Abstract
As an effect of changing forest management—away from softwood monocultures to more robust mixed stands—the availability of hardwood on the European timber market increases. Thus, a more diversified spectrum of hardwood products is required between the established uses in furniture and energy production. Glued timber products are a promising option in this respect. One important prerequisite for efficiently producing glued hardwood products is to establish hardwood strength grading. To this end, the current paper explored the potential of microwave scanning, stand-alone or combined with the measurement of dynamic stiffness, to estimate the tension strength of ash, beech, sweet chestnut and oak lamellas. In this preliminary study, combining microwave and dynamic stiffness measurement showed much potential for hardwood strength grading for all four species; for beech and sweet chestnut, coefficients of determination (\({r}^{2}\)) beyond 60% could be achieved, which is on a level with established softwood grading principles. For ash and oak, \({r}^{2}\approx 45\%\) was observed, which is acceptable for machine strength grading. The paper also considered measuring density using microwaves. Such a density measurement was found to be as accurate for hardwoods as for softwoods.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Aichholzer A, Arthaber H, Schuberth C, Mayer H (2013) Non-destructive evaluation of grain angle, moisture content and density of spruce with microwaves. Eur J Wood Prod 71(6):779–786. https://doi.org/10.1007/s00107-013-0740-1
Anon (2011) IBM SPSS statistics 20 algorithms. http://public.dhe.ibm.com/software/analytics/spss/documentation/statistics/20.0/en/client/Manuals/IBM_SPSS_Statistics_Algorithms.pdf. Accessed 25 Jan 2019
Bacher M (2008) Comparison of different machine strength grading principles. In: Gard WF, van de Kuilen JG (eds) End user’s needs for wood material and products. In: Proceedings of the conference in COST E53 quality control for wood and wood products, pp 183–193 http://www.coste53.net/downloads/Delft/Presentations/COSTE53-Conference_Delft_Bacher.pdf. Accessed 25 Jan 2019
BMEL (2016) Ergebnisse der Bundeswaldinventur 2012 (Results of the federal forest inventory 2012) (In German), Berlin. https://www.bmel.de/SharedDocs/Downloads/Broschueren/Wald-Rohholzpotential-40Jahre.pdf. Accessed 21 Jan 2019
BMEL (2017) Wald und Rohholzpotenzial der nächsten 40 Jahre: Ausgewählte Ergebnisse der Waldentwicklungs- und Holzaufkommensmodellierung 2013 bis 2052 (Forest and raw material potential for the next 40 years: selected results of modelling forest development and timber production 2013–2052) (In German), Berlin. https://www.bmel.de/SharedDocs/Downloads/Broschueren/ErgebnisseBWI2012.pdf. Accessed 21 Jan 2019
Boström L (1994) Machine strength grading. Comparison of four different systems. SP Report nr. (1994:49). http://www.diva-portal.org/smash/get/diva2:961864/FULLTEXT01.pdf. Accessed 25 Jan 2019
Canty A, Ripley BD (2017) boot: Bootstrap R (S-Plus) Functions. R package version 1.3–20. https://cran.r-project.org/web/packages/boot/. Accessed 25 Jan 2019
Daval V, Pot G, Belkacemi M, Meriaudeau F, Collet R (2015) Automatic measurement of wood fiber orientation and knot detection using an optical system based on heating conduction. Opt Express 23(26):33529–33539. https://doi.org/10.1364/OE.23.033529
Denzler JK, Weidenhiller A (2014) New perspectives in machine strength grading: or how to identify a top rupture. In: Aicher S, Reinhardt H, Garrecht H (eds) Materials and joints in timber structures, vol 9. Springer, Netherlands, pp 761–771
Denzler JK, Weidenhiller A (2015) Microwave scanning as an additional grading principle for sawn timber. Eur J Wood Prod 73(4):423–431. https://doi.org/10.1007/s00107-015-0906-0
Denzler JK, Koppensteiner J, Arthaber H (2013) Grain angle detection on local scale using microwave transmission. Int Wood Prod J 4(2):68–74. https://doi.org/10.1179/2042645313Y.0000000030
Denzler JK, Lux C, Arthaber H (2014) Contactless moisture content and density evaluation of sawn timber using microwave transmission. Int Wood Prod J 5(4):200–206. https://doi.org/10.1179/2042645314Y.0000000066
Diebold R, Schleifer A, Glos P (2000) Machine grading of structural sawn timber from various softwood and hardwood species. In: Proceedings of the 12th International Symposium on Nondestructive Testing of Wood University of Western Hungary, Sopron, 13–15 September 2000
Ehrhart T, Fink G, Steiger R, Frangi A (2016) Experimental investigation of tensile strength and stiffness indicators regarding European Beech timber. In: Eberhardsteiner J, Winter W, Fadai A (eds) WCTE 2016 e-book (Proceedings of the 2016 world conference on timber engineering, 22–25 August 2016, Vienna, Austria), pp 600–607 (ISBN 9783903024359)
Ehrhart T, Steiger R, Frangi A (2018) A non-contact method for the determination of fibre direction of European beech wood (Fagus sylvatica L.). Eur J Wood Prod 76(3):925–935. https://doi.org/10.1007/s00107-017-1279-3
EN 14081-2 (2012) Timber structures—strength graded structural timber with rectangular cross section. Part 2: machine grading—additional requirements for initial type testing (EN 14081-2:2010 + A1:2012-11). https://shop.austrian-standards.at/action/en/public/details/462133/OENORM_EN_14081-2_2013_01_15. Accessed 25 Jan 2019
EN 384 (2010) Structural timber—determination of characteristic values of mechanical properties and density. https://shop.austrian-standards.at/action/en/public/details/362300/OENORM_EN_384_2010_05_15. Accessed 25 Jan 2019
EN 408 (2012) Timber structures—structural timber and glued laminated timber—determination of some physical and mechanical properties (EN 408:2010 + A1:2012-07). https://shop.austrian-standards.at/action/en/public/details/448783/DIN_EN_408_2012_10. Accessed 25 Jan 2019
Firmanti A, Bachtiar ET, Surjokusumo S, Komatsu K, Kawai S (2005) Mechanical stress grading of tropical timbers without regard to species. J Wood Sci 51(4):339–347. https://doi.org/10.1007/s10086-004-0661-z
Gil-Moreno D, Ridley-Ellis DJ (2015) Comparing usefulness of acoustic measurements on standing trees for segregation by timber stiffness. In: Ross RJ, Gonçalves R, Wang X (eds) Proceedings: 19th international nondestructive testing and evaluation of wood symposium, pp 378–385. https://www.napier.ac.uk/research-and-innovation/research-search/outputs/comparing-usefulness-of-acoustic-measurements-on-standing-trees-for-segregation-by-timber-1. Accessed 25 Jan 2019
Hanhijärvi A, Ranta-Maunus A (2008) Development of strength grading of timber using combined measurement techniques. Report of the Combigrade-project—phase 2. https://www.vtt.fi/inf/pdf/publications/2008/P686.pdf. Accessed 25 Jan 2019 (ISBN 978-951-38-7106-2)
Hunger F, van de Kuilen JG (2018) Slope of grain measurement: a tool to improve machine strength grading by detecting top ruptures. Wood Sci Technol 52(3):821–838. https://doi.org/10.1007/s00226-018-1000-7
IGN (2014) Résultats d’inventaire forestier—Résultats standards (campagnes 2009 à 2013) (standardized results of the forest inventory (campaigns 2009–2013)): Tome national version régions administratives, Saint-Mandé, France (In French). https://inventaire-forestier.ign.fr/IMG/pdf/RS_0913_FR_RA.pdf. Accessed 25 Jan 2019
Kandler G, Lukacevic M, Füssl J (2016) An algorithm for the geometric reconstruction of knots within timber boards based on fibre angle measurements. Constr Build Mater 124:945–960. https://doi.org/10.1016/j.conbuildmat.2016.08.001
Kollmann F, Cote WA Jr (1984) Principles of wood science and technology, reprint. Springer, Berlin
Koppensteiner J, Denzler JK, Weidenhiller A, Arthaber H, Leder N (2017) Method and apparatus for estimating the projection on a reference plane of the direction of extension of the fibres of a portion of a wooden plank (EP2829876 (B1))
Kretschmann DE, Green DW (1999) Mechanical grading of oak timbers. J Mater Civ Eng 11(2):91–97. https://doi.org/10.1061/(ASCE)0899-1561(1999)11:2(91)
Lukacevic M, Füssl J, Eberhardsteiner J (2015) Discussion of common and new indicating properties for the strength grading of wooden boards. Wood Sci Technol 49(3):551–576. https://doi.org/10.1007/s00226-015-0712-1
Lundgren N, Brännström M, Hagman O, Oja J (2007) Predicting the strength of norway spruce by microwave scanning: a comparison with other scanning techniques. Wood Fiber Sci 39(1):167–172
Nocetti M, Brunetti M, Bacher M (2016) Efficiency of the machine grading of chestnut structural timber: prediction of strength classes by dry and wet measurements. Mater Struct 49(11):4439–4450. https://doi.org/10.1617/s11527-016-0799-3
Nyström J (2003) Automatic measurement of fiber orientation in softwoods by using the tracheid effect. Comput Electron Agric 41(1–3):91–99. https://doi.org/10.1016/S0168-1699(03)00045-0
Olsson A, Oscarsson J, Serrano E, Källsner B, Johansson M, Enquist B (2013) Prediction of timber bending strength and in-member cross-sectional stiffness variation on the basis of local wood fibre orientation. Eur J Wood Prod 71(3):319–333. https://doi.org/10.1007/s00107-013-0684-5
R Core Team (2018) R: A Language and Environment for Statistical Computing. https://www.R-project.org/. Accessed 25 Jan 2019
Ravenshorst GJP (2015) Species independent strength grading of structural timber. Dissertation Thesis, Technische Universiteit Delft
Şahin Kol H, Yalçın İ (2015) Predicting wood strength using dielectric parameters. BioResour. https://doi.org/10.15376/biores.10.4.6496-6511
Schajer GS, Orhan FB (2005) Microwave non-destructive testing of wood and similar orthotropic materials. Subsurf Sens Technol Appl 6(4):293–313. https://doi.org/10.1007/s11220-005-0014-z
Schajer GS, Orhan FB (2006) Measurement of wood grain angle, moisture content and density using microwaves. Holz Roh Werkst 64(6):483–490. https://doi.org/10.1007/s00107-006-0109-9
Schlotzhauer P, Wilhelms F, Lux C, Bollmus S (2018) Comparison of three systems for automatic grain angle determination on European hardwood for construction use. Eur J Wood Prod 76(3):911–923. https://doi.org/10.1007/s00107-018-1286-z
Torgovnikov GI (1993) Dielectric properties of wood and wood-based materials. Springer series in wood science. Springer-Verlag, Berlin
van de Kuilen JG, Torno S (2014) Materialkennwerte von Eschenholz für den Einsatz in Brettschichtholz: Schlussbericht zum Vorhaben [Material characteristics of ash timber for use in glue laminated timber: final report], Munich
Vega A, Dieste A, Guaita M, Majada J, Baño V (2012) Modelling of the mechanical properties of Castanea sativa Mill. structural timber by a combination of non-destructive variables and visual grading parameters. Eur J Wood Prod 70(6):839–844. https://doi.org/10.1007/s00107-012-0626-7
Viguier J, Jehl A, Collet R, Bleron L, Meriaudeau F (2015) Improving strength grading of timber by grain angle measurement and mechanical modeling. Wood Mater Sci Eng 10(1):145–156. https://doi.org/10.1080/17480272.2014.951071
Wang X (2013) Acoustic measurements on trees and logs: a review and analysis. Wood Sci Technol 47(5):965–975. https://doi.org/10.1007/s00226-013-0552-9
Zhou J, Shen J (2003) Ellipse detection and phase demodulation for wood grain orientation measurement based on the tracheid effect. Opt Lasers Eng 39(1):73–89. https://doi.org/10.1016/S0143-8166(02)00041-6
Acknowledgements
This study was conducted in the scope of the WoodWisdom-Net project European hardwoods for the building sector (EU Hardwoods) which was financed by Fachagentur Nachwachsende Rohstoffe e.V. (FNR) under grant number 22004114 in Germany and Bundesministerium für Land- und Forstwirtschaft, Umwelt und Wasserwirtschaft (BMLFUW) under grant number 101003 in Austria.
Author information
Authors and Affiliations
Corresponding author
Additional information
Publisher’s Note
Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Rights and permissions
About this article
Cite this article
Weidenhiller, A., Linsenmann, P., Lux, C. et al. Potential of microwave scanning for determining density and tension strength of four European hardwood species. Eur. J. Wood Prod. 77, 235–247 (2019). https://doi.org/10.1007/s00107-019-01387-x
Received:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s00107-019-01387-x