代表性论文专著
[25]Jinpeng Zhai, Xiangxin Han*, Guohao Zhai, Xiumin Jiang. Renewable nitrogen-containing products by Maillard reaction of sewage sludge and glucose. Part I. Analysis of nitrogen composition and protein model based on AlphaFold2. Fuel, 2022, 325, 124968.
[24]Bin Chen, Xiangxin Han*, Jianhui Tong, et al. Studies of fast co-pyrolysis of oil shale and wood in a bubbling fluidized bed. Energy Conversion and Management, 2020, 205, 112356
[23]Mao Mu, Xiangxin Han*, Xiumin Jiang. Interactions between oil shale and hydrogen-rich wastes during co-pyrolysis: 1. Co-pyrolysis of oil shale and polyolefins. Fuel, 2020, 265, 116994
[22]Mao Mu, Xiangxin Han*, Xiumin Jiang. Combined fluidized bed retorting and circulating fluidized bed combustion system of oil shale: 3. Exergy analysis. Energy, 2018, 151, 930-939.
[21]Bin Chen, Xiangxin Han*, Mao Mu, et al. Studies of the co-pyrolysis of oil shale and wheat straw. Energy & Fuels, 2017, 31(7): 6941-6950.
[20]Bin Chen, Xiangxin Han*, Xiumin Jiang. In situ FTIR analysis of the evolution of functional groups of oil shale during pyrolysis. Energy & Fuel, 2016, 30(7): 5611–5616.
[19]Xiangxin Han, Qingqing Liu, Xiumin Jiang. Heat transfer characteristic of oil shale particle during the retorting. International Journal of Heat and Mass Transfer, 2015, 84: 578–583.
[18] Xiangxin Han, Mengting Niu, Xiumin Jiang. Combined fluidized bed retorting and circulating fluidized bed combustion system of oil shale: 2. Energy and economic analysis. Energy, 2014, 74, 788–794.
[17]Xiangxin Han, Indrek Kulaots, Xiumin Jiang, et al. Review of oil shale semicoke and its combustion utilization. Fuel, 2014, 126, 143–161.
[16]Qingyou Li, Xiangxin Han*, Qingqing Liu, et al.Thermal decomposition of Huadian oil shale. Part 1. Critical organic intermediates. Fuel, 2014, 121, 109–116.
[15]Jianhui Tong, Jianguo Liu, Xiangxin Han, et al. Characterization of nitrogen-containing species in Huadian shale oil by electrospray ionization Fourier transform ion cyclotron resonance mass spectrometry. Fuel, 2013, 104, 365–371.
[14]Junwei Yan, Xiumin Jiang, Xiangxin Han, Jianguo Liu. A TG-FTIR investigation to the catalytic effect of mineral matrix in oil shale on the pyrolysis and combustion of kerogen. Fuel, 2013.104, 307–317.
[13]Xiangxin Han, Mengting Niu, Xiumin Jiang, and Jianguo Liu. Combustion characteristics of sewage sludge in a fluidized bed. Industrial & Engineering Chemistry Research, 2012, 51(2): 10565–10570.
[12]Xiangxin Han, Xiumin Jiang, Zhigang Cui, et al. Effects of retorting factors on combustion properties of shale char. 2. Pore structure. Energy & Fuel, 2011, 25(1): 97–102.
[11]Jianhui Tong, Xiangxin Han, Sha Wang, Xiumin Jiang. Evaluation of Structural Characteristics of Huadian Oil Shale Kerogen Using Direct Techniques (Solid-State 13C NMR, XPS, FT-IR and XRD). Energy & Fuel, 2011, 25(9): 4006–4013.
[10]Xiangxin Han, Xiumin Jiang, Zhigang Cui, et al. Effects of retorting factors on combustion properties of shale char. 3. Distribution of residual organic matters. Journal of Hazardous Materials, 2010, 175(1-3): 445-451.
[9]Xiangxin Han, Xiumin Jiang. Effects of retorting factors on combustion properties of shale char: 1. pyrolysis characteristics. Energy & Fuels, 2009, 23(2): 677–682.
[8]Xiangxin Han, Xiumin Jiang, Zhigang Cui. Change of Pore Structure of Oil Shale Particles during Combustion. 2. Pore Structure of Oil-Shale Ash. Energy & Fuels, 2008, 22(2): 972–975.
[7]Xiangyong Huang, Xiumin Jiang, Xiangxin Han, et al. Combustion characteristics of fine- and micro-pulverized coal in the mixture of O2/CO2. Energy & Fuels, 2008, 22(6), 3756–3762.
[6]Xiangxin Han, Zhigang Cui, Xiumin Jiang, et al. Regulating characteristics of loop seal in a 65t/h oil shale-fired circulating fluidized bed boiler. Powder Technology, 2007, 178(2): 114–118.
[5]X. M. Jiang, X. X. Han*, Z. G. Cui. Progress and recent utilization trends in combustion of Chinese oil shale. Progress in Energy and Combustion Science, 2007, 33(6): 552–575.
[4]Xiumin Jiang, Xiangxin Han*, Zhigang Cui. New technology for comprehensive utilization of oil shale resources. Energy, 2007,32(5):772–777.
[3]Xiangxin Han, Xiumin Jiang, Lijun Yu, et al. Change of pore structure of oil shale particles during combustion: Part 1. Evolution mechanism. Energy & Fuels, 2006, 20(6): 2408–2412.
[2]Xiangxin Han, Xiumin Jiang, Hui Wang, et al. Study on design of Huadian oil shale-fired circulating fluidized bed boiler. Fuel Processing Technology, 2006,87(4): 289–295.
[1]Xiangxin Han, Xiumin Jiang, Zhigang Cui. Flow structure and combustion characteristic of 65t/h oil shale-fired circulating fluidized bed riser: 2. Dilute phase. Chemical Engineering Science, 2006, 61(8): 2533–2539.
软件版权登记及专利
[12]韩向新, 姜秀民, 翟金鹏, 等. 一种多能互补污泥处理装置及实施方法. 国家发明专利, ZL 202010047633.3
[11]刘建国, 刘加勋, 韩向新, 等,. 一种工业煤粉锅炉烟气再循环低氮燃烧方法和系统. 国家发明专利, ZL 201610614713.6.
[10]韩向新, 刘加勋, 刘建国, 等.一种工业有机废弃物处理和再利用方法. 国家发明专利, ZL 201410138526.6
[9]韩向新, 姜秀民, 刘庆庆, 等.油页岩增压加氢干馏制油工艺. 国家发明专利, ZL 201410157840.9
[8]韩向新, 姜秀民, 钮梦婷, 等.气固组合式载热油页岩流化床干馏系统. 国家发明专利, ZL 201210189395.5
[7]韩向新, 姜秀民, 刘建国, 等. 油页岩干馏、半焦焚烧一体化系统. 国家发明专利, ZL 201010179437.8.
[6]韩向新, 姜秀民, 刘建国, 等. 油页岩流化床干馏系统. 国家发明专利, ZL 200810204396.6.
[5]韩向新, 姜秀民, 王辉, 等. 以湿油页岩半焦为燃料的循环流化床焚烧系统. 国家发明专利, ZL 200710047696.3.
[4]王爽, 姜秀民, 韩向新, 等. 海藻生物质的异密度循环流化床燃烧处理方法. 国家发明专利, ZL 200710172603.X.
[3]姜秀民, 于立军, 韩向新, 等. 油页岩综合利用的方法. 国家发明专利, ZL 200510024417.2.
[2]韩向新, 姜秀民, 于立军, 等. 油页岩的气热电三联供应用系统. 国家发明专利, ZL 200510025253.5.
[1]姜秀民, 韩向新, 于立军, 等. 油污泥的异密度循环流化床燃烧处理方法. 国家发明专利, ZL 200410089304.6.