CFD predictions of Swirl burner aerodynamics with variable outlet configurations

Baej, Hesham

doi:10.32438/ijet.0615

Cited by 2 publications

(1 citation statement)

References 23 publications

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“…Moreover, it could also unify a radial flow profile when blade-type swirl generators are used. A burner modification with a variable outflow angle from the nozzle was tested by Baej et al [35]. The change of the outflow geometry can affect the CTRZ shape and residence time because of the control of the shear layer direction.…”

Section: Introductionmentioning

confidence: 99%

Emission Characteristics for Swirl Methane–Air Premixed Flames with Ammonia Addition

Jójka

Ślefarski

2021

Energies

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This paper details the experimental and numerical analysis of a combustion process for atmospheric swirl burners using methane with added ammonia as fuel. The research was carried out for lean methane–air mixtures, which were doped with ammonia up to 5% and preheated up to 473 K. A flow with internal recirculation was induced by burners with different outflow angles from swirling blades, 30° and 50°, where tested equivalence ratio was 0.71. The NO and CO distribution profiles on specified axial positions of the combustor and the overall emission levels at the combustor outlet were measured and compared to a modelled outcome. The highest values of the NO emissions were collected for 5% NH3 and 50° (1950 ppmv), while a reduction to 1585 ppmv was observed at 30°. The doubling of the firing rates from 15 kW up to 30 kW did not have any great influence on the overall emissions. The emission trend lines were not proportional to the raising share of the ammonia in the fuel. 3D numerical tests and a kinetic study with a reactor network showed that the NO outlet concentration for swirl flame depended on the recirculation ratio, residence time, wall temperature, and the mechanism used. Those parameters need to be carefully defined in order to get highly accurate NO predictions—both for 3D simulations and simplified reactor-based models.

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Section: Introductionmentioning

confidence: 99%

Emission Characteristics for Swirl Methane–Air Premixed Flames with Ammonia Addition

Jójka

Ślefarski

2021

Energies

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CFD predictions of Swirl burner aerodynamics with variable outlet configurations

Baej¹

2019

IJET

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Swirl stabilised combustion is one of the most widely used techniques for flame stabilisation in gas turbine combustors. Lean premixed combustion systems allow the reduction of NOx coupled with fair flame stability. The swirl mechanism produces an aerodynamic region known as central recirculation zone (CRZ) providing a low velocity region where the flame speed matches the flow velocity, thus anchoring the flame whilst serving to recycle heat and active chemical species to the root of the former. Another beneficial feature of the CRZ is the enhancement of the mixing in and around this region. However, the mixing and stabilisation processes inside of this zone have shown to be extremely complex. The level of swirl, burner outlet configuration and combustor expansion are very important variables that define the features of the CRZ. Therefore, in this paper swirling flame dynamics are investigated using computational fluid dynamics (CFD) with commercial software (ANSYS). A new generic swirl burner operated under lean-premixed conditions was modelled. A variety of nozzles were analysed using several gaseous blends at a constant power output. The investigation was based on recognising the size and strength of the central recirculation zones. The dimensions and turbulence of the Central Recirculation Zone were measured and correlated to previous experiments. The results show how the strength and size of the recirculation zone are highly influenced by the blend and infer that it is governed by both the shear layer surrounding the Central Recirculation Zones (CRZ) and the gas composition.

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CFD predictions of Swirl burner aerodynamics with variable outlet configurations

Cited by 2 publications

References 23 publications

Emission Characteristics for Swirl Methane–Air Premixed Flames with Ammonia Addition

Emission Characteristics for Swirl Methane–Air Premixed Flames with Ammonia Addition

CFD predictions of Swirl burner aerodynamics with variable outlet configurations

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