Your search keyword '"Tayebeh Marzoughi"' showing total 2 results

1. Environmental and thermodynamic performance assessment of biomass gasification process for hydrogen production in a downdraft gasifier

Author

Tayebeh Marzoughi, Mohammad Reza Rahimpour, and Fereshteh Samimi

Subjects

Waste management, 020209 energy, Modeling and Simulation, General Chemical Engineering, Scientific method, Downdraft gasifier, 0202 electrical engineering, electronic engineering, information engineering, Environmental science, 02 engineering and technology, Biomass gasification, 021001 nanoscience & nanotechnology, 0210 nano-technology, Hydrogen production

Abstract

Gasification is one of the most efficient techniques for sustainable hydrogen production from biomass. In this study, a comparative performance analysis of the gasification process using various types of biomass materials was undertaken via thermodynamic approach. Air, steam, and air/steam as the traditional gasifying agents were applied to provide an opportunity to choose the most proper agent in the process. This paper also evaluates the environmental impacts of the process in terms of CO2 emission by using Aspen Energy Analyzer. The effects of agent to biomass molar ratio, agent inlet temperature, moisture content of biomass material, and gasification temperature were estimated based on the producer gas compositions, hydrogen yield and heating values. The results indicate that the highest hydrogen yield (0.074 g H2/g biomass) was obtained in the steam gasification of plastic, while air gasification of paper generates the lowest one. It was also observed that manure is the most beneficial from environmental perspectives, while tire and plastic have the highest contribution to CO2 emission and consequently global warming. The higher values of hydrogen production and LHV of produced gas are associated respectively with using steam, air/steam, and air as the gasification agents. The lowest value of CO2 emission is obtained for air, air/steam, and steam as the gasifying agents, respectively.

Published

2021

2. Energy and exergy analysis and optimization of biomass gasification process for hydrogen production (based on air, steam and air/steam gasifying agents)

Author

Tayebeh Marzoughi, Mohammad Reza Rahimpour, and Fereshteh Samimi

Subjects

Exergy, Hydrogen, Waste management, Renewable Energy, Sustainability and the Environment, business.industry, Fossil fuel, Energy Engineering and Power Technology, Biomass, chemistry.chemical_element, 02 engineering and technology, 010402 general chemistry, 021001 nanoscience & nanotechnology, Condensed Matter Physics, 01 natural sciences, 0104 chemical sciences, Renewable energy, Fuel Technology, chemistry, Exergy efficiency, Environmental science, 0210 nano-technology, business, Energy source, Hydrogen production

Abstract

Growing the consumption of fossil fuels and emerging global warming issue have driven the research interests toward renewable and environmentally friendly energy sources. Biomass gasification is identified as an efficient technology to produce sustainable hydrogen. In this work, energy and exergy analysis coupled with thermodynamic equilibrium model were implemented in biomass gasification process for production of hydrogen. In this regard, a detailed comparison of the performance of a downdraft gasifier was implemented using air, steam, and air/steam as the gasifying agents for horse manure, pinewood and sawdust as the biomass materials. The comparison results indicate that the steam gasification of pinewood generates a more desired product gas compositions with a much higher hydrogen exergy efficiency and low exergy values of unreacted carbon and irreversibility. Then the effects of the inherent operating factors were investigated and optimized applying a response surface methodology to maximize hydrogen exergy efficiency of the process. A hydrogen exergy efficiency of 44% was obtained when the product gas exergy efficiency reaches to the highest value (88.26%) and destruction and unreacted carbon efficiencies exhibit minimum values of 7.96% and 1.9%.

Published

2020