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Impact of Ball-Milling and Thermal Hydrolysis on Physicochemical Properties and Anaerobic Digestion Kinetics of Mixed Slaughterhouse and Agricultural Wastesopen access

Authors
Lee, Sang HeonGweon, Oh HyunLee, Hye SunJeon, Byoung SeungGo, YoungwookJin, Chang SookYu, YoungseobSang, Byoung-InLee, Jin Hyung
Issue Date
Mar-2026
Publisher
Multidisciplinary Digital Publishing Institute (MDPI)
Keywords
agricultural residues; anaerobic co-digestion; ball-milling; reaction kinetics; slaughterhouse waste; thermal hydrolysis; waste valorization
Citation
Bioengineering, v.13, no.3, pp 1 - 18
Pages
18
Indexed
SCIE
SCOPUS
Journal Title
Bioengineering
Volume
13
Number
3
Start Page
1
End Page
18
URI
https://scholarworks.bwise.kr/hanyang/handle/2021.sw.hanyang/212325
DOI
10.3390/bioengineering13030326
ISSN
2306-5354
2306-5354
Abstract
Slaughterhouse by-products are promising feedstocks for anaerobic digestion due to their high lipid and protein content. However, their complex structures often limit hydrolysis, and excessive pretreatment can induce inhibitory conditions. This study evaluates the effects of ball-milling (BM), ball-milling with water (BM + water), and combined thermal hydrolysis and ball-milling (THP + BM) on the digestion performance of a mixed substrate of slaughterhouse and agricultural wastes. The results demonstrate that all BM-based pretreatments significantly improved digestion kinetics, reducing the lag phase by 26–66% and shortening the T50 values by approximately 40% compared to the untreated substrate. While no statistically significant differences were observed in the ultimate methane yield, the onset of methanogenesis was markedly accelerated in the BM and BM + water treatments. In contrast, despite achieving superior solubilization, the THP + BM treatment failed to provide proportional kinetic enhancements. This was attributed to a severe initial metabolic imbalance—characterized by a pH drop below the inhibitory threshold (6.33)—which induced physiological stress and delayed the functional recovery of methanogens. These findings indicate that while ball-milling effectively facilitates digestion initiation by enhancing physical accessibility, the intensity of combined thermal-mechanical processes must be strategically optimized. For high-strength organic biomass, managing pretreatment severity is crucial to prevent initial acid stress and maximize process efficiency.
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