Influence of Inlet Dilution of Reactants on Premixed Combustion in a Recuperative Furnace

Li, Pengfei; Mi, Jianchun

doi:10.1007/s10494-011-9348-x

Cited by 24 publications

(23 citation statements)

References 28 publications

(62 reference statements)

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“…However, chemical effects, such as the addition of H 2 O and CO 2 to NO emission, were observed. The results showed that the reduction in the temperature of beak flame with additional CO 2 is higher than that of the beak flame with additional H 2 O . Diluted fuel (50% natural gas and 50% N 2 ) had an effect on industrial furnaces in highly preheated and diluted air (1273 K with 10% O 2 and 90% N 2 ) combustion.…”

Section: Reduction In Thermal Nox During Flameless Combustionmentioning

confidence: 97%

“…Influence of diluents on temperature uniformity [51]. temperature of beak flame with additional CO 2 is higher than that of the beak flame with additional H 2 O [98][99][100][101]. Diluted fuel (50% natural gas and 50% N 2 ) had an effect on industrial furnaces in highly preheated and diluted air (1273 K with 10% O 2 and 90% N 2 ) combustion.…”

Section: Effect Of Gas Diluentsmentioning

confidence: 99%

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Flameless combustion role in the mitigation of NO_Xemission: a review

Abuelnuor

Wahid

Mohammed

et al. 2014

Int. J. Energy Res.

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SUMMARYNitrogen oxide formation is one source of pollution emission in fossil fuel combustion. Numerous technologies, such as flameless combustion, have been introduced to prevent such formation. This paper presents a panorama of flameless combustion and its principles. The influence of this technology on air preheats and gas diluents is discussed, as well as the effect of the firing mode on thermal NO X . The benefits of flameless combustion, including its energy conservation capability and capability to reduce pollutant emissions such as NO X emission to overcome environmental dilemmas in combustion, are discussed in this paper.

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Section: Reduction In Thermal Nox During Flameless Combustionmentioning

confidence: 97%

Section: Effect Of Gas Diluentsmentioning

confidence: 99%

Flameless combustion role in the mitigation of NO_Xemission: a review

Abuelnuor

Wahid

Mohammed

et al. 2014

Int. J. Energy Res.

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“…In practice, MILD combustion is achieved typically by injecting fuel and air into either a recirculating flow or a stream containing hot products. In these configurations, the conditions for MILD combustion are achieved despite the limited time available for the fuel to mix with oxidizer because of the high momentum of the jets (Awosope et al, 2006;Cavaliere and de Joannon, 2004;Dally et al, 2002Dally et al, , 2004Galleti et al, 2007;Katsuki and Hasegawa, 1998;Li and Mi, 2011). Also, there is a possibility to find inhomogeneous mixture containing pockets of unburned and burned gases.…”

Section: Flow Configurationmentioning

confidence: 99%

“…The combustion efficiency is enhanced under MILD conditions due to high preheating temperature using recovered exhaust heat (Cavaliere and de Joannon, 2004;Katsuki and Hasegawa, 1998;Wünning and Wünning, 1997). The thermal NO x formation is suppressed significantly due to low combustion temperature rise and intense dilution (Cavaliere and de Joannon, 2004;Katsuki and Hasegawa, 1998;Krishnamurthy et al, 2009;Li and Mi, 2011;Mohamed et al, 2009;Wünning and Wünning, 1997). Typically, it takes few seconds to produce a substantial amount of thermal NO x at around 1900 K and this reduces to a few milliseconds when the temperature is about 2300 K (Wünning and Wünning, 1997).…”

Section: Introductionmentioning

confidence: 99%

Reaction Zones and Their Structure in MILD Combustion

Minamoto

Swaminathan

Cant

et al. 2014

Combustion Science and Technology

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Three-dimensional direct numerical simulation (DNS) of turbulent combustion under moderate and intense low-oxygen dilution (MILD) conditions has been carried out inside a cuboid with inflow and outflow boundaries on the upstream and downstream faces, respectively. The initial and inflowing mixture and turbulence fields are constructed carefully to be representative of MILD conditions involving partially mixed pockets of unburned and burned gases. The combustion kinetics are modeled using a skeletal mechanism for methane-air combustion, including non-unity Lewis numbers for species and temperature-dependent transport properties. The DNS data is analyzed to study the MILD reaction zone structure and its behavior. The results show that the instantaneous reaction zones are convoluted and the degree of convolution increases with dilution and turbulence levels. Interactions of reaction zones occur frequently and are spread out in a large portion of the computational domain due to the mixture non-uniformity and high turbulence level. These interactions lead to local thickening of reaction zones yielding an appearance of distributed combustion despite the presence of local thin reaction zones. A canonical MILD flame element, called MIFE, is proposed, which represents the averaged mass fraction variation for major species reasonably well, although a fully representative canonical element needs to include the effect of reaction zone interactions and associated thickening effects on the mean reaction rate.

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“…According to Li et al [12], high temperature pre-heating of combustion air and the high-speed injection of fuel are the main requirements to achieve MILD combustion condition. Based on these requirements, model flames like the Adelaide Jet in Hot Co-flow (JHC) burner [13] and Delft JHC burner [14,15] were built to emulate MILD condition.…”

Section: Introductionmentioning

confidence: 99%

Comprehensive numerical study of the Adelaide Jet in Hot-Coflow burner by means of RANS and detailed chemistry

Cuoci

Sadiki

et al. 2017

Energy

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The present paper shows an in-depth numerical characterisation of the Jet in Hot Co-flow (JHC) configuration using the Reynolds Averaged Navier-Stokes (RANS) modelling with detailed chemistry. The JHC burner emulates the MILD combustion by means of a hot and diluted co-flow and high speed injection. The current investigation focuses on the effect of turbulent combustion models, turbulence model parameters, boundary conditions, multi-component molecular diffusion and kinetic mechanisms on the results. Results show that the approaches used to model the reaction fine structures, namely as Perfectly Stirred Reactors (PSR) or Plug Flow Reactors (PFR), do not have a major impact on the results. Similarly, increasing the complexity of the kinetic mechanism does not lead to major improvements on the numerical predictions. On the other hand, the inclusion of multi-component molecular diffusion helps increasing the prediction accuracy. Three different Eddy Dissipation Concept (EDC) model formulations are compared, showing their interaction with the choice of the C 1 constant in the k − turbulence model. Finally, two approaches are benchmarked for turbulence-chemistry interactions, the EDC model and the Partially Stirred Reactor (PaSR) model.

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Influence of Inlet Dilution of Reactants on Premixed Combustion in a Recuperative Furnace

Cited by 24 publications

References 28 publications

Flameless combustion role in the mitigation of NO_Xemission: a review

Flameless combustion role in the mitigation of NO_Xemission: a review

Reaction Zones and Their Structure in MILD Combustion

Comprehensive numerical study of the Adelaide Jet in Hot-Coflow burner by means of RANS and detailed chemistry

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Influence of Inlet Dilution of Reactants on Premixed Combustion in a Recuperative Furnace

Cited by 24 publications

References 28 publications

Flameless combustion role in the mitigation of NOXemission: a review

Flameless combustion role in the mitigation of NOXemission: a review

Reaction Zones and Their Structure in MILD Combustion

Comprehensive numerical study of the Adelaide Jet in Hot-Coflow burner by means of RANS and detailed chemistry

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Flameless combustion role in the mitigation of NO_Xemission: a review

Flameless combustion role in the mitigation of NO_Xemission: a review