胡二峰，男，博士，副教授。长期致力于煤清洁高效利用研究，围绕“新型内构件固定床煤热解技术”开展系统性研究工作。曾先后在中科院过程所许光文研究员课题组（2012.6—2015.6）、加拿大新不伦瑞克大学郑莹教授课题组（2015.7—2017.1）学习。2017年7月至2019年6月进入农业部规划设计研究院开展博士后研究（合作导师：赵立欣研究员）；2020年11月至2023年6月进入重庆大学矿业工程流动站开展博士后研究（合作导师：卢义玉教授）。

担任国家自然科学基金函评专家、重庆市科委评审专家、重庆市经济和信息化委员会专家；担任全国分析与应用热裂解学术联合会理事、《洁净煤技术》中青年专家委员会委员（2019-2021）、山西省煤炭学会煤炭清洁高效利用常务委员。累计发表论文50余篇，其中以第一/通讯作者在 Chemical Engineering Journal、Energy、Fuel等期刊发表SCI 论文30余篇；授权发明专利10余项。主持国家自基金青年项目、科技部自主研发设备项目、重庆市自然基金面上项目等多个项目。

联系方式

Email：ehu@cqu.edu.cn，Tel：13641135012

研究团队网址：www.taochangyuan.com

研究方向

低阶煤清洁高效利用、新型反应器研发、有机固体废弃物资源化利用。

代表性论文、专著和专利

论文：

1. Hu Erfeng, Zhang Yue, Liu Zuohua, Yu Jianglong, et al. Insight into dechlorination of pyrolysis oil during fast co-pyrolysis of high-alkali coal and polyvinyl chloride (PVC)[J]. Chemical Engineering Journal, 2024: 153016.

2. Li Moshan, Lu Yiyu, Hu Erfeng*, et al. Fast co-pyrolysis characteristics of high-alkali coal and polyethylene using infrared rapid heating[J]. Energy, 2023: 126635.  

3. Zeng Yongfu, Liu Zuohua, Yu Jianglong, Hu Erfeng*,et al. Pyrolysis kinetics and characteristics of waste tyres: Products distribution and optimization via TG-FTIR-MS and rapid infrared heating techniques[J]. Chemical Engineering Journal, 2024, 482: 149106.

4. Zeng Yue, Liu Zuohua, Hu Erfeng*,et al. Optimization of product distribution during co-pyrolysis of furfural residues and waste tyres via response surface method and infrared heating[J]. Separation and Purification Technology, 2025, 354: 129209.

5. Zeng Yongfu, Liu Zuohua, Hu Erfeng*,et al. Insight into impact of co-pyrolysis process parameters on cross-interaction of volatiles between furfural residue and coal via rapid infrared heating[J]. Energy, 2024, 309: 133118.

6. Hu Erfeng*,Zhang Yue, Liu Zuohua, et al. Enhanced synergies for product distributions and interactions during co-pyrolysis between corn stover and tyres[J]. Journal of Analytical and Applied Pyrolysis, 2024, 183: 106770.

7. Zhang Yue, Liu Zuohua, Hu Erfeng*, et al. Synergistic effects and comprehensive analysis of interaction during infrared co-pyrolysis of furfural residues and PVC[J]. Process Safety and Environmental Protection, 2024, 191: 2095-2103.

8. Zhang Yue, Liu Zuohua, Hu Erfeng*,et al. Elucidating synergistic effects and environmental value enhancement in infrared-Assisted Co-Pyrolysis of coal and polyvinyl chloride[J]. Separation and Purification Technology, 2025, 357: 130071.

9. Li Shuai, Qu Rui, Hu Erfeng*, et al. Co-pyrolysis kinetics and enhanced synergy for furfural residues and polyethylene using artificial neural network and fast heating[J]. Waste Management, 2025, 195: 177-188.

10. Li Shuai, Zeng Yongfu, Hu Erfeng*, et al. Insight into fast infrared-assisted and coal rank on pyrolysis kinetics and products distribution[J]. Journal of Analytical and Applied Pyrolysis, 2025: 106986.

11. Zeng Yongfu, Liu Zuohua, Yu Jianglong, Hu Erfeng*,et al. Enhanced energy efficiency and fast co-pyrolysis characteristics of biogas residues and long-flame coal using infrared heating and TG-FTIR-MS[J]. Process Safety and Environmental Protection, 2024.

12. Zhang Yue, Li Moshan, Hu Erfeng*, Qu Rui, Li Shuai, Xiong Qingang. Interaction and characteristics of furfural residues and polyvinyl chloride in fast Co-pyrolysis. Front. Chem. Sci. Eng., 2024

13. Li Chenhao, Liu zuohua, Yu Jianglong, Hu Erfeng* et al. Cross-interaction of volatiles in fast co-pyrolysis of waste tyre and corn stover via TG-FTIR and rapid infrared heating techniques[J]. Waste Management, 2023, 171: 421-432.

14. Li Chenhao, Liu zuohua, Yu Jianglong, Hu Erfeng* et al. Infrared heating and synergistic effects during fast co-pyrolysis of corn stover and high alkali coal[J]. Process Safety and Environmental Protection, 2023, 179: 812-821.

15. Dai Chongyang, Hu Erfeng*, Yang Yang, et al. Fast co-pyrolysis behaviors and synergistic effects of corn stover and polyethylene via rapid infrared heating[J]. Waste Management, 2023, 169: 147-156.

16. Li Moshan, Hu Erfeng*, Tian Yishui, et al. Fast pyrolysis characteristics and its mechanism of corn stover over iron oxide via quick infrared heating[J]. Waste Management, 2022, 149: 60-69.  

17. Dai Chongyang, Hu Erfeng*, Tian Yishui, et al. Infrared heated co-pyrolysis behavior of polyethylene and corn stover via optimization of secondary reactions[J]. Journal of Analytical and Applied Pyrolysis, 2022: 105565.

18. Hu Erfeng*, Tian Yishui, Yang Yang, et al. Pyrolysis behaviors of corn stover in new two-stage rotary kiln with baffle[J]. Journal of Analytical and Applied Pyrolysis, 2022, 161: 105398.

19. Hu Erfeng*, Moshan Li, Yishui Tian, et al. Pyrolysis behaviors of anaerobic digestion residues in a fixed-bed reactor with rapid infrared heating [J]. Environmental Science and Pollution Research, 2022:1-12.

20. Hu Erfeng*, Dai Chongyang, Tian Yishui, et al. Infrared heated pyrolysis of corn stover: Determination of kinetic and thermodynamic parameters[J]. Journal of Analytical and Applied Pyrolysis, 2021: 105273.

21. Xu Shipei, Hu Erfeng*, Li Xingchun*, Xu Yu. Quantitative Analysis of Pore Structure and Its Impact on Methane Adsorption Capacity of Coal[J]. Natural Resources Research, 2021, 30(1): 605-620.

22. Hu Erfeng, Kyle Rogers, Fu Xiaoheng*, et al. Coal pyrolysis and its mechanism in indirectly heated fixed-bed with metallic heating plate enhancement[J]. Fuel, 2016, 185: 656-662.

23. Hu Erfeng, Zeng Xi*, Fu Xiaoheng, et al. Characterization of coal pyrolysis in indirectly heated fixed bed based on field effects[J]. Fuel, 2017, 200: 186-192.

24. Hu Erfeng, Zeng Xi*, Fu Xiaoheng, et al. Effect of the moisture content in coal on the pyrolysis behavior in an indirectly heated fixed-bed reactor with internals[J]. Energy & Fuels, 2017, 31(2): 1347-1354.

25. Hu Erfeng, Zeng Xi*, Wang Fang, et al. Effects of Metallic Heating Plates on Coal Pyrolysis Behavior in a Fixed-Bed Reactor Enhanced with Internals[J]. Energy & Fuels, 2017, 31(3): 2716-2721.

26. Hu Eefeng, Yao Zonglu, Zhao Lixin*, et al. Characteristics of zeolite-modified NiMo/Al2O3 catalysts and their hydrotreating performance for light cycled oil[J]. The Canadian Journal of Chemical Engineering, 2019, 97(5): 1107-1113.

27. Zhang Chun, Wu Rongcheng, Hu Erfeng, Liu Shuyuan, Xu Guangwen*. Coal Pyrolysis for High-Quality Tar and Gas in 100 kg Fixed Bed Enhanced with Internals[J]. Energy & Fuels, 2014, 28 (11):7294-7302.

28. 胡二峰,武荣成,张纯,郭二卫,付晓恒,许光文*.间热径向流反应器料层厚度对煤热解特性的影响[J].化工学报,2015,66(02):738-745.

29. 胡二峰, 张纯,武荣成,付晓恒,许光文*.内构件固定床反应器中不同水分煤的热解特性[J].化工学报,2015,66(07):2656-2663.

30. 胡二峰,赵立欣*,等.石英管定向强化流场模拟内构件反应器不同厚度煤热解特性[J].煤炭学报,2018,43(12):3504-3509.

31. 胡二峰,赵立欣*,等.生物质热解影响因素及技术研究进展[J].农业工程学报,2018,34(14):212-220.

32. 胡二峰, 赵立欣*,等.热解温度对回转窑玉米秸秆热解产物理化特性的影响[J].农业工程学报,2019,35(11):233-238.

33. 刘壮, 田宜水, 胡二峰*, 等. 低阶煤热解影响因素及其工艺技术研究进展[J]. 洁净煤技术, 2021, 27(1):50-59.

34. 曾永福,田宜水,胡二峰, 屈锐等.长焰煤与糠醛渣共热解动力学、热力学及快速热解产物特性[J].太阳能学报, 2024,46(6): 108-114.

35. 李晨浩,田宜水,胡二峰*,等.厌氧消化残渣与低阶长焰煤共热解特性[J].农业工程学报,2022,38(23):188-194.

36. 戴重阳,田宜水,胡二峰*,等. 生物质与低阶煤共热解特性研究及其技术进展[J].太阳能学报, 2021,42(12):318-325.

37. 李沫杉,田宜水,胡二峰*,等. 沼渣热解动力学、热力学分析及热解产物特性研究[J].太阳能学报, 2022, 43(6):225-233.

代表性专利：

        1. 胡二峰. 一种碳氢原料耦合废弃PVC和LCD共热解提取InCl3的装置与方法， 202211380889.1，发明专利；

2. 胡二峰. 一种碳氢原料热解装置与热解方法202011233503.5，发明专利；

3. 胡二峰.生物质与低阶煤分离耦合传热板与低品位铁矿石的共热解系统，202110298334.1，发明专利；

4. 胡二峰.一种扰动式内构件回转炉生物质热解炭化多联产系统，201710739505.3，发明专利；

5. 胡二峰.一种用于生物质热解的赤泥基催化剂的制备方法，202110296820.X，发明专利；

6. 胡二峰. 一种红外快速加热医疗废弃物的热解多联产系统，202110874631.6，发明专利；

7. 胡二峰. 一种熔融盐加热医疗废弃物或废旧塑料的热解方法 ，202110874646.2 ，发明专利；

8. 胡二峰. 一种废机油热解装置与热解方法，202011233499.2，发明专利；

9. 胡二峰.多功能两段床热解系统监测控制平台，2020SR1874567，软件著作权；

10. 胡二峰.废机油热解控制系统及监测平台，2020SR1862029，软件著作权；