张双保

点击数:更新日期: 2018-04-17

张双保.jpg张双保教授、博士生导师


性 别:男

电子邮箱shuangbaozhang@163.com

办公电话136 8159 3543

研究方向:木质复合材料与胶黏剂


详细资料

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教育/工作经历

教育背景

1995/09 - 1998/07,江南的注册网址,森林工业学院,博士,导师:赵立 教授

1983/09 - 1986/07,东北林业大学,林产工业系,硕士,导师:包学耕 教授

1978/09 - 1982/07,东北林学院,林产工业系,学士,导师:张广仁 教授

工作经历

2002/02 – 至今,江南的注册网址,材料科学与技术学院,教授

1998/07 – 2002/02,江南的注册网址,森林工业学院,副教授

1992/07 – 1995/09,林业部,林产工业规划设计院,高级工程师

1987/06 – 1992/07,林业部,林产工业规划设计院,工程师

1986/07 – 1987/06,林业部,林产工业规划设计院,助理工程师

1982/07 – 1983/09,东北林学院,帽儿山林场,技术员/助理工程师

2000/04 – 2002/04,中国林业科学研究院,林业工程博士后流动站,博士后,合作导师:鲍甫成 研究员


主讲课程

本科生课程

(1)木材科学与工程专业:人造板工程设计、木工企业管理与法规、建筑材料学;

(2)包装工程专业:包装管理与法规。

研究生课程

木质复合材料与胶黏剂。


科研工作及成果

研究领域:木质(天然植物纤维)复合材料与胶黏剂/木材保护与改性。

作为科技工作者:主持及参加完成了40余项科研项目,有近100家生产企业应用其成果;作为工程设计人员:主持及参加完成了10余项林产工业工程项目;作为监理工程师:参与完成了5项林产工业工程项目;作为教师:主讲过5门研究生课程、10门本科生课程,培养博士后、博士生及硕士生108名(含在站或在读),指导过113名本科生完成毕业论文(设计),曾指导学生获美国林产品学会(Forest Products Society)“国际木材科学竞赛(Wood Science Bowl)”一等奖”和大学生“挑战杯”:国家三等奖、北京市一、二等奖等多个奖项。

近年来承担项目:国家重点研发计划(2017YFD0600804)、国家自然科学基金(32171707、31670571、31070501)、北京市自然科学基金:(6202024、6162019、2122045)、北京市教育委员会共建项目(2016、2014、2012、2010)、全国林业行业标准制订项目(2019-LY-116、2017-LY-045、2013-LY-192、2012-LY-200、2010-LY-134、2009-LY-053)及浙江省(成竹新材料科技股份有限公司)共建项目(CZXC201410)等课题。迄今为止,在国内外专业期刊发表科技论文100余篇,其中SCI/EI/ISTP/CSCD收录多篇;参编教材或专著4部,申报国家发明专利20余件。


奖励及荣誉称号

(1)2020年,北京,江南的注册网址优秀共产党员.

22019年,北京,梁希林业科学技术奖一等奖.

32018年,美国,美国林产品学会“国际木材科学竞赛”一等奖(指导教师).

42015,北京,北京市孝星”.

52014,北京,海淀区五好文明家庭标兵.

62013,北京,中国林业教育学会第三届高等林(农)业教育研究优秀论文三等奖.

72012,北京,北京市高教学会实验室工作研究会“2012年学术研讨会优秀论文二等奖.

82011,北京,北京市第二届职工技能大赛优秀裁判员先进工作者”.

92006,北京,北京市教育系统工会积极分子.

102001,北京,教育部、团中央、北京市大学生挑战杯赛全国三等奖、北京市一、二等奖(指导教师).

112000,北京,团中央、北京市赴内蒙古三下乡博士社会实践团社会实践优秀团队奖(团长).

121998,北京,全国林业系统十佳大学生奖.

131997,北京,宝钢教育基金奖.

141993,北京,国家科技进步三等奖(排名第2)、全国高新技术成果金奖(排名第2.

151992,北京,林业部科技进步一等奖(排名第2.

161991,北京,国家级重点科技推广项目(排名第2

171990,北京,林业部重点科技推广项目(排名第2


学术/社会兼职

(1)学术兼职:

曾被聘为:1.科技部“国家科技计划(863”计划技术方向)、科技进步奖、发明奖”;2.教育部“科技进步奖、发明奖、长江学者“特聘教授、青年长江”、霍英东教育基金会“高等院校青年科学奖、教育教学奖、青年教师基金、青年教师奖”、高等学校专项引智和科研基金、博士点专项基金”;3.人事部“博士后基金”等评审专家;4.国家林业局“科技进步奖、发明奖”等评审专家及“高级职称”评委;5.住建部、国家文物局、环保部“科技项目”、中国林学会“梁希科技进步奖”、黑龙江、河北、山东、浙江、湖南、内蒙古、广西及北京等部委省市“科技进步奖”、“发明奖”和“自然基金”及“政府采购”等评审专家。

担任如下期刊评审专家:SCI收录期刊如《Bioresource Technology》、《European Journal of Wood and Wood Products》、《Journal of Material Cycles and Waste Management》、《Polymer Composites》、《Polymer International》、《Journal of Natural Fibers》、《Forest Products Journal》、《PLoS ONE》、《Journal of Thermoplastic Composite Materials》,EI收录期刊如《林业科学》、《农业工程学报》、《复合材料学报》、《建筑材料学报》,CSCD收录期刊如《林业工程学报》、《森林与环境学报》、《福建林学院学报》、《浙江农林大学学报》、《西南林业大学学报》,中文核心期刊如《木材工业》等。

(2)社会兼职:

中国林学会木材科学分会及生物质材料分会、中国木材保护协会、全国专业标准化委员会、全国人造板标准化委员会及竹(藤)材标准委员会等(理事)委员。


学术成果展示

[1] Song, W., Zhang, S., Fei, B., & Zhao, R. (2022). Performance elevation of bamboo flour/high-density polyethylene composites by pretreating bamboo flour with mussel adhesive proteins-inspired poly (catechol/amine). European Journal of Wood and Wood Products, 1-16. https://doi.org/10.1007/s00107-022-01876-6.

[2] Hong, G., Cheng, H., Zhang, K., Chen, Z., & Zhang, S. (2022). Cleaner production strategy tailored versatile biocomposites for antibacterial application and electromagnetic interference shielding. Journal of Cleaner Production, 366, 132835.

[3] Hong, G., Cheng, H., Zhang, S., & Rojas, O. J. (2022). Polydopamine-treated hierarchical cellulosic fibers as versatile reinforcement of polybutylene succinate biocomposites for electromagnetic shielding. Carbohydrate Polymers, 277, 118818.

[4] Zhang, K., Chen, Z., Boukhir, M., Song, W., & Zhang, S. (2022). Bioinspired polydopamine deposition and silane grafting modification of bamboo fiber for improved interface compatibility of poly (lactic acid) composites. International Journal of Biological Macromolecules, 201, 121-132.

[5] Song W, Zhang S, Fei B, Zhao R. (2021). Effect of monomer type on polydopamine modification of bamboo flour and the resulting interfacial properties of bamboo plastic composites. Industrial Crops and Products, 171, 113874.

[6] Song W, Zhang S, Fei B, Zhao R. (2021). Mussel-inspired polydopamine modification of bamboo flour for superior interfacial compatibility of bamboo plastic composites: influence of oxidant type Cellulose, 28(13), 8567-8580.

[7] Hong G, Cheng H, Zhang S, Rojas O J. (2021). Mussel-inspired reinforcement of a biodegradable aliphatic polyester with bamboo fibers. Journal of Cleaner Production, 296, 126587.

[8] Zhang K, Chen Z, Smith L M, Hong G, Song W, Zhang S. (2021). Polypyrrole-modified bamboo fiber/polylactic acid with enhanced mechanical, the antistatic properties and thermal stability. Industrial Crops and Products, 162, 113227.

[9] Hu, X., Chen, Z., Cao, Y., Chen, Z., Zhang, S., & Song, W. (2019). The effect of modifier on properties of bamboo powder/high-density polyethylene composites. Forest Products Journal, 69(4), 313-321.

[10] Zhang, K., Lin, J., Hao, C., Hong, G., Chen, Z., Chen, Z., Zhang, S., & Song, W. (2019). Effect of nano-hydroxyapatite modification of bamboo fiber on the properties of bamboo fiber/polylactic acid composites. BioResources, 14(1), 1694-1707.

[11] Chen, Z., Wang, C., Cao, Y., Zhang, S., & Song, W. (2018). Effect of adhesive content and modification method on physical and mechanical properties of eucalyptus veneer-poly-beta-hydroxybutyrate film composites. Forest Products Journal, 68(4), 419-429.

[12] Hao, C., Zhang, K., Zhang, S., & Song, W. (2018). Modification of wood flour/phenolic resin composites with bamboo pulp residue. Forest Products Journal, 68(3), 211-215.

[13] Song, W., Zhang, K., Chen, Z., Hong, G., Lin, J., Hao, C., & Zhang, S. (2018). Effect of xylanase-laccase synergistic pretreatment on physical-mechanical properties of environment-friendly self-bonded bamboo particleboards. Journal of Polymers and the Environment, 26(10), 4019-4033.

[14] Song, W., Zhu, M., Lin, W., & Zhang, S. (2018). Determining optimum material mixture ratio and hot-pressing parameters for new hybrid fiber-reinforced composites: Modeling and optimization by response surface methodology. BioResources, 13(2), 4202-4223.

[15] Li, R., Xu, W., Wang, C., Zhang, S., & Song, W. (2018). Optimization for the liquefaction of moso bamboo in phenol using response surface methodology. Wood and Fiber Science, 50(2), 220-227.

[16] Hong G, Cheng H, Meng Y, Lin J, Chen Z, Zhang S, Song W. (2018). Mussel-Inspired polydopamine as a green, efficient, and stable platform to functionalize bamboo fiber with amino-terminated alkyl for high performance poly(butylene succinate) composites. Polymers, 10(4), 461.

[17] Lin J, Yang Z, Hu X, Hong G, Zhang S, Song W. (2018). The effect of alkali treatment on properties of dopamine modification of bamboo fiber/polylactic acid composites. Polymers, 10(4), 403.

[18] Song, W., Zhu, M., & Zhang, S. (2018). Comparison of the properties of fiberboard composites with bamboo green, wood, or their combination as the fibrous raw material. BioResources, 13(2), 3315-3334.

[19] Song, W., Xu, Z., & Zhang, S. (2018). Using surface modified E-glass fiber cloths to enhance poplar laminated veneer lumber composites: Effects of modification conditions, gluing processes, hot-pressing parameters, and assembly patterns on physical-mechanical and interfacial properties. BioResources, 13(1), 597-631.

[20] Song, W., Wei, W., Ren, C., & Zhang, S. (2017). Effect of heat treatment or alkali treatment of veneers on the mechanical properties of eucalyptus veneer/polyethylene film plywood composites. BioResources, 12(4), 8683-8703.

[21] Hong, G., Meng, Y., Yang, Z., Cheng, H., Zhang, S., & Song, W. (2017). Mussel-inspired polydopamine modification of bamboo fiber and its effect on the properties of bamboo fiber/polybutylene succinate composites. BioResources, 12(4), 8419-8442.

[22] Song, W., Wei, W., Wang, D., & Zhang, S. (2017). Preparation and properties of new plywood composites made from surface modified veneers and polyvinyl chloride films. BioResources, 12(4), 8320-8339.

[23] Song, W., Wei, W., Li, X., & Zhang, S. (2016). Utilization of polypropylene film as an adhesive to prepare formaldehyde-free, weather-resistant plywood-like composites: Process optimization, performance evaluation, and interface modification. BioResources, 12(1), 228-254.

[24] Song, W., Wei, W., Ren, C., & Zhang, S. (2016). Developing and evaluating composites based on plantation eucalyptus rotary-cut veneer and high-density polyethylene film as novel building materials. BioResources, 11(2), 3318-3331.

[25] Song, W., Cao, Y., Wang, D., Hou, G., Shen, Z., & Zhang, S. (2015). An investigation on formaldehyde emission characteristics of wood building materials in Chinese standard tests: Product emission levels, measurement uncertainties, and data correlations between various tests. PLoS ONE, 10(12), e0144374.

[26] Song, W., Zhao, F., Yu, X., Wang, C., Wei, W., & Zhang, S. (2015). Interfacial characterization and optimal preparation of novel bamboo plastic composite engineering materials. BioResources, 10(3), 5049-5070.

[27]中华人民共和国林业行业标准. LY/T3199-2020铝合金增强竹塑复合型材.北京:中国标准出版社,2020.

[28]中华人民共和国林业行业标准. LY/T 2722-2016指接材用结构胶黏剂胶合性能测试方法.北京:中国标准出版社,2016.

[29]中华人民共和国林业行业标准. LY/T 2720-2016胶合面木破率的测定方法.北京:中国标准出版社,2016.

中华人民共和国林业行业标准. LY/T 2565-2015竹塑复合材料.北京:中国标准出版社, 2015.



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