Русский
English 93-104 стр.
Исследована возможность использования измельченной биомассы стручков гороха посевного (Pisum sativum) в качестве сорбционного материала для очистки модельных вод от производства липидного концентрата из личинок мухи вида Hermetia illucens. Кратко приведены сведения об составе и количестве липидов и насыщенных и ненасыщенных жирных кислот в составе личинок насекомого. Исследовано влияние размеров частиц сорбционного материала на эффективность адсорбционного извлечения эмульсии липидного концентрата из модельных сточных вод и выявлено увеличение степени очистки с повышением дисперсности высушенной биомассы стручков гороха.
Также исследована зависимость эффективности удаления частиц эмульсии от дозировки сорбционного материала и времени контактирования последнего с сорбатом. Определены оптимальные параметры адсорбционной очистки.
Также исследована зависимость эффективности удаления частиц эмульсии от дозировки сорбционного материала и времени контактирования последнего с сорбатом. Определены оптимальные параметры адсорбционной очистки.
1. Lin S., Shen S., Zhou A., Lyu H.Assessment and management of lake eutrophication: A case study in Lake Erhai, China // Science of the Total Environment. 2021. Vol. 751. Art. 141618. 21 р.
2. Lehtoranta S., Vilpas R., Mattila T.J. Comparison of carbon footprints and eutrophication impacts of rural on-site wastewater treatment plants in Finland // Journal of Cleaner Production. 2014. Vol. 65. Р. 439 – 446.
3. Liew W.L., Kassim M.A., Muda K. et al. Conventional methods and emerging wastewater polishing technol-ogies for palm oil mill effluent treatment: A review // Journal of Environmental Management. 2015. Vol. 149. P. 222 – 235.
4. Azbar N., Bayram A., Filibeli A. et al. A review of waste management options in olive oil production // Criti-cal Reviews in Environmental Science and Technology. 2004. Vol. 34. № 3. P. 209 – 247.
5. Ushakova N.A., Brodskii E.S., Kovalenko A.A. et al.Characteristics of lipid fractions of larvae of the Black Soldier fly Hermetia illucens // Doklady Biochemistry and Biophysics. 2016. Vol. 468. P. 1 – 4.
6. Ewald N., Vidakovic A., Langeland M. et al. Fatty acid composition of black soldier fly larvae (Hermetia il-lucens) – Possibilities and limitations for modification through diet // Waste Management. 2020. Vol. 102. P. 40 – 47.
7. Smets R., Verbinnen B., Van De Voorde I. et al. Sequential extraction and characterisation of lipids, proteins, and chitin from Black Soldier fly (Hermetia illucens) larvae, prepupae, and pupae // Waste Biomass Valorization. 2020. Vol. 11. P. 6455 – 6466.
8. Jucker C., Erba D., Leonardi M.G. et al. Assessment of vegetable and fruit substrates as potential rearing me-dia for Hermetia illucens (Diptera: Stratiomyidae) larvae // Environmental Entomology. 2017. Vol. 46. № 6. P. 1415 – 1423.
9. Choi Y., Choi J., Kim J. et al. Potential usage of food waste as a natural fertilizer after digestion by Hermetia illucens (Diptera: Stratiomyidae) // International Journal of Industrial Entomology. 2009. Vol. 19. № 1. P. 171 – 174.
10. Mertenat A., Diener S., Zurbrügg C. Black Soldier fly biowaste treatment – assessment of global warming potential // Waste Management. 2019. Vol. 84. P. 173 – 181.
11. Lic Q., Zheng L., Qiu N. et al. Bioconversion of dairy manure by black soldier fly (Diptera: Stratiomyidae) for biodiesel and sugar production // Waste Management. 2011. Vol. 31. P. 1316 – 1320.
12. Шайхиев И.Г., Свергузова С.В., Сапронова Ж.А., Бомба И.В. Переработка куриного помета с исполь-зованием личинок Черной Львинки (Hermetia illucens): обзор // Птицеводство. 2021. № 2. С. 68 – 73.
13. Cai M., Hu R., Zhang K. Resistance of black soldier fly (Diptera: Stratiomyidae) larvae to combined heavy metals and potential application in municipal sewage sludge treatment // Environmental Science and Pollution Re-search. 2018. Vol. 25. P. 1559 – 1567.
14. Yurina O.V., Karagodin V.P. Studying development of Hermetia illucens fl y larvae cultivated on high cel-lulose plant substrates. Bulgarian Journal of Agricultural Science. 2018. Vol. 24. № 2. P. 279 – 284.
15. Ewald N., Vidakovic A., Langeland M. et al. Fatty acid composition of black soldier fly larvae (Hermetia il-lucens) – possibilities and limitations for modification through diet // Waste Management. 2020. Vol. 102. P. 40 – 47.
16. Makkar H.P.S., Tranb G., Heuzé V. et al. State-of-the-art on use of insects as animal feed // Animal Feed Science and Technology. 2014. Vol. 197. P. 1 – 33.
17. Liu C., Wang C., Yao H. Comprehensive resource utilization of waste using the black soldier fly (Hermetia illucens (L.) (Diptera: Stratiomyidae) // Animals. 2019. Vol. 9. Article 349. 19 p.
18. Moula N., Scippo M., Douny C.et al.Performances of local poultry breed fed black soldier fly larvae reared on horse manure // Animal Nutrition. 2018. Vol. 4. P. 73 – 78.
19. Shelomi M. Nutrient composition of black soldier fly (Hermetia illucens) // In African Edible Insects As Alternative Source of Food, Oil, Protein and Bioactive Components. 2020. P. 195 – 212.
20. Sverguzova S.V., Sapronova Z.A., Fomina Z.A. et al. Use of fly larvae Hermetia illucens in poultry feeding. A review paper // Journal of Water and Land Development. 2021. Vol. 49. P. 95 – 103.
21. Шайхиев И.Г., Свергузова С.В., Сапронова Ж.А., Даньшина Е.П. Использование биомассы личинок Hermetia illucens для выращивания рыб в аквакультуре (обзор зарубежной литературы) // Рыбное хозяйство. 2020. № 5. С. 86 – 92.
22. Shaikhiev I.G., Sverguzova S.V., Sapronova Zh.A. Use offly larvae Hermetia illucens in feed dietfor grow-ing piglets and adult pigs // Sciences of Europe (Praha, Czech Republic). 2020. Vol. 2. № 59. P. 12 – 19.
23. Ahmad T., Belwal T., Li L. et al. Utilization of wastewater from edible oil industry, turning waste into valu-able products: A review // Trends in Food Science & Technology. 2020. Vol. 99. Р. 21 – 33.
24. Liang H., Esmaeili H. Application of nanomaterials for demulsification of oily wastewater: A review study // Environmental Technology & Innovation. 2021. Vol. 22. Art. 101498. 15 p.
25. Saththasivam J., Loganathan K., Sarp S. An overview of oil-water separation using gas flotation systems // Chemosphere. 2016. Vol. 144. P. 671 – 680.
26. Zhao C., Zhou J., Yan Y. et al. Application of coagulation/flocculation in oily wastewater treatment: A re-view // Science of The Total Environment. 2021. Vol. 765. Art. 142795.
27. Pulido J.M.O. A review on the use of membrane technology and fouling control for olive mill wastewater treatment // Science of The Total Environment. 2016. Vol. 563 – 564. P. 664 – 675.
28. Solomakou N., Goula A.M. Treatment of olive mill wastewater by adsorption of phenolic compounds // Re-views in Environmental Science and Bio/Technology. 2021. Vol. 20. P. 839 – 863.
29. Paraskeva P., Diamadopoulos E. Review Technologies for olive mill wastewater (OMW) treatment: a review // Journal of Chemical Technology and Biotechnology. 2006. Vol. 81. P. 1475 – 1485.
30. Lakshmipathy R., Sarada N.C., Jayaprakash N. Agricultural wastes as low cost adsorbents for sequestration of heavy metal ions and synthetic dyes from aqueous solution: A mini review // International Journal of ChemTech. 2015. Vol.8. № 5. P. 25 – 31.
31. Sharma N., Tiwari D.P., Singh S.K. Decolourisation of synthetic dyes by agricultural waste – A review // In-ternational Journal of Scientific & Engineering Research. 2012. Vol. 3. № 2. 10 p.
2. Lehtoranta S., Vilpas R., Mattila T.J. Comparison of carbon footprints and eutrophication impacts of rural on-site wastewater treatment plants in Finland // Journal of Cleaner Production. 2014. Vol. 65. Р. 439 – 446.
3. Liew W.L., Kassim M.A., Muda K. et al. Conventional methods and emerging wastewater polishing technol-ogies for palm oil mill effluent treatment: A review // Journal of Environmental Management. 2015. Vol. 149. P. 222 – 235.
4. Azbar N., Bayram A., Filibeli A. et al. A review of waste management options in olive oil production // Criti-cal Reviews in Environmental Science and Technology. 2004. Vol. 34. № 3. P. 209 – 247.
5. Ushakova N.A., Brodskii E.S., Kovalenko A.A. et al.Characteristics of lipid fractions of larvae of the Black Soldier fly Hermetia illucens // Doklady Biochemistry and Biophysics. 2016. Vol. 468. P. 1 – 4.
6. Ewald N., Vidakovic A., Langeland M. et al. Fatty acid composition of black soldier fly larvae (Hermetia il-lucens) – Possibilities and limitations for modification through diet // Waste Management. 2020. Vol. 102. P. 40 – 47.
7. Smets R., Verbinnen B., Van De Voorde I. et al. Sequential extraction and characterisation of lipids, proteins, and chitin from Black Soldier fly (Hermetia illucens) larvae, prepupae, and pupae // Waste Biomass Valorization. 2020. Vol. 11. P. 6455 – 6466.
8. Jucker C., Erba D., Leonardi M.G. et al. Assessment of vegetable and fruit substrates as potential rearing me-dia for Hermetia illucens (Diptera: Stratiomyidae) larvae // Environmental Entomology. 2017. Vol. 46. № 6. P. 1415 – 1423.
9. Choi Y., Choi J., Kim J. et al. Potential usage of food waste as a natural fertilizer after digestion by Hermetia illucens (Diptera: Stratiomyidae) // International Journal of Industrial Entomology. 2009. Vol. 19. № 1. P. 171 – 174.
10. Mertenat A., Diener S., Zurbrügg C. Black Soldier fly biowaste treatment – assessment of global warming potential // Waste Management. 2019. Vol. 84. P. 173 – 181.
11. Lic Q., Zheng L., Qiu N. et al. Bioconversion of dairy manure by black soldier fly (Diptera: Stratiomyidae) for biodiesel and sugar production // Waste Management. 2011. Vol. 31. P. 1316 – 1320.
12. Шайхиев И.Г., Свергузова С.В., Сапронова Ж.А., Бомба И.В. Переработка куриного помета с исполь-зованием личинок Черной Львинки (Hermetia illucens): обзор // Птицеводство. 2021. № 2. С. 68 – 73.
13. Cai M., Hu R., Zhang K. Resistance of black soldier fly (Diptera: Stratiomyidae) larvae to combined heavy metals and potential application in municipal sewage sludge treatment // Environmental Science and Pollution Re-search. 2018. Vol. 25. P. 1559 – 1567.
14. Yurina O.V., Karagodin V.P. Studying development of Hermetia illucens fl y larvae cultivated on high cel-lulose plant substrates. Bulgarian Journal of Agricultural Science. 2018. Vol. 24. № 2. P. 279 – 284.
15. Ewald N., Vidakovic A., Langeland M. et al. Fatty acid composition of black soldier fly larvae (Hermetia il-lucens) – possibilities and limitations for modification through diet // Waste Management. 2020. Vol. 102. P. 40 – 47.
16. Makkar H.P.S., Tranb G., Heuzé V. et al. State-of-the-art on use of insects as animal feed // Animal Feed Science and Technology. 2014. Vol. 197. P. 1 – 33.
17. Liu C., Wang C., Yao H. Comprehensive resource utilization of waste using the black soldier fly (Hermetia illucens (L.) (Diptera: Stratiomyidae) // Animals. 2019. Vol. 9. Article 349. 19 p.
18. Moula N., Scippo M., Douny C.et al.Performances of local poultry breed fed black soldier fly larvae reared on horse manure // Animal Nutrition. 2018. Vol. 4. P. 73 – 78.
19. Shelomi M. Nutrient composition of black soldier fly (Hermetia illucens) // In African Edible Insects As Alternative Source of Food, Oil, Protein and Bioactive Components. 2020. P. 195 – 212.
20. Sverguzova S.V., Sapronova Z.A., Fomina Z.A. et al. Use of fly larvae Hermetia illucens in poultry feeding. A review paper // Journal of Water and Land Development. 2021. Vol. 49. P. 95 – 103.
21. Шайхиев И.Г., Свергузова С.В., Сапронова Ж.А., Даньшина Е.П. Использование биомассы личинок Hermetia illucens для выращивания рыб в аквакультуре (обзор зарубежной литературы) // Рыбное хозяйство. 2020. № 5. С. 86 – 92.
22. Shaikhiev I.G., Sverguzova S.V., Sapronova Zh.A. Use offly larvae Hermetia illucens in feed dietfor grow-ing piglets and adult pigs // Sciences of Europe (Praha, Czech Republic). 2020. Vol. 2. № 59. P. 12 – 19.
23. Ahmad T., Belwal T., Li L. et al. Utilization of wastewater from edible oil industry, turning waste into valu-able products: A review // Trends in Food Science & Technology. 2020. Vol. 99. Р. 21 – 33.
24. Liang H., Esmaeili H. Application of nanomaterials for demulsification of oily wastewater: A review study // Environmental Technology & Innovation. 2021. Vol. 22. Art. 101498. 15 p.
25. Saththasivam J., Loganathan K., Sarp S. An overview of oil-water separation using gas flotation systems // Chemosphere. 2016. Vol. 144. P. 671 – 680.
26. Zhao C., Zhou J., Yan Y. et al. Application of coagulation/flocculation in oily wastewater treatment: A re-view // Science of The Total Environment. 2021. Vol. 765. Art. 142795.
27. Pulido J.M.O. A review on the use of membrane technology and fouling control for olive mill wastewater treatment // Science of The Total Environment. 2016. Vol. 563 – 564. P. 664 – 675.
28. Solomakou N., Goula A.M. Treatment of olive mill wastewater by adsorption of phenolic compounds // Re-views in Environmental Science and Bio/Technology. 2021. Vol. 20. P. 839 – 863.
29. Paraskeva P., Diamadopoulos E. Review Technologies for olive mill wastewater (OMW) treatment: a review // Journal of Chemical Technology and Biotechnology. 2006. Vol. 81. P. 1475 – 1485.
30. Lakshmipathy R., Sarada N.C., Jayaprakash N. Agricultural wastes as low cost adsorbents for sequestration of heavy metal ions and synthetic dyes from aqueous solution: A mini review // International Journal of ChemTech. 2015. Vol.8. № 5. P. 25 – 31.
31. Sharma N., Tiwari D.P., Singh S.K. Decolourisation of synthetic dyes by agricultural waste – A review // In-ternational Journal of Scientific & Engineering Research. 2012. Vol. 3. № 2. 10 p.