Experimental Study on the Effect of Hydrogen Enrichment of Methane on the Stability and Emission of Nonpremixed Swirl Stabilized Combustor

Sanusi, Yinka S.; Habib, Mohamed A.; Mokheimer, Esmail M. A.

doi:10.1115/1.4028699

Cited by 20 publications

(11 citation statements)

References 36 publications

(29 reference statements)

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“…Mokheimer et al numerically investigated the stability and emission of hydrogen enriched methane under very lean air combustion in a diffusion flam. They developed a combustion mechanism that can closely fit with the experimental results by Sanusi et al From their numerical analysis, Mokheimer et al could determine the optimum equivalence ratio at which the CO emission can be eliminated and NOx emission can be limited below 5 ppm. This optimal equivalence ratio was 0.45 for a hydrogen enriched methane fuel mixture with 30% H 2 .…”

Section: Trends Of Oxycombustion Technologymentioning

confidence: 99%

Oxy-fuel combustion technology: current status, applications, and trends

Nemitallah

Habib

Badr

et al. 2017

Int. J. Energy Res.

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Summary The increased level of emissions of carbon dioxide into the atmosphere due to burning of fossil fuels represents one of the main barriers toward the reduction of greenhouse gases and the control of global warming. In the last decades, the use of renewable and clean sources of energies such as solar and wind energies has been increased extensively. However, due to the tremendously increasing world energy demand, fossil fuels would continue in use for decades which necessitates the integration of carbon capture technologies (CCTs) in power plants. These technologies include oxycombustion, pre‐combustion, and post‐combustion carbon capture. Oxycombustion technology is one of the most promising carbon capture technologies as it can be applied with slight modifications to existing power plants or to new power plants. In this technology, fuel is burned using an oxidizer mixture of pure oxygen plus recycled exhaust gases (consists mainly of CO2). The oxycombustion process results in highly CO2‐concentrated exhaust gases, which facilitates the capture process of CO2 after H2O condensation. The captured CO2 can be used for industrial applications or can be sequestrated. The current work reviews the current status of oxycombustion technology and its applications in existing conventional combustion systems (including gas turbines and boilers) and novel oxygen transport reactors (OTRs). The review starts with an introduction to the available CCTs with emphasis on their different applications and limitations of use, followed by a review on oxycombustion applications in different combustion systems utilizing gaseous, liquid, and coal fuels. The current status and technology readiness level of oxycombustion technology is discussed. The novel application of oxycombustion technology in OTRs is analyzed in some details. The analyses of OTRs include oxygen permeation technique, fabrication of oxygen transport membranes (OTMs), calculation of oxygen permeation flux, and coupling between oxygen separation and oxycombustion of fuel within the same unit called OTR. The oxycombustion process inside OTR is analyzed considering coal and gaseous fuels. The future trends of oxycombustion technology are itemized and discussed in details in the present study including: (i) ITMs for syngas production; (ii) combustion utilizing liquid fuels in OTRs; (iii) oxy‐combustion integrated power plants and (iv) third generation technologies for CO2 capture. Techno‐economic analysis of oxycombustion integrated systems is also discussed trying to assess the future prospects of this technology. Copyright © 2017 John Wiley & Sons, Ltd.

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Section: Trends Of Oxycombustion Technologymentioning

confidence: 99%

Oxy-fuel combustion technology: current status, applications, and trends

Nemitallah

Habib

Badr

et al. 2017

Int. J. Energy Res.

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“…Syngas combustion characteristics and emission was studied in a vertically positioned swirl-stabilized combustor. The combustor adopted in this study has been used for various experimental studies [32][33][34]. Air was supplied through an eight-vane swirler with vane angle of 45 degrees and deliver to an orifice of 16mm diameter situated at the combustor dump plane.…”

Section: Numerical Schemementioning

confidence: 99%

“…In order to validate the governing equations used in this study, experiments were conducted in a swirl stabilized combustor for methane air combustion. Details of the experimental set can be found in [32]. Experiments were carried out with 100% methane and 3.67 MW/m 3 fuel energy input.…”

Section: Validationmentioning

confidence: 99%

Effect of different syngas compositions on the combustion characteristics and emission of a model combustor

Sanusi¹,

Dandajeh²

2020

Nig. J. Tech.

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There is a growing need to design fuel flexible combustors. This require understanding of the combustion and emission characteristics of the combustors under varying fuel compositions. In the present study, the combustion characteristics and emission of methane and syngas flames were investigated numerically in a swirl stabilized combustor. The numerical model was developed using ANSYS-fluent software and validated using experimental values of temperature, CO2 and NOx emissions. A two-step chemical mechanism was used to model methane-air combustion. Results of the numerical validation showed similar trend between the experimental and predicted temperature along the combustor axis with about 5 % over prediction of the temperature. Syngas-air combustion was thereafter modeled using a 21 step chemical mechanism. Syngas compositions studied were: syngas A (67% CO: 33% H2), syngas B (50% CO: 50% H2) and syngas C (33% CO: 67% H2). Results showed that for pure methane, a V-shaped flame was observed with the flame attached to the fuel nozzle, while a lifted flame was observed for case of syngas A composition. CO gas with higher ignition temperature and flammability as compared to H2 gas is the dominant gas in syngas A fuel composition. Jet flames were observed for syngas B and syngas C. Carbon monoxide is a slow burning gas. Therefore syngas with low CO content has a low tendency of emission of CO from the combustor. This suggests that syngas with high CO content such syngas A may require more residence time to completely combust the CO gas. The NOx emission was observed to have the same trend as that of the combustor maximum temperature. Syngas C flame had the highest NOx emission, while, syngas A flame had no NOx emission. This is due to low combustor temperature observed in the case of syngas A flame. Keywords: Syngas, ANSYS-FLUENT, Swirl-stabilized combustor, NOx emission, Chemical Mechanism

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“…Lean, premixed fuel-gas combustion has been receiving increased attention recently because of its ability to reduce emissions of nitrogen oxides (NO X ). The reason for the reduction in emissions is because under lean-burn conditions peak flame temperatures are reduced, and the thermal NO X formation rate decreases because it is strongly temperature dependent − and, also, because for a fixed fuel energy input the overall combustor volume flow rate increases, which reduces the residence time available for NO X formation . Using a mixture that is highly fuel lean, on the other hand, may result, potentially, in incomplete/unstable combustion, which may then increase the concentration of carbon monoxide (CO) and unburned hydrocarbons (UHC) in the exhaust gas.…”

Section: Introductionmentioning

confidence: 99%

Feasibility Study of Biogas Reforming To Improve Energy Efficiency and To Reduce Nitrogen Oxide Emissions

Dabir

Cao

Prosser

et al. 2017

Ind. Eng. Chem. Res.

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The goal of this research was to determine the feasibility of employing the catalytic steam reforming of biogas to increase its energy content by converting the methane it contains into a hydrogen-rich syngas mixture and using this reformate product intermixed with raw biogas in a lean-burn gas engine in order to enhance combustion stability and to reduce NOX emissions. The field-testing component of the project involved catalytically reforming a side stream of biomethane from a landfill gas collection system at a California landfill via a waste energy chemical recuperation process, in which waste heat from a gas engine was used to promote the reforming reaction of biogas. In the study, the total flow of raw biogas diverted to the engine remained constant. A fraction of that biogas was, however, separated and directed to the aforementioned catalytic reactor. The reformer exit stream was then dried, blended with the remaining biogas, and burned in an internal combustion engine to produce electricity. When operating on the blended biogas mixture, combustion stability was enhanced, and the engine ran smoothly at the full speed of 3600 rpm with a 60 Hz output frequency. On the other hand, when burning raw biogas without any reformate gas blended, the test engine ran poorly, sputtering and never reaching 3600 rpm. Also, when operating at various loads under fuel-lean (excess-air) conditions, NOX emissions were significantly reduced when compared to the engine operating on propane under the same load conditions. Similar comparative testing could not be performed on raw landfill gas alone because the engine would not operate at full speed, as noted above. The research presented here has validated the technical and economic feasibility of using reforming products during biogas combustion in a lean-burn gas engine in order to reduce NOX emissions and to enhance combustion stability. This, in our opinion, is an important contribution to the scientific/technical literature and a significant advance for the field of biogas utilization.

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Experimental Study on the Effect of Hydrogen Enrichment of Methane on the Stability and Emission of Nonpremixed Swirl Stabilized Combustor

Cited by 20 publications

References 36 publications

Oxy-fuel combustion technology: current status, applications, and trends

Oxy-fuel combustion technology: current status, applications, and trends

Effect of different syngas compositions on the combustion characteristics and emission of a model combustor

Feasibility Study of Biogas Reforming To Improve Energy Efficiency and To Reduce Nitrogen Oxide Emissions

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