TY - GEN
T1 - Mechanical Pre-Treatment of Co-Digested Wastewater Sludge (WWS) and Brewery Spent Yeast (BSY) Under Anaerobic Condition
AU - Rasmeni, Zelda Z.
AU - Madyira, Daniel M.
AU - Matheri, Antony N.
AU - Olatunji, Obafemi O.
AU - Olatunji, Kehinde O.
N1 - Publisher Copyright:
© 2024 IEEE.
PY - 2024
Y1 - 2024
N2 - The food and beverage industries produce vast amounts of organic residue with the potential for biogas production. Among others, mechanical pre-treatment could be a useful option that enhances the biomethane yield of brewery-spent yeast and wastewater sludge. Therefore, this study investigates the co-digestion of brewery-spent yeast and wastewater sludge via mechanical pre-treatment to improve the biomethane yield. The co-digestion was carried out in 1: 2 of wastewater sludge to brewery spent yeast. A high-pressure homogenizer was used to mechanically pre-treat the WWS and (BSY) with 5-, 10-, and 15-minute exposure times. The proximate analysis was carried out, and biomethane potential was measured using the BMP AMPTS 11 setup. This study noticed a tremendous increase in biomethane yields compared to mono digestion; this can be traced to the co-digestion with wastewater sludge. The effect of co-digestion can be inferred to be more effective in the treatment with the best pre-treatment conditions. The treatment with 10 min exposure time released the highest volume of 175.30 Nml biogas. This can be traced to pre-treatment methods that have made the substrate accessible to biomethane-produced microorganisms. The pre-treatment improved the substrate's surface area, enabling sufficient interaction between the wastewater sludge, substrate, and microbes. Finally, this result shows the significant impact of mechanical pre-treatment, which is more noticeable than the effect of co-digestion.
AB - The food and beverage industries produce vast amounts of organic residue with the potential for biogas production. Among others, mechanical pre-treatment could be a useful option that enhances the biomethane yield of brewery-spent yeast and wastewater sludge. Therefore, this study investigates the co-digestion of brewery-spent yeast and wastewater sludge via mechanical pre-treatment to improve the biomethane yield. The co-digestion was carried out in 1: 2 of wastewater sludge to brewery spent yeast. A high-pressure homogenizer was used to mechanically pre-treat the WWS and (BSY) with 5-, 10-, and 15-minute exposure times. The proximate analysis was carried out, and biomethane potential was measured using the BMP AMPTS 11 setup. This study noticed a tremendous increase in biomethane yields compared to mono digestion; this can be traced to the co-digestion with wastewater sludge. The effect of co-digestion can be inferred to be more effective in the treatment with the best pre-treatment conditions. The treatment with 10 min exposure time released the highest volume of 175.30 Nml biogas. This can be traced to pre-treatment methods that have made the substrate accessible to biomethane-produced microorganisms. The pre-treatment improved the substrate's surface area, enabling sufficient interaction between the wastewater sludge, substrate, and microbes. Finally, this result shows the significant impact of mechanical pre-treatment, which is more noticeable than the effect of co-digestion.
KW - biomethane yield
KW - Brewery spent yeast
KW - co-digestion
KW - mechanical pretreatment
KW - wastewater sludge
UR - http://www.scopus.com/inward/record.url?scp=105001864575&partnerID=8YFLogxK
U2 - 10.1109/ICECER62944.2024.10920381
DO - 10.1109/ICECER62944.2024.10920381
M3 - Conference contribution
AN - SCOPUS:105001864575
T3 - International Conference on Electrical and Computer Engineering Researches, ICECER 2024
BT - International Conference on Electrical and Computer Engineering Researches, ICECER 2024
PB - Institute of Electrical and Electronics Engineers Inc.
T2 - 2024 International Conference on Electrical and Computer Engineering Researches, ICECER 2024
Y2 - 4 December 2024 through 6 December 2024
ER -