|
常飞虎, 张彬, 傅万四, 等. 高频技术在竹材加工技术装备中的应用研究. 木材加工机械, 2018. 29 (5): 34- 36, 4.
|
|
Chang F H , Zhang B , Fu W S , et al. Application and research of high frequency technology in bamboo processing equipment. Wood Processing Machinery, 2018. 29 (5): 34- 36, 4.
|
|
陈勇平, 王金林, 李春生, 等. 高频介质加热在木材胶合中的应用. 木材加工机械, 2007. 18 (5): 37- 41.
|
|
Chen Y P , Wang J L , Li C S , et al. The application of high-frequency heating technology in wood bonding process. Wood Processing Machinery, 2007. 18 (5): 37- 41.
|
|
江泽慧, 常亮, 王正, 等. 结构用竹集成材物理力学性能研究. 木材工业, 2005. (4): 22- 24, 30.
|
|
Jiang Z F , Chang L , Wang Z , et al. Physical and mechanical properties of glued structural laminated bamboo. China Wood Industry, 2005. (4): 22- 24, 30.
|
|
李海涛, 张齐生, 吴刚, 等. 竹集成材研究进展. 林业工程学报, 2016. 1 (6): 10- 16.
|
|
Li H T , Zhang Q S , Wang G , et al. A review on development of laminated bamboo lumber. Journal of Forestry Engineering, 2016. 1 (6): 10- 16.
|
|
李文定, 王超, 张洋, 等. 豆胶胶合板的高频热压机理及胶合特性. 南京林业大学学报:自然科学版, 2014. 38 (3): 120- 124.
|
|
Li W D , Wang C , Zhang Y , et al. Hot-pressing mechanism and bonding characteristics of soy protein adhesive plywood under radio-frequency heating. Journal of Nanjing Forestry University:Natural Sciences Edition, 2014. 38 (3): 120- 124.
|
|
刘晓辉. 热塑性树脂胶合板板坯热压过程中影响温度变化的主要因素. 林业工程学报, 2018. 3 (2): 35- 39.
|
|
Liu X H . The main factors affecting temperature change of mat during the manufacturing process of thermoplastic resin plywood. Journal of Forestry Engineering, 2018. 3 (2): 35- 39.
|
|
阮氏香江, 张齐生, 蒋身学. 竹集成材高频热压胶合工艺及性能研究. 林业科技开发, 2014. 28 (4): 109- 112.
|
|
Nguyen T H G , Zhang Q S , Jiang S X . Technology of glued laminated bamboo laminated in high frequency hot press and the properties. Journal of Forestry Engineering, 2014. 28 (4): 109- 112.
|
|
NguyenThi Huong Giang, 张齐生. 竹集成材高频热压过程中板坯内温度的变化趋势. 浙江农林大学学报, 2015. 32 (2): 167- 172.
|
|
Nguyen T H G , Zhang Q S . Temperature inside mats of high-frequency, hot pressed, glued and laminated bamboo. Journal of Zhejiang A & F University, 2015. 32 (2): 167- 172.
|
|
王文静, 左宏亮, 郭楠, 等. 胶合竹顺纹受拉力学性能试验研究. 低温建筑技术, 2015. 37 (4): 38- 40.
|
|
Wang W J , Zuo H L , Guo N , et al. The mechanical property tests for structural glubam of the tensile strength parallel to grain. Low Temperature Architecture Technology, 2015. 37 (4): 38- 40.
|
|
叶张柠. 2019.竹集成材家具角部接合的力学性能研究.杭州:浙江农林大学硕士学位论文
|
|
Ye Z N. 2019. Dissertaiton for the degree of master. Hangzhou: MS thesis of Zhejiang A & F University.[in Chinese]
|
|
詹先旭, 唐周梅, 程明娟, 等. 重组装饰材高频热压工艺的研究. 林产工业, 2018. 45 (1): 19- 23.
|
|
Zhan X X , Tang Z M , Cheng M J , et al. Study on high-frequency hot-pressing process of reconstituted decorative lumber. China Forest Products Industry, 2018. 45 (1): 19- 23.
|
|
张浩, 曹现雷, 唐刚, 等. 基于正交实验设计制备Cu-Ce/TiO2的多元非线性回归分析. 环境工程学报, 2015. 9 (7): 3368- 3372.
|
|
Zhang H , Cao X L , Tang G , et al. Multivariate nonlinear regression analysis for preparation of Cu-Ce/TiO2 based on orthogonal experimental design. Chinese Journal of Environmental Engineering, 2015. 9 (7): 3368- 3372.
|
|
张仲凤, 周先雁. 国产胶合木复合增强效应的非线性有限元分析. 建筑结构, 2014. 44 (9): 83- 88.
|
|
Zhang Z F , Zhou X Y . Nonlinear finite element analysis on reinforced effect of domestic laminated timber. Building Structure, 2014. 44 (9): 83- 88.
|
|
朱红兵, 席凯强. SPSS 17.0中的正交试验设计与数据分析. 首都体育学院学报, 2013. 25 (3): 283- 288.
|
|
Zhu H B , Xi K Q . The orthogonal experimental design in SPSS17.0 and data analysis. Journal of Capital University of Physical Education and Sports, 2013. 25 (3): 283- 288.
|
|
Aydin I , Colakoglu G , Colak S , et al. Effects of moisture content on formaldehyde emission and mechanical properties of plywood. Building and Environment, 2006. 41 (10): 1311- 1316.
doi: 10.1016/j.buildenv.2005.05.011
|
|
Kalawate A , Shahoo S C , Khatua P K , et al. Evaluation of mechanical properties of plywood treated with a new wood preservative(CEB)chemical. Journal of the Institution of Engineers(India):Series D, 2017. 98 (1): 37- 41.
doi: 10.1007/s40033-015-0108-2
|
|
Muhammad F S , Suffian M , Wan-Mohd-Nazri W A R , et al. Mechanical properties erties of plywood from batai(Paraserianthes falcataria), eucalyptus(Eucalyptus pellita)and kelempayan(Neolamarckia cadamba)with different layer and species arrangement. Journal of Tropical Forest Science, 2018. 30 (1): 58- 66.
doi: 10.26525/jtfs2018.30.1.5866
|
|
Sharma B , Gatóo A , Ramage M H . Effect of processing methods on the mechanical properties of engineered bamboo. Construction and Building Materials, 2015. 83, 98- 101.
|
|
Wei Y , Tang S F , Ji X W , et al. Stress-strain behavior and model of bamboo scrimber under cyclic axial compression. Engineering Structures, 2020. 209, 110279.
doi: 10.1016/j.engstruct.2020.110279
|
|
Xiao Z Q , Liao X P , Long Z H , et al. Effect of cutting parameters on surface roughness using orthogonal array in hard turning of AISI 1045 steel with YT5 tool. The International Journal of Advanced Manufacturing Technology, 2017. 93 (1/4): 273- 282.
|
|
Xu M , Cui Z Y , Tu L H , et al. The effect of elevated temperatures on the mechanical properties of laminated bamboo. Construction and Building Materials, 2019. 226, 32- 43.
doi: 10.1016/j.conbuildmat.2019.07.274
|