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-?red 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.
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