[KSCI] Korea Science Citation Index Service

Study on Physical Properties of Domestic Species III: Sorption, Thermal, Electrical and Acoustic properties of Liriodendron tulipifera, Betula costata, Paulownia coreana

Lee, Won-Hee (College of Agriculture and Life Science, Kyungpook National University)
Park, Byung-Soo (Forest Products Division, Korea Forest Research Institute,)
Chong, Sung-Ho (Forest Products Division, Korea Forest Research Institute,)
Kang, Ho-Yang (College of Agriculture. Chungnam National University)
Hwang, Kwon-Hwan (Forest Products Division, Korea Forest Research Institute,)
Byeon, Hee-Seop (College of Agriculture and Life Science, IALS, Gyeongsang National University)

Publication Information

Journal of the Korean Wood Science and Technology / v.36, no.6, 2008 , pp. 1-12 More about this Journal

Abstract

A series of the studies on the applied physical properties of domestic species have been conducted last three years. Liriodendron tulipifera, Betula costata, Paulownia coreana were examined on sorption property, thermal property, electric property, acoustic property. Because the same apparatus and experimental procedures were used for all species, their results can be easily comparable. The experiments for sorption property were conducted with 80 mesh wood powder and resulted in their EMC's and sorption isotherms. The thermal conductivity and diffusivity, and electric resistance and volumetric electric resistivity were measured with a thermal-wire device and a high electric resistance meter. The differences of the thermal and electric properties between quarter-and flat-sawn specimens were observed, which was partially attributed to their anatomical differences. An acoustic measurement system was used to evaluate dynamic MOE and internal friction. This paper provides the useful fundamental data for designing a wood structure, correcting a portable resistance-type moisture meter, and acoustic properties of wood.

Keywords

Liriodendron tulipifera; Betula costata; Paulownia coreana; sorption isotherm; thermal conductivity; thermal diffusivity; electric volume resistivity; electric resistance; acoustic property; dynamic MOE; internal friction;

Citations & Related Records

Times Cited By KSCI : 1 (Citation Analysis)

Reference
Cited By KSCI

1	Chirkova, J., I. Irbe, B. Andersons, and I. Andersone. 2006. Study of the structure of biodegraded wood using the water vapour sorption method. International Biodeterioration & Biodegradation. 58: 162-167. DOI ScienceOn
2	Kataoka, A. and T. Ono. 1976. The dynamic mechanical properties of Sitka spruce used for sounding boards. J. Japan Wood Res. 22(8): 436-443.
3	Suleiman, B. M., J. Larfeldt, B. Leckner, and M. Gustavsson. 1999. Thermal conductivity and diffusivity of wood. Wood Science and Technology 33: 465-473. DOI
4	岡野健. 1991. 木材の音響的性質. 木材學會誌. 37(11): 991-998.
5	矢野浩之, 山田一正. 1989. ピアノ響板用シトカスプルース材放射方向の音響特性. 木材學會誌. 31(3): 222-230.
6	변희섭, 강호양, 이원희, 박병수, 정성호, 박정환. 2008. 국산재의 응용물성연구 II: 잣나무 낙엽송의 수분흡착성 및 열적.전기적.음향적 성질. 목재공학 36(4): 1-10.
7	변희섭, 홍병화. 1997. 피아노향판용 아가티스재의 동역학적 성질. 한국가구학회지. 8(1/2): 10-15.
8	정우양, 박선행. 1999. 바이올린용 소재의 진동모드해석에 관한연구-절삭방향 및 밀도에 따른 공진주파수의 변화. 목재공학. 27(3): 1-6.
9	홍병화. 1985. 響板用 오동나무재의 動力學的性質. 목재공학. 13(3): 34-40.
10	Brunauer, S., P. H. Emmett, and E. Teller, 1938. J. Amer. chem. Soc. 60, 309-319. DOI
11	Bucur, V. 1995. Acoustic of Wood. CRC Press. pp. 14-44.
12	Rice, Robert, W. and R. K. Shepard 2004. The thermal conductivity of plantation grown white pine (Pinus strobus) and red pine (Pinus resinosa) at two moisture content levels. Forest Products Journal 54(1): 92-94.
13	矢野浩之, 松岡一郞, 椋代純輔. 1992. バイオリン用材の音響的性質. 木材學會誌. 38(2): 122-127.
14	강호양, 변희섭, 이원희, 박병수, 박정환. 2008. 국산재의 응용물성연구 I: 소나무의 수분흡착성 및 열적.전기적.음향적 성질. 목재공학 36(3): 70-84.
15	Gillis, Christopher M., W. Stephens, and P. Peralta. 2001. Moisture meter correction factors for four Brazilian wood species. Forest Products Journal 51(4): 83-86.
16	Norimoto, M. 1982. Structure and properties of wood used for musical instruments I (On the selection of wood used for piano sound boards). J. Japan Wood Res. Soc. 28(7): 407-413.
17	Olek, W., J. Weres, and R. Guzenda. 2003. Effects of Thermal Conductivity Data on Accuracy of Modeling Heat Transfer in Wood. Holzforschung 57(3): 317-325. DOI ScienceOn