., and ZHANG, W. Functionally graded materials: an overview of stability, buckling, and free vibration analysis. Advances in Materials Science and Engineering, 2019, 1354150 (2019)
29	KATILI, I., SYAHRIL, T., and KATILI, A. M. Static and free vibration analysis of FGM beam based on unified and integrated of Timoshenko's theory. Composite Structures, 242, 112130 (2020)
30	LI, S. R., WAN, Z. Q., and ZHANG, J. H. Free vibration of functionally graded beams based on both classical and first-order shear deformation beam theories. Applied Mathematics and Mechanics (English Edition), 35 (5), 591- 606 (2014) doi: 10.1007/s10483-014-1815-6
31	ARMANDEI, M., DARWISH, I. F., and GHAVAMI, K. Experimental study on variation of mechanical properties of a cantilever beam of bamboo. Construction and Building Materials, 101, 784- 790 (2015)
32	MURIN, J., AMINBAGHAI, M., HRABOVSKY, J., GOGOLA, R., and KUGLER, S. Beam finite element for modal analysis of FGM structures. Engineering Structures, 121, 1- 18 (2016)
33	KARAMANLI, A. Free vibration analysis of two directional functionally graded beams using a third order shear deformation theory. Composite Structures, 189, 127- 136 (2018)
34	ZHANG, Z., LI, Y., WU, H., ZHANG, H., WU, H., JIANG, S., and CHAI, G. Mechanical analysis of functionally graded graphene oxide-reinforced composite beams based on the first-order shear deformation theory. Mechanics of Advanced Materials and Structures, 27 (1), 3- 11 (2020)
35	SONG, M., GONG, Y., YANG, J., ZHU, W., and KITIPORNCHAI, S. Free vibration and buckling analyses of edge-cracked functionally graded multilayer graphene nanoplatelet-reinforced composite beams resting on an elastic foundation. Journal of Sound and Vibration, 458, 89- 108 (2019)
36	MOHAMMADIMEHR, M., MONAJEMI, A., and AFSHARI, H. Free and forced vibration analysis of viscoelastic damped FG-CNT reinforced micro composite beams. Microsystem Technologies, 26, 3085- 3099 (2020)
37	HEIDARI, M., and ARVIN, H. Nonlinear free vibration analysis of functionally graded rotating composite Timoshenko beams reinforced by carbon nanotubes. Journal of Vibration and Control, 25 (14), 2063- 2078 (2019)
38	YAS, M. H., and MOLOUDI, N. Three-dimensional free vibration analysis of multi-directional functionally graded piezoelectric annular plates on elastic foundations via state space based differential quadrature method. Applied Mathematics and Mechanics (English Edition), 36 (4), 439- 464 (2015) doi: 10.1007/s10483-015-1923-9
39	SHI, Z., YAO, X., PANG, F., and WANG, Q. An exact solution for the free-vibration analysis of functionally graded carbon-nanotube-reinforced composite beams with arbitrary boundary conditions. Scientific Reports, 7 (1), 12909 (2017)
40	YAS, M. H., and RAHIMI, S. Thermal vibration of functionally graded porous nanocomposite beams reinforced by graphene platelets. Applied Mathematics and Mechanics (English Edition), 41 (8), 1209- 1226 (2020) doi: 10.1007/s10483-020-2634-6
41	MALLICK, P. K. Fiber-Reinforced Composites: Materials, Manufacturing, and Design, CRC Press, Boca Raton (2007)
42	REDDY, J. N. Mechanics of Laminated Composite Plates and Shells: Theory and Analysis, CRC Press, Boca Raton (2003)
43	SHU, C. Differential Quadrature and Its Application in Engineering, Springer Science & Business Media, Berlin (2000)
44	SHU, C., and DU, H. Implementation of clamped and simply supported boundary conditions in the GDQ free vibration analysis of beams and plates. International Journal of Solids and Structures, 34 (7), 819- 835 (1997)
45	BERT, C. W., and MALIK, M. Differential quadrature method in computational mechanics: a review. Applied Mechanics Reviews, 49 (1), 1- 28 (1996)
46	YAN, T., KITIPORNCHAI, S., YANG, J., and HE, X. Q. Dynamic behaviour of edge-cracked shear deformable functionally graded beams on an elastic foundation under a moving load. Composite Structures, 93 (11), 2992- 3001 (2011)
47	KE, L. L., YANG, J., KITIPORNCHAI, S., and XIANG, Y. Flexural vibration and elastic buckling of a cracked Timoshenko beam made of functionally graded materials. Mechanics of Advanced Materials and Structures, 16 (6), 488- 502 (2009)
48	YAS, M. H., and SAMADI, N. Free vibrations and buckling analysis of carbon nanotube-reinforced composite Timoshenko beams on elastic foundation. International Journal of Pressure Vessels and Piping, 98, 119- 128 (2012)

[1]	Xiaoyang SU, Tong HU, Wei ZHANG, Houjun KANG, Yunyue CONG, Quan YUAN. Transfer matrix method for free and forced vibrations of multi-level functionally graded material stepped beams with different boundary conditions [J]. Applied Mathematics and Mechanics (English Edition), 2024, 45(6): 983-1000.
[2]	S. JAHANGIRI, A. GHORBANPOUR ARANI, Z. KHODDAMI MARAGHI. Dynamics of a rotating ring-stiffened sandwich conical shell with an auxetic honeycomb core [J]. Applied Mathematics and Mechanics (English Edition), 2024, 45(6): 963-982.
[3]	Xiaodong GUO, Zhu SU, Lifeng WANG. Dynamic characteristics of multi-span spinning beams with elastic constraints under an axial compressive force [J]. Applied Mathematics and Mechanics (English Edition), 2024, 45(2): 295-310.
[4]	Zhi LI, Cuiying FAN, Mingkai GUO, Guoshuai QIN, Chunsheng LU, Dongying LIU, Minghao ZHAO. Natural frequency analysis of laminated piezoelectric beams with arbitrary polarization directions [J]. Applied Mathematics and Mechanics (English Edition), 2024, 45(11): 1949-1964.
[5]	A. RAHMANI, S. FAROUGHI, M. SARI. On wave dispersion of rotating viscoelastic nanobeam based on general nonlocal elasticity in thermal environment [J]. Applied Mathematics and Mechanics (English Edition), 2023, 44(9): 1577-1596.
[6]	Xueqian FANG, Qilin HE, Hongwei MA, Changsong ZHU. Multi-field coupling and free vibration of a sandwiched functionally-graded piezoelectric semiconductor plate [J]. Applied Mathematics and Mechanics (English Edition), 2023, 44(8): 1351-1366.
[7]	U. N. ARIBAS, M. AYDIN, M. ATALAY, M. H. OMURTAG. Cross-sectional warping and precision of the first-order shear deformation theory for vibrations of transversely functionally graded curved beams [J]. Applied Mathematics and Mechanics (English Edition), 2023, 44(12): 2109-2138.
[8]	Pei ZHANG, P. SCHIAVONE, Hai QING. Dynamic stability analysis of porous functionally graded beams under hygro-thermal loading using nonlocal strain gradient integral model [J]. Applied Mathematics and Mechanics (English Edition), 2023, 44(12): 2071-2092.
[9]	Changsong ZHU, Xueqian FANG, Jinxi LIU. Nonlinear free vibration of piezoelectric semiconductor doubly-curved shells based on nonlinear drift-diffusion model [J]. Applied Mathematics and Mechanics (English Edition), 2023, 44(10): 1761-1776.
[10]	Lingkang ZHAO, Peijun WEI, Yueqiu LI. Free vibration of thermo-elastic microplate based on spatiotemporal fractional-order derivatives with nonlocal characteristic length and time [J]. Applied Mathematics and Mechanics (English Edition), 2023, 44(1): 109-124.
[11]	Pei ZHANG, P. SCHIAVONE, Hai QING. Unified two-phase nonlocal formulation for vibration of functionally graded beams resting on nonlocal viscoelastic Winkler-Pasternak foundation [J]. Applied Mathematics and Mechanics (English Edition), 2023, 44(1): 89-108.
[12]	Zhaonian LI, Juan LIU, Biao HU, Yuxing WANG, Huoming SHEN. Wave propagation analysis of porous functionally graded piezoelectric nanoplates with a visco-Pasternak foundation [J]. Applied Mathematics and Mechanics (English Edition), 2023, 44(1): 35-52.
[13]	Qingdong CHAI, Yanqing WANG, Meiwen TENG. Nonlinear free vibration of spinning cylindrical shells with arbitrary boundary conditions [J]. Applied Mathematics and Mechanics (English Edition), 2022, 43(8): 1203-1218.
[14]	M. H. YAS, F. AKHLAGHI, S. KAMARIAN, A. H. YAS. Static and free vibration analysis of four-parameter continuous grading elliptical sandwich plates [J]. Applied Mathematics and Mechanics (English Edition), 2022, 43(4): 523-536.
[15]	Chi XU, Yang LI, Mingyue LU, Zhendong DAI. Buckling analysis of functionally graded nanobeams under non-uniform temperature using stress-driven nonlocal elasticity [J]. Applied Mathematics and Mechanics (English Edition), 2022, 43(3): 355-370.