OPTIMIZING BIOGAS PRODUCTION FROM OLIVE OIL MILL RESIDUES: A COMPARATIVE EVALUATION OF TREATMENT TECHNIQUES FOR SUSTAINABLE RESOURCE RECOVERY

The olive oil sector is one of the most widespread agricultural and agro-industrial activities in the Mediterranean region, and it also produces a significant amount of waste biomass. This research aimed to find energy valorisation for the olive oil byproducts through biogas/biomethane production fr...

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Published inInternational Multidisciplinary Scientific GeoConference SGEM Vol. 4; no. 2; pp. 117 - 123
Main Authors Di Mario, J, Gambelli, A M, Del Buono, D, Puglia, D, Gigliotti, G
Format Conference Proceeding
LanguageEnglish
Published Sofia Surveying Geology & Mining Ecology Management (SGEM) 01.07.2024
Subjects
Agricultural production
Alternative energy sources
Anaerobic digestion
Anaerobic treatment
Biogas
Biological activity
Biomass
Cellulose
Digestion
Environmental impact
Food industries wastewaters
Freeze drying
Hemicellulose
Industrial areas
Ionic liquids
Lignin
Methane
Microbial activity
Microorganisms
Oil
Olive oil
Pharmaceutical industry
Resource recovery
Sulfuric acid
Sulphuric acid
Triethylamine
Waste materials
Wastewater
Italy
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Summary:The olive oil sector is one of the most widespread agricultural and agro-industrial activities in the Mediterranean region, and it also produces a significant amount of waste biomass. This research aimed to find energy valorisation for the olive oil byproducts through biogas/biomethane production from olive pomace (OP) and olive mill wastewater (OW). To this end, these biomasses underwent preliminary treatments: the OP was processed using an ionic liquid (IL) consisting of triethylamine and sulfuric acid [Et:N][HSO4], which removed hemicellulose and lignin, thus allowing recovering of the insoluble OP, mainly composed of cellulose. On the other hand, OW was treated through freeze-drying. After that, the pulp from olive pomace (POP) and freeze-dried OW (FDOW) were subjected to anaerobic digestion in lab-scale reactors. The biogas output from these materials was compared to the biogas yield shown by the untreated biomasses (OW and OP). FDOW anaerobic digestion resulted in the highest amount of biogas production, likely due to surface and structural modifications caused by the freeze-drying treatment, which presumably enhanced microbial activity. In contrast, the IL treatment of POP significantly lowered the biogas production, which ended after two days of digestion, resulting in a minimal yield. Future research will focus on codigesting POP and FDOW with a nitrogen-rich biomass, such as Brewery's Spent Grain, to potentially increase biogas output and better understand the cause of the low yield.
Bibliography:ObjectType-Conference Proceeding-1
SourceType-Conference Papers & Proceedings-1
content type line 21
ISSN:1314-2704
DOI:10.5593/sgem2024v/4.2/s17.17