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Year 2024, , 400 - 409, 31.08.2024
https://doi.org/10.18185/erzifbed.1448654

Abstract

References

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  • [2] Semaan, J.N., Belandria, V., Missaoui, A., Sarh, B., Gökalp, I., Bostyn, S., (2022) Energy analysis of olive pomace valorization via hydrothermal carbonization, Biomass and Bioenergy, 165, 106590.
  • [3] Zhang, T., Kang, K., Nanda, S., Dalai, A. K., Xie, T., Zhao, Y., (2022) Comparative study on fuel characteristics and pyrolysis kinetics of corn residue-based hydrochar produced via microwave hydrothermal carbonization, Chemosphere, 291, 132787.
  • [4] Sangare, D., Chartier, A., Santillan, M. M., Gökalp, I., Bostyn, S., (2022) Kinetic studies of hydrothermal carbonization of avocado stone and analysis of the polycyclic aromatic hydrocarbon contents in the hydrochars produced, Fuel, 316, 123163.
  • [5] Wang, Q., Li, Y., Yu, Z., Li, X., Yin, S., Ji, W., Hu, Y., Cai, W., Wang, X., (2023) Highly porous carbon derived from hydrothermal-pyrolysis synergistic carbonization of biomass for enhanced CO2 capture, Colloids and Surfaces A: Physicochemical and Engineering Aspects, 673, 131787.
  • [6] Malhotra, M., Garg, A., (2023) Hydrothermal carbonization of sewage sludge: Optimization of operating conditions using design of experiment approach and evaluation of resource recovery potential, Journal of Environmental Chemical Engineering 11, 109507.
  • [7] Zulkornain, M.F., Shamsuddin, A.H., Normanbhay, S., Saad, J. M., Zhang, Y. S., Samsuri, S., Ghani, W. A. W. A. K., (2021) Microwave-assisted Hydrothermal Carbonization for Solid Biofuel Application: A Brief Review, Carbon Capture Science & Technology, 1, 100014.
  • [8] Samaksaman, U., Pattaraprakorn, W., Neramittagapong, A., Kanchanatip, E., (2023) Solid fuel production from macadamia nut shell: effect of hydrothermal carbonization conditions on fuel characteristics, Biomass Conversion and Biorefinery, 13:2225–2232.
  • [9] Poomsawat, S., Poomsawat, W., (2022) Characterization and pyrolysis kinetics study of hydrochar derived from turfgrass (Zoysia matrella) using hydrothermal carbonization, Biomass Conversion and Biorefinery.
  • [10] Zhang, X., Gao, B., Zhao, S., Wu, P., Han, L., Liu, X., (2020) Optimization of a “coal-like” pelletization technique based on the sustainable biomass fuel of hydrothermal carbonization of wheat straw, Journal of Cleaner Production, 242, 118426.
  • [11] Lu, X., Ma, X., Qin, Z., Chen, X., Yue, W., (2022) Co-hydrothermal carbonization of sewage sludge and swine manure: Hydrochar properties and heavy metal chemical speciation, Fuel, 330, 125573.
  • [12] Ercan, B., Alper, K., Ucar, S., Karagoz, S., (2023) Comparative studies of hydrochars and biochars produced from lignocellulosic biomass via hydrothermal carbonization, torrefaction and pyrolysis, Journal of the Energy Institute, 109, 101298.
  • [13] Yin, C.Y., (2011) Prediction of higher heating values of biomass from proximate and ultimate analyses, Fuel, 90, 1128–1132.
  • [14] Wang, Q., Wu, S., Cui, D., Zhoua, H., Wu, D., Pana, S., Xu, F., Wang, Z., (2022) Co-hydrothermal carbonization of organic solid wastes to hydrochar as potential fuel: A review Science of the Total Environment, 850, 158034.
  • [15] Ding, Y., Guo, C., Wang, S. Q, B., Zhao, P., Cui, X., (2022) Effects of process water recirculation on yields and quality of hydrochar from hydrothermal carbonization process of rice husk, Journal of Analytical and Applied Pyrolysis, 166, 105618.
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  • [17] Liang, W., Wang, G., Xu, R., Ning, X., Zhang, J., Guo, X., Ye, L., Li, J., Jiang, C., Wang, P., Wang, C., (2022) Hydrothermal carbonization of forest waste into solid fuel: Mechanism and combustion behavior, Energy, 246, 123343.
  • [18] Zhi, Y., Xu, D., Jiang, G., Yang, W., Chen, Z., Duan, P., Zhang, J., (2024) A review of hydrothermal carbonization of municipal sludge: Process conditions, physicochemical properties, methods coupling, energy balances and life cycle analyses, Fuel Processing Technology, 254, 107943.
  • [19] Sharma, H.B., Sarmah, A. K., Dubey, B., (2020) Hydrothermal carbonization of renewable waste biomass for solid biofuel production: A discussion on process mechanism, the influence of process parameters, environmental performance and fuel properties of hydrochar, Renewable and Sustainable Energy Reviews, 123, 109761.
  • [20] Zhang, Z., Yang, J., Qian, J., Zhao, Y., Wang, T., Zhai, Y., (2021) Biowaste hydrothermal carbonization for hydrochar valorization: Skeleton structure, conversion pathways and clean biofuel applications, Bioresource Technology 324, 124686.
  • [21] Yu, Y., Guo, Y., Wang, G., El-Kassaby, Y. A., Sokhansanj, S., (2022) Hydrothermal carbonization of waste ginkgo leaf residues for solid biofuel production: Hydrochar characterization and its pelletization, Fuel 324, 124341.
  • [22] Ahmad, S., Zhu, X., Wei, X., Zhang, S., (2021) Influence of process parameters on hydrothermal modification of soybean residue: Insight into the nutrient, solid biofuel, and thermal properties of hydrochars, Journal of Environmental Management 283, 111981.
  • [23] Zhang, Z., Yang, J., Qian, J., Zhao, Y., Wang, T., Zhai, Y., (2021) Biowaste hydrothermal carbonization for hydrochar valorization: Skeleton structure, conversion pathways and clean biofuel applications, Bioresource Technology, 324, 124686
  • [24] Pauline A. L., Joseph K., (2020) Hydrothermal carbonization of organic wastes to carbonaceous solid fuel –A review of mechanisms and process parameters, Fuel, 279, 118472.
  • [25] Cai, J., Li, B., Chen, C., Wang, J., Zhao, M., Zhang K., (2016) Hydrothermal carbonization of tobacco stalk for fuel application, Bioresource Technology, 220, 305–311.
  • [26] Kabakcı, S.B., Baran, S.S., (2019) Hydrothermal carbonization of various lignocellulosics: Fuel characteristics of hydrochars and surface characteristics of activated hydrochars, Waste Management, 100, 259–268.
  • [27] Qin, X., Meng, W., Cheng, S., Xing, B., Shi, C., Nie, Y., Wang, Q., Xia, H., (2023) Efficient removal of heavy metal and antibiotics from wastewater by phosphate-modified hydrochar, Chemosphere, 345, 140484.
  • [28] Yang, J., Zhang, Z., Wang, J., Zhao, X., Zhao, Y., Qiana, J., Wang, T., (2023) Pyrolysis and hydrothermal carbonization of biowaste: A comparative review on the conversion pathways and potential applications of char product, Sustainable Chemistry and Pharmacy 33, 101106.

Investigation of the Effect of Temperature on the Biofuel Performance of Hydrochar Obtained from Kidney Bean Shell

Year 2024, , 400 - 409, 31.08.2024
https://doi.org/10.18185/erzifbed.1448654

Abstract

In this study, hydrochar products were obtained from kidney bean shell (KBS) biomass at different temperatures using the hydrothermal carbonization (HTC) method. Hydrochar products were produced at three different temperatures (200, 220 and 240 C) and a holding time of 90 minutes. Biomass/water ratio was taken as 1:10. Analysis techniques such as Thermogravimetric analysis (TG), Ultimate analysis and Fourier Transform Infrared Spectroscopy (FTIR) were used in the characterization of raw materials and hydrochar products. In addition, the fuel properties (high heating value, energy yield and energy densification ratio) of raw KBS and hydrochar products were also investigated. As the HTC temperature increases, the high heating value of hydrochar products increases. Among hydrochar products, the highest high heating value belongs to the product obtained at 240 C. The combustion behavior of raw and hydrochar a product was examined using the thermogravimetric analysis method and combustion parameters (Ti, Tb and Tm) were determined. As a result, this study has shown that the hydrochar product produced from KBS by hydrothermal carbonization method can be used as a biofuel material.

References

  • [1] Li, J., Yao, X., Ge, J., Yu, Y., Yang, D., Chen, S., Xu, K., Geng, L., (2022) Investigation on the pyrolysis process, products characteristics and BP neural network modelling of pine sawdust, cattle dung, kidney bean stalk and bamboo, Process Safety and Environmental Protection, 162:752–764.
  • [2] Semaan, J.N., Belandria, V., Missaoui, A., Sarh, B., Gökalp, I., Bostyn, S., (2022) Energy analysis of olive pomace valorization via hydrothermal carbonization, Biomass and Bioenergy, 165, 106590.
  • [3] Zhang, T., Kang, K., Nanda, S., Dalai, A. K., Xie, T., Zhao, Y., (2022) Comparative study on fuel characteristics and pyrolysis kinetics of corn residue-based hydrochar produced via microwave hydrothermal carbonization, Chemosphere, 291, 132787.
  • [4] Sangare, D., Chartier, A., Santillan, M. M., Gökalp, I., Bostyn, S., (2022) Kinetic studies of hydrothermal carbonization of avocado stone and analysis of the polycyclic aromatic hydrocarbon contents in the hydrochars produced, Fuel, 316, 123163.
  • [5] Wang, Q., Li, Y., Yu, Z., Li, X., Yin, S., Ji, W., Hu, Y., Cai, W., Wang, X., (2023) Highly porous carbon derived from hydrothermal-pyrolysis synergistic carbonization of biomass for enhanced CO2 capture, Colloids and Surfaces A: Physicochemical and Engineering Aspects, 673, 131787.
  • [6] Malhotra, M., Garg, A., (2023) Hydrothermal carbonization of sewage sludge: Optimization of operating conditions using design of experiment approach and evaluation of resource recovery potential, Journal of Environmental Chemical Engineering 11, 109507.
  • [7] Zulkornain, M.F., Shamsuddin, A.H., Normanbhay, S., Saad, J. M., Zhang, Y. S., Samsuri, S., Ghani, W. A. W. A. K., (2021) Microwave-assisted Hydrothermal Carbonization for Solid Biofuel Application: A Brief Review, Carbon Capture Science & Technology, 1, 100014.
  • [8] Samaksaman, U., Pattaraprakorn, W., Neramittagapong, A., Kanchanatip, E., (2023) Solid fuel production from macadamia nut shell: effect of hydrothermal carbonization conditions on fuel characteristics, Biomass Conversion and Biorefinery, 13:2225–2232.
  • [9] Poomsawat, S., Poomsawat, W., (2022) Characterization and pyrolysis kinetics study of hydrochar derived from turfgrass (Zoysia matrella) using hydrothermal carbonization, Biomass Conversion and Biorefinery.
  • [10] Zhang, X., Gao, B., Zhao, S., Wu, P., Han, L., Liu, X., (2020) Optimization of a “coal-like” pelletization technique based on the sustainable biomass fuel of hydrothermal carbonization of wheat straw, Journal of Cleaner Production, 242, 118426.
  • [11] Lu, X., Ma, X., Qin, Z., Chen, X., Yue, W., (2022) Co-hydrothermal carbonization of sewage sludge and swine manure: Hydrochar properties and heavy metal chemical speciation, Fuel, 330, 125573.
  • [12] Ercan, B., Alper, K., Ucar, S., Karagoz, S., (2023) Comparative studies of hydrochars and biochars produced from lignocellulosic biomass via hydrothermal carbonization, torrefaction and pyrolysis, Journal of the Energy Institute, 109, 101298.
  • [13] Yin, C.Y., (2011) Prediction of higher heating values of biomass from proximate and ultimate analyses, Fuel, 90, 1128–1132.
  • [14] Wang, Q., Wu, S., Cui, D., Zhoua, H., Wu, D., Pana, S., Xu, F., Wang, Z., (2022) Co-hydrothermal carbonization of organic solid wastes to hydrochar as potential fuel: A review Science of the Total Environment, 850, 158034.
  • [15] Ding, Y., Guo, C., Wang, S. Q, B., Zhao, P., Cui, X., (2022) Effects of process water recirculation on yields and quality of hydrochar from hydrothermal carbonization process of rice husk, Journal of Analytical and Applied Pyrolysis, 166, 105618.
  • [16] Bağ, Ö. and Tekin, K. (2020) Production and characterization of hydrothermal carbon from waste lignocellulosic biomass, Journal of the Faculty of Engineering and Architecture of Gazi University 35:2, 1063-1076.
  • [17] Liang, W., Wang, G., Xu, R., Ning, X., Zhang, J., Guo, X., Ye, L., Li, J., Jiang, C., Wang, P., Wang, C., (2022) Hydrothermal carbonization of forest waste into solid fuel: Mechanism and combustion behavior, Energy, 246, 123343.
  • [18] Zhi, Y., Xu, D., Jiang, G., Yang, W., Chen, Z., Duan, P., Zhang, J., (2024) A review of hydrothermal carbonization of municipal sludge: Process conditions, physicochemical properties, methods coupling, energy balances and life cycle analyses, Fuel Processing Technology, 254, 107943.
  • [19] Sharma, H.B., Sarmah, A. K., Dubey, B., (2020) Hydrothermal carbonization of renewable waste biomass for solid biofuel production: A discussion on process mechanism, the influence of process parameters, environmental performance and fuel properties of hydrochar, Renewable and Sustainable Energy Reviews, 123, 109761.
  • [20] Zhang, Z., Yang, J., Qian, J., Zhao, Y., Wang, T., Zhai, Y., (2021) Biowaste hydrothermal carbonization for hydrochar valorization: Skeleton structure, conversion pathways and clean biofuel applications, Bioresource Technology 324, 124686.
  • [21] Yu, Y., Guo, Y., Wang, G., El-Kassaby, Y. A., Sokhansanj, S., (2022) Hydrothermal carbonization of waste ginkgo leaf residues for solid biofuel production: Hydrochar characterization and its pelletization, Fuel 324, 124341.
  • [22] Ahmad, S., Zhu, X., Wei, X., Zhang, S., (2021) Influence of process parameters on hydrothermal modification of soybean residue: Insight into the nutrient, solid biofuel, and thermal properties of hydrochars, Journal of Environmental Management 283, 111981.
  • [23] Zhang, Z., Yang, J., Qian, J., Zhao, Y., Wang, T., Zhai, Y., (2021) Biowaste hydrothermal carbonization for hydrochar valorization: Skeleton structure, conversion pathways and clean biofuel applications, Bioresource Technology, 324, 124686
  • [24] Pauline A. L., Joseph K., (2020) Hydrothermal carbonization of organic wastes to carbonaceous solid fuel –A review of mechanisms and process parameters, Fuel, 279, 118472.
  • [25] Cai, J., Li, B., Chen, C., Wang, J., Zhao, M., Zhang K., (2016) Hydrothermal carbonization of tobacco stalk for fuel application, Bioresource Technology, 220, 305–311.
  • [26] Kabakcı, S.B., Baran, S.S., (2019) Hydrothermal carbonization of various lignocellulosics: Fuel characteristics of hydrochars and surface characteristics of activated hydrochars, Waste Management, 100, 259–268.
  • [27] Qin, X., Meng, W., Cheng, S., Xing, B., Shi, C., Nie, Y., Wang, Q., Xia, H., (2023) Efficient removal of heavy metal and antibiotics from wastewater by phosphate-modified hydrochar, Chemosphere, 345, 140484.
  • [28] Yang, J., Zhang, Z., Wang, J., Zhao, X., Zhao, Y., Qiana, J., Wang, T., (2023) Pyrolysis and hydrothermal carbonization of biowaste: A comparative review on the conversion pathways and potential applications of char product, Sustainable Chemistry and Pharmacy 33, 101106.
There are 28 citations in total.

Details

Primary Language English
Subjects Chemical Thermodynamics and Energetics, Physical Chemistry (Other), Material Characterization
Journal Section Makaleler
Authors

Zeynep Yıldız Uzun 0000-0001-6280-1215

Publication Date August 31, 2024
Submission Date March 7, 2024
Acceptance Date July 18, 2024
Published in Issue Year 2024

Cite

APA Yıldız Uzun, Z. (2024). Investigation of the Effect of Temperature on the Biofuel Performance of Hydrochar Obtained from Kidney Bean Shell. Erzincan University Journal of Science and Technology, 17(2), 400-409. https://doi.org/10.18185/erzifbed.1448654