Investigation of the heat release rate and particle generation during fixed bed gasification of sweet sorghum stalk

•Syngas can be generated from sweet sorghum stalk residue for heating or electricity.•Optimum gasification air flux and Ø for sweet sorghum stalk are 12.9 g/m2·s and 2.1.•Optimum gasification thermal efficiency of sweet sorghum stalk is 81%•The yield of particles was lowest at the optimum gasificati...

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Published in:Fuel (Guildford) 2023-01, Vol.332, p.126013, Article 126013
Main Authors: Olanrewaju, Francis O., Andrews, Gordon E., Li, Hu, Phylaktou, Herodotos N., Mustafa, Bintu G., Kiah, Miss H. Mat
Format: Article
Language:English
Subjects:
Biomass
Equivalence ratio
Gasification
Particulate number
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Summary:•Syngas can be generated from sweet sorghum stalk residue for heating or electricity.•Optimum gasification air flux and Ø for sweet sorghum stalk are 12.9 g/m2·s and 2.1.•Optimum gasification thermal efficiency of sweet sorghum stalk is 81%•The yield of particles was lowest at the optimum gasification conditions. Sweet sorghum (SS) is an agricultural crop that is produced commercially in Nigeria. The crop has a high biowaste energy in its stalk, which is an attractive source of bioenergy in rural areas where it is produced. The residue–to-produce ratio (RPR) of the crop is 1.25 kg of biowaste for 1 kg of SS produced. The solid residue that results from the crop can be subjected to gasification to produce combustible gases: carbon monoxide (CO), hydrocarbon gases (total hydrocarbons) and hydrogen. The combustible gases can be piped into a burner for heat or into a Compression Ignition (CI) engine for electricity generation. This will enhance energy security as well as energy equity in rural areas in Nigeria and sub-saharan African countries where the crop is also produced. This research was aimed at optimising the gasification of SS stalk residue to maximise the yield of combustible gases from the first stage of the process. The restricted ventilation cone calorimeter method was used to gasify SS stalks on a laboratory scale. The test was carried out at air flow rates per exposed flat surface area of 9, 11.2, 12.9, 14.3, 15.5, 16.3, and 19.2 g/s·m2 respectively, which controls the gasification rate or power output. The speciation of the gases that evolved from the gasification of the biomass samples was carried out by an FTIR that was calibrated for 60 species. Current uses of biomass residues in open fire heating generates toxic fine particulate emissions and this work aimed to show that this was not a greater problem with gasification. A dynamic electrical mobility particle spectrometer (DMS500) was used to measure the particulate size distribution and concentration, as an efficient gasifier should not be generating major yields of soot, which would be a problem for a downstream reciprocating engine. The optimum equivalence ratio (Ф) for the best energy transfer to the gaseous products was 2.1, which was similar to previous work on pine using this equipment where the optimum equivalence ratio was 2.8. The hot gases efficiency at the optimum Ф was 81%, which compares well to that of 78% for pine.
ISSN:0016-2361
DOI:10.1016/j.fuel.2022.126013