1 강춘원, "충남 홍성지역에서 자란 비목나무(Lindera erythrocarpa)의 열기건조스케쥴 개발" 한국목재공학회 46 (46): 10-16, 2018
2 장윤성, "국산 참나무류의 이용활성화를 위한 건조특성 및 가공수율 평가" 한국목재공학회 45 (45): 622-628, 2017
3 Siau, J., "Wood influence of water on physical properties" Virginia Polytechnic Institute and State University 1995
4 Okoh, E. T, "Water absorption properties of some tropical timber species" 3 (3): 20-24, 2014
5 Batista, D. C., "Volume loss as a tool to assess kiln drying of Eucalyptus Wood" 20 (20): 250-256, 2013
6 Wessels, C. B., "Variation in physical and mechanical properties from three drought tolerant Eucalyptus species grown on the dry West coast of Southern Africa" 74 : 563-575, 2016
7 Famiri, A., "Sawing and growth stresses in green wood of Eucalyptus grandis & E. gomphocephala" 1 (1): 45-50, 2001
8 Sandoval-Torres, S., "Numerical simulation of warm-air drying of Mexican softwood(Pinus pseudostrobus) : An empirical and mechanistic approach" 28 : 125-133, 2014
9 Franke, B., "Moisture diffusion in wood–Experimental and numerical investigations" 1-8, 2016
10 Bennani, L., "Modelling the absorption process of water in wood in the transient regime" 15 (15): 137-147, 2017
1 강춘원, "충남 홍성지역에서 자란 비목나무(Lindera erythrocarpa)의 열기건조스케쥴 개발" 한국목재공학회 46 (46): 10-16, 2018
2 장윤성, "국산 참나무류의 이용활성화를 위한 건조특성 및 가공수율 평가" 한국목재공학회 45 (45): 622-628, 2017
3 Siau, J., "Wood influence of water on physical properties" Virginia Polytechnic Institute and State University 1995
4 Okoh, E. T, "Water absorption properties of some tropical timber species" 3 (3): 20-24, 2014
5 Batista, D. C., "Volume loss as a tool to assess kiln drying of Eucalyptus Wood" 20 (20): 250-256, 2013
6 Wessels, C. B., "Variation in physical and mechanical properties from three drought tolerant Eucalyptus species grown on the dry West coast of Southern Africa" 74 : 563-575, 2016
7 Famiri, A., "Sawing and growth stresses in green wood of Eucalyptus grandis & E. gomphocephala" 1 (1): 45-50, 2001
8 Sandoval-Torres, S., "Numerical simulation of warm-air drying of Mexican softwood(Pinus pseudostrobus) : An empirical and mechanistic approach" 28 : 125-133, 2014
9 Franke, B., "Moisture diffusion in wood–Experimental and numerical investigations" 1-8, 2016
10 Bennani, L., "Modelling the absorption process of water in wood in the transient regime" 15 (15): 137-147, 2017
11 Baronas, R., "Modelling of moisture movement in wood during outdoor storage" 6 (6): 3-14, 2001
12 Noorolahi, S., "Modeling Cyclic water absorption and desorption characteristics of three varieties of wood. Tokyo, Japan" 13-22, 2008
13 Houngan, C. A., "Mass diffusivity determination of Teak wood (Tectona grandis) used as building material" 127 : 201-207, 2015
14 김현빈, "Finite Difference Evaluation of Moisture Profile in Boxed-heart Large-cross-section Square Timber of Pinus densiflora during High Temperature Drying" 한국목재공학회 45 (45): 762-771, 2017
15 Jannot, Y., "Experimental determination and modelling of water desorption isotherms of tropical woods: afzelia, ebony, iroko, moabi and obeche" 64 : 121-124, 2006
16 Hakam, A., "Eucalyptus wood drying" 123 : 327-330, 2005
17 Travan, L., "Eucalyptus drying process: qualitative comparison of different clones cultivated in Italy. Edinburgh, UK" 57-70, 2010
18 Maziri, A., "Etude des contraintes de croissance chez l’Eucalyptus camaldulensis et leur relation avec les fentes d’abattage" 53 : 15-21, 2010
19 Ghazil, A., "Etude de la migration des fluides dans le bois" Université Henri Poincaré 2010
20 방성준, "Effects of Density, Temperature, Size, Grain Angle of Wood Materials on Nondestructive Moisture Meters" 한국목재공학회 47 (47): 40-50, 2019
21 Kouchadé, A. C., "Détermination en routine de la diffusivité massique dans le bois par méthode inverse à partir de la mesure électrique en régime transitoire" Ecole Nationale du génie Rural des Eaux et des Forets 2004
22 Kantay, R., "Drying problems of fast growing tree species: Evaluation of Maritime pine (Pinus pinaster Ait) and Eucalyptus (Eucalyptus camaldulensis Dehn) wood. Izmit-Turkey" 208-212, 2002
23 이정민, "Dimensional Stabilization through Heat Treatment of Thermally Compressed Wood of Korean Pine" 한국목재공학회 46 (46): 471-485, 2018
24 Shi, S. Q, "Diffusion model based on Fick’s second law for the moisture absorption process in wood fiber-based composites : is it suitable or not" 41 (41): 645-658, 2007
25 Amer, M., "Determination of growth stresses indicator, moisture profiles and basic density of clonal eucalyptus wood" 14 (14): 91-98, 2017
26 Tamme, V., "Determination of effective diffusion coefficient and mechanical stress of pine wood during convective drying" 17 : 110-117, 2011
27 Hakam, A., "Contrôle et quantification de la dégradation mécanique du bois pendant le séchage. Cas d’eucalyptus" 13 : 110-114, 2003
28 Khouya, A., "Contribution aux études expérimentale et numérique d’un processus de séchage du bois" Université Abdelmalek Essaadi 2008
29 Sonderegger, W., "Combined bound water and water vapour diffusion of Norway spruce and European beech in and between the principal anatomical directions" 65 : 819-828, 2011
30 Vasic, M., "Calculation of the effective diffusion coefficient during the drying of clay samples" 77 (77): 523-533, 2012
31 Peralta, P. N., "A nonlinear regression technique for calculating the average diffusion coefficient of wood during drying" 35 (35): 401-408, 2003
32 Engelund, E. T., "A critical discussion of the physics of wood–water interactions" 47 : 141-161, 2013