Frontiers in combustion techniques and burner designs for emissions control and CO<sub>2</sub>capture: A review

Nemitallah, Medhat A.; Abdelhafez, Ahmed; Ali, Asif; Mansir, Ibrahim B.; Habib, Mohamed A.

doi:10.1002/er.4730

Cited by 31 publications

(44 citation statements)

References 244 publications

(406 reference statements)

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“…To tackle this problem, efficient coal utilization techniques have been proposed. 2,3 Guo et al 4,5 proposed a novel cycle of coal gasification in supercritical water (CGSW). This cycle abandons the traditional burning process and generates a gasified water and carbon-dioxide (H 2 O/CO 2 ) medium.…”

Section: Introductionmentioning

confidence: 99%

Design and analysis of amulti‐stageaxial turbine for gasifiedcoal‐waterpower system

et al. 2021

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Efficient coal gasification is critical to energy saving and environmental protection. Based on a power generation cycle of coal gasification in supercritical water, this article develops a design method for its low-pressure turbine component. The working medium is a mixture of gasified water and carbondioxide (H 2 O/CO 2). Preliminary design is combined with an optimization algorithm to get the optimum design parameters. To analyze turbine off-design performance, a quasi-one dimensional (Q1D) analysis method is proposed, and three dimensional CFD (3D CFD) predictions are also conducted. In addition, a property table for computing thermodynamic properties of mixture fluids is adopted. It is not only employed in the preliminary design, but also utilized by Q1D and 3D CFD calculations. Based on the developed procedure, a nine-stage H 2 O/CO 2 axial turbine is finally designed. Results indicate that the designed H 2 O/CO 2 turbine has an efficiency of 89.0% in the preliminary design, but 3D CFD predicts a lower value of 84%. This discrepancy is mainly due to a fact that the Q1D method ignores 3D flow effects because it uses empirical loss models to evaluate the performance. Moreover, both Q1D and 3D CFD numerical simulations prove a good off-design performance of the turbine.

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Section: Introductionmentioning

confidence: 99%

Design and analysis of amulti‐stageaxial turbine for gasifiedcoal‐waterpower system

et al. 2021

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“…In oxy‐fuel combustion, the fuel is burnt in a mixture of O 2 and recycled flue gas (mainly CO 2 and H 2 O) instead of air 8 . The resulting CO 2 ‐rich flue gas is readily purified in subsequent processes 4,7,8 …”

Section: Introductionmentioning

confidence: 99%

Effects of flue gas recirculation on energy, exergy, environment, and economics in oxy‐coal circulating fluidized‐bed power plants with CO₂ capture

Kim

Lim

Lee

et al. 2020

Intl J of Energy Research

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Summary CO2 capture and storage(CCS) are required for coal‐fired power plants, which are major sources of anthropogenic CO2 emission. In this study, energy, exergy, environment, and economic (4E) analyses were performed for a 500‐MWe oxy‐coal ultra‐supercritical circulating fluidized‐bed (CFB) power plant with CO2 capture. The effect of the location of flue‐gas recirculation (FGR) on the 4E values was investigated for wet FGR (wFGR) at 170°C, dry FGR (dFGR) at 68°C, and 80% wet and 20% dry FGR (wdFGR). The net electricity efficiencies of the wFGR and dFGR power plants were 37% and 36%, respectively. The exergy loss was the largest in the combustor and boiler area, where process improvement was possible. The levelized cost of electricity was approximately 60 $/MWh. The return on investment was 6.7% and 6.1%/y for the wFGR and dFGR plants, respectively. The CO2 emission rate decreased by 90% (from 690 to 76 kg‐CO2/MWh) in the oxy‐coal power plants with CO2 capture. Relative to the wFGR, the dFGR was advantageous for preventing material corrosion because of the lower sulfur content in the FGR stream. For the wdFGR power plant, the process performance was intermediate, that is, between that of the wFGR plant and that of the dFGR plant. The study provided an effective tool for identifying the technological and economic effects of the FGR location for the oxy‐coal power plant with CCS via 4E analyses.

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“…Currently, the main portion of the global energy consumption is obtained from fossil fuel which is not only limited in resources but also has a significant impact on the environment 1,2 . Energy from renewable sources is considered as the best alternatives to fossil fuels, 3,4 and there is a strong relation between the circular economy and renewable energy 5,6 .…”

Section: Introductionmentioning

confidence: 99%

Application of artificial intelligence to maximize methane production from waste paper

et al. 2020

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This article proposes a methodology based on artificial intelligence to enhance methane production from waste paper. The proposed methodology combines fuzzy logic-based modelling and modern optimization. Firstly, a robust Adaptive Network-based Fuzzy Inference System model of methane production process through fuzzy logic modelling is created using experimental datasets. Second, a particle swarm optimizer was used to obtain the optimal process conditions. During the optimization procedure, the beating time and feedstock/inoculum ratio are employed as decision variables in order to maximize methane production. The obtained resulted from the proposed methodology are compared with those obtained by response surface methodology. The results of the comparison confirmed the superiority of the proposed methodology. The fuzzy model shows a better fitting to the experimental data compared to ANOVA. The fuzzy model showed a higher coefficient of determination and a lower value of root mean squared errors compared to ANOVA. Moreover, the proposed strategy, that is, modelling and optimization, is an effective method for increasing the biomethane yield at extended range conditions.

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Frontiers in combustion techniques and burner designs for emissions control and CO₂capture: A review

Cited by 31 publications

References 244 publications

Design and analysis of amulti‐stageaxial turbine for gasifiedcoal‐waterpower system

Design and analysis of amulti‐stageaxial turbine for gasifiedcoal‐waterpower system

Effects of flue gas recirculation on energy, exergy, environment, and economics in oxy‐coal circulating fluidized‐bed power plants with CO₂ capture

Application of artificial intelligence to maximize methane production from waste paper

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Frontiers in combustion techniques and burner designs for emissions control and CO2capture: A review

Cited by 31 publications

References 244 publications

Design and analysis of amulti‐stageaxial turbine for gasifiedcoal‐waterpower system

Design and analysis of amulti‐stageaxial turbine for gasifiedcoal‐waterpower system

Effects of flue gas recirculation on energy, exergy, environment, and economics in oxy‐coal circulating fluidized‐bed power plants with CO2 capture

Application of artificial intelligence to maximize methane production from waste paper

Contact Info

Product

Resources

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Frontiers in combustion techniques and burner designs for emissions control and CO₂capture: A review

Effects of flue gas recirculation on energy, exergy, environment, and economics in oxy‐coal circulating fluidized‐bed power plants with CO₂ capture