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Wood Material Science & Engineering Volume 17, 2022 - Issue 6
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Original Articles

Rolling shear properties of cross-laminated timber made of fibre-managed plantation eucalyptus under short-span bending

Azin Ettelaeia Centre for Sustainable Architecture with Wood, University of Tasmania, Launceston, AustraliaCorrespondence[email protected]
ORCID Iconhttps://orcid.org/0000-0002-8409-7596
ORCID Icon,
Assaad Taoumb School of Engineering, College of Sciences and Engineering, University of Tasmania, Hobart, AustraliaORCID Iconhttps://orcid.org/0000-0002-8294-1909
ORCID Icon &
Gregory Nolana Centre for Sustainable Architecture with Wood, University of Tasmania, Launceston, AustraliaORCID Iconhttps://orcid.org/0000-0002-5846-7012
ORCID Icon
Pages 744-751 | Received 27 Apr 2021, Accepted 09 Jun 2021, Published online: 17 Jun 2021

References

  • Aicher, S., Christian, Z. and Hirsch, M. (2016) Rolling shear modulus and strength of beech wood laminations. Holzforschung, 70(8), 773–781. Accessed 9 February 2021, available at: http://www.degruyter.com/view/j/hfsg.2016.70.issue-8/hf-2015-0229/hf-2015-0229.xml
  • American National Standard/The Engineered Wood Association (2012) Standard for performance-rated cross-laminated timber. ANSI/APA PRG, 320-2018.
  • Blackburn, D. P., Hamilton, M. G., Harwood, C. E., Innes, T. C., Potts, B. M. and Williams, D. (2011) Genetic variation in traits affecting sawn timber recovery in plantation-grown Eucalyptus nitens. Annals of Forest Science, 68(7), 1187–1195.
  • Cao, Y., Street, J., Li, M. and Lim, H. (2019) Evaluation of the effect of knots on rolling shear strength of cross-laminated timber (CLT). Construction and Building Materials, 222, 579–587.
  • Derikvand, M., Kotlarewski, N., Lee, M., Jiao, H., Chan, A. and Nolan, G. (2018) Visual stress grading of fibre-managed plantation Eucalypt timber for structural building applications. Construction and Building Materials, 167, 688–699.
  • Derikvand, M., Kotlarewski, N., Lee, M., Jiao, H. and Nolan, G. (2020) Flexural and visual characteristics of fibre-managed plantation Eucalyptus globulus timber. Wood Material Science & Engineering, 15(3), 172–181.
  • Downham, R. and Gavran, M. (2019) Australian plantation statistics 2019 update, Australian Bureau of Agricultural and Resource Economics and Sciences (ABARES), Australian Bureau of Agricultural and Resource Economics and Sciences, Canberra.
  • Dugmore, M., Nocetti, M., Brunetti, M., Naghizadeh, Z. and Wessels, C. B. (2019) Bonding quality of cross-laminated timber: Evaluation of test methods on Eucalyptus grandis panels. Construction and Building Materials, 211, 217–227.
  • Ehrhart, T. and Brandner, R. (2018) Rolling shear: Test configurations and properties of some European soft- and hardwood species. Engineering Structures, 172, 554–572.
  • Ehrhart, T., Brandner, R., Schickhofer, G. and Frangi, A. (2015) Rolling shear properties of some European timber species with focus on cross-laminated timber (CLT): Test configuration and parameter study. In International Network on Timber Engineering Research: Proceedings of Meeting 48. Vol. 2015 (Sibenik, Croatia: Timber Scientific Publishing), pp. 61–76.
  • Espinoza, O. and Buehlmann, U. (2018) Cross-laminated timber in the USA: Opportunity for hardwoods? Current Forestry Reports, 4(1), 1–12.
  • Espinoza, O., Trujillo, V. R., Mallo, M. F. L. and Buehlmann, U. (2016) Cross-laminated timber: Status and research needs in Europe. BioResources, 11(1), 281–295.
  • Fellmoser, P. and Blass, H. J. (2004) Influence of rolling shear modulus on strength and stiffness of structural bonded timber elements. In Proceedings of the International Council for Research and Innovation in Building and Construction - Working Commission W18 - Timber Structures, Meeting Thirty-Seven, Edinburgh, UK.
  • Fink, G., Kohler, J. and Brandner, R. (2018) Application of European design principles to cross laminated timber. Engineering Structures, 171, 934–943.
  • Kaboli, H., Clouston, P. L. and Lawrence, S. (2020) Feasibility of two northeastern species in three-layer ANSI-approved cross-laminated timber. Journal of Materials in Civil Engineering, 32(3), 04020006. Accessed 10 February 2021, available at: http://ascelibrary.org/doi/10. 1061/%28ASCE%29MT.1943-5533.0003058
  • Karacabeyli, E. and Douglas, B. (2013) CLT handbook: Cross-laminated timber, US edition, FPInnovations.
  • Li, M. (2017) Evaluating rolling shear strength properties of cross-laminated timber by short-span bending tests and modified planar shear tests. Journal of Wood Science, 63(4), 331–337. Accessed 25 February 2021, available at: http://link.springer.com/10. 1007/s10086-017-1631-6.
  • Li, M., Dong, W. and Lim, H. (2019) Influence of lamination aspect ratios and test methods on rolling shear strength evaluation of cross-laminated timber. Journal of Materials in Civil Engineering, 31(12), 04019310.
  • Liao, Y., Tu, D., Zhou, J., Zhou, H., Yun, H., Gu, J. and Hu, C. (2017) Feasibility of manufacturing cross-laminated timber using fast-grown small diameter eucalyptus lumbers. Construction and Building Materials, 132, 508–515.
  • Navaratnam, S., Christopher, P. B., Ngo, T. and Le, T. V. (2020) Bending and shear performance of Australian radiata pine cross-laminated timber. Construction and Building Materials, 232, 117215.
  • Nocetti, M., Pröller, M., Brunetti, M., Dowse, G. P. and Wessels, C. B. (2017) Investigating the potential of strength grading green Eucalyptus grandis lumber using multi-sensor technology. BioResources, 12(4), 9273–9286.
  • Nolan, G. B., Greaves, B. L., Washusen, R., Parsons, M. and Jennings, S. (2005) Eucalypt plantations for solid wood products in Australia-A review ‘If you don’t prune it, we can’t use it’.
  • O’Ceallaigh, C., Sikora, K. and Harte, A. (2018) The influence of panel lay-up on the characteristic bending and rolling shear strength of CLT. Buildings, 8(9), 114. Accessed 8 February 2021, available at: http://www.mdpi.com/2075-5309/8/9/114
  • Pangh, H., Hosseinabadi, H. Z., Kotlarewski, N., Moradpour, P., Lee, M. and Nolan, G. (2019) Flexural performance of cross-laminated timber constructed from fibre-managed plantation eucalyptus. Construction and Building Materials, 208, 535–542.
  • Pereira, M. C. D. M. and Calil Junior, C. (2019) Strength and stiffness of cross laminated timber (CLT) panels produced with Pinus and Eucalyptus: Experimental and analytical comparisons. Matéria (Rio de Janeiro), 24(4) ISSN 1517-7076 article e-12519, 2019.
  • Rahman, M. D., Ashraf, M., Ghabraie, K. and Subhani, M. (2020) Evaluating timoshenko method for analyzing CLT under out-of-plane loading. Buildings, 10(10), 184.
  • Ross, R. J. (2010) Wood handbook: wood as an engineering material. Madison, WI: USDA Forest Service, Forest Products Laboratory, General Technical Report FPL-GTR-190, 2010: 509 p. 1 v., 190.
  • Sikora, K. S., McPolin, D. O. and Harte, A. M. (2016) Effects of the thickness of cross-laminated timber (CLT) panels made from Irish Sitka spruce on mechanical performance in bending and shear. Construction and Building Materials, 116, 141–150.
  • Standards Australia (AS) (2010) AS 1720.1:2010 Timber Structures – Part 1: Design methods. AS 1720.1:2010, Sydney, Australia and Wellington, New Zealand.
  • Standards Australia/Standards New Zealand (AS/NZS) (2010) AS/NZS 4063.1:2010 structural timber—characteristic values of strength graded timber. AS/NZS 4063.1:2010, Sydney, Australia and Wellington, New Zealand.
  • Ukyo, S., Shindo, K. and Miyatake, A. (2019) Evaluation of rolling shear modulus and strength of Japanese cedar cross-laminated timber (CLT) laminae. Journal of Wood Science, 65(1), 31. Accessed 8 February 2021, available at: https://jwoodscience.springeropen.com/articles/10. 1186/s10086-019-1810-8.
  • Wang, Z., Zhou, J., Dong, W., Yao, Y. and Gong, M. (2018) Influence of technical characteristics on the rolling shear properties of cross laminated timber by modified planar shear tests. Maderas. Ciencia y tecnología, 20(3), 469–478.
  • Washusen, R., Harwood, C., Morrow, A., Northway, R., Valencia, J. C., Volker, P. and Farrell, R. (2009) Pruned plantation-grown Eucalyptus nitens: Effect of thinning and conventional processing practices on sawn-timber quality and recovery. New Zealand Journal of Forestry Science, 39(1), 39–55.

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