朱向楠 照片

朱向楠

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所属大学: 山东科技大学

所属学院: 化学与生物工程学院

邮箱:
zhuxiangnan1989@163.com

个人主页:
https://huagong.sdust.edu.cn/info/1010/2950.htm

个人简介

招生专业: 资源与环境、矿物加工工程

个人经历 2017.09-至今 就职于山东科技大学 2014.09-2017.06 中国矿业大学 矿物加工工程专业 获工学博士学位 2011.09-2014.06 中国矿业大学 矿物加工工程专业 获工学硕士学位 2007.09-2011.06 山东科技大学 矿物加工工程专业 获工学学士学位

科研项目 1. 山东省自然科学基金:基于物理分选属性差异的城市金属矿山资源化利用研究,主持。 2. 山东科技大学人才引进科研启动基金:基于有价组分力学特性差异的电子废弃物高效解离基础研究,主持。 3. 青岛市博士后应用研究项目: 机械活化对废弃线路板天然可浮性的影响机制研究,主持。

学术成就 以第一作者发表SCI论文二十余篇(中科院一区论文十余篇),担任《Journal of hazardous materials》、《Journal of cleaner production》、《Waste Management》、《Resources conservation and recycling》等TOP期刊审稿人。指导本科生发表论文十余篇,指导本科生获得国家级学术竞赛奖励2项,获“山东科技大学优秀班主任”荣誉称号。

论著专利 1、阎正卿,张怡晴,张远康,朱向楠. 一种废弃线路板分选尾矿中有机质的热解回收装置,专利号:201922063550.9. 2、朱向楠,陶有俊,等.一种连续排料的细粒煤离心分选设备, 专利号:ZL 2015 2 1021932.0 3、陶有俊,朱向楠,等.一种间断排料的细粒煤离心分选机, 专利号:ZL 2015 2 0495707.4 4、陶有俊,朱向楠,等.一种立式间断排料离心选矿机的自动排料装置, 专利号:ZL 2015 2 0496000.5

讲授课程 为本科生主讲《矿物加工导论》(山东省一流课程); 为研究生主讲《专业英语》; 为留学生主讲《Professional foreign language》。

研究领域

电子废弃物资源化利用、矿物分选理论及工艺研究、新型浮选药剂及矿山环境治理。

近期论文

1. Zhu, X., Zhang, Y., Zhang, Y., Yan, Z., Nie, C., Lyu, X., Tao, Y., Qiu, J., Li, L., 2020. Flotation dynamics of metal and non-metal components in waste printed circuit boards. J Hazard Mater. 392, 122322. doi: https://doi.org/10.1016/j.jhazmat.2020.122322. (IF=9.04)

2. Zhu, X., Nie, C., Ni, Y., Zhang, T., Li, B., Wang, D., Qu, S., Qiao, F., Lyu, X., Qiu, J., Li, L., Ren, Y., Wu, P., 2020. Advanced utilization of copper in waste printed circuit boards: synthesis of nano-copper assisted by physical enrichment. J Hazard Mater. 123294. https://doi.org/10.1016/j.jhazmat.2020.123294. (IF=9.04)

3. Zhu, X., Ni, Y., Wang, D., Zhang, T., Qu, S., Qiao, F., Ren, Y., Nie, C., Lyu, X., Qiu, J., Li, L., 2020. Effect of dissociation size on flotation behavior of waste printed circuit boards. J Clean Prod. 265, 121840. https://doi.org/10.1016/j.jclepro.2020.121840. (IF=6.39)

4. Zhu, X., Zhang, L., Dong, S., Kou, W., Nie, C., Lyu, X., Qiu, J., Li, L., Liu, Z., Wu, P., 2020. Mechanical activation to enhance the natural floatability of waste printed circuit boards. Waste Manage.109. 222-230. https://doi.org/10.1016/j.wasman.2020.05.008. (IF=5.43)

5. Nie, C., Wang, Y., Zhang, H., Zhang, Y., Zhang, Y., Yan, Z., Li, B., Lyu, X., Tao, Y., Qiu, J., Li, L., Zhang, G., Zhu, X., 2020. Cleaner utilization of non-metallic components in separation tailings of waste printed circuit board: Pyrolysis oil, calorific value and building aggregate. J Clean Prod. 258. 120976. https://doi.org/10.1016/j.jclepro.2020.120976. (IF=6.39,通讯)

6. Zhu, X., Zhang, H., Nie, C., Liu, X., Lyu, X., Tao, Y., Qiu, J., Li, L., Zhang, G., 2020. Recycling metals from -0.5 mm waste printed circuit boards by flotation technology assisted by ionic renewable collector. J Clean Prod. 258, 120628. DOI: https://doi.org/10.1016/j.jclepro.2020.120628. (IF=6.39)

7. Zhu, X. N., Nie, C. C., Zhang, H., Lyu, X. J., Qiu, J., Li, L. 2019., Recovery of metals in waste printed circuit boards by flotation technology with soap collector prepared by waste oil through saponification. Waste Manag, 89, 21-26. (IF=5.43)

8. Zhu, X.-n., Cui, T., Li, B., Nie, C.-c., Zhang, H., Lyu, X.-j., Tao, Y., Qiu, J., Li, L., Zhang, G., 2020. Metal recovery from waste printed circuit boards by flotation technology with non-ionic renewable collector. J Clean Prod. 255. 120289. https://doi.org/10.1016/j.jclepro.2020.120289. (IF=6.39)

9. Zhu, X., Wang, D., Ni, Y., Wang, J., Nie, C., Yang, C., Lyu, X., Qiu, J., Li, L., 2020. Cleaner approach to fine coal flotation by renewable collectors prepared by waste oil transesterification. J Clean Prod. 252 ,119822. https://doi.org/10.1016/j.jclepro.2019.119822. (IF=6.39)

10. Zhu, X.-n., Nie, C.-c., Wang, S.-s., Xie, Y., Zhang, H., Lyu, X.-j., Qiu, J., Li, L., 2019. Cleaner approach to the recycling of metals in waste printed circuitboards by magnetic and gravity separation. J Clean Prod. 248. 119235. https://doi.org/10.1016/j.jclepro.2019.119235. (IF=6.39)

11. Zhu, X.-n., Lyu, X.-j., Wang, Q., Qiu, J., Wang, S.-s., Liu, X.-y., Li, L., 2019. Clean utilization of waste oil: Soap collectors prepared by alkaline hydrolysis for fluorite flotation. J Clean Prod. 240, 118179. doi:10.1016/j.jclepro.2019.118179. (IF=6.39)

12. Zhu, X.-n., Nie, C.-c., Zhang, H., Lyu, X.-j., Tao, Y.-j., Qiu, J., Zhang, G.-w., 2019. Recovery of high-grade copper from waste printed circuit boards by mechanical-grinding assisted flotation. J Clean Prod. 232, 1251-1256. (IF=6.39)

13. Zhu, X., Tao, Y., Zhang, L., 2018. Numerical simulation of flow field in enhanced gravity concentrator. Physicochem. Probl. Miner. Process., 54(3), 975-980. (IF=1.06)

14. Zhu, X., Tao, Y., Sun, Q., 2016. Deashing and desulphurization of fine oxidized coal by falcon concentrator and flotation. Physicochem. Probl. Miner. Process. 52(2), 634-646. (IF=1.06)

15. Zhu, X., Tao, Y., Sun, Q., 2019. Particle migration regularity in compound force field of enhanced gravity concentrator. Int J Coal Prep Util. 39(4), 219-231. DOI: 10.1080/19392699.2017.1310722.(IF=2.02)

16. Zhu, X., Tao, Y., Sun, Q., 2017. Enrichment and migration regularity of particles in enhanced gravity concentrator. Int J Miner Process. 163:48-54. (IF=2.26)

17. 朱向楠, 陶有俊, 何亚群, 等. 微波预处理对炼焦中煤破碎解离特性的影响 [J]. 煤炭学报,2015,40(8):1942-1948. (EI)

18. 朱向楠, 陶有俊, 何亚群, 等. 炼焦中煤挤压破碎条件下破碎解离特性研究 [J]. 中国矿业大学学报, 2015, 44(4):714-719. (EI)