English
Русский 93-104 p.
The possibility of using the crushed biomass of the pods of the common pea (Pisum sativum) as a sorption material for purifying model waters from the production of lipid concentrate from the larvae of the fly of the species Hermetia illucens has been investigated. Information on the composition and amount of lipids and saturated and unsaturated fatty acids in insect larvae is briefly presented. The effect of the particle size of the sorption material on the efficiency of the adsorptive extraction of the lipid concentrate emulsion from the model wastewater was investigated and an increase in the degree of purification with an increase in the dispersion of the dried biomass of pea pods was revealed. The dependence of the efficiency of removal of emulsion particles on the dosage of the sorption material and the time of contact of the latter with the sorbate was also investigated. The optimal pa-rameters of adsorption purification have been determined.
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 r.
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. R. 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/ Critical 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: Strati-omyidae) for biodiesel and sugar production. Waste Management. 2011. Vol. 31. P. 1316 – 1320.
12. Shajhiev I.G., Sverguzova S.V., Sapronova Zh.A., Bomba I.V. Pererabotka kurinogo pometa s ispol'zovaniem lichinok CHernoj L'vinki (Hermetia illucens): obzor. Pticevodstvo. 2021. № 2. S. 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 Sci-ence 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 Al-ternative 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. SHajhiev I.G., Sverguzova S.V., Sapronova ZH.A., Dan'shina E.P. Ispol'zovanie biomassy lichinok Hermetia illucens dlya vyrashchivaniya ryb v akvakul'ture (obzor zarubezhnoj literatury). Rybnoe hozyajstvo. 2020. № 5. S. 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. R. 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 re-view. 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. R. 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/ Critical 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: Strati-omyidae) for biodiesel and sugar production. Waste Management. 2011. Vol. 31. P. 1316 – 1320.
12. Shajhiev I.G., Sverguzova S.V., Sapronova Zh.A., Bomba I.V. Pererabotka kurinogo pometa s ispol'zovaniem lichinok CHernoj L'vinki (Hermetia illucens): obzor. Pticevodstvo. 2021. № 2. S. 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 Sci-ence 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 Al-ternative 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. SHajhiev I.G., Sverguzova S.V., Sapronova ZH.A., Dan'shina E.P. Ispol'zovanie biomassy lichinok Hermetia illucens dlya vyrashchivaniya ryb v akvakul'ture (obzor zarubezhnoj literatury). Rybnoe hozyajstvo. 2020. № 5. S. 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. R. 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 re-view. 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.