Thermochemical Conversion Processes for Solid Fuels and Renewable Energies
Alobaid, Falah
Thermochemical Conversion Processes for Solid Fuels and Renewable Energies - Basel, Switzerland MDPI - Multidisciplinary Digital Publishing Institute 2021 - 1 electronic resource (222 p.)
Open Access
It is widely believed that a large proportion of greenhouse gas emissions originated anthropogenically from the use of fossil fuels with additional contributions coming from manufactured materials, deforestation, soil erosion, and agriculture (including livestock). The global society actively supports measures to create a flexible and low-carbon energy economy to attenuate climate change and its devastating environmental consequences. In this Special Issue, the recent advancements in the next-generation thermochemical conversion processes for solid fuels and renewable energies (e.g., the operational flexibility of co-combustion of biomass and lignite, integrated solar combined cycle power plants, and advanced gasification systems such as the sorption-enhanced gasification and the chemical looping gasification) were shown.
Creative Commons
English
books978-3-0365-1097-2 9783036510965 9783036510972
10.3390/books978-3-0365-1097-2 doi
Research & information: general
Technology: general issues
hydrochar hydrothermal carbonization biogas upgrading CO2 capture pressure swing adsorption gasification kinetic model conversion model reaction model low-rank coal tar absorption process simulation validation study sensitivity analyses lignite lignite gasification fluidized-bed gasifier olivine solar cooling solar cooling system TRNSYS absorption chiller performance and analysis solar energy chemical looping biomass gasification process control CO2 absorption experimental study energy analysis exergy analysis CSP PTC ISCC power plant CFB combustion operational flexibility load transients fluctuating electricity generation renewables one-dimensional SEG model dual fluidized bed sorbent deactivation hydrodynamics kinetics fuel feeding rate biomass thermochemical conversion technologies combustion carbon capture and storage/utilization solar-driven air-conditioning integrated solar combined cycle energy and exergy analyses thermodynamic modeling dynamic process simulation
Thermochemical Conversion Processes for Solid Fuels and Renewable Energies - Basel, Switzerland MDPI - Multidisciplinary Digital Publishing Institute 2021 - 1 electronic resource (222 p.)
Open Access
It is widely believed that a large proportion of greenhouse gas emissions originated anthropogenically from the use of fossil fuels with additional contributions coming from manufactured materials, deforestation, soil erosion, and agriculture (including livestock). The global society actively supports measures to create a flexible and low-carbon energy economy to attenuate climate change and its devastating environmental consequences. In this Special Issue, the recent advancements in the next-generation thermochemical conversion processes for solid fuels and renewable energies (e.g., the operational flexibility of co-combustion of biomass and lignite, integrated solar combined cycle power plants, and advanced gasification systems such as the sorption-enhanced gasification and the chemical looping gasification) were shown.
Creative Commons
English
books978-3-0365-1097-2 9783036510965 9783036510972
10.3390/books978-3-0365-1097-2 doi
Research & information: general
Technology: general issues
hydrochar hydrothermal carbonization biogas upgrading CO2 capture pressure swing adsorption gasification kinetic model conversion model reaction model low-rank coal tar absorption process simulation validation study sensitivity analyses lignite lignite gasification fluidized-bed gasifier olivine solar cooling solar cooling system TRNSYS absorption chiller performance and analysis solar energy chemical looping biomass gasification process control CO2 absorption experimental study energy analysis exergy analysis CSP PTC ISCC power plant CFB combustion operational flexibility load transients fluctuating electricity generation renewables one-dimensional SEG model dual fluidized bed sorbent deactivation hydrodynamics kinetics fuel feeding rate biomass thermochemical conversion technologies combustion carbon capture and storage/utilization solar-driven air-conditioning integrated solar combined cycle energy and exergy analyses thermodynamic modeling dynamic process simulation