The pyrolysis process verification of hydrogen rich gas (H–rG) production by artificial neural network (ANN)

The pyrolysis process verification of hydrogen rich gas (H–rG) production by artificial neural network (ANN)

The main aim of this study is subject of thermochemical conversion process data into computational modelling. Especially, prediction of hydrogen gas from the pyrolysis of waste materials regarded as environmentally pollutants were accomplished by Artificial Neural Network (ANN) in context of sustain...

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Veröffentlicht in:International journal of hydrogen energy 2016-03, Vol.41 (8), p.4570-4578
Hauptverfasser: Karaci, Abdulkadir, Caglar, Atila, Aydinli, Bahattin, Pekol, Sefa
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Sprache:eng
Schlagworte:
Artificial neural network
Biomass waste
Hydrogen
Hydrogen rich gas
Learning theory
Mathematical models
Matlab
Neural networks
Prediction
Pyrolysis
Sustainability
Wastes
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container_end_page 4578
container_issue 8
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container_title International journal of hydrogen energy
container_volume 41
creator Karaci, Abdulkadir
Caglar, Atila
Aydinli, Bahattin
Pekol, Sefa
description The main aim of this study is subject of thermochemical conversion process data into computational modelling. Especially, prediction of hydrogen gas from the pyrolysis of waste materials regarded as environmentally pollutants were accomplished by Artificial Neural Network (ANN) in context of sustainability. The data obtained from pyrolysis of biomass wastes; cotton cocoon shell (cotton–S), tea waste (tea–W) and olive husk (olive–H) were categorized and hydrogen rich gas (H–rG) portion was introduced to the NFTOOL of MATLAB program for ANN. The variables in the pyrolysis process were catalyst type, amount, temperature and biomass diversity. The H–rG production was rendered by catalysts; ZnCl2, NaCO3 and K2CO3. The combination of following condition; ZnCl2–10%, Olive–H and 973 K yield the best ANN models. This helped us save comprehensive amount of labour and time during experimentations, which also result in sharpness data in energy and environmental issues and were very ambiguous. The results were discussed by using new concepts related with energy resources, hydrogen gas, modelling and sustainability. The presented perspective here can be a useful tool for researchers and users as well as planners. [Display omitted] •Prediction of hydrogen rich gas production from pyrolysis of biomass wastes was accomplished by artificial neural network.•The data accumulated by thermochemical conversion process have opened new study area for the artificial neural network modelling.•A new way to produce hydrogen gas in the future was presented to planners and producers in terms of saving labour and time.
doi_str_mv 10.1016/j.ijhydene.2016.01.094
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subjects Artificial neural network
Biomass waste
Hydrogen
Hydrogen rich gas
Learning theory
Mathematical models
Matlab
Neural networks
Prediction
Pyrolysis
Sustainability
Wastes
title The pyrolysis process verification of hydrogen rich gas (H–rG) production by artificial neural network (ANN)
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