The Role of Anaerobic Digestion and Solar PV to Achieve GHG Neutrality in a Farm Setting
Abstract
:1. Introduction
2. Materials and Methods
2.1. LCA Model Description: System Boundaries, Functional Unit, and Data
2.2. Large Farm Characteristics
2.3. Small Farm Characteristics
2.4. Anaerobic Digestion System
2.5. Solar PV System
3. Results
3.1. Net Energy Intensity
3.2. GHG Emissions
3.3. Manure, Land, and Costs to Install AD and PV Systems in the Base-Cases
3.4. Adding AD and PV Capacity to Achieve GHG Neutrality
4. Conclusions
Author Contributions
Funding
Institutional Review Board Statement
Informed Consent Statement
Data Availability Statement
Acknowledgments
Conflicts of Interest
References
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Feed | Lactating Cows | Young Heifers | Growing Heifers | Old Heifers and Dry Cows |
---|---|---|---|---|
kg of DMI/Animal/Day | ||||
Alfalfa silage | 8.0 | 2.01 | 6.55 | 3.99 |
Corn silage | 5.0 | 1.77 | 5.36 | 3.26 |
Cottonseed | 2.0 | - | - | - |
Corn grain | 6.6 | 0.46 | - | - |
Soybean meal * | 0.8 | 0.81 | - | - |
Total | 22.3 | 5.05 | 11.91 | 7.25 |
Variable | Value | Reference |
---|---|---|
Hydraulic retention time | 28 days | [33] |
Generator efficiency | Electric: 35% Thermal: 50% | [34] |
Energy consumed by the digester (of produced energy) | Electricity: 17% Thermal: 20% | [33] |
Biogas composition | 65% CH4 35% CO2 | [34] |
CH4 production | CH4 = Methane production rate (volume of gas produced per volume of digester per day, L/L/day); Bo = Ultimate methane yield per gram of volatile solids added (L/g/VS); HRT = Hydraulic retention time (days); So = Influent volatile solids concentration (g/L); µm = Bacterial growth rate (per day, µm = 0.013 × T − 0.129); T = Temperature of the digester (°C); K = kinetic parameter [dimensionless, K = 0.8 + 0.0016 × exp(0.06 × So)] | [35] |
Lower heating value of CH4 | 36 MJ/m3 | [36] |
VS destruction | 30% | [37] |
Increase in ammoniacal nitrogen after digestion | 15% | [32] |
CH4 leaks from digester | 1.0% | [38] |
Resources Use | Base-Case Large | Base-Case Small | ||
---|---|---|---|---|
AD | Solar PV | AD | Solar PV | |
Manure (ton/day) | 93 | NA | 14 | NA |
Area (HA) | NA | 34 | NA | 3 |
Capital costs (US$ total) | 1,734,328 | 4,116,216 | 498,322 | 494,291 |
O&M (US$/year) | 98,120 | 50,667 | 56,700 | 5222 |
Total costs (US$/year) | 184,836 | 215,316 | 81,616 | 24,993 |
Additional Resources Use for GHG Neutrality | Base-Case Large | Base-Case Small | ||
---|---|---|---|---|
AD | Solar PV | AD | Solar PV | |
Manure (ton/day) | 282 | NA | 47 | NA |
Area (HA) | NA | 125 | NA | 19 |
Capital costs (US$ total) | 3,058,961 | 11,747,808 | 1,044,693 | 2,528,318 |
O&M (US$/year) | 246,609 | 166,740 | 75,009 | 26,709 |
Total costs (US$/year) | 399,557 | 636,652 | 127,244 | 127,842 |
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Aguirre-Villegas, H.A.; Cortus, E.; Reinemann, D.J. The Role of Anaerobic Digestion and Solar PV to Achieve GHG Neutrality in a Farm Setting. Energies 2022, 15, 1975. https://doi.org/10.3390/en15061975
Aguirre-Villegas HA, Cortus E, Reinemann DJ. The Role of Anaerobic Digestion and Solar PV to Achieve GHG Neutrality in a Farm Setting. Energies. 2022; 15(6):1975. https://doi.org/10.3390/en15061975
Chicago/Turabian StyleAguirre-Villegas, Horacio Andres, Erin Cortus, and Douglas J. Reinemann. 2022. "The Role of Anaerobic Digestion and Solar PV to Achieve GHG Neutrality in a Farm Setting" Energies 15, no. 6: 1975. https://doi.org/10.3390/en15061975
APA StyleAguirre-Villegas, H. A., Cortus, E., & Reinemann, D. J. (2022). The Role of Anaerobic Digestion and Solar PV to Achieve GHG Neutrality in a Farm Setting. Energies, 15(6), 1975. https://doi.org/10.3390/en15061975