| 姓名: | 况敏 |
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系/所: | 轮机工程系/机电与能源工程研究所 |
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职称: | 教授 |
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电话: | 13616516384 |
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电子邮件: | [email protected] |
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通讯地址: | 浙江省宁波大学梅山校区海运楼 |
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研究领域
个人简介
1982年生,江西高安人,教授/博导,博士毕业于哈尔滨工业大学,浙江大学博士后出站。主要从事清洁高效燃烧、船舶尾气净化、船舶力学特性方面研究。主持国家重点研发计划、国家自然科学基金、浙江省自然科学基金等国家级和省部级项目。以第一及通讯作者在《Environmental Science & Technology》、《Applied Energy》、《Energy》、《Fuel》、《Energy Conversion and Management》、《Fuel Processing Technology》等SCI一/二区权威期刊发表论文60多篇,在《Energy》上发表特约长篇英文综述1篇;获英国/中国发明专利授权近20项。入选浙江省高校创新领军人才、浙江省高校中青年学科带头人、宁波市领军人才、宁波市领军与拔尖人才第一层次、浙东青年学者等人才计划。获得中国发明协会发明创新一等奖和浙江省工程热物理学会青年科技奖。
科研项目
一、纵向项目
[1] 国家重点研发计划青年项目:硫和微粒排放双达标的船舶尾气梯级洗涤装置关键技术研究,2016YFC0205800,213万,2016.7~2019.12,已结题.
[2] 国家自然科学基金面上项目:梯级拱型W火焰布局下深度空气分级、烟气再循环和细煤粉再燃的低NOx燃烧耦合作用研究,52276122,70.2万,2023.1~2026.12,在研.
[3] 国家自然科学基金青年项目:W火焰炉炉内流场偏斜与不对称燃烧的形成机制研究,51306167,25万,2014.1~2016.12,已结题.
[4] 浙江省自然科学基金项目:基于四拱双W火焰的炉内流动、煤燃烧和NOx生成特性研究,LY18E060002,9万,2018.1~2020.12,已结题.
[5] 中国博士后科学基金面上项目:对称配风条件下W火焰炉内偏斜气固两相流研究,2014M551733,5万,2014.1~2015.12已结题.
[6] 省属高校基本科研业务费项目:梯级拱型W火焰高效低NOx燃烧研究,SJLY2022009,8万,2022.1~2024.12,在研.
[1] 克拉玛依市独山子区集中供热系统优化提升项目改造-低氮燃烧技术服务,120万,2021.1~2022.5,已结题.
代表性论文和专著
一、代表性论文:
[1] Shengchen Qi, Min Kuang*, Zehao Ge, et al. Distinguishing the vertical air-staging low-NOx function of secondary air for suspension combustion within an industrial-scale coal-fired reversal grate furnace. Case Studies in Thermal Engineering, In Press, Available online 11 September 2024, 105113. (SCI二区)
[2] Shuting Cheng, Min Kuang*, Jiaqi Chen, et al. Hopper-air distribution impact on the low-NOx combustion and hopper environment in a 600 MWe staged arch-firing furnace. Energy & Environment, article in press, DOI: 10.1177/0958305X241267772. (SSCI二区)
[3] Shuting Cheng, Min Kuang*, Yiping Zhao. Assessment of a staged and inclined hopper-air injection in enhancing low-NOx combustion and establishing a safe hopper environment for a large-scale arch-fired furnace. Energy & Environment, article in press, DOI: 10.1177/0958305X241253768. (SSCI二区)
[4] Shuting Cheng, Min Kuang*, Jiaqi Chen, et al. Enhancing the arch-fired low-NOx performance with a throat overfire air for lowering NOx and hopper overheating. Energy & Environment, article in press, DOI: 10.1177/0958305X241228516. (SSCI二区)
[5] Yiping Zhao, Min Kuang*, Sheng Liu, et al. Reducing persistently high NOx emissions and the risk of hopper's thermal-fatigue in a 600-MWe low-NOx down-fired boiler furnace with a staged arch-firing framework: Effect of the primary-burner location. Combustion Science and Technology, article in press, DOI: 10.1080/00102202.2023.2288215.
[6] Sheng Liu, Min Kuang*, Shuting Cheng, et al. Confirming the efficacy of a new arch-firing solution in safely strengthening low-NOx combustion within a large-scale furnace: Impact of the flue gas recirculation position in burners. Energy & Environment, article in press, DOI: 10.1177/0958305X231225301. (SSCI二区)
[7] Zehao Ge, Min Kuang*, Shengchen Qi, et al. Effect of the coal-spreading air on airflow and low-NOx combustion within a 75 t/h coal-fired grate furnace. Applied Thermal Engineering, 2024, 256: 124076. (SCI二区)
[8] Jiaqi Chen, Min Kuang*, Sheng Liu, et al. Furnace-height FGR location impact of a cascade-arch-firing configuration in ameliorating low-NOx combustion and eliminating hopper overheating for a large-scale arch-fired furnace. Applied Thermal Engineering, 2024, 252: 123707. (SCI二区)
[9] Shuting Cheng, Min Kuang*, Sheng Liu, et al. Lowering further NOx emissions and improving the hopper's overheating environment in a low-NOx down-fired furnace by a staged arch-firing framework with a primary-burner flue gas recirculation. Case Studies in Thermal Engineering, 2023, 51: 103546. (SCI二区)
[10] Shengchen Qi, Xiu Wang, Yiping Zhao, Min Kuang*, et al. High-burnout and low-NOx combustion characteristics in a 600-MWe W-shaped flame furnace: Air-regulating solution selection as varying overfire air and impact of the overfire air ratio. Asia-Pacific Journal of Chemical Engineering, 2023, 18: e2903.
[11] Yangyang Chen, Min Kuang*, Zehao Ge, et al. Establishing essentially symmetrical combustion plus apparent improvement in burnout and NOx emissions within a down-fired furnace by rearranging its W-shaped flame into a sidewall-dominated pattern. Fuel, 2023, 340: 127544. (SCI一区)
[12] Sheng Liu, Min Kuang*, Shengchen Qi, et al. Strengthening low-NOx combustion with flue gas recirculation in a 600-MWe down-fired furnace. Asia-Pacific Journal of Chemical Engineering, 2022, 17: e2831.
[13] Xiu Wang, Min Kuang*, Shuting Cheng, et al. Establishing an appropriate overfire air angle at the furnace throat of a low-NOx W-shaped flame furnace. Applied Thermal Engineering, 2022, 212: 118534. (SCI二区)
[14] Min Kuang*, Xiaojuan Zhao, Jialin Wang, et al. Upgrading the strengthened low-NOx and high-burnout combustion performance by staging the hopper air in a down-fired furnace. Fuel, 2021, 294: 120582. (SCI一区)
[15] Long Jiao, Min Kuang*, Yangyang Chen, et al. Detailed measurements of in-furnace gas temperature and species concentration distribution regarding the primary-air distribution mode in a spreader and reversal chain-grate furnace. Energy, 2021, 235: 121384. (SCI一区)
[16] Min Kuang*, Jialin Wang, Xiu Wang, et al. In-furnace flow field, coal combustion and NOx emission characteristics regarding the staged-air location in a cascade-arch down-fired furnace. Journal of the Energy Institute, 2021, 98: 259–270. (SCI二区)
[17] Sili Wu, Min Kuang*, Minsen Zhao, et al. ASPEN PLUS desulfurization simulations for the scrubber of a large-scale marine diesel engine: main scrubbing section’s desulfurization share optimization and superiority confirmation for the seawater/seawater cascade-scrubbing solution. Environmental Science and Pollution Research, 2021, 28: 22131–22145.
[18] Xiaojuan Zhao, Min Kuang*, Sheng Liu, et al. Impact of the upper/lower furnace depth ratio on the strengthened low-NOx combustion performance in a two-stage W-shaped flame furnace. Asia-Pacific Journal of Chemical Engineering, 2021, 16: e2640.
[19] Minsen Zhao, Min Kuang*, Sili Wu, et al. Desulfurization performance of a large-scale marine diesel engine's scrubber with packing scrubbing: Validation of design parameters based on ASPEN PLUS simulations. Asia-Pacific Journal of Chemical Engineering, 2021, 16: e2619.
[20] Haiqian Wu, Min Kuang*, Jialin Wang, et al. Lower-arch location effect on the flow field, coal combustion, and NOx formation characteristics in a cascade-arch, down-fired furnace. Applied Energy, 2020, 268: 115032. (SCI一区)
[21] Jialin Wang, Min Kuang*, Xiaojuan Zhao, et al. Trends of the low-NOx and high-burnout combustion characteristics in a cascade-arch, W-shaped flame furnace regarding with the staged-air angle. Energy, 2020, 212: 118768. (SCI一区)
[22] Min Kuang*, Jinxin Wang, Xuehui Hu, et al. Seawater/seawater cascade-scrubbing desulfurization performance for exhaust gas of a 162-kW marine diesel engine. Journal of Environmental Engineering, 2020, 146: 04019090.
[23] Haiqian Wu, Min Kuang*, Jialin Wang, et al. Low-NOx and high-burnout combustion characteristics of a cascade-arch-firing, W-shaped flame furnace: Numerical simulation on the effect of furnace arch configuration. Environmental Science & Technology, 2019, 53: 11597–11612. (SCI一区)
[24] Min Kuang*, Xuehui Hu, Guohua Yang, et al. Seawater/alkaline liquid cascade-scrubbing desulfurization performance for the exhaust gas of a 162-kW marine diesel engine. Asia-Pacific Journal of Chemical Engineering, 2019, 14: e2370.
[25] Jinxin Wang, Min Kuang*, Guohua Yang, et al. Desulfurization performance comparison of a 162-kW marine diesel engine's exhaust gas based on two kinds of alkaline liquid scrubbing models. Asia-Pacific Journal of Chemical Engineering, 2019, 14: e2323.
[26] Min Kuang*, Haiqian Wu, Qunyi Zhu, et al. Establishing an overall symmetrical combustion setup for a 600 MWe supercritical down-fired boiler: A numerical and cold-modeling experimental verification. Energy, 2018, 147: 208–225. (SCI一区)
[27] Min Kuang*, Guohua Yang, Qunyi Zhu, et al. Effect of burner location on flow-field deflection and asymmetric combustion in a 600 MWe supercritical down-fired boiler. Applied Energy, 2017, 206: 1393–1405. (SCI一区)
[28] Zhongqian Ling, Bo Ling, Min Kuang*, et al. Comparison of airflow, coal Combustion, NOx emissions, and slagging characteristics among three large-scale MBEL down-fired Boilers manufactured at different times. Applied Energy, 2017, 187: 689–705. (SCI一区)
[29] Min Kuang*, Qunyi Zhu, Guohua Yang, et al. The fate of shrinking boiler nose to improve the flow-field deflection and asymmetric combustion in a 600 MWe supercritical down-fired boiler. Fuel Processing Technology, 2017, 167: 371–381. (SCI一区)
[30] Min Kuang*, Qunyi Zhu, Zhongqian Ling, et al. Improving gas/particle flow deflection and asymmetric combustion of a 600 MWe supercritical down-fired boiler by increasing its upper furnace height. Energy, 2017, 127: 581–593. (SCI一区)
[31] Yanhui Wei, Min Kuang*, Qunyi Zhu, et al. Alleviating gas/particle flow deflection and asymmetric combustion in a 600 MWe supercritical down-fired boiler by expanding its furnace throat space. Applied Thermal Engineering, 2017, 123: 1201–1213. (SCI二区)
[32] Min Kuang*, Guohua Yang, Qunyi Zhu, et al. Trends of the flow-field deflection and asymmetric combustion in a 600 MWe supercritical down-fired boiler with respect to the furnace arch’s burner span. Energy & Fuels, 2017, 31: 12770–12779.
[33] Min Kuang, Zhengqi Li, Zhongqian Ling*, et al. Improving flow and combustion performance of a large-scale down-fired furnace by shortening secondary-air port area. Fuel, 2014, 121: 232–239. (SCI一区)
[34] Min Kuang, Zhengqi Li, Zhongqian Ling*, et al. Effect of overfire air angle on flow characteristics within a small-scale model for a deep-air-staging down-fired furnace. Energy Conversion and Management, 2014, 79: 367–376. (SCI一区)
[35] Min Kuang*, Zhengqi Li. Review of gas/particle flow, coal combustion, and NOx emission characteristics within down-fired boilers. Energy, 2014, 69: 144–178. (SCI一区)
[36] Min Kuang, Zhengqi Li, Zhongqian Ling*, et al. Evaluation of staged air and overfire air in regulating air-staging conditions within a large-scale down-fired furnace. Applied Thermal Engineering, 2014, 67: 97–105. (SCI二区)
[37] Min Kuang, Zhihua Wang*, Yanqun Zhu, et al. Regulating low-NOx and high-burnout deep-air-staging combustion under real-furnace conditions in a 600 MWe down-fired supercritical boiler by strengthening the staged-air effect. Environmental Science & Technology, 2014, 48: 12419–12426. (SCI一区)
[38] Min Kuang, Zhengqi Li, Zhihua Wang*, et al. Combustion and NOx emission characteristics with respect to staged-air damper opening in a 600 MWe down-fired pulverized-coal furnace under deep-air-staging conditions. Environmental Science & Technology, 2014, 48: 837–844. (SCI一区)
[39] Min Kuang, Zhengqi Li, Zhongqian Ling*, et al. Characterization of coal combustion and steam temperature with respect to staged-air angle in a 600 MWe down-fired boiler. Energy & Fuels, 2014, 28: 4199–4205.
[40] Zhongqian Ling, Min Kuang*, Xianyang Zeng, et al. Combustion flexibility of a large-scale down-fired furnace with respect to boiler load and staging conditions at partial loads. Energy & Fuels, 2014, 28: 725–734.
[41] Min Kuang, Qunyi Zhu, Zhengqi Li*, et al. Numerical investigation on combustion and NOx emissions of a down-fired 350 MWe utility boiler with multiple injection and multiple staging: Effect of the air stoichiometric ratio in the primary combustion zone. Fuel Processing Technology, 2013, 109: 32–42. (SCI一区)
[42] Min Kuang, Zhengqi Li*, Chunlong Liu, et al. Experimental study on combustion and NOx emissions for a down-fired supercritical boiler with multiple-injection multiple-staging technology without overfire air. Applied Energy, 2013, 106: 254–261. (SCI一区)
[43] Min Kuang, Zhengqi Li*, Qunyi Zhu, et al. Characterization of gas/particle flows with respect to staged-air ratio for a down-fired 600 MWe supercritical utility boiler with multiple injection and multiple staging: a lab-scale study. International Journal of Thermal Sciences, 2013, 70: 154–165. (SCI二区)
[44] Min Kuang, Zhengqi Li*, Qunyi Zhu, et al. Cold-modeling flow characteristics for a 300-MWe down-fired furnace at different secondary-air distributions. International Journal of Thermal Sciences, 2013, 68: 148–157. (SCI二区)
[45] Min Kuang, Zhengqi Li*, Qunyi Zhu, et al. Arch- and wall-air distribution optimization for a down-fired 350 MWe utility boiler: A cold-modeling experimental study accompanied by real-furnace measurements. Applied Thermal Engineering, 2013, 54(1): 226–236. (SCI二区)
[46] Min Kuang, Zhengqi Li*, Qunyi Zhu, et al. Performance assessment of staged-air declination in improving asymmetric gas/particle flow characteristics within a down-fired 600 MWe supercritical utility boiler. Energy, 2013, 49: 423–433. (SCI一区)
[47] Min Kuang, Zhengqi Li*, Chunlong Liu, et al. Overall evaluation of combustion and NOx emissions for a down-fired 600 MWe supercritical boiler with multiple injection and multiple staging. Environmental Science & Technology, 2013, 47: 4850–4858. (SCI一区)
[48] Min Kuang, Zhengqi Li*, Qunyi Zhu. Evaluation on cold modeling flow field for a down-fired 600 MWe supercritical boiler with multi-injection and multi-staging: A burner location experimental optimization and its validation by real-furnace measurements. Experimental Thermal and Fluid Science, 2013, 45: 213–220. (SCI二区)
[49] Min Kuang*, Zhengqi Li, Xinjing Jing, et al. Characterization of combustion and NOx emissions with respect to over-fire air damper opening in a down-fired pulverized-coal furnace. Energy & Fuels, 2013, 27: 5518–5526.
[50] Min Kuang, Zhengqi Li*, Chunlong Liu, et al. Evaluation of overfire air behavior for a down-fired 350 MWe utility boiler with multiple injection and multiple staging. Applied Thermal Engineering, 2012, 48: 164–175. (SCI二区)
[51] Zhengqi Li*, Min Kuang, Qunyi Zhu, et al. Aerodynamic characteristics within a cold small-scale model for a down-fired 350 MWe utility boiler applying a multiple-injection and multiple-staging technology: Effect of the staged-air declination angle. Experimental Thermal and Fluid Science, 2012, 38: 184–194. (SCI二区)
[52] Min Kuang, Zhengqi Li*, Qunyi Zhu, et al. Experimental gas/particle flow characteristics of a down-fired 600 MWe supercritical utility boiler at different staged-air ratios. Energy, 2012, 42: 411–423. (SCI一区)
[53] Min Kuang, Zhengqi Li*, Yan Zhang, et al. Asymmetric combustion characteristics and NOx emissions of a down-fired 300 MWe utility boiler at different boiler loads. Energy, 2012, 37: 580–590. (SCI一区)
[54] Min Kuang, Zhengqi Li*, Qunyi Zhu, et al. Gas/particle flow characteristics, combustion and NOx emissions of down-fired 600 MWe supercritical utility boilers with respect to two configurations of combustion systems. Energy & Fuels, 2012, 26: 3316–3328.
[55] Min Kuang, Zhengqi Li*, Qunyi Zhu, et al. Inner and outer secondary-air distance-effect study within a cold small-scale model of a new down-fired 600 MWe supercritical utility boiler. Energy & Fuels, 2012, 26: 417–424.
[56] Min Kuang, Zhengqi Li*, Pengfei Yang, et al. Flow-field deflection characteristics within a cold small-scale model for a down-fired 300 MWe utility boiler at different secondary-air angles. Fuel Processing Technology, 2011, 92(6): 1261–1271. (SCI一区)
[57] Min Kuang, Zhengqi Li*, Shantian Xu, et al. Improving combustion characteristics and NOx emissions of a down-fired 350 MWe utility boiler with multiple injection and multiple staging. Environmental Science & Technology, 2011, 45: 3803–3811. (SCI一区)
[58] Min Kuang, Zhengqi Li*, Shantian Xu, et al. Impact of overfire air location on combustion improvement and NOx abatement of a down-fired 350 MWe utility boiler with multiple injection and multiple staging. Energy & Fuels, 2011, 25: 4322–4332.
[59] Min Kuang, Zhengqi Li*, Pengfei Yang, et al. Staged-air ratio optimization for a new down-fired technology within a cold small-scale model of a 350 MWe utility boiler. Energy & Fuels, 2011, 25: 1485–1496.
[60] Zhengqi Li*, Min Kuang, Pengfei Yang, et al. Flow-field deflection within a cold small-scale model for a down-fired 300 MWe utility boiler at asymmetric staged-air distribution. Energy & Fuels, 2011, 25: 86–96.
[61] Zhengqi Li*, Min Kuang, Jia Zhang, et al. Influence of staged-air on airflow, combustion characteristics and NOx emissions of a down-fired pulverized-coal 300 MWe utility boiler with direct flow split burners. Environmental Science & Technology, 2010, 44: 1130–1136. (SCI一区)
[62] Zhengqi Li*, Min Kuang, Qunyi Zhu, et al. Staged-air ratio optimization within a cold small-scale model for a MBEL down-fired pulverized-coal 300 MW (electrical) utility boiler. Energy & Fuels, 2010, 24: 4883–4892.
[63] Min Kuang, Zhengqi Li*, Yunfeng Han, et al. Influence of staged-air declination angle on flow field deflection in a down-fired pulverized-coal 300 MWe utility boiler with direct flow split burners. Energy & Fuels, 2010, 24(3): 1603–1610.
课程教学与人才培养
一、课程教学
二、人才培养
1.指导的2017级硕士生获宁波大学曹光彪学生科研奖。2.指导的2017级硕士生获宁波大学优秀硕士学位论文。3.指导的2018级和2019级硕士生获研究生国家奖学金。4.指导本科生获得国家级大学生创新创业项目和浙江省新苗人才计划项目资助10余项。
软件版权登记及专利
一、专利
1. 况敏, 凌忠钱, 曾宪阳. 一种对称燃烧的W型火焰锅炉, 发明专利号: ZL201410543855.9
2. 况敏, 王金鑫, 吴海茜, 等. 一种侧墙布置拱部燃烧器的对称燃烧W型火焰锅炉, 发明专利号: ZL20171010896667.8
3. 况敏, 吴海茜, 胡雪慧, 等. 一种侧墙主导对称燃烧的低氮高效燃尽W火焰锅炉, 发明专利号: ZL201810032042.1
4. Zhengqi Li, Zhichao Chen, Min Kuang, et al. Methods for multi-stage combustion with multi-ejection by a boiler. Great Britain Certificate of Grant of Patent, Patent Number: GB2486630, Publication Date: 11 April 2018. (英国发明专利)
获奖与荣誉
1.中国发明协会发明创新一等奖,2022(2/6);2.浙江省工程热物理学会青年科技奖,2022(1/1);3.黑龙江省专利优秀奖,2022(3/9);4.入选浙江省高校创新领军人才(2020)、浙江省高校中青年学科带头人(2017)、宁波市领军人才(2020)、宁波市甬江育才工程领军拔尖人才第一层次(2022)、宁波市B类专家(2018)、郑州市创新创业领军人才(2017)、浙东青年学者培养计划(2017)
学术兼职
1.担任SCI期刊《Energy Exploration & Exploitation》副主编;
2.连续两年入选爱思唯尔中国高被引学者(2022年和2023年);
3.担任EI期刊《哈尔滨工程大学学报》编委;