1 206

PAPERmaking! Vol8 Nr1 2022

1642

journal of materials research and technology 2021;14:1630 e 1643

407451/2018-8 and ordinance 304106/2017-8). The authors also thank Espac¸o da Escrita e Pr  o-Reitoria de Pesquisa e UNI- CAMP e for the language services provided.

[18] Chen Z, Yan N, Cooper P. Predicting performance of oriented strandboard under concentrated static loading conditions using finite element modeling. Wood Fiber Sci 2008;40:505 e 18. [19] Shrestha D. Shear properties tests of oriented strandboard panels. For Prod J 1999;49:41 e 6. [20] Plenzler R, Ludwiczak-Niewiadomska L, Mielcarek P. Shear and bending properties of structural oriented strand boards osb/4. Wood Res 2013;58:285 e 94. [21] ASTM D 1037. Standard test methods for evaluating properties of Wood-base fiber and particle panel materials. Philadelphia: American Society for Testing Materials; 2012. [22] Zobeiry N, Poursartip A. The origins of residual stress and its evaluation in composite materials. In: Beaumont PWR, Soutis C, Hodzic A, editors. Woodhead publishing series in composites science and engineering, structural integrity and durability of advanced composites. Woodhead Publishing; 2015. p. 43 e 72. [23] Safarabadi M. Evaluation of curing residual stresses in three- phase thin composite laminates considering micro-scale effects. J Compos Mater 2016;50:3753 e 64. [24] Mostafa NH, Ismarrubie ZN, Sapuan SM, Sultan MTH. Fibre prestressed polymer-matrix composites: a review. J Compos Mater 2017;51:39 e 66. [25] Zappino E, Zobeiry N, Petrolo M, Vaziri R, Carrera E, Poursartip A. Analysis of process-induced deformations and residual stresses in curved composite parts considering transverse shear stress and thickness stretching. Compos Struct 2020;241:112057. [26] Smit TC, Reid RG. Residual stress measurement in composite laminates using incremental hole-drilling with power series. Exp Mech 2018;58:1221 e 35. [27] Nairn JA. Predicting layer cracks in cross-laminated timber with evaluations of strategies for suppressing them. Eur. J. Wood Prod 2019;77:405 e 19. [28] Dai J, Xi S, Li D. Numerical analysis of curing residual stress and deformation in thermosetting composite laminates with comparison between different constitutive models. Materials 2019;12:572. https://doi.org/10.3390/ma12040572. [29] Mostafa NH, Ismarrubie ZN, Sapuan SM, Sultan MTH. Fibre prestressed composites: theoretical and numerical modelling of unidirectional and plain-weave fibre reinforcement forms. Compos Struct 2017;159:410 e 23. [30] Clouston P. Characterization and strength modeling of parallel-strand lumber. Holzforschung 2007;61:394 e 9. [31] Winter MB, Muller G. Modeling of orthotropic plates out of cross laminated timber in the mid and high frequency range. Procedia Engineering 2017;199:1392 e 7. [32] Wu Q, Lee JN, Han G. The influence of voids on the engineering constants of oriented strandboard: a finite element model. Wood Fiber Sci 2004;36:71 e 83. [33] Ba ~ no V, Arriaga F, Soil  an A, Guaita M. Prediction of bending load capacity of timber using a finite element method simulation of knots and grain deviation. Biosyst Eng 2011;109:241 e 9. [34] Sandhaas C, Van de Kuilen JWG. Material model for wood. Heron 2013;58:173 e 94. [35] Zhang J, Xu Q, Xu Y, Zhang M. Research on residual bending capacities of used wood members based on the correlation between non-destructive testing results and the mechanical properties of wood. J Zhejiang Univ - Sci 2015;16:541 e 50. [36] Susainathan J, Eyma F, De Luycker E, Cantarel A, Castanie B. Manufacturing and quasi-static bending behavior of wood- based sandwich structures. Compos Struct 2017;182:487 e 504.

references

[1] Archanowicz E, Kowaluk G, Niedzi  nski W, Beer P. Properties of particleboards made of biocomponents from fibrous chips for FEM modeling. BioResources 2013;8:6220 e 30. [2] V € ais € anen T, Das O, Tomppo L. A review on new bio-based constituents for natural fiber-polymer composites. J Clean Prod 2017;149:582 e 96. [3] Dumitrascu A, Lunguleasa A, Salca E, Ciobanu V. Evaluation of selected properties of oriented strand boards made from fast growing wood species. BioResources 2019;15:199 e 210. [4] Barbirato GHA, Lopes Junior WEL, Hellmeister V, Pavesi M, Fiorelli J. OSB Panels with Balsa wood waste and castor oil polyurethane resin. Waste Biomass Valor 2020;11:743 e 51. [5] Bertolini MS, Morais CAG, Lahr FAR, Freire RTS, Panzera TH, Christoforo AL. Particleboards from CCB-treated Pinus sp. Wastes and castor oil resin: morphology analyses and physical e mechanical properties. J Mater Civ Eng 2019;31:05019003. [6] Iwakiri S, Mendes LM, Saldanha LK. Produc¸ ~ ao de chapas de partı´culas orientadas “ osb ” de Eucalyptus gandis com diferentes teores de resina, parafina e composic¸ ~ ao em camadas. Ci ^ encia Florest 2003;13:89 e 94. [7] Mirski R, Dziurka D, Czarnecki R. The possibility of replacing strands in the core layer of oriented strand board by particles from the stems of rape (Brassica napus L. var. napus). BioResources 2016;11:9273 e 9. [8] Shmulsky R, Jones PD. Forest products and wood science: an introduction. Chichester: Wiley-Blackwell; 2011. [9] Thomas WH. Poisson ' s ratios of an oriented strand board. Wood Sci Technol 2003;37:259 e 68. [10] Collins M, Cosgrove T, Mellad A. Characterisation of OSB properties for application in gridshells. Mater Struct 2017;50:131. https://doi.org/10.1617/s11527-017-1005-y. [11] Yang X, Zhao Q, Hao D, Wang J, Fu S, Ma L. Flexural behavior of OSB reinforced wood truss. Wood Res 2020;65:245 e 56. [12] Asdrubali F, Ferracuti B, Lombardi L, Guattari C, Evangelisti L, Grazieschi G. A review of structural, thermo-physical, acoustical, and environmental properties of wooden materials for building applications. Build Environ 2017;114:307 e 32. [13] Fiorelli J, Soriano J, Lahr FAR. Roof modular system in wood and particle board (OSB) to rural construction. Sci Agric 2012;69(3):189 e 93. [14] Wood handbook - wood as an engineering material. General technical report FPL-GTR-190. Madison: Forest Products Laboratory (FPL); 2010. [15] Ferro FS, Souza AM, Araujo II, Almeida MMVN, Christoforo AL, Lahr FAR. Effect of alternative wood species and first thinning wood on oriented strand board performance. Advances in Materials Science and Engineering 2018;2018:4603710. [16] Lunguleasa A, Dumitrascu A-E, Spirchez C, Ciobanu V-D. Influence of the strand characteristics on the properties of oriented strand boards obtained from resinous and broad- leaved fast-growing species. Appl Sci 2021;11:1784. https:// doi.org/10.3390/app11041784. [17] Tackie AD, Wang S, Bennett RM, Shi SQ. Investigation of OSB thickness-swell based on a 3D density distribution. part I. The finite element model. Wood Fiber Sci 2008;40:91 e 102.

Made with FlippingBook - Online magazine maker