Fuel Evaporation in an Atmospheric Premixed Burner: Sensitivity Analysis and Spray Vaporization

Csemány, Dávid; Józsa, Viktor

doi:10.3390/pr5040080

Cited by 13 publications

(8 citation statements)

References 35 publications

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“…The mentioned flame shapes are presented in Figure 3. Even though there are visible flares, the majority of the droplets evaporate inside the mixing tube, according to our previous work [43]. Notable flares were only observed in the λ < 1 range.…”

Section: Swirl Characterization and Observed Flamessupporting

confidence: 75%

“…A significant portion of the ORZ is occupied and hence substituted by the 45 • quarl on the right image. inside the mixing tube, according to our previous work [43]. Notable flares were only observed in the λ < 1 range.…”

Section: Swirl Characterization and Observed Flamessupporting

confidence: 62%

“…Over the course of the measurements, the combustion air flow rate increased from 11.9 kg/h until blowout in 2.38 kg/h steps in all setups, which meant 2 m 3 /h steps in rotameter reading. Since the atomizing air flow rate can be calculated using an adiabatic expansion at the atomizer nozzle [43], the second rotameter was used only for validation. The air-to-fuel equivalence ratio, λ, was varied in the range of 0.7-2.…”

Section: Introductionmentioning

confidence: 99%

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Sound Pressure Level Analysis of a Liquid-Fueled Lean Premixed Swirl Burner with Various Quarls

Novotni

Józsa

2020

Acoustics

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Swirl burners are widely used in numerous practical applications since they are characterized by low pollutant emission and a wide operating range. Besides reliable operation, a burner must fulfill noise emission regulations, which is often a sound pressure level in dB(A) when people are affected. Therefore, the present paper evaluates the overall sound pressure level (OASPL) variation of a 15-kW liquid-fueled turbulent atmospheric swirl burner at various setups. Firstly, the combustion air flow rate was adjusted, which induced a swirl number modification due to the fixed swirl vanes. Secondly, the atomizing pressure of the plain-jet airblast atomizer was modified, which also affected the swirl number. High atomizing air jets notably increased combustion noise by intensifying the shear layer. Thirdly, a geometrical modification was performed; 0°–60° half cone angle quarls in 15° steps were installed on the lip of the baseline burner for extended flame stability. By filtering the OASPL to the V-shaped flames, a linearly decreasing trend was observed as a function of swirl number. Their derivative also has a linearly decreasing characteristic as a function of the atomizing pressure.

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Section: Swirl Characterization and Observed Flamessupporting

confidence: 75%

Section: Swirl Characterization and Observed Flamessupporting

confidence: 62%

Section: Introductionmentioning

confidence: 99%

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Sound Pressure Level Analysis of a Liquid-Fueled Lean Premixed Swirl Burner with Various Quarls

Novotni

Józsa

2020

Acoustics

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“…In SCM fluid flow is calculated only for one gaseous phase, which results that the evaporation process of inlet fuel is modelled inside the evaporation and induction time in Equation 3. Further description about evaporation time calculation can be found in literature [27]. This model gives good coverage of kinetic combustion for the lean region and for the burning of evaporated fuel in the region of disintegrated droplets.…”

Section: Combustion Modellingmentioning

confidence: 99%

Assessment of radiative heat transfer impact on a temperature distribution inside a real industrial swirled furnace

et al. 2020

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Combustion systems will continue to share a portion in energy sectors along the current energy transition, and therefore the attention is still given to the further improvements of their energy efficiency. Modern research and development processes of combustion systems are improbable without the usage of predictive numerical tools such as Computational Fluid Dynamics (CFD). The radiative heat transfer in participating media is modelled in this work with Discrete Transfer Radiative Method (DTRM) and Discrete Ordinates Method (DOM) by finite volume discretisation, in order to predict heat transfer inside combustion chamber accurately. DTRM trace the rays in different directions from each face of the generated mesh. At the same time, DOM is described with the angle discretisation, where for each spatial angle the radiative transport equation needs to be solved. In combination with the steady combustion model in AVL FIRE? CFD code, both models are applied for computation of temperature distribution in a real oil-fired industrial furnace for which the experimental results are available. For calculation of the absorption coefficient in both models weighted sum of grey gasses model is used. The focus of this work is to estimate radiative heat transfer with DTRM and DOM models and to validate obtained results against experimental data and calculations without radiative heat transfer, where approximately 25 % higher temperatures are achieved. The validation results showed good agreement with the experimental data with a better prediction of the DOM model in the temperature trend near the furnace outlet. Both radiation modelling approaches show capability for the computation of radiative heat transfer in participating media on a complex validation case of the combustion process in oil-fired furnace.

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“…Table 1 summarizes the relevant parameters of the atomization process. The evaporation of liquid drops inside the mixing tube was calculated elsewhere 34,35 . Note that small droplets are slightly affected by both convection and radiation due to their low inertia and surface area, respectively 36 .…”

Section: The Measurement Systemmentioning

confidence: 99%

Wavelet analysis of flame blowout of a liquid-fueled swirl burner with quarls

Józsa

Novotni

2019

noise cont engng j

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Lean swirl combustion is the leading burner concept today, used in several steadyoperating applications to ensure awide operating range and low pollutant emissions. Approaching lean blowout is highly desired by design to achieve the lowest possible NOX emission. It was shown earlier that quarls could significantly extend the operating regime of liquid-fueled swirl burners. In the present study, the accompanying acoustic noise is evaluated by continuous wavelet transformation to show the effect of various quarl geometries on lean flame blowout. However, the desired flame shape of swirl burners is V, first, and a straight flame, and then a transitory regime can be observed before the developed V-shaped flame through increasing the swirl number. If the axial thrust is excessive, blowout might occur in earlier stages. Presently, the characteristic bands before blowout were analyzed and evaluated at various quarl geometries, swirl numbers, and atomizing pressures. The latter parameter also acts as an axial thrust control to adjust the swirl number. firstly, a straight flame, then a transitory regime can be observed before the developed V-shaped flame through increasing the swirl number. If the axial thrust is excessive, blowout might occur in earlier stages. Presently, the characteristic bands before blowout were analyzed and evaluated at various quarl geometries, swirl numbers, and atomizing pressures. The latter parameter also acts as an axial thrust control to adjust the swirl number.

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Fuel Evaporation in an Atmospheric Premixed Burner: Sensitivity Analysis and Spray Vaporization

Cited by 13 publications

References 35 publications

Sound Pressure Level Analysis of a Liquid-Fueled Lean Premixed Swirl Burner with Various Quarls

Sound Pressure Level Analysis of a Liquid-Fueled Lean Premixed Swirl Burner with Various Quarls

Assessment of radiative heat transfer impact on a temperature distribution inside a real industrial swirled furnace

Wavelet analysis of flame blowout of a liquid-fueled swirl burner with quarls

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