Vibrational properties of wetwood of todomatsu (Abies sachalinensis) at high temperature

The object of this study was to understand precisely the drying characteristics of wetwood of todomatsu (Abies sachalinensis Mast.). For this purpose, the vibrational properties of wetwood of todomatsu at high temperature were compared with those of normal parts that had lower green moisture content...

Full description

Saved in:
Bibliographic Details
Published inJournal of wood science Vol. 53; no. 2; pp. 134 - 138
Main Authors Ohsaki, H.(Hokkaido. Forest Products Research Inst., Asahikawa (Japan)), Kubojima, Y, Tonosaki, M, Ohta, M
Format Journal Article
LanguageEnglish
Published Heidelberg Springer Nature B.V 01.04.2007
Subjects
ABIES SACHALINENSIS
ACONDICIONADO DE LA MADERA
CALENTAMIENTO
CHAUFFAGE
CONDITIONNEMENT DU BOIS
Cooling
Drying ovens
ELASTICIDAD
ELASTICITE
ELASTICITY
ENSAYOS NO DESTRUCTIVOS
Free vibration
HEATING
High temperature
Modulus of elasticity
Moisture content
NONDESTRUCTIVE TESTING
PROPIEDADES DE LA MADERA
PROPRIETE DU BOIS
TESTAGE NON DESTRUCTIF
VIBRACIONES
VIBRATION
Vibration measurement
Vibration tests
Viscoelasticity
WOOD CONDITIONING
WOOD PROPERTIES
Online AccessGet full text

Cover

More Information
Summary:The object of this study was to understand precisely the drying characteristics of wetwood of todomatsu (Abies sachalinensis Mast.). For this purpose, the vibrational properties of wetwood of todomatsu at high temperature were compared with those of normal parts that had lower green moisture content than the wetwood. Specimens were cut respectively from the wetwood and normal parts, and matched in the radial direction. The specimens and the measuring systems were placed in an electric drying oven and free-free vibration tests were conducted in the oven under absolutely dry conditions. The wetwood and the normal parts were tested separately. The temperature was raised from room temperature to 200°C and then lowered to 50°C in steps of 25°C. The specific Young’s modulus decreased with an increase in temperature during the heating process while it increased with the decreasing temperature during the cooling process. There was no significant difference in the specific Young’s modulus between the wetwood and the normal part at all tested temperatures. The loss tangent took a minimum value at about 100°C in both the heating and cooling processes. There was no significant difference in the loss tangent between the wetwood and the normal part. Thus, the elastic and viscoelastic behaviors of the wetwood appear to be similar to those of the normal part in the temperature range of an actual kiln-drying process.
Bibliography:2007007037
K50
ISSN:1435-0211
1611-4663
DOI:10.1007/s10086-006-0828-x