| [1] | MOGHADDAM M S, van den BULCKE J, WÅLINDER M E P, et al. Microstructure of chemically modified wood using X-ray computed tomography in relation to wetting properties [J]. Holzforschung, 2017, 71(2): 119 − 128. |
| [2] | GAFF M, KAČÍK F, GAŠPARÍK M. Impact of thermal modification on the chemical changes and impact bending strength of European oak and Norway spruce wood [J]. Composite Structures, 2019, 216: 80 − 88. |
| [3] | 张燕, 佟达, 宋魁彦. 水热-微波处理水曲柳顺纹压缩应力-应变本构关系[J]. 南京林业大学学报(自然科学版), 2013, 37(4): 105 − 109. ZHANG Yan, TONG Da, SONG Kuiyan. Stress-strain constitutive relation of longitudinal compressed Fraxinus mandshurica Rupr. with hydrothermal-microwave treatment [J]. Journal of Nanjing Forestry University (Natural Sciences Edition), 2013, 37(4): 105 − 109. |
| [4] | BÁDER M, NÉMETH R, KONNERTH J. Micromechanical properties of longitudinally compressed wood [J]. European Journal of Wood and Wood Products, 2019, 77: 341 − 351. |
| [5] | 宋魁彦. 木材顺纹压缩与多维弯曲技术研究[D]. 哈尔滨: 东北林业大学, 2008. SONG Kuiyan. Study on the Technology of Longitudinal Compressing and Multi-Dimensional Bending of Wood[D]. Harbin: Northeast Forestry University, 2008. |
| [6] | HOU Junfeng, JIANG Yinqiu, YIN Yeqiao, et al. Experimental study and comparative numerical modeling of creep behavior of white oak wood with various distributions of earlywood vessel belt[J/OL]. Journal of Wood Science, 2021, 67: 57[2022-10-20]. doi: 10.1186/s10086-021-01989-1. |
| [7] | 尹业桥, 侯俊峰, 姜志宏, 等. 早材管孔分布对环孔材栎木蠕变特性的影响[J]. 林业工程学报, 2021, 6(3): 54 − 60. YIN Yeqiao, HOU Junfeng, JIANG Zhihong, et al. Effect of earlywood vessel distribution on creep characteristics of ring-porous oak wood [J]. Journal of Forestry Engineering, 2021, 6(3): 54 − 60. |
| [8] | 吕建雄, 蒋佳荔. 木材动态黏弹性基础研究[M]. 北京: 科学出版社, 2015. LÜ Jianxiong, JIANG Jiali. Foundation Study on Dynamic Viscoelastic of Wood [M]. Beijing: Science Press, 2015. |
| [9] | 彭辉, 蒋佳荔, 詹天翼, 等. 木材普通蠕变和机械吸湿蠕变研究概述[J]. 林业科学, 2016, 52(4): 116 − 126. PENG Hui, JIANG Jiali, ZHAN Tianyi, et al. A review of pure viscoelastic creep and mechano-sorptive creep of wood [J]. Scientia Silvae Sinicae, 2016, 52(4): 116 − 126. |
| [10] | PLACET V, PASSARD J, PERRÉ P. Viscoelastic properties of green wood across the grain measured by harmonic tests in the range 0 to 95 ℃: hardwood vs. softwood and normal wood vs. reaction wood [J]. Holzforschung, 2007, 61(5): 548 − 557. |
| [11] | WANG Junfeng, WANG Xuan, HE Qian, et al. Time-temperature-stress equivalence in compressive creep response of Chinese fir at high-temperature range[J/OL]. Construction and Building Materials, 2020, 235: 117809[2023-10-20]. doi: 10.1016/j.conbuildmat.2019.117809. |
| [12] | MOOSAVI V, KHADEMI ESLAM H, BAZYAR B, et al. Bending creep behavior of Hornbeam wood [J]. Drvna Industrija, 2016, 67(4): 341 − 350. |
| [13] | HSIEH T Y, CHANG F C. Effects of moisture content and temperature on wood creep [J]. Holzforschung, 2018, 72(12): 1071 − 1078. |
| [14] | NAKAI T, TOBA K, YAMAMOTO H. Creep and stress relaxation behavior for natural cellulose crystal of wood cell wall under uniaxial tensile stress in the fiber direction [J]. Journal of Wood Science, 2018, 64(6): 745 − 750. |
| [15] | 刘一星, 赵广杰. 木材学[M]. 北京: 中国林业出版社, 2012. LIU Yixing, ZHAO Guangjie. Wood Science[M]. Beijing: China Forestry Publishing House, 2012. |
| [16] | 王聪, 吴强, 林鹏, 等. 不同纹理方向栎木微小无疵试样板材蠕变特性[J]. 林业科学, 2018, 54(4): 76 − 83. WANG Cong, WU Qiang, LIN Peng, et al. Orthotropic creep performance of small flawless oak board [J]. Scientia Silvae Sinicae, 2018, 54(4): 76 − 83. |
| [17] | 杨小军. 热处理对实木地板尺寸稳定性影响的研究[J]. 林业和草原机械, 2004(6): 18 − 19. YANG Xiaojun. Influence of thermal treatment upon dimensional stability of solid wood floors [J]. Forestry and Grassland Machinery, 2004(6): 18 − 19. |
| [18] | 彭辉, 蒋佳荔, 吕建雄, 等. 杉木正交异向蠕变行为的时温等效性[J]. 林业科学, 2021, 57(1): 153 − 160. PENG Hui, JIANG Jiali, LÜ Jianxiong, et al. Time-temperature superposition in Chinese fir orthotropic creep response [J]. Scientia Silvae Sinicae, 2021, 57(1): 153 − 160. |
| [19] | CHANG Fengcheng, LAM F. Effects of temperature-induced strain on creep behavior of wood-plastic composites [J]. Wood Science and Technology, 2018, 52(5): 1213 − 1227. |
| [20] | FURUTA Y, NAKJIMA M, NAKANII E, et al. The effects of lignin and hemicellulose on thermal-softening properties of water-swollen wood [J]. Wood Science and Technology, 2010, 56(3): 132 − 138. |
| [21] | TJEERDSMA B F, MILITZ H. Chemical changes in hydrothermal treated wood: FTIR analysis of combined hydrothermal and dry heat-treated wood [J]. Holz als Roh-und Werkstoff, 2005, 63(2): 102 − 111. |
| [22] | BOONSTRA M. A Two-Stage Thermal Modification of Wood [D]. Nancy: Henry Poincare University, 2008. |
| [23] | HILLIS W E. High temperature and chemical effects on wood stability [J]. Wood Science and Technology, 1984, 18: 281 − 293. |
| [24] | 齐华春, 程万里, 刘一星. 高温高压过热蒸汽处理木材的力学特性及化学成分变化[J]. 东北林业大学学报, 2005, 33(3): 44 − 46. QI Huachun, CHENG Wanli, LIU Yixing. Mechanical characteristics and chemical compositions of superheated steam-treated wood under high temperature and pressure [J]. Journal of Northeast Forestry University, 2005, 33(3): 44 − 46. |
| [25] | 陈国荣. 弹性力学[M]. 南京: 河海大学出版社, 2005. CHEN Guorong. Elasticity [M]. Nanjing: Hehai University Press, 2005. |