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Yucheng Kuang, Boshu He, Chaojun Wang, Wenxiao Tong & Di He. (2024) Numerical Research for MILD Burners with Different configurations. Combustion Science and Technology 196:3, pages 421-438.
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Jeffrey William Labahn & Cecile Devaud. (2017) Species and temperature predictions in a semi-industrial MILD furnace using a non-adiabatic conditional source-term estimation formulation. Combustion Theory and Modelling 21:3, pages 466-486.
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A. S. Veríssimo, A. M. A. Rocha, P. J. Coelho & M. Costa. (2015) Experimental and Numerical Investigation of the Influence of the Air Preheating Temperature on the Performance of a Small-Scale Mild Combustor. Combustion Science and Technology 187:11, pages 1724-1741.
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A. Rebola, P.J. Coelho & M. Costa. (2013) Assessment of the Performance of Several Turbulence and Combustion Models in the Numerical Simulation of a Flameless Combustor. Combustion Science and Technology 185:4, pages 600-626.
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Lin Wang, Zhaohui Liu, Sheng Chen & Chuguang Zheng. (2012) Comparison of Different Global Combustion Mechanisms Under Hot and Diluted Oxidation Conditions. Combustion Science and Technology 184:2, pages 259-276.
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Articles from other publishers (63)
Marco Lubrano Lavadera, M. Mustafa Kamal, Saurabh Sharma, Laura Donato, Chiara Galletti, Axel Coussement & Alessandro Parente. (2024) A combined experimental, numerical, and data consistency approach for the characterization of temperature distribution in a MILD combustion furnace. Applied Thermal Engineering 243, pages 122625.
Crossref
Crossref
Haohua Liao, Fan Hu, Xinying Wu, Pengfei Li, Cuijiao Ding, Chao Yang, Tai Zhang & Zhaohui Liu. (2024) Effects of H2 addition on the characteristics of the reaction zone and NO mechanisms in MILD combustion of H2-rich fuels. International Journal of Hydrogen Energy 58, pages 174-189.
Crossref
Crossref
Tingyao Zhang, Yuegui Zhou & Bofei Zhou. (2022) The effects of the initial NO volume fractions on the NOx generation and reduction routes under natural gas MILD combustion conditions. Fuel 328, pages 125175.
Crossref
Crossref
Chunjing Liu, Xiude Hu, Gang Chen & Jianyi Lu. (2022) Temperature and NOx distribution characteristics of coal particles under high-temperature and low-oxygen environments simulating MILD oxy-coal combustion conditions. Journal of the Energy Institute 101, pages 73-86.
Crossref
Crossref
Manabendra Saha & Bassam B. Dally. 2022. Fundamentals of Low Emission Flameless Combustion and Its Applications. Fundamentals of Low Emission Flameless Combustion and Its Applications
505
552
.
Xuebin Wang, Zia ur Rahman & Yixiang Zhang. 2022. Fundamentals of Low Emission Flameless Combustion and Its Applications. Fundamentals of Low Emission Flameless Combustion and Its Applications
565
593
.
Saurabh Sharma & Sudarshan Kumar. 2022. Fundamentals of Low Emission Flameless Combustion and Its Applications. Fundamentals of Low Emission Flameless Combustion and Its Applications
45
79
.
Yaxin Su & Bingtao Zhao. 2022. Fundamentals of Low Emission Flameless Combustion and Its Applications. Fundamentals of Low Emission Flameless Combustion and Its Applications
81
117
.
Shunta Xu, Yihao Xie, Pu Huang, Hao Ren, Yaojie Tu & Hao Liu. (2021) Nonpremixed Air/Oxygen Jet Burner to Improve Moderate or Intense Low-Oxygen Dilution Combustion Characteristics in Oxygen-Enriched Conditions. Energy & Fuels 35:11, pages 9609-9622.
Crossref
Crossref
Jianchun Mi, Pengfei Li, Feifei Wang, Kin-Pang Cheong & Guochang Wang. (2021) Review on MILD Combustion of Gaseous Fuel: Its Definition, Ignition, Evolution, and Emissions. Energy & Fuels 35:9, pages 7572-7607.
Crossref
Crossref
Aleksi Laukka, Eetu-Pekka Heikkinen & Timo Fabritius. (2021) The Atmosphere’s Effect on Stainless Steel Slabs’ Oxide Formation in a CH4-Fuelled Reheating Furnace. Metals 11:4, pages 621.
Crossref
Crossref
Yaojie Tu, Shunta Xu, Mengqian Xie, Zean Wang & Hao Liu. (2021) Numerical simulation of propane MILD combustion in a lab-scale cylindrical furnace. Fuel 290, pages 119858.
Crossref
Crossref
Tingyao Zhang, Zhongfa Hu & Yuegui Zhou. (2020) Numerical analysis on the characteristic chemical time scale and combustion regime of natural gas MILD combustion. Fuel 282, pages 118811.
Crossref
Crossref
Mohsen Saffari Pour, Ali Hakkaki-Fard & Bahar Firoozabadi. (2020) Numerical Investigation of a Portable Incinerator: A Parametric Study. Processes 8:8, pages 923.
Crossref
Crossref
Yihao Xie, Yaojie Tu, Hu Jin, Congcong Luan, Zean Wang & Hao Liu. (2019) Numerical study on a novel burner designed to improve MILD combustion behaviors at the oxygen enriched condition. Applied Thermal Engineering 152, pages 686-696.
Crossref
Crossref
Zewu Zhang, Xiaoshan Li, Liqi Zhang, Cong Luo, Zhihui Mao, Yongqing Xu, Ji Liu, Gaocheng Liu & Chuguang Zheng. (2019) Numerical investigation of the effects of different injection parameters on Damköhler number in the natural gas MILD combustion. Fuel 237, pages 60-70.
Crossref
Crossref
Feifei Wang, Pengfei Li, Jianchun Mi & Jinbo Wang. (2018) A refined global reaction mechanism for modeling coal combustion under moderate or intense low-oxygen dilution condition. Energy 157, pages 764-777.
Crossref
Crossref
Fan Hu, Pengfei Li, Junjun Guo, Feifei Wang, Kai Wang, Xudong Jiang, Zhaohui Liu & Chuguang Zheng. (2018) Optimal Equivalence Ratio to Minimize NO Emission during Moderate or Intense Low-Oxygen Dilution Combustion. Energy & Fuels 32:4, pages 4478-4492.
Crossref
Crossref
Manabendra Saha, Giovanni Gitto, Alfonso Chinnici & Bassam B. Dally. (2017) Comparative Study of the MILD Combustion Characteristics of Biomass and Brown Coal. Energy & Fuels 32:4, pages 4202-4211.
Crossref
Crossref
Yaojie Tu, Wenming Yang & Hao Liu. (2017) A Refined Global Reaction Mechanism for Gently Preheated MILD Combustion of Methane. Energy & Fuels 31:9, pages 10144-10157.
Crossref
Crossref
R. Gültekin, A. Rückert & H. Pfeifer. (2017) Numerical Approach for the Implementation of the Interaction of Pyrolysis Gases and Combustion Products in an Aluminium-Melting Furnace. Energy Procedia 120, pages 157-164.
Crossref
Crossref
A. Chinnici, Z.F. Tian, J.H. Lim, G.J. Nathan & B.B. Dally. (2017) Comparison of system performance in a hybrid solar receiver combustor operating with MILD and conventional combustion. Part II: Effect of the combustion mode. Solar Energy 147, pages 479-488.
Crossref
Crossref
Yaojie Tu, Kai Su, Hao Liu, Zean Wang, Yihao Xie, Chuguang Zheng & Weijie Li. (2017) MILD combustion of natural gas using low preheating temperature air in an industrial furnace. Fuel Processing Technology 156, pages 72-81.
Crossref
Crossref
İ. Bedii Özdemir & Murat Kantaş. (2016) Investigation of partially-premixed combustion in a household cooker-top burner. Fuel Processing Technology 151, pages 107-116.
Crossref
Crossref
Manabendra Saha, Bassam B. Dally, Paul R. Medwell & Alfonso Chinnici. (2016) Burning characteristics of Victorian brown coal under MILD combustion conditions. Combustion and Flame 172, pages 252-270.
Crossref
Crossref
Qiyuan Li, Ali Shirazi, Cheng Zheng, Gary Rosengarten, Jason A. Scott & Robert A. Taylor. (2016) Energy concentration limits in solar thermal heating applications. Energy 96, pages 253-267.
Crossref
Crossref
Seyyed Shahabeddin Azimi & Mohammad Hosain Namazi. (2015) Modeling of combustion of gas oil and natural gas in a furnace: Comparison of combustion characteristics. Energy 93, pages 458-465.
Crossref
Crossref
Jeongwon Lee, Sangtae Jeon & Yongmo Kim. (2015) Multi-environment probability density function approach for turbulent CH4/H2 flames under the MILD combustion condition. Combustion and Flame 162:4, pages 1464-1476.
Crossref
Crossref
Yaojie Tu, Hao Liu, Sheng Chen, Zhaohui Liu, Haibo Zhao & Chuguang Zheng. (2015) Effects of furnace chamber shape on the MILD combustion of natural gas. Applied Thermal Engineering 76, pages 64-75.
Crossref
Crossref
Y. Minamoto & N. Swaminathan. (2015) Subgrid scale modelling for MILD combustion. Proceedings of the Combustion Institute 35:3, pages 3529-3536.
Crossref
Crossref
Seyed Ehsan Hosseini & Mazlan Abdul Wahid. (2014) Development of biogas combustion in combined heat and power generation. Renewable and Sustainable Energy Reviews 40, pages 868-875.
Crossref
Crossref
Jean Lamouroux, Matthias Ihme, Benoit Fiorina & Olivier Gicquel. (2014) Tabulated chemistry approach for diluted combustion regimes with internal recirculation and heat losses. Combustion and Flame 161:8, pages 2120-2136.
Crossref
Crossref
Y. Minamoto & N. Swaminathan. (2014) Modelling paradigms for MILD combustion. International Journal of Advances in Engineering Sciences and Applied Mathematics 6:1-2, pages 65-75.
Crossref
Crossref
Seyed Ehsan Hosseini, Ghobad Bagheri & Mazlan Abdul Wahid. (2014) Numerical investigation of biogas flameless combustion. Energy Conversion and Management 81, pages 41-50.
Crossref
Crossref
Carlos E. Arrieta & Andrés A. Amell. (2014) Highly flexible burner concept for research on combustion technologies with recirculation of hot combustion products. Applied Thermal Engineering 63:2, pages 559-564.
Crossref
Crossref
İlker Yılmaz. (2013) Effect of Swirl Number on Combustion Characteristics in a Natural Gas Diffusion Flame. Journal of Energy Resources Technology 135:4.
Crossref
Crossref
Ali Abuelnuor Abdeen Abuelnuor, Mazlan Abdul Wahid, Aminuddin Saat, Mohsin M. Sies, M. Kabashi Elbasheer, Seyed Ehsan Hosseini, Ahmed G. Dairobi, H.A. Mohammed & A.N. Darus. (2013) Review of Numerical Studies on NO<sub>x</sub> Emission in the Flameless Combustion. Applied Mechanics and Materials 388, pages 235-240.
Crossref
Crossref
?lker Y?lmaz, Murat Ta?tan, Mustafa ?lba?Cevahir Tarhan. (2013) Effect of turbulence and radiation models on combustion characteristics in propane?hydrogen diffusion flames. Energy Conversion and Management 72, pages 179-186.
Crossref
Crossref
M. Graça, A. Duarte, P.J. Coelho & M. Costa. (2013) Numerical simulation of a reversed flow small-scale combustor. Fuel Processing Technology 107, pages 126-137.
Crossref
Crossref
Qiang Li, Huimin Lu & Lian Zhou. 2013. EPD Congress 2013. EPD Congress 2013
143
150
.
A Veríssimo, R Oliveira, P J Coelho & M Costa. (2012) Numerical Simulation of a Small-Scale Mild Combustor. Journal of Physics: Conference Series 395, pages 012003.
Crossref
Crossref
M. Vascellari & G. Cau. (2012) Influence of turbulence–chemical interaction on CFD pulverized coal MILD combustion modeling. Fuel 101, pages 90-101.
Crossref
Crossref
Paolo Gobbato, Massimo Masi, Andrea Toffolo, Andrea Lazzaretto & Giordano Tanzini. (2012) Calculation of the flow field and NO x emissions of a gas turbine combustor by a coarse computational fluid dynamics model. Energy 45:1, pages 445-455.
Crossref
Crossref
Ya Xin Su & Cui Wu Chen. (2012) Numerical Study on NO Mechanism during High Temperature Air Combustion of Natural Gas. Applied Mechanics and Materials 190-191, pages 609-614.
Crossref
Crossref
Abbas Khoshhal, Masoud Rahimi & Ammar Abdulaziz Alsairafi. (2011) CFD study on influence of fuel temperature on NOx emission in a HiTAC furnace. International Communications in Heat and Mass Transfer 38:10, pages 1421-1427.
Crossref
Crossref
Ashoke De, Ernst Oldenhof, Pratap Sathiah & Dirk Roekaerts. (2011) Numerical Simulation of Delft-Jet-in-Hot-Coflow (DJHC) Flames Using the Eddy Dissipation Concept Model for Turbulence–Chemistry Interaction. Flow, Turbulence and Combustion 87:4, pages 537-567.
Crossref
Crossref
E. Oldenhof, M.J. Tummers, E.H. van Veen & D.J.E.M. Roekaerts. (2011) Role of entrainment in the stabilisation of jet-in-hot-coflow flames. Combustion and Flame 158:8, pages 1553-1563.
Crossref
Crossref
Pauline Eugenie Vervisch, Olivier Colin, Jean-Baptiste Michel & Nasser Darabiha. (2011) NO Relaxation Approach (NORA) to predict thermal NO in combustion chambers. Combustion and Flame 158:8, pages 1480-1490.
Crossref
Crossref
A. S. Veríssimo, A. M. A. Rocha & M. Costa. (2011) Operational, Combustion, and Emission Characteristics of a Small-Scale Combustor. Energy & Fuels 25:6, pages 2469-2480.
Crossref
Crossref
Yaxin Su, Wenhui Wang & Fan Jiang. (2011) Prediction of swirling combustion in high temperature and low oxygen condition. Prediction of swirling combustion in high temperature and low oxygen condition.
Yaxin Su, Wenyi Deng & Fan Jiang. (2011) Notice of Retraction: Numerical Simulation of Inlet Oxygen Influence on NO Emission under Preheated Air Condition. Notice of Retraction: Numerical Simulation of Inlet Oxygen Influence on NO Emission under Preheated Air Condition.
Abhas Khoshhal, Masoud Rahimi, Afshar Ghahramani & Ammar Abdulaziz Alsairafi. (2011) Computational fluid dynamics modeling of high temperature air combustion in an heat recovery steam generator boiler. Korean Journal of Chemical Engineering 28:5, pages 1181-1187.
Crossref
Crossref
Yaxin Su, Wenyi Deng & Fan Jiang. (2011) NO emission from high temperature air combustion of natural gas with longitudinal and swirling burner. NO emission from high temperature air combustion of natural gas with longitudinal and swirling burner.
Yaxin Su, Wenyi Deng, Fan Jiang & Henggen Shen. (2011) Numerical Study of Effect of Burner Jet Parameters on High Temperature Air Combustion of Coal Gas. Numerical Study of Effect of Burner Jet Parameters on High Temperature Air Combustion of Coal Gas.
PengFei Li, JianChun Mi, B. B. Dally, FeiFei Wang, Lin Wang, ZhaoHui Liu, Sheng Chen & ChuGuang Zheng. (2011) Progress and recent trend in MILD combustion. Science China Technological Sciences 54:2, pages 255-269.
Crossref
Crossref
Mariarosaria de Joannon, Pino Sabia & Antonio Cavaliere. 2010. Handbook of Combustion. Handbook of Combustion
237
256
.
Yaxin Su & Bingtao Zhao. (2010) CFD Simulation of High Temperature Air Combustion of Coal Gas at Different Air Straddle Angle. CFD Simulation of High Temperature Air Combustion of Coal Gas at Different Air Straddle Angle.
K.W. Lee & D.H. Choi. (2009) Numerical study on high-temperature diluted air combustion for the turbulent jet flame in crossflow using an unsteady flamelet model. International Journal of Heat and Mass Transfer 52:25-26, pages 5740-5750.
Crossref
Crossref
K.W. Lee & D.H. Choi. (2009) Analysis of NO formation in high temperature diluted air combustion in a coaxial jet flame using an unsteady flamelet model. International Journal of Heat and Mass Transfer 52:5-6, pages 1412-1420.
Crossref
Crossref
Jochen R. Kalb & Thomas Sattelmayer. (2006) Lean Blowout Limit and NOx Production of a Premixed Sub-ppm NOx Burner With Periodic Recirculation of Combustion Products. Journal of Engineering for Gas Turbines and Power 128:2, pages 247-254.
Crossref
Crossref
Priya Gopalakrishnan, Satish Undapalli, Mohan Krishna Bobba, Vaidyanathan Sankaran, Suresh Menon, Ben Zinn & Jerry Seitzman. (2006) Measurements and Modeling of the Flow Field in an Ultra-Low Emissions Combustor. Measurements and Modeling of the Flow Field in an Ultra-Low Emissions Combustor.
Yang Weihong & Wlodzimierz Blasiak. (2004) Combustion performance and numerical simulation of a high‐temperature air–LPG flame on a regenerative burner. Scandinavian Journal of Metallurgy 33:2, pages 113-120.
Crossref
Crossref
Tingyao Zhang, Yuegui Zhou & Bofei Zhou. (2021) The Effects of the Initial NO Volume Fractions on NOx Generation and Reduction Routes Under Natural Gas MILD Combustion Condition. SSRN Electronic Journal.
Crossref
Crossref