Reference Area Investigation in a Gas Turbine Combustion Chamber Using CFD

Dias, Fagner Luis Goular; António, Marco; Nascimento, Rosa do; Rodrigues, Lucilene de Oliveira

doi:10.5923/j.jmea.20140402.04

Cited by 12 publications

(3 citation statements)

References 6 publications

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“…The generation of the combustors mesh was one of the most important steps in modelling the combustion and flow in the combustors. From an accuracy point of view, tetrahedral elements are often used to create meshes of gas microturbine simulations [26][27][28][29][30]. This kind of mesh element is known to be able to fill complex structures while keeping acceptable quality parameter values (skewness, orthogonality, and aspect ratio).…”

Section: Computational Domainmentioning

confidence: 99%

Computational Fluid Dynamics (CFD) Assessment of the Internal Flue Gases Recirculation (IFGR) Applied to Gas Microturbine in the Context of More Hydrogen-Enriched Fuel Use

Fąfara,

Modliński

2023

Energies

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Renewable energy is a promising substitute for fossil fuels when corelated with P2G technology. To optimise P2G efficiency, there is a need to increase hydrogen fraction in the fuel stream. Simultaneously gas microturbines are widely applied in many industry sectors. These devices are often equipped with diffusion combustors. This situation was investigated in this paper. The P2G and gas microturbines may be integrated together in the future leading to the application of hydrogen-enriched fuel. Hydrogen-enriched fuel causes increase in combustion temperature and velocity. In a nonadapted combustor, these phenomena could result in an increase of NOx emissions and risk of material overheating and failure. In order to adapt the combustors for hydrogen-enriched fuel, the concept of autonomous internal flue gases recirculation (IFGR) system was applied to this issue. In this paper, the IFGR system applied to gas microturbine was studied in terms of hydrogen-enriched fuel application. The obtained exhaust gases recirculation ratios were too low to affect the combustion process as it was expected. The observed combustion modifications in the combustor were hardly linked to the air flow modification in the liner, due to IFGR system implementation. After CFD studies, the proposed IFGR system does not seem to provide the expected effects.

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Section: Computational Domainmentioning

confidence: 99%

Computational Fluid Dynamics (CFD) Assessment of the Internal Flue Gases Recirculation (IFGR) Applied to Gas Microturbine in the Context of More Hydrogen-Enriched Fuel Use

Fąfara,

Modliński

2023

Energies

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“…Specific fuel consumption, turbine inlet temperature, exhaust gas temperature, and emission characteristics were investigated. NOx and CO emission were lowered for butanol-blends compared to those with Jet-A [13][14][15][16][17][18].…”

Section: -Introductionmentioning

confidence: 99%

Numerical Investigation on the Effect of Using Mixtures of Natural Gas and Aviation Fuel on Flame Characteristics of Swirl Gas Turbine Combustor

Farag¹,

Belal

Zeid³

2015

International Conference on Aerospace Sciences and Aviation Tec

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The present paper is directed to study aviation fuel combustion compared to that of natural gas in a gas turbine swirl Combustor. Finite-volume based CFD commercial package ANSYS Fluent 12 is used for the present investigation. The SST k-ω model is used to simulate turbulence. The non-premixed combustion model is used to simulate the reacting flow. Combustion of natural gas is sooty in nature. Thus, soot distribution in the combustor is investigated numerically using the two step soot model. Simple expressions for the soot formation and oxidation rates were employed. The radiation heat transfer equation was solved using the P-1 radiation model. The formation of thermal NO from molecular nitrogen was modeled and the prompt NO was also included in the computations. CFD modeling is validated against experimental temperature measurements for a swirl combustor when firing natural gas as referred to a previous paper. Using the SST-K-ω for predicting gas temperature distributions satisfy reasonable agreement with the experimental temperature measurements, except near the combustor upstream and in the vicinity of the combustor axis.

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“…As powerful computing technologies are continuously and rapidly improved, the feasibility of using CFD analyses is undoubted for combustor design. Many researchers [1][2][3][4][5][6][7][8][9][10][11] employed different model and CFD methods using commercial code to capture the axial, swirl flow and combustion flams. The research [18][19][20][21][22][23][24] using CFD analysis to study the reacting flow within the combustor tube, Crocker et al [18] conducted a numerical analysis of an entire combustor domain, including the fuel nozzle, dome, inner and outer diffuser passages, and the dilution holes.…”

Section: Introductionmentioning

confidence: 99%

CFD Study of Cooled Flow in Annular Combustor of Aircraft-Engine

2017

Sept. 8-10, 2017 Istanbul (Turkey) ESTIA-2017, HEFBS-2017, UTAEE-17, BLECSR-17 &Amp; LEHSS-17

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Reference Area Investigation in a Gas Turbine Combustion Chamber Using CFD

Cited by 12 publications

References 6 publications

Computational Fluid Dynamics (CFD) Assessment of the Internal Flue Gases Recirculation (IFGR) Applied to Gas Microturbine in the Context of More Hydrogen-Enriched Fuel Use

Computational Fluid Dynamics (CFD) Assessment of the Internal Flue Gases Recirculation (IFGR) Applied to Gas Microturbine in the Context of More Hydrogen-Enriched Fuel Use

Numerical Investigation on the Effect of Using Mixtures of Natural Gas and Aviation Fuel on Flame Characteristics of Swirl Gas Turbine Combustor

CFD Study of Cooled Flow in Annular Combustor of Aircraft-Engine

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