迟祥,博士、预聘副教授、硕士生导师
学术硕士招生学科:林业工程-木材科学与技术
专业硕士招生学科:材料与化工-林业工程
研究方向:干燥技术与智能装备,可再生能源和技术;
联系方式:chixiangnefu@163.com
学习与工作经历
2022-2023,不列颠哥伦比亚大学,联合培养博士(师从国际木材科学院主席Stavros Avramidis)
2020-2024,新葡的京集团35222vip,获博士学位(师从程万里教授)
2024-至今,新葡的京集团35222vip,预聘副教授
主持与参与项目:
6.新葡的京集团35222vip成栋骨干青年人才启动基金、2024/09-2029/09、在研,主持
5.黑龙江省自然科学基金项目、基于东北地区季候性的木材太阳能干燥动力学特性及应用基础研究、2022/07-2025/06、在研,参与立项
4.中央高校基本科研业务费专项资金资助、木材水分蒸发面(湿线)形成机制的可视化动态研究、2022/07-2024/06、结题,主持
3.新葡的京集团35222vip林业工程一流学科博士创新基金项目、基于东北地区季候性的木材空气能辅助太阳能干燥动力学及工艺优化、2021/09-2024/05、结题,主持
2.国家自然科学基金面上项目、基于太阳能/空气能联合供热的木制品水性涂料干燥固化特性及其热质传递规律、2021/01-2024/12、在研,参与立项
1.国家自然科学基金面上项目、木材太空能/空气能联合干燥的过程调控及能源转换阈值模型的建立、2019/1-2020/12、结题,参与立项
学术成果展示:
22.Characterization of hygrothermal, gas pressure and stress characteristics for poplar wood during unilateral surface densification.Construction and Building Materials, 2024, 438, 137099. (工程技术1区)
21. Solar Drying of timber in Northeast China.Wood Science and technology, 2024, 58(1):195-212. (纸与木材1区)
20.Energy and quality analysis of forced convection air-energy assisted solar timber drying.Energy, 2023(283): 128718. (工程技术1区)
19.Visible dynamic changes in the mechanism of water evaporation surface formation during wood drying.Wood Science and Technology, 2023 (57):1061-1076. (纸与木材1区)
18. Effects of air-assisted solar drying on poplar lumber drying processes in sub frigid zone regions.Drying Technology, 2022, 40(16): 3580-3590. (工程技术3区)
17.Design of sustainable 3D printable polylactic acid composites with high lignin content.International Journal of Biological Macromolecules, 2023, 253, 127264. (化学1区)
16.Advancing Multi-Stimuli 4D Printing of Polylactic Acid with Rapid Shape Memory and Enhanced Toughness Using Lignin-Coated Fe3O4 Nanoparticles.Industrial Crops & Products, 2023, accepted. (农业科学1区)
15.4D printing light-driven actuator with lignin photothermal conversion module.International Journal of Biological Macromolecules, 2023, 253, 126562. (化学1区)
14.Effect of Hot-Air Drying Conditions on the Drying Efficiency and Performance of a Waterborne Coating on Pine Wood.Forests, 2023, 14(9), 1752. (农林科学2区)
13.Efficient extraction of nanocellulose from lignocellulose using aqueous butanediol fractionation to improve the performance of waterborne wood coating.Carbohydrate Polymers, 2023, 322, 121347. (化学1区)
12.Efficient downstream valorization of lignocellulose after organosolv fractionation: Synergistic enhancement of waterborne coatings by co-assembled lignin@cellulose nanocrystals.International Journal of Biological Macromolecules, 2023, 227, p1325-1335 (化学1区).
11.空气能辅助太阳能干燥过程中“闷窑”工艺对杨木干燥效能的影响.森林工程, 2023, 39(3): 107-115.
10.Insights from molecular dynamics simulations for interfacial effects between polylactic acid and wood cell wall constituents.Composites Part A: Applied Science and Manufacturing, 2023, 164, 107310. (材料科学1区).
9.Effect of wood microstructure and hygroscopicity on the drying characteristics of waterborne wood coating.Wood Science and Technology, 2022 56(3):743-758-. (纸与木材1区)
8.Valorization of Lignin from Biorefinery: Colloidal Lignin Micro-Nanospheres as Multifunctional Bio-Based Fillers for Waterborne Wood Coating Enhancement.ACS Sustainable Chemistry and Engineering, 2022. (化学1区)
7.Selection of cross-seasonal heat collection/storage media for wood solar drying.Drying Technology, 2020, 38(16): 2172-2181.(工程技术2区)
6.荧光-麦秸纤维/PP复合材料的制备及其性能.功能材料, 2021, 52(8): 08192-08198.
5.杨木锯材间歇加热常规干燥过程中的含水率和应力变化.新葡的京集团35222vip学报, 2021, 49(12): 126-131.
4.发光纤维的研究进展.功能材料, 2021, 52(2): 02085-02097.
3.依据响应曲面法和BP神经网络对木纤维脉冲-旋流气流干燥工艺优化.新葡的京集团35222vip学报, 2020, 48(4): 104-108.
2.木材太阳能-空气能联合干燥设备的集热介质选择及能耗.新葡的京集团35222vip学报, 2020, 48(8): 107-111.
1.Co-Mn掺杂碳气凝胶的制备与性能表征.复合材料学报, 2019, 36(9): 2196-2203.
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