Thermodynamic assessment and techno-economic analysis of a liquid indium-based chemical looping system for biomass gasification

Sarafraz, M.M.; Christo, Farid

doi:10.1016/j.enconman.2020.113428

Cited by 33 publications

(9 citation statements)

References 37 publications

(37 reference statements)

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“…2. Sarafraz and Christo [28] performed thermodynamic analysis on the proposed chemical looping gasification system based on liquid metal oxide carrier (CLG-LMOC) and subsequently evaluated the economic viability of the process based on the levelized cost of energy (LCOE).…”

Section: Techno-economic Evaluation Models Without Optimizationmentioning

confidence: 99%

Stochastic techno-economic evaluation model for biomass supply chain: A biomass gasification case study with supply chain uncertainties

How

Teng

et al. 2021

Renewable and Sustainable Energy Reviews

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Section: Techno-economic Evaluation Models Without Optimizationmentioning

confidence: 99%

Stochastic techno-economic evaluation model for biomass supply chain: A biomass gasification case study with supply chain uncertainties

How

Teng

et al. 2021

Renewable and Sustainable Energy Reviews

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“…In the following work, the improved automatic disturbance rejection control is applied to the continuous reactor of the production to improve the stability, productivity, anti-interference, and energy efficiency of the continuous reactor and to alleviate the sludge environmental problems caused by the paper mill. Additionally, the internal circulation reactor used for integrated CO 2 capture and power generation [31] and the reactor in the liquid indium-based chemical circulation system based on biomass gasification [32], respectively, will introduce improved automatic disturbance rejection control to further reduce the energy loss involved in the capture of carbon dioxide from the conversion of hydrocarbon and to maintain the temperature stability to achieve the optimum performance.…”

Section: Conclusion and Prospectmentioning

confidence: 99%

Optimization and Realization of the Continuous Reactor with Improved Automatic Disturbance Rejection Control

Ouyang

Wang

2020

Complexity

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In the chemical production process, the temperature of the continuous reactor has nonlinear characteristics such as large inertia. An improved autodisturbance control method is proposed. By improving the tracking differentiator with adjustable parameters, the expanded state observer and the control structure obtained an improved automatic disturbance rejection control model and realized the optimal control of the nonlinear and large-delay systems. On the process control training system, the experiment of the continuous system process flow is compared with the anti-interference of the Smith predictive compensation system, which uses an optimal set of data. The reactor temperature fluctuates, but the self-resistance is improved. The optimal overshoot of the disturbance is close to 0. Compared with the original antidisturbance controller, the antidisturbance time is not affected by the number of iterations, which reduces the high requirements on the accuracy of the parameters. Therefore, the improved automatic disturbance rejection control improves the operation and enhances the ability to resist external disturbance that changes the controlled object.

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“…In addition to solving these operational challenges, the economic and environmental impact of CLG must be understood to facilitate its transition to an industrial scale. Only a few studies examined the technoeconomic aspects of biomass CLG and showed that the technology is outperforming several existing processes for power generation [26,27] and methanol production [28]. For power generation, Mohamed et al [27] performed a technoeconomic analysis for a potential plant, with a capacity of 650 MW using wood pellets as biomass feedstock and hematite as oxygen carrier.…”

Section: Introductionmentioning

confidence: 99%

Technoeconomic and Environmental Assessment of Biomass Chemical Looping Gasification for Advanced Biofuel Production

Gogulancea

Rolfe

Jaffar

et al. 2023

International Journal of Energy Research

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Chemical looping gasification is a promising biomass conversion technology that could produce sustainable liquid transportation fuels on a large scale to reduce fossil fuel dependency. The current paper examines the technical, economic, and environmental performance of a biomass-to-liquid (BtL) process based on chemical looping gasification and Fischer-Tropsch synthesis. Two biomass feedstocks, i.e., pine forest residues and wheat straw, are selected for assessing the complete BtL production chain. The results of process simulations showed that both biomass types are suitable gasification feedstocks, with an overall energy efficiency of 53% and 52% for pine residues and wheat straw, respectively. The economic results show that the breakeven selling prices (BESP) are €816 and €781 per m3 for the pine forest residues and wheat straw pellets, respectively. However, if low-grade excess heat valorisation and CO2 credits are considered, the BESPs could meet or become lower than the target value of €700 per m3, making the BtL plant competitive with other biofuel plants. The CO2 avoidance cost is estimated at €74.4/tCO2 for pine residues and €61.3/tCO2 for wheat straw, when replacing fossil fuels. The results of the life cycle assessment study showed that the produced biofuels fulfil the requirements of the EU Renewable Energy Directive II, achieving the reduction in greenhouse gases emissions of up to 79% without carbon capture and storage (CCS) and up to 264% with CCS compared to fossil fuels.

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Thermodynamic assessment and techno-economic analysis of a liquid indium-based chemical looping system for biomass gasification

Abstract: Graphical abstract

Cited by 33 publications

References 37 publications

Stochastic techno-economic evaluation model for biomass supply chain: A biomass gasification case study with supply chain uncertainties

Stochastic techno-economic evaluation model for biomass supply chain: A biomass gasification case study with supply chain uncertainties

Optimization and Realization of the Continuous Reactor with Improved Automatic Disturbance Rejection Control

Technoeconomic and Environmental Assessment of Biomass Chemical Looping Gasification for Advanced Biofuel Production

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