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Vol. 6. Issue 4.
Pages 334-338 (October - December 2017)
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Vol. 6. Issue 4.
Pages 334-338 (October - December 2017)
Original Article
DOI: 10.1016/j.jmrt.2017.06.001
Open Access
Toughness of polyester matrix composites reinforced with sugarcane bagasse fibers evaluated by Charpy impact tests
Verônica Scarpini Candidoa, Alisson Clay Rios da Silvaa, Noan Tonini Simonassib, Fernanda Santos da Luzb, Sergio Neves Monteirob,
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Corresponding author.
a Federal University of Pará (UFPA), Campus Ananindeua, Materials Engineering Faculty, Ananindeua, PA, Brazil
b Military Institute of Engineering (IME), Rio de Janeiro, RJ, Brazil
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The fibers extracted from the sugarcane bagasse have been investigated as possible reinforcement for polymer matrix composites. The use of these composites in engineering applications, associated with conditions such as ballistic armor, requires information on the impact toughness. In the present work, Charpy tests were performed in ASTM standard specimens of polyester matrix composites, reinforced with 10, 20 and 30vol% of continuous and aligned sugarcane bagasse fibers, in order to evaluate the impact energy. Within the standard deviation, the composite absorbed impact energy increased with the volume fraction of sugarcane bagasse fiber. This toughness performance was found by scanning electron microscopy to be associated with the fiber/matrix delamination.

Sugarcane bagasse fiber
Polyester composites
Charpy test
Impact toughness
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In the past decade, a marked interest in natural lignocellulosic fibers obtained from plants as engineering materials has motivated their use as reinforcement of polymer composites [1–6]. The diversity of natural lignocellulosic fiber, which exists worldwide, has raised interest on their properties aiming at replacing strong synthetic fibers such as glass, carbon, nylon and aramid in engineering applications [7–9]. This is of special interest in the case of applying several natural fibers extracted from plants as reinforcement of polymer composites [1,2]. Nowadays these composites are already being used in the automobile industry [2,10,11]. Economical, societal, technical and environmental advantages favor the increase number of research works [5] on natural fiber composites. In particular, the possibility of substituting natural fiber composites for conventional materials made of synthetic fibers, such as Kevlar™, in personal ballistic armor has recently been investigated [12–16]. It was found that mechanisms other than the fiber strength [17] benefit a natural fiber over a synthetic like the aramid in Kevlar™. In principle, in multilayered armor systems, composites might not be reinforced with stronger fibers to equally perform as compared to Kevlar™.

Based on these findings, it was decided to investigate the impact resistance of a composite reinforced with sugarcane bagasse fiber, which is considered a by-product or even a residue of the sugar/ethanol industry [18]. Several works have been dedicated to polymer composites incorporated with sugarcane bagasse both in raw state [19–24] or its extracted fibers (bagasse fiber for short) [25–32]. The tensile strength of these bagasse fibers was found to vary from 26 to 174MPa [33]. It is also worth mentioning that bagasse fiber composites are already industrially applied in automobile components in Brazil [34]. In spite of all these works on bagasse fiber composites, their impact properties have not yet been fully investigated. Therefore, the objective of the present work was to evaluate the notch toughness of polyester matrix composites reinforced with bagasse fibers by means of Charpy impact tests.

2Materials and methods

The bagasse fibers used in this work were collected in commercial places that extract the sugarcane juice by roll-pressing the stalks and dispose the bagasse as residue. The as-collected bagasse was cleaned in running water to remove any remaining sugar. This cleaning procedure was followed by drying in a store at 60°C for 24h. Fibers were then manually extracted from the bagasse and selected for a minimum length of 10cm. Polyester orthophthalic unsaturated resin was hardened with 5wt% of methyl-ethyl-ketone catalyst, both produced by Dow Chemical and supplied by Resinpoxy, Brazil.

Notched impact specimens were molded according to the Charpy configuration as per the ASTM standard [35]. For the molding procedure, aligned bagasse fibers were lay down at the bottom of a 150mm×120mm×10mm steel mold in amounts of 10, 20 and 30vol%. Still fluid polyester resin mixed with catalyst was poured onto the fibers and the mold was closed. A pressure of about 3MPa was applied to the lid of the mold for 24h at room temperature (RT). A second curing stage of 2h at 100°C followed by cutting the composite plate and machining the 2.54mm notch with an angle of 45°, finished the specimen preparation. Control specimens of plain polyester (0vol% fiber) were also fabricated in a similar way as the composites.

Charpy tests were performed at RT according to ASTM standards [35] in a model X-50 Pantec instrumented impact pendulum. After test the broken specimens were macroscopically analyzed and the ruptured surface observed by scanning electron microscopy (SEM) in a model Quanta FEG-250, FEI microscope operating at 20kV.

3Results and discussion

Fig. 1 shows the Charpy impact energy, associated with the notch toughness, of polyester matrix composites incorporated with different volume fraction of bagasse fibers. In this figure, one should notice that the Charpy impact energy, within the standard deviation, continuously increases with the amount of fibers. A mathematical adjustment to the average values of impact energy revealed a linear relationship between the impact energy, Ei, and the volume fraction if fibers, Vf, with a precision of R2=0.91.

In principle, Eq. (1) indicates that higher volume fractions of aligned bagasse fibers would correspond to increasing composite toughness. In other words, despite a relatively weaker strength, the bagasse fiber is able to improve the absorbed impact energy of a polymer composite.

Fig. 1.

Variation of the Charpy impact energy of polyester composites as a function of volume fraction of reinforcing bagasse fibers.


The results in Fig. 1 are, to the best of our knowledge, the first showing the evolution of the impact resistance of a polymer composite with incorporation of bagasse fiber. Tita et al. [36] reported on the impact resistance of phenolic matrix composites incorporated with 70vol% of bagasse fibers. In their work only pure phenolic and 70vol% bagasse fiber-incorporated composites were presented. Thus, it was not possible to have an evolution of the impact resistance. Moreover, much lower values for the impact energy, below 25J/m, were found by Tita et al. [36].

As for the macroscopic fracture, Fig. 2, all specimens were split in two parts after the Charpy hammer impact. The specimen rupture occurred at the notch as required by the standard [35].

Fig. 2.

Macroscopic aspect of impact-tested polyester composites Charpy specimens with different volume fractions of aligned bagasse fibers.


Fig. 3 shows SEM micrographs of the fracture surface of polyester specimens incorporated with different volume fraction of bagasse fibers. All specimens displayed typical brittle fracture, which is a characteristic of the polyester matrix. Indeed, specimen of plain polyester, without bagasse fiber in Fig. 3(a), revealed brittle fracture with river pattern associated with crack propagation. The incorporation of 10vol% of bagasse fiber, Fig. 3(b), is not enough to interfere with the main crack propagation in the brittle polyester matrix. By contrast, incorporation of 20vol%, Fig. 3(c), and 30vol%, Fig. 3(d), displayed evidence of crack arrest by the bagasse fiber, which causes irregular ruptured surfaces of the polyester matrix near the fibers. Moreover, the relatively low adherence of bagasse fiber to the polyester matrix is responsible for fiber pullout and secondary crack propagation at the fiber/matrix interface. As a consequence, a relatively higher fracture area is created and contributes to increase the impact energy [37] as shown in Fig. 1.

Fig. 3.

SEM fractographs of Charpy impact tested: (a) plain polyester, (b) 10vol%, (c) 20vol% and (d) 30vol% sugarcane bagasse fiber reinforced polyester composites.


  • The incorporation of sugarcane bagasse fiber in volume fractions of 10, 20 and 30% into a polyester matrix composites continuously increases the notch toughness of Charpy impact tested composites.

  • The impact energy increase followed a linear relationship and indicates that higher toughness might be attained with increasing volume fraction.

  • The macroscopic aspect of the impact ruptured specimens was brittle and typical of a polyester fracture.

  • The incorporation of bagasse fiber interfered with crack propagation in the polyester matrix and promotes fiber pullout and secondary crack propagation along the fiber/matrix interface.

  • The relatively low interface resistance causes an increase in surface fracture that justifies the increasing impact energy with volume fraction of bagasse fiber.

Conflicts of interest

The authors declare no conflicts of interest.


The authors of the present work wish to thank the Brazilian supporting agencies CAPES, CNPq and FAPERJ.

S.N. Monteiro, F.P.D. Lopes, A.P. Barbosa, A.B. Bevitori, I.L.A. da Silva, L.L. da Costa.
Natural lignocellulosic fibers as engineering materials – an overview.
Metall Mater Trans A, 42 (2011), pp. 2963-2974
Cellulose fibers: bio and nano-polymer composites,
O. Faruk, A.K. Bledzki, H.P. Fink, M. Sain.
Biocomposites reinforced with natural fibers: 2000–2010.
Prog Polym Sci, 37 (2012), pp. 1552-1596
V.K. Thakur, M.K. Thakur.
Processing and characterization of natural cellulose fibers/thermoset polymer composites.
Carbohydr Polym, 109 (2014), pp. 102-117
O. Güven, S.N. Monteiro, E.A.B. Moura, J.W. Drelich.
Re-emerging field of lignocellulosic fiber – polymer composites and ionizing radiation technology in their formulation.
Polym Rev, 56 (2016), pp. 702-736
K.L. Pickering, M.G.A. Efendy, T.M. Le.
A review of recent developments in natural fibre composites and their mechanical performance.
Composites A, 83 (2016), pp. 98-112
P. Wambua, J. Ivens, I. Verpoest.
Natural fibres: can they replace glass in fibre reinforced plastics.
Compos Sci Technol, 63 (2003), pp. 1259-1264
K.G. Satyanarayana, J.L. Guilmarães, F. Wypych.
Studies on lignocellulosic fibers of Brazil. Part I: source, production, morphology, properties and applications.
Composites A, 38 (2007), pp. 1694-1709
S.N. Monteiro, F.P.D. Lopes, A.S. Ferreira, D.C.O. Nascimento.
Natural fiber polymer matrix composites: cheaper, tougher and environmentally friendly.
JOM, 61 (2009), pp. 17-22
J. Holbery, D. Houston.
Natural-fiber-reinforced polymer composites applications in automotive.
JOM, 58 (2006), pp. 80-86
Mercedes-Benz.; 2016 [cited 15.11.16].
R.B. da Cruz, E.P. Lima Jr., S.N. Monteiro, L.H.L. Louro.
Giant bamboo fiber reinforced epoxy composite in multilayered ballistic armor.
Mater Res, 18 (2015), pp. 70-75
S.N. Monteiro, L.H.L. Louro, W. Trindade, C.N. Elias, C.L. Ferreira, E.S. Lima, et al.
Natural curaua fiber-reinforced composites in multilayered ballistic armor.
Metall Mater Trans A, 46 (2015), pp. 4567-4577
L.A. Rohen, F.M. Margem, S.N. Monteiro, C.M.F. Vieira, B.M. Araujo, E.S. Lima.
Ballistic efficiency of an individual epoxy composite reinforced with sisal fibers in multilayered armor.
Mater Res, 18 (2015), pp. 55-62
F.S. da Luz, E.P. Lima Jr., L.H.L. Louro, S.N. Monteiro.
Ballistic test of multilayered armor with intermediate epoxy composite reinforced with jute fabric.
Mater Res, 18 (2015), pp. 170-177
S.N. Monteiro, F.O. Braga, E.P. Lima Jr., L.H.L. Louro, L.C. da Silva, J.W. Drelich.
Promising curaua fiber-reinforced polyester composite.
S.N. Monteiro, E.P. Lima Jr., L.H.L. Louro, L.C. da Silva, J.W. Drelich.
Unlocking function of aramid fibers in multilayered ballistic armor.
Metall Mater Trans A, 46 (2015), pp. 37-40
W. Kiatkittipong, P. Wongsuchoto, P. Pavasant.
Life cycle assessment of bagasse waste management options.
Waste Manag, 29 (2009), pp. 1628-1633
S.N. Monteiro, R.J.S. Rodriguez, M.V. Souza, J.R.M. d’Almeida.
Sugarcane bagasse waste as reinforcement in low cost composites.
Adv Perform Mater, 5 (1998), pp. 183-191
G.C. Stael, M.I.B. Tavares.
Solid-state carbon-13 NMR study of material composites based on sugarcane bagasse and thermoplastics polymers.
J Appl Polym Sci, 81 (2001), pp. 2150-2154
C.G. Mothé, C.R. Araujo, M.A. Oliveira, M.I. Yoshida.
Thermal decomposition kinetics of polyurethane – composites with bagasse of sugarcane.
J Therm Anal Calorim, 67 (2002), pp. 305-312
R.J. Brugnago, J.L. Guimarães, F. Wypych, L.P. Ramos.
The effect of steam explosion on the production of sugarcane bagasse/polyester composites.
Composites A, 42 (2011), pp. 364-370
S. Riyajan, I. Intharit.
Characterization of modified bagasse and investigation properties 16 of its novel composite.
J Elastom Plast, 43 (2011), pp. 513-528
Z. Huang, N. Wang, Y. Zhang, H. Hu, Y. Luo.
Effect of mechanical activation pretreatment on the properties of sugarcane bagasse/poly(vinyl chloride) composites.
Composites A, 43 (2012), pp. 114-120
J.Z. Lu, Q. Wu, I.I. Negulescu, Y. Chen.
The influences of fiber feature and polymer melt index on mechanical properties of sugarcane fiber/polymer composites.
J Appl Polym Sci, 102 (2006), pp. 5607-5619
V. Vilay, M. Mariatti, R. Mattaib, M. Todo.
Effect of fiber surface treatment and fiber loading on the properties of bagasse-fiber reinforced unsaturated polyester composites.
Compos Sci Technol, 68 (2008), pp. 631-638
S.M. Luz, A. Caldeira-Pires, P.M.C. Ferrão.
Environmental benefits of substituting talc by sugarcane bagasse fibers as reinforcement in polypropylene composites: ecodesign and LCA as strategy for automotive components.
Resour Conserv Recycl, 54 (2010), pp. 1135-1144
E.F. Cerqueira, C.A.R.P. Baptista, D.R. Mulinari.
Mechanical behavior of polypropylene reinforced sugarcane bagasse fiber composites.
Eng Proc, 10 (2011), pp. 2046-2051
D. Verma, P.C. Gope, M.K. Maheshwari, R.K. Sharma.
Bagasse fiber composites – a review.
J Mater Environ Sci, 3 (2012), pp. 1079-1092
A. Moubarik, N. Grimi, N. Boussetta.
Structural and thermal characterization of Moroccan sugarcane bagasse cellulose fibers and their applications as a reinforcing agent in low density polyethylene.
Composites B, 52 (2013), pp. 233-238
A.L.B.S. Martins, R.A. Gouvea, M.P. Oliveira, V.S. Candido, S.N. Monteiro.
Characterization of epoxy matrix composites incorporated with sugarcane bagasse fibers.
Mater Sci Forum, 775–776 (2014), pp. 102-106
P.G. de Paula, R.J.S. Rodriguez, L.P.R. Duarte, V.S. Candido, S.N. Monteiro.
Formulation and characterization of polypropylene composites with alkali treated bagasse fiber.
Mater Sci Forum, 775–776 (2014), pp. 319-324
V.S. Candido, M.P. Oliveira, R.A. Gouvea, A.L.B.S. Martins, S.N. Monteiro.
Weibull analysis to characterize the diameter dependence of tensile strength in sugarcane bagasse fibers.
Mater Sci Forum, 775–776 (2014), pp. 80-85
American Society for Testing Materials ASTM D6110.
Standard Test Methods for Determining the Charpy Impact Resistance of Notched Specimens of Plastics.
Pennsylvania, USA
S.P.S. Tita, J.M.F. de Paiva, E. Frollini.
Impact strength and other properties of lignocellulosic composites: phenolic thermoset matrices reinforced with sugarcane bagasse fibers.
Polím Ciênc Tecnol, 12 (2002), pp. 228-239
[in Portuguese]
C.Y. Yue, H.C. Looi, M.Y. Quek.
Assessment of fibre-matrix adhesion and interfacial properties using the pull-out test.
Int J Adhes Adhes, 15 (1995), pp. 73-80

Paper was a contribution part of the 3rd Pan American Materials Congress, February 26th to March 2nd, 2017.

Copyright © 2017. Brazilian Metallurgical, Materials and Mining Association
Journal of Materials Research and Technology

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