ПРОМІЖНИЙ ПІРОЛІЗ ЯК ТЕХНОЛОГІЯ ДЛЯ ВИРОБНИЦТВА РІДКИХ МОТОРНИХ БІОПАЛИВ
Ключові слова:
біомаса, рідке біопаливо, біонафта, швидкий піроліз, проміжний піроліз, піропаливо
Анотація
Представлено етапи і перспективи розвитку технології проміжного піролізу біомаси. Проаналізовано і порівняно характеристики біонафти швидкого піролізу і проміжного піролізу біомаси. Розглянуто паливні властивості біонафти термокаталітичного риформінгу біомаси. Розроблено рекомендації для подальшого дослідження та розвитку технологій піролізу біомаси в Україні.
Посилання
1. Bridgwater T. Pyrolysis of biomass. Presentation at ETIP webinar 25.05.2020.
https://www.music-h2020.eu/about-music/webinars-on-bioenergy-technologies/ETIP-Bioenergy_Webinar-WG2_25-May-2020_Presentation-T-Bridgwater_Aston-University.pdf
2. Álvarez-Chávez B.J., Godbout S., Le Roux É. et al. Bio-oil yield and quality enhancement through fast pyrolysis and fractional condensation concepts // Biofuel Research Journal. – 2019, N 24, p. 1054-1064. DOI: 10.18331/BRJ2019.6.4.2
3. Reumerman P., Vos J., Lammens T. White Paper: Fast Pyrolysis Bio-oil (FPBO). Deliverable D6.1 Part 2 of MUSIC project, 2022. https://www.music-h2020.eu/publications-reports/MUSIC_D6-1_WhitePaperPart2FastPyrolysisBio-Oil_FV.pdf
4. Zheliezna T.A., Drahniev S.V. Analiz napriamkiv pidvyshchennia konkurentospromozhnosti ridkykh biopalyv druhoho pokolinnia [Analysis of directions for increasing the competitiveness of second-generation liquid biofuels.]. Thermophysics and Thermal Power Engineering. – V. 45, № 3 (2023), P. 78-87. (Ukr.) https://doi.org/10.31472/ttpe.3.2023.9
5. Prasertpong P. et al. Characterization of Bio-oils from Jatropha Residues and Mixtures of Model Compounds // Chiang Mai University Journal of Natural Sciences. – 2017, v. 16 (2), p. 135-144.
https://www.researchgate.net/publication/314287475_Characterization_of_Bio-oils_from_Jatropha_Residues_and_Mixtures_of_Model_Compounds#fullTextFileContent
6. Xiujuan G. et al. Properties of Bio-oil from Fast Pyrolysis of Rice Husk // Chinese Journal of Chemical Engineering. – 2011, v. 19, N 1, p. 116-121. https://cjche.cip.com.cn/EN/abstract/abstract1942.shtml
7. ASTM D7544-23. Standard Specification for Pyrolysis Liquid Biofuel. https://cdn.standards.iteh.ai/samples/115155/5a69c009fa7d49adb0c18b193134558e/ASTM-D7544-23.pdf
8. Panwar N.L., Paul A.S. An overview of recent development in bio-oil upgrading and separation techniques // Environmental Engineering Research. – 2021, v. 26, N 5: 200382. https://doi.org/10.4491/eer.2020.382
9. Yang H., Yao J., Chen G. et al. Overview of upgrading of pyrolysis oil of biomass // Energy Procedia. – 2014, N 61, p. 1306-1309. https://doi.org/10.1016/j.egypro.2014.11.1087
10. Lachos-Perez D., Martins-Vieira J.C., Missau J. et al. Review on Biomass Pyrolysis with a Focus on Bio-Oil Upgrading Techniques // Analytica. – 2023, v. 4, N 2, p. 182-205. https://doi.org/10.3390/analytica4020015
11. Kazawadi D., Ntalikwa J., Kombe G. A Review of Intermediate Pyrolysis as a Technology of Biomass Conversion for Coproduction of Biooil and Adsorption Biochar // Journal of Renewable Energy. – 2021, v. 2021: 5533780. https://doi.org/10.1155/2021/5533780
12. Jäger N., Neumann J., Apfelbacher A. et al. Two decades of intermediate pyrolysis: a major step towards CHP applicable bio-oils. Paper for 25th Europ Biomass Conf. and Exhibition, EUBCE 2017, Stockholm 12-15.06.17. https://www.researchgate.net/publication/317822570_TWO_DECADES_OF_INTERMEDIATE_PYROLYSIS_A_MAJOR_STEP_TOWARDS_CHP_APPLICABLE_BIO-OILS
13. Hornung A., Apfelbacher A., Neumann J. et al. Combined heat and power generation from solid biomass derived bioliquids and syngas by TCR® – upgrade of TCR-liquids by hydrodeoxygenation. Paper for 24th European Biomass Conference and Exhibition, EUBCE 2016, Amsterdam, 6-9 June 2016. bit.ly/3ZgKyV5
14. Hornung A. Intermediate Pyrolysis as an Alternative to Fast Pyrolysis. In "BioEnergy IV: Innovations in Biomass Conversion for Heat, Power, Fuels and Chemicals". ECI Symposium Series, 2013. https://dc.engconfintl.org/bioenergy_iv/2/
15. Hornung A., Jahangiri H., Ouadi M. et al. Thermo-Catalytic Reforming (TCR) – An important link between waste management and renewable fuels as part of the energy transition // Application in Energy and Combustion Science. – 2022, v. 12, 100088. https://doi.org/10.1016/j.jaecs.2022.100088
16. Yang Y, Brammer J.G., Mahmood A.S.N., Hornung A. Intermediate pyrolysis of biomass energy pellets for producing sustainable liquid, gaseous and solid fuels // Bioresource technology. – 2014, N 169, p. 794–799. https://doi.org/10.1016/j.biortech.2014.07.044
17. Hossain A.K., Ouadi M., Siddiqui S.U. et al. Experimental investigation of performance, emission and combustion characteristics of an indirect injection multi-cylinder CI engine fuelled by blends of de-inking sludge pyrolysis oil with biodiesel // Fuel. – 2013, v. 105, p. 135–142. DOI: 10.1016/j.fuel.2012.05.007
18. Daschner R., Onyishi H. Conversion of biogenic waste into high quality hydrocarbons: recent progress in development of TCR-technology. Newsletter. Direct Thermochemical Liquefaction, IEA Bioenergy, Task 34, PyNe 54, December 2023. https://task34.ieabioenergy.com/wp-content/uploads/sites/3/2023/12/PyNe54-komplett.pdf
19. Di Gruttola F., Jahangiri H., Sajdak M. et al. Thermo-catalytic reforming (TCR) of waste solid grade laminate // Journal of Cleaner Production. – 2023, v. 419, 138276. https://doi.org/10.1016/j.jclepro.2023.138276
20. Turning sewage sludge into fuels and hydrogen. TO-SYN-FUEL Project Final publication, 2022.
https://www.tosynfuel.eu/wp-content/uploads/2022/09/TO-SYN-FUEL-Final-Publication.pdf
21. Oasmaa A., Elliott D.C., Müller S. Quality Control in Fast Pyrolysis Bio-Oil Production and Use // Environmental Progress & Sustainable Energy. – 2009, v. 28, N 3, p. 404-409. https://doi.org/10.1002/ep.10382
22. Kass M., Abdullah Z., Biddy M. et al. Understanding the Opportunities of Biofuels for Marine Shipping. Report by Oak Ridge National Laboratory, 2018. https://info.ornl.gov/sites/publications/Files/pub120597.pdf
23. Zheliezna T.A., Drahniev S.V. Rol ridkykh biopalyv u dekarbonizatsii transportnoho sektoru [Role of biofuels in transport sector decarbonization.]. Thermophysics and Thermal Power Engineering. – V. 46, № 4 (2024), P. 82-90. (Ukr.) https://doi.org/10.31472/ttpe.4.2024.9
24. Drahniev S.V., Zheliezna T.A., Haidai O.I. Perspektyvy vykorystannia alternatyvnykh palyv na vodnomu transporti [Prospect for the use of biofuels in woterborne transport.]. Thermophysics and Thermal Power Engineering. – V. 45, № 1 (2023), P. 55-63. (Ukr.) https://doi.org/10.31472/ttpe.1.2023.7
25. Klimenko V.M., Bashtovyi A.I., Zubenko V.I., Antoshchuk T.O. Doslidzhennia shvydkoho pirolizu biomasy v abliatsiinomu shnekovomu reaktori [Research of biomass fast pyrolysis in the ablative screw reactor.]. Industrial Heat Engineering. – V. 38, № 2 (2016), P. 48-55. (Ukr.) https://doi.org/10.31472/ihe.2.2016.06
https://www.music-h2020.eu/about-music/webinars-on-bioenergy-technologies/ETIP-Bioenergy_Webinar-WG2_25-May-2020_Presentation-T-Bridgwater_Aston-University.pdf
2. Álvarez-Chávez B.J., Godbout S., Le Roux É. et al. Bio-oil yield and quality enhancement through fast pyrolysis and fractional condensation concepts // Biofuel Research Journal. – 2019, N 24, p. 1054-1064. DOI: 10.18331/BRJ2019.6.4.2
3. Reumerman P., Vos J., Lammens T. White Paper: Fast Pyrolysis Bio-oil (FPBO). Deliverable D6.1 Part 2 of MUSIC project, 2022. https://www.music-h2020.eu/publications-reports/MUSIC_D6-1_WhitePaperPart2FastPyrolysisBio-Oil_FV.pdf
4. Zheliezna T.A., Drahniev S.V. Analiz napriamkiv pidvyshchennia konkurentospromozhnosti ridkykh biopalyv druhoho pokolinnia [Analysis of directions for increasing the competitiveness of second-generation liquid biofuels.]. Thermophysics and Thermal Power Engineering. – V. 45, № 3 (2023), P. 78-87. (Ukr.) https://doi.org/10.31472/ttpe.3.2023.9
5. Prasertpong P. et al. Characterization of Bio-oils from Jatropha Residues and Mixtures of Model Compounds // Chiang Mai University Journal of Natural Sciences. – 2017, v. 16 (2), p. 135-144.
https://www.researchgate.net/publication/314287475_Characterization_of_Bio-oils_from_Jatropha_Residues_and_Mixtures_of_Model_Compounds#fullTextFileContent
6. Xiujuan G. et al. Properties of Bio-oil from Fast Pyrolysis of Rice Husk // Chinese Journal of Chemical Engineering. – 2011, v. 19, N 1, p. 116-121. https://cjche.cip.com.cn/EN/abstract/abstract1942.shtml
7. ASTM D7544-23. Standard Specification for Pyrolysis Liquid Biofuel. https://cdn.standards.iteh.ai/samples/115155/5a69c009fa7d49adb0c18b193134558e/ASTM-D7544-23.pdf
8. Panwar N.L., Paul A.S. An overview of recent development in bio-oil upgrading and separation techniques // Environmental Engineering Research. – 2021, v. 26, N 5: 200382. https://doi.org/10.4491/eer.2020.382
9. Yang H., Yao J., Chen G. et al. Overview of upgrading of pyrolysis oil of biomass // Energy Procedia. – 2014, N 61, p. 1306-1309. https://doi.org/10.1016/j.egypro.2014.11.1087
10. Lachos-Perez D., Martins-Vieira J.C., Missau J. et al. Review on Biomass Pyrolysis with a Focus on Bio-Oil Upgrading Techniques // Analytica. – 2023, v. 4, N 2, p. 182-205. https://doi.org/10.3390/analytica4020015
11. Kazawadi D., Ntalikwa J., Kombe G. A Review of Intermediate Pyrolysis as a Technology of Biomass Conversion for Coproduction of Biooil and Adsorption Biochar // Journal of Renewable Energy. – 2021, v. 2021: 5533780. https://doi.org/10.1155/2021/5533780
12. Jäger N., Neumann J., Apfelbacher A. et al. Two decades of intermediate pyrolysis: a major step towards CHP applicable bio-oils. Paper for 25th Europ Biomass Conf. and Exhibition, EUBCE 2017, Stockholm 12-15.06.17. https://www.researchgate.net/publication/317822570_TWO_DECADES_OF_INTERMEDIATE_PYROLYSIS_A_MAJOR_STEP_TOWARDS_CHP_APPLICABLE_BIO-OILS
13. Hornung A., Apfelbacher A., Neumann J. et al. Combined heat and power generation from solid biomass derived bioliquids and syngas by TCR® – upgrade of TCR-liquids by hydrodeoxygenation. Paper for 24th European Biomass Conference and Exhibition, EUBCE 2016, Amsterdam, 6-9 June 2016. bit.ly/3ZgKyV5
14. Hornung A. Intermediate Pyrolysis as an Alternative to Fast Pyrolysis. In "BioEnergy IV: Innovations in Biomass Conversion for Heat, Power, Fuels and Chemicals". ECI Symposium Series, 2013. https://dc.engconfintl.org/bioenergy_iv/2/
15. Hornung A., Jahangiri H., Ouadi M. et al. Thermo-Catalytic Reforming (TCR) – An important link between waste management and renewable fuels as part of the energy transition // Application in Energy and Combustion Science. – 2022, v. 12, 100088. https://doi.org/10.1016/j.jaecs.2022.100088
16. Yang Y, Brammer J.G., Mahmood A.S.N., Hornung A. Intermediate pyrolysis of biomass energy pellets for producing sustainable liquid, gaseous and solid fuels // Bioresource technology. – 2014, N 169, p. 794–799. https://doi.org/10.1016/j.biortech.2014.07.044
17. Hossain A.K., Ouadi M., Siddiqui S.U. et al. Experimental investigation of performance, emission and combustion characteristics of an indirect injection multi-cylinder CI engine fuelled by blends of de-inking sludge pyrolysis oil with biodiesel // Fuel. – 2013, v. 105, p. 135–142. DOI: 10.1016/j.fuel.2012.05.007
18. Daschner R., Onyishi H. Conversion of biogenic waste into high quality hydrocarbons: recent progress in development of TCR-technology. Newsletter. Direct Thermochemical Liquefaction, IEA Bioenergy, Task 34, PyNe 54, December 2023. https://task34.ieabioenergy.com/wp-content/uploads/sites/3/2023/12/PyNe54-komplett.pdf
19. Di Gruttola F., Jahangiri H., Sajdak M. et al. Thermo-catalytic reforming (TCR) of waste solid grade laminate // Journal of Cleaner Production. – 2023, v. 419, 138276. https://doi.org/10.1016/j.jclepro.2023.138276
20. Turning sewage sludge into fuels and hydrogen. TO-SYN-FUEL Project Final publication, 2022.
https://www.tosynfuel.eu/wp-content/uploads/2022/09/TO-SYN-FUEL-Final-Publication.pdf
21. Oasmaa A., Elliott D.C., Müller S. Quality Control in Fast Pyrolysis Bio-Oil Production and Use // Environmental Progress & Sustainable Energy. – 2009, v. 28, N 3, p. 404-409. https://doi.org/10.1002/ep.10382
22. Kass M., Abdullah Z., Biddy M. et al. Understanding the Opportunities of Biofuels for Marine Shipping. Report by Oak Ridge National Laboratory, 2018. https://info.ornl.gov/sites/publications/Files/pub120597.pdf
23. Zheliezna T.A., Drahniev S.V. Rol ridkykh biopalyv u dekarbonizatsii transportnoho sektoru [Role of biofuels in transport sector decarbonization.]. Thermophysics and Thermal Power Engineering. – V. 46, № 4 (2024), P. 82-90. (Ukr.) https://doi.org/10.31472/ttpe.4.2024.9
24. Drahniev S.V., Zheliezna T.A., Haidai O.I. Perspektyvy vykorystannia alternatyvnykh palyv na vodnomu transporti [Prospect for the use of biofuels in woterborne transport.]. Thermophysics and Thermal Power Engineering. – V. 45, № 1 (2023), P. 55-63. (Ukr.) https://doi.org/10.31472/ttpe.1.2023.7
25. Klimenko V.M., Bashtovyi A.I., Zubenko V.I., Antoshchuk T.O. Doslidzhennia shvydkoho pirolizu biomasy v abliatsiinomu shnekovomu reaktori [Research of biomass fast pyrolysis in the ablative screw reactor.]. Industrial Heat Engineering. – V. 38, № 2 (2016), P. 48-55. (Ukr.) https://doi.org/10.31472/ihe.2.2016.06
Переглядів анотації: 316 Завантажень PDF: 144
Опубліковано
2025-03-31
Як цитувати цю статтю:
Zheliezna, T., & Drahniev, S. (2025). ПРОМІЖНИЙ ПІРОЛІЗ ЯК ТЕХНОЛОГІЯ ДЛЯ ВИРОБНИЦТВА РІДКИХ МОТОРНИХ БІОПАЛИВ. Теплофізика та Теплоенергетика, 47(1), 100-109. https://doi.org/https://doi.org/10.31472/ttpe.1.2025.10
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Якщо стаття прийнята до друку в журналі «Теплофізика та Теплоенергетика», автор має підписати угоду про передачу авторських прав. Угода надсилається на поштову (оригінал) або електронну адресу (сканована копія) Редакції журналу.



