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刘新华


Tel:010-82544940
Email:[email protected]

    刘新华,中国科学院过程工程研究所研究员。1998年和2001年分别在中国石油大学(华东)与中国石油大学(北京)获得工学学士和硕士学位,2005年在中国科学院过程工程研究所获得工学博士学位后留所工作。2008年到加拿大不列颠哥伦比亚大学进行了为期一年的访问研究。主要从事气固流态化、解耦燃煤技术、多相复杂系统以及化工虚拟现实的理论研究和应用推广工作,目前正致力于复杂气固反应器的全循环跨流域多尺度稳态数学建模、清洁高效解耦燃煤技术开发与应用、以及化工虚拟过程工程平台等相关实验与模拟研究。已主持完成国家自然科学基金青年基金和国家国际科技合作项目各1项,正在主持中科院战略先导科技专项课题、国家自然科学基金面上基金和基金委重大研究计划培育项目各1项,以及与兖矿集团有限公司等国有大中型企业合作的各类横向项目多项。在国内外主流化工期刊上发表论文近40篇,撰写首部介尺度科学英文专著中的2章,获得中国发明专利授权21项、软件著作权1项、以及中国分析测试协会科学技术奖一等奖。

代表性论文与专利:

  1. Shanwei Hu, Xinhua Liu*, Nan Zhang, Jinghai Li, Wei Ge, Wei Wang,2016. Quantifying cluster dynamics to improve EMMS drag law and radial heterogeneity description in coupling with gas-solid two-fluid method. Chemical Engineering Journal, doi: http://dx.doi.org/10.1016/j.cej. 2016.08.084.
  2. Zhixin Zhang, Shanwei Hu, Xinhua Liu*, Hui Zhao, 2016. Modeling the hydrodynamics of cocurrent gas-solid downers according to energy-minimization multi-scale theory. Particuology, http://dx.doi.org/10.1016/j.partic.2016.01.011.
  3. Xinhua Liu*, Yuefang Jiang, Nan Zhang, Jinghai Li, 2016. Gas penetrating flow through dynamic particle clusters. Powder Technology, 297, 409-414.
  4. Meng Zhao, Nan Zhang, Xinhua Liu*, Wei Du, 2015. Numerical simulation of loop seal for a circulating fluidized bed based on an improved EMMS bubbling model. Powder Technology, 284, 443-451.
  5. Xinhua Liu*, Shanwei Hu, Yuefang Jiang, Jinghai Li, 2015. Extension and application of energy-minimization multi-scale (EMMS) theory for full-loop hydrodynamic modeling of complex gas-solid reactors, Chemical Engineering Journal, 278, 492-503.
  6. Xinhua Liu*. Yuefang Jiang, Cenfan Liu, Wei Wang, Jinghai Li, 2014. Hydrodynamic modeling of gas−solid bubbling fluidization based on energy-minimization multiscale (EMMS) theory. Industry & Engineering Chemistry Research, 53, 2800-2810.
  7. Shanwei Hu, Xinhua Liu*, Jinghai Li, 2013. Steady-state modeling of axial heterogeneity in CFB risers based on one-dimensional EMMS model. Chemical Engineering Science, 96, 165-173.
  8. Xinhua Liu, Li Guo, Zhaojie Xia, Bona Lu, Mingkun Zhao, Fanxiao Meng, Zhouzhou Li, Jinghai Li, 2012. Harnessing the power of virtual reality, Chemical Engineering Progress, 108(7), 28-33.
  9. Fanxiao Meng, Xinhua Liu*, 2012. Parametric effects of superficial gas velocity and cluster internal voidage on the penetrating flow through clusters, Powder Technology, 224, 404-409.
  10. Xinhua Liu, Xin Cui, Guang Sun, Toshiyuki Suda, Masahiro Narukawa, Yunyi Liu, Guogang Sun, Guangwen Xu*, 2009. Buildup of high solids flux conveying flow by coupling a moving bed to the riser bottom. AIChE Journal, 55(9), 2477-2481.
  11. Xinhua Liu, Guangwen Xu*, Shiqiu Gao, 2008. Fluidization of extremely large and widely sized coal particles as well as its application in an advanced chain grate boiler. Powder Technology, 188, 23-29.
  12. Xinhua Liu, Xin Cui, Guang Sun, Guogang Sun, Toshiyuki Suda, Guangwen Xu*, 2008. High solid-flux concurrent conveying flow realized by coupling a moving bed to the bottom section of a riser. Industry & Engineering Chemistry Research, 47 (23), 9703-9708.
  13. Xinhua Liu, Guangwen Xu*, 2008. Shiqiu Gao. Micro fluidized beds: wall effect and operability. Chemical Engineering Journal, 137, 302-307.
  14. Xinhua Liu, Shiqiu Gao, Wenli Song, Jinghai Li*, 2006. Effect of particle acceleration/deceleration on particle clustering behavior in dilute gas–solid flow. Chemical Engineering Science, 61, 7087-7095.
  15. Xinhua Liu, Shiqiu Gao, Jinghai Li*, 2005. Characterizing particle clustering behavior by PDPA measurement for dilute gas-solid flow. Chemical Engineering Journal, 108(3), 193-202.
  16. Jinghai Li, Wei Ge, Wei Wang, Ning Yang, Xinhua Liu, Limin Wang, Xianfeng He, Xiaowei Wang, Junwu Wang, Mooson Kwauk, 2013. Chapter 2 & 12, Meso-Scale Modeling: The EMMS Model for Gas-Solid Systems & Experimental Characterization of Meso-Scale Processes. In: From Multiscale Modeling to Meso-Science. Springer, pp. 47-89 & 431-460.
  17. 气固反应动力学参数分析仪. 发明专利, NO.200610171515.3. (2010.2.10 授权)
  18. 气固两相流流场实时测量系统及方法. 发明专利, NO.201010228204.2. (2013.7.10 授权)
  19. 一种对流化催化裂化系统的全循环稳态模拟方法.发明专利, NO. 201110122298.X. (2016.1.20 授权)
  20. 制备无焦油产品气的贫氧流化燃烧下吸式气化方法及装置.发明专利, NO. 200510086256.X. (2009.9.23 授权)
  21. 燃煤锅炉的燃烧方法及燃烧装置. 发明专利, NO. 200610011353.7. (2009.3.18 授权)
  22. 固体燃料解耦流化床气化方法及气化装置. 发明专利, NO. 200610113063.3. (2010.12.29 授权)
  23. 煤热解层燃装置及其燃烧方法. 发明专利, NO. 200710120221.2. (2011.6.1 授权)
  24. 固体燃料联合热转化方法及转化装置. 发明专利, NO. 200710098713.6. (2012.7.25 授权)
  25. 一种燃煤解耦燃烧装置及燃烧方法.发明专利, NO.201310381626.7. (2016.5.4 授权)
  26. 一种多角切圆多尺度煤粉解耦燃烧装置及其解耦燃烧方法. 发明专利, NO.201110374539.X. (2015.9.30授权)
  27. 一种提高层状燃烧下点火方式稳燃能力的往复运动机械炉排. 发明专利, NO. 201310384934.5. (2015.9.30 授权)
  28. 一种浓侧分级的煤粉解耦燃烧器及燃烧方法. 发明专利, NO.201110455316.6. (2015.8.19 授权)
  29. 一种分流增浓的煤粉解耦燃烧器及燃烧方法. 发明专利, NO.201210587100.X. (2015.6.3 授权)
  30. 一种流化床分级煤热解反应器和煤热解方法. 发明专利, NO.201210552805.8. (2014.7.30 授权)
  31. 一种流化雾化和液膜洗涤组合的烟气净化装置. 实用新型, NO.201420822206.8. (2015.8.19授权)
  32. 虚拟流态化模拟软件(Virtual Fluidization). 软件著作权, NO.2015SRBJ0279. (2015.5.29授权)

 

 

 

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