代表性论文专著
期刊论文:
2024年
[34] Xu S*, Qiu Y, Xu L, et al. Phase change and combustion of iron particles in premixed CH4/O2/N2 flames. Combustion and Flame, 2024, 259: 113171.
[33] Zhang Y, Zhang Q, Cheng C, Xu S*, et al. Effects of droplet evaporation on negative temperature coefficient phenomenon and a prediction model for two-stage auto-ignition. Combustion and Flame, 2024, 262: 113376.
[32] Feng S, Qiu Y, Xu S, et al. Modeling of micron-sized aluminum particle combustion in hot gas flow. Fuel, 2024, 369: 131718.
[31] Peng F, Kong C, Liu H, Mi X, Xu S, Liu Y, Cai W. Ignition and combustion of a single iron particle with impurities in hot post-flame gas flow. Combustion and Flame, 2024, 265:113509.
2023年
[30] Hadadpour A, Xu S*, Zhang Y, Bai X S, Jangi M. An extended FGM model with transported PDF for LES of spray combustion. Proceeding of Combustion Institute, 2023, 39: 4889-4898.
[29] Zhong S, Xu S, Zhang F*, Peng Z, Chen L, Bai X S. Cool flame propagation in high pressure spray flames. Proceeding of Combustion Institute, 2023, 39: 2513-2522.
[28] Xu L*, Xu S, Bai X S*, Repo J A, Hautala S, Hyvönen J. Performance and emission characteristics of an ammonia/diesel dual-fuel marine engine. Renewable and Sustainable Energy Reviews, 2023: 185: 113631.
[27] Xu L*, Xu S, Lu X, Jia M, Bai X S*. Large eddy simulation of spray and combustion characteristics of biodiesel and biodiesel/butanol blend fuels in internal combustion engines. Applications in Energy and Combustion Science, 2023, 185: 100197.
[26] Ong J, Zhang Y, Xu S, Walther J, Bai X S, Pang K M. Large eddy simulation of n-dodecane spray flame: Effects of injection pressure on spray combustion characteristics at low ambient temperature. Proceeding of Combustion Institute, 2023, 39: 2631-2642.
[25] Yang M, Shenghui Zhong S, Xu S, Xu L, Ottosson P, Fatehi H, Bai X-S*. CFD simulation of biomass combustion in an industrial circulating fluidized bed furnace. Combustion Science and Technology, 2023, 195: 3310-3340.
[24] Zhang M, Ong J*, Pang K M, Xu S, Zhang Y, Nemati A, Bai X S Walther J H. Large eddy simulation of combustion recession: Effects of ambient temperature and injection pressure. Fuel, 2023, 351: 128831.
[23] Zhang Y, L Xu*, Zhu Y, Xu S, Bai X S. Numerical study on liquid ammonia direct injection spray characteristics under engine-relevant conditions. Applied Energy, 2023, 334: 120680.
2022年
[22] Xu S, Zhong S, Zhang F, Bai X S*. On the element mass conservation in Eulerian stochastic field modelling of turbulent combustion. Combustion and Flame, 2022, 239: 111577.
[21] Hadadpour A*, Xu S, Pang K M, Bai X S, et al. Effects of pre-injection on ignition, combustion and emissions of spray under engine-like conditions. Combustion and Flame, 2022, 241: 112082.
[20] Zhong S, Xu L, Xu S, et al. Assessment of grid/filter size dependence in large eddy simulation of high-pressure spray flames. Fuel, 2022, 329: 125316.
[19] Guo L, Zhai M*, Xu S, Shen Q, Dong P, Bai X S, Flame characteristics of methane/air with hydrogen addition in the micro adjustable-spaced combustor. International Journal of Hydrogen Energy, 2022, 47: 19319-19337.
2021年
[18] Xu S*, Pang K M, Li Y, Hadadpour A, et al. LES/TPDF investigation of the effects of ambient methanol concentration on pilot fuel ignition characteristics and reaction front structures. Fuel, 2021, 287: 119502.
[17] Xu S*, Zhong S, Hadadpour A, Zhang Y, et al. Large-eddy simulation of the injection timing effects on the dual-fuel spray flame. Fuel, 2021, 310: 122445.
[16] Huang J, Li S, Sanned D, Xu L, Xu S, Cai W, Qian Y*, Berrocal E, Aldén M, Li Z.S. A detailed study on the micro-explosion of burning iron particles in hot oxidizing environments. Combustion and Flame, 2021, 238: 111755.
[15] Ong J*, Walther J H, Xu S, et al. Effects of ambient pressure and nozzle diameter on ignition characteristics in diesel spray combustion. Fuel, 2021, 290: 119887.
[14] Zhong S, Xu S, Bai X S*, et al. Large eddy simulation of n-heptane/syngas pilot ignition spray combustion: ignition process, liftoff evolution and pollutant emissions. Energy, 2021, 233: 121080.
[13] Zhong S, Xu S, Bai X S*, et al. Combustion characteristics of n-heptane spray combustion in a low temperature reform gas/air environment. Fuel, 2021, 293: 120377.
2020年
[12] Xu S*, Zhong S, Pang K M, et al. Effects of ambient methanol on pollutants formation in dual-fuel spray combustion at varying ambient temperatures: A large-eddy simulation. Applied Energy, 2020, 279: 115774.
[11] Zhang Y, Xu S, Zhong S, et al. Large eddy simulation of spray combustion using flamelet generated manifolds combined with artificial neural networks. Energy and AI, 2020, 2: 100021.
2019年及以前
[10] Xu S, Huang S, Huang R*, et al. Estimation of turbulence characteristics from PIV in a high-pressure fan-stirred constant volume combustion chamber. Applied Thermal Engineering, 2017, 110: 346-355.
[9] Pucilowski M, Li R, Xu S, et al. Comparison of kinetic mechanisms for numerical simulation of methanol combustion in DICI heavy-duty engine. No. 2019-01-0208. SAE Technical Paper, 2019.
[8] Huang S, Zhang Y, Huang R*, Xu S, Ma Y, Wang Z. Quantitative characterization of crack and cell's morphological evolution in premixed expanding spherical flames. Energy, 2019, 171: 161-169.
[7] Zhang Y, Huang R*, Huang Y, Huang S, Ma Y, Xu S, Zhou P. Effect of ambient temperature on the puffing characteristics of single butanol-hexadecane droplet. Energy, 2018, 145: 430-441.
[6] Zhang Y, Huang Y, Huang R*, Huang S, Ma Y, Xu S, Wang Z. A new puffing model for a droplet of butanol-hexadecane blends. Applied Thermal Engineering, 2018, 133: 633-644.
[5] Zhang Y, Huang R*, Xu S, Huang Y, Huang S, Ma Y. The effect of different n-butanol-fatty acid methyl esters (FAME) blends on puffing characteristics. Fuel, 2017, 208: 30-40.
[4] Ma Y, Huang S, Huang R*, Zhang Y, Xu S. Ignition and combustion characteristics of n-pentanol-diesel blends in a constant volume chamber. Applied Energy, 2017, 185: 519-530.
[3] Zhang Y, Huang R*, Wang Z, Xu S, Huang S, Ma Y. Experimental study on puffing characteristics of biodiesel-butanol droplet. Fuel, 2017, 191: 454-462.
[2] Ma Y, Huang R*, Huang S, Zhang Y, Xu S. Experimental investigation on the effect of n-pentanol blending on spray, ignition and combustion characteristics of waste cooking oil biodiesel. Energy Conversion and Management, 2017, 148: 440-455.
[1] Ma Y, Huang R*, Huang S, Zhang Y, Xu S. Spray and evaporation characteristics of n-pentanol-diesel blends in a constant volume chamber. Energy Conversion and Management, 2016, 130: 240-251.
会议报告:
[5] Xu S, Treacy M, Bai X S*. On the combustion modes of ammonia/n-heptane dual-fuel spray combustion: 2D DNS. The 1st Symposium on Ammonia Energy, UK, 2022.
[4] Xu S, Zhang Y, Zhong S, Bai X S*. Automatic generation of the reaction progress variable: a novel approach based on the artificial neural network. The 2nd International Conference on Energy and AI, UK, 2021.
[3] Xu S, Zhong S, Hadadpour A, et al. Effects of the injection timing on the dual-fuel spray flame: A large-eddy simulation. The 2nd world congress on internal combustion engines, China, 2021.
[2] Xu S, Bai X S*, Li Y, et al. Modeling of ammonia solution spray and mixing in selective catalytic reduction (SCR) system. The 11th International Conference on Applied Energy, Sweden, 2019.
[1] Xu S, Bai X S*, Li Y, Xu L. CFD study of selective catalytic reduction (SCR) ammonia solution spray in exhaust pipe of diesel engines. The 37th International Symposium on Combustion, Ireland, 2018.
邀请报告:
- 许世杰. 液氨直喷与双燃料燃烧的高保真数值模拟. 交通能源与智能动力大会 (TEIP), 中国天津, 2023.
- Xu S. Numerical simulation of metal particle combustion. The 1st Workshop on Metal-enabled Cycle of Renewable Energy (MECRE), The Netherlands, 2022.