Startseite The stiffness modulus in Norway spruce as a function of year ring
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The stiffness modulus in Norway spruce as a function of year ring

  • Tiina Koponen , Timo Karppinen , Edward Hæggström , Pekka Saranpää und Ritva Serimaa
Veröffentlicht/Copyright: 5. Juli 2005
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Abstract

The elastic properties of Norway spruce were studied by means of ultrasound. Samples were from stems that were grown either at a medium- or a high-fertility site in Finland. The stiffness modulus was determined in the longitudinal, radial, and tangential directions as a function of the distance from the pith using 1-mm-thick samples. Tangentially cut samples contained only earlywood, while radially and longitudinally cut samples contained both earlywood and latewood. The stiffness modulus in the longitudinal direction for Norway spruce grown at a medium-fertility site increased with distance from the pith from 6±1 to 8.5±1 GPa. This parameter increased as the mean microfibril angle decreased. In the radial and tangential directions, the stiffness modulus was nearly constant, at 1±0.15 and 0.35±0.04 GPa, respectively. The longitudinal stiffness modulus of fast-growing clonal trees, which contained a large share of juvenile wood and were growing on a fertile site, was ca. 30% smaller (4±1 GPa near the pith and 6±1 GPa at the age of 12 years) than that of trees on a medium-fertility site. No difference was found in the radial and tangential stiffness modulus between stems grown at the two sites.

Keywords: modulus of elasticity; Picea abies; ultra-sound
:
Corresponding author. Department of Physical Sciences, P.O. Box 64, FI-00014 University of Helsinki, Helsinki, Finland

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Published Online: 2005-07-05
Published in Print: 2005-07-01

© Walter de Gruyter Berlin New York

Artikel in diesem Heft

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https://doi.org/10.1515/HF.2005.074
Schlagwörter für diesen Artikel
modulus of elasticity; Picea abies; ultra-sound

Artikel in diesem Heft

  1. Chemical changes in silver birch (Betula pendula Roth) wood caused by hydrogen peroxide bleaching and monitored by color measurement (CIELab) and UV-Vis, FTIR and UVRR spectroscopy
  2. Hydrophobisation and densification of wood by different chemical treatments
  3. Functionalisation of wood by reaction with 3-isocyanatopropyltriethoxysilane: Grafting and hydrolysis of the triethoxysilane end groups
  4. Isolation and fractionation of lignosulfonates by amine extraction and ultrafiltration: A comparative study
  5. Bioactive phenolic substances in industrially important tree species. Part 4: Identification of two new 7-hydroxy divanillyl butyrolactol lignans in some spruce, fir, and pine species
  6. Characterization of physiological functions of sapwood IV: Formation and accumulation of lignans in sapwood of Cryptomeria japonica (L.f.) D. Don after felling
  7. X-ray scattering studies of thermally modified Scots pine (Pinus sylvestris L.)
  8. Differences in acoustic velocity by resonance and transit-time methods in an anisotropic laminated wood medium
  9. Parallel-plate rheology of latex films bonded to wood
  10. An assessment of the feasibility of ultrasound as a defect detector in lumber
  11. Vibrational properties of green wood in high-temperature water vapor
  12. The stiffness modulus in Norway spruce as a function of year ring
  13. Strain analysis in bulk forming of wood
  14. Decay fungi from playground wood products in service using 28S rDNA sequence analysis
  15. Effect of climatic variables on chromated copper arsenate (CCA) leaching during above-ground exposure
  16. Protic ionic liquids with organic anion as wood preservative
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