| Title | Co-hydrothermal carbonization of swine and chicken manure: Influence of cross-interaction on hydrochar and liquid characteristics |
|---|---|
| ID_Doc | 23976 |
| Authors | Li, QY; Zhang, S; Gholizadeh, M; Hu, X; Yuan, XZ; Sarkar, B; Vithanage, M; Masek, O; Ok, YS |
| Title | Co-hydrothermal carbonization of swine and chicken manure: Influence of cross-interaction on hydrochar and liquid characteristics |
| Year | 2021 |
| Published | |
| Abstract | Swine and chicken manures are abundant solid wastes that can be converted into carbonaceous materials through hydrothermal carbonization (HTC). Owing to their unique biochemical compositions, co-HTC of these two types of manures may have significant implications for the generated products. We investigated the coHTC of swine manure and chicken manure to understand the influence of the interaction between contrasting manures on the properties of the derived products. The results indicated that co-HTC treatment enhanced the formation of solid product and improved the C and N contents, heating value, and energy yield of the resulting hydrochar. Regarding the ignition temperature and comprehensive combustion index, the combustion properties of the hydrochar were enhanced owing to the mutual effect of the HTC intermediates. Additionally, the interaction of the intermediates significantly impacted the transfer of nitrogenous species and generation of organic acids and organic polymers with fused-ring structures. Therefore, co-HTC processing of animal manures could potentially provide a sustainable pathway for the conversion of animal waste into solid products with improved characteristics compared to those produced by treating the two feedstocks separately. (c) 2021 Published by Elsevier B.V. |
Similar Articles
| ID | Score | Article |
|---|---|---|
10743
|
Mahata, S; Periyavaram, SR; Akkupalli, NK; Srivastava, S; Matli, C A review on Co-Hydrothermal carbonization of sludge: Effect of process parameters, reaction pathway, and pollutant transport(2023) | |
| 9156
|
Rasaq, WA; Thiruchenthooran, V; Wirkijowska, K; Valentin, M; Bobak, L; Igwegbe, CA; Bialowiec, A Hydrothermal carbonization of combined food waste: A critical evaluation of emergent products(2024) | |
| 25616
|
Su, XH; Zhang, T; Zhao, JY; Mukherjee, S; Alotaibi, NM; Abou-Elwafa, SF; Tran, HT; Bolan, NS Phosphorus Fraction in Hydrochar from Co-Hydrothermal Carbonization of Swine Manure and Rice Straw: An Optimization Analysis Based on Response Surface Methodology(2024)Water, 16, 15 | |
| 20897
|
Sarrion, A; Ipiales, RP; de la Rubia, MA; Mohedano, AF; Diaz, E Chicken meat and bone meal valorization by hydrothermal treatment and anaerobic digestion: Biofuel production and nutrient recovery(2023) | |
| 7658
|
Qaramaleki, SV; Villamil, JA; Mohedano, AF; Coronella, CJ Factors Affecting Solubilization of Phosphorus and Nitrogen through Hydrothermal Carbonization of Animal Manure(2020)Acs Sustainable Chemistry & Engineering, 8, 33 | |
| 3639
|
Dhull, SB; Rose, PK; Rani, J; Goksen, G; Bains, A Food waste to hydrochar: A potential approach towards the Sustainable Development Goals, carbon neutrality, and circular economy(2024) | |
| 9048
|
Sathish, T; Kumar, PS; Mageswari, SDU; Stalin, N; Pandian, R; Giri, J; Atif, M; Prakash, C; Yusuf, M Carbonization and Gasification of Cow-Dung and Fe3O4 Nanoparticles at Different Operating Conditions for Hydrogen Production(2024)Chemistryselect, 9.0, 35 | |
| 6081
|
Sharma, HB; Panigrahi, S; Sarmah, AK; Dubey, BK Downstream augmentation of hydrothermal carbonization with anaerobic digestion for integrated biogas and hydrochar production from the organic fraction of municipal solid waste: A circular economy concept(2020) | |
| 3938
|
Sharma, HB; Panigrahi, S; Dubey, BK Food waste hydrothermal carbonization: Study on the effects of reaction severities, pelletization and framework development using approaches of the circular economy(2021) | |
| 26584
|
Maj, I Significance and Challenges of Poultry Litter and Cattle Manure as Sustainable Fuels: A Review(2022)Energies, 15, 23 |