Abstract
India is one among the major leather-producing countries in the world which shares close to one-fourth of the world’s leather solid wastes and most of these wastes are not effectively utilized. These wastes are rich in protein and lipids that could be a potential feedstock for biofuel production, i.e., biogas, biodiesel, etc. Among the 150,000 tons of daily leather solid wastes in India, approximately 87,150 tons are shared by pre-tanning operations (i.e., raw trimmings, fleshing, and hair wastes) while the rest of the 62,850 tons are shared by tanning, post-tanning, and finishing operations (i.e., wet blue trimmings, chrome splits, shavings, buffing dust, crust trimming wastes). This review article shows that there is considerable bioenergy potential for the use of leather solid wastes as a green fuel. The biogas potential of leather solid wastes is estimated to be 40,532.9 m3/day whereas the biodiesel potential is estimated as 15,452.6 L/day. The bio-oil and bio-char potential of leather solid wastes is estimated to be 80,513.0 L/day and 45.8 tons/day, respectively. Several factors influence the biofuel process efficacy, which needs to be taken into consideration while setting up a biofuel recovery plant. The overall biofuel potential of leather solid wastes shows that this feedstock is an untapped resource for energy recovery to add commercial benefits to India’s energy supply. Furthermore, in addition to the economic benefits for investors, the use of leather solid wastes for biofuel production will yield a positive environmental impact.
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Abbreviations
- AD:
-
anaerobic digestion
- AcoD:
-
anaerobic co-digestion
- ASTM:
-
American Society for Testing and Materials
- MSW:
-
municipal solid waste
- CTBD:
-
chrome tanned buffing dust
- LDPE:
-
low density polyethylene
- OFMSW:
-
organic fractions of municipal solid waste
- GHG:
-
greenhouse gas
- LFT:
-
chrome-tanned finished trimmings
- CS:
-
chrome shavings
- COD:
-
chemical oxygen demand
- C/N ratio:
-
carbon /nitrogen ratio
- CBG:
-
compressed biogas
- CER:
-
certified emission reductions
- CAGR:
-
compound annual growth rate
- CLD:
-
clean development mechanism
- CSTR:
-
continuous stirred tank reactor
- FFA:
-
free fatty acid
- FAME:
-
fatty acid methyl esters
- I/S:
-
inoculum-substrate
- LSW:
-
leather solid waste
- MNRE:
-
Ministry of New & Renewable Energy
- OLR:
-
organic loading rates
- UASB:
-
upflow anaerobic sludge blanklet reactor
- VS:
-
volatile solid
- VFA:
-
volatile fatty acids
- VOA:
-
volatile organic acids
- VM:
-
volatile matter
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Acknowledgements
CSIR-CLRI Communication No. 1670. The authors thank the Director, CSIR-CLRI for the continuous support.
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This work was supported by CSIR-Central Leather Research Institute through MLP-19, MLP-27 and Research Seed Grant: CSIR-CLRI (STS-32) projects.
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All authors contributed to the study conception and design. Material preparation, data collection and analysis were performed by Velusamy Mozhiarasi. The first draft of the manuscript was written by Velusamy Mozhiarasi, Thillai Sivakumar Natarajan, Vijayarangan Karthik (“Leather Industry” section only) and Parthiban Anburajan (“Emerging biofuel from leather solid wastes” section only). All authors read and approved the final manuscript.
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Mozhiarasi, ., Natarajan, T.S., Karthik, V. et al. Potential of biofuel production from leather solid wastes: Indian scenario. Environ Sci Pollut Res 30, 125214–125237 (2023). https://doi.org/10.1007/s11356-023-28617-3
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DOI: https://doi.org/10.1007/s11356-023-28617-3