Elucidation of both basic parameters of the coagulation and ways of interaction between potassium humate and mycromicete exsoproteine

The work shows that exoprotein (hereinafter biological coagulant, BC), which the micromycete produces in the cultivation medium, can interact with the potassium humate (PH) and subsequently coagulate and sediment in the form of complexes. The rate and time of interaction between PH and BC depend on their ratio in solution. It has been found that when using 2.37:1 (PH÷BC) or 0.00141 g/ml PH÷12,73 mcg/ml BC, complete sedimentation of PH occurs. The interrelation between the PH÷BC in solution and the efficiency of PH sedimentation has been analyzed. The sedimentation rate, time and the change in the pH of the medium on the amount of BC in the solution have been determined. The ways of interaction of PH with BC have been analyzed using the method of IR spectroscopy.

1. Walber M., Meyrhn H., Felgener G.W. Biotechnological Lignite Conversion – A Large Scale Concept. Proc. 9th Intern. Conf. on Coal Science. Essen, Germany, 1997, vol. 3, pp. 1689-1692.

2. Apel W.A., Dugan P.R., Wiebe M.R. Influence kaolin on methane oxidation by Methylomonas methanica in gas phase bioreactors. Fuel, 1992, vol. 71, pp. 805-808.

3. Shumkov S., Terehova S., Laurinovichinsk K. Coal biogasification in combined aerobic anaerobic bioreacto. Proc. 9th Intern. Conf. on Coal Science. Essen, Germany, 1997, vol. 3, pp. 1623-1626.

4. Eligwe Ch. A. Microbial desulphirization of coal. Fuel, 1988, vol. 67, pp. 451-458.

5. Rohwerder T., Schippers A., Sand W. Quantification of metal sulfide oxidation by microcalorimetry. Proc. 8th Intern. Conf. on Coal Science. Oviedo, Spain, 1995, vol. 3, pp. 1659-1662.

6. Lin M.P., Premuzic E.T., Manowitz B., et al. Biodegradation of coal. Fuel, 1993, vol. 72, pp. 1667-1672.

7. Shevkoplyas V.N. Strukturno-khimicheskaya transformatsiya nizkosortnykh ugley mikromitsetami [Structural-chemical transformation of low-grade coals by micromycetes]. Problemy sbora, pererabotki i utilizatsii otkhodov – Problems of collection, processing and disposal of waste. Odessa, 2001, pp. 379-383.

8. Kamneva A.I., Platonov V.V. Teoreticheskiye osnovy khimicheskikh tekhnologiy goryuchikh iskopayemykh [Theoretical foundations of the chemical technology of fossil fuels]. Moscow: Khimiya Publ., 1990. 288 p.

9. Khilko S.L., Semenova R.G. Vzaimodeystviye guminovykh kislot s lekarstvennym preparatom [Interaction of humic acids with drugs]. Khimiya tverdogo topliva – Chemistry of solid fuel, 2016. no. 6, p. 60.

10. Khilko S.L., Rogatko M.I., Makarova R.A., Semenova R.G. Osobennosti formirovaniya adsorbtsionnykh sloyev produktov mekhanokhimicheskoy modifikatsii guminovykh kislot na granitse razdela zhidkost'-gaz [Features of the formation of adsorption layers of products of mechanochemical modification of humic acids at the liquid-gas interface]. Kolloidnyy zhurnal – Colloid Journal, 2020, vol. 82, no. 6, pp. 749-760.

11. Tayts Ye.M., Andreyeva I.A. Metody analiza i ispytaniye ugley [Analysis methods and testing of coals]. Moscow, Nedra Publ., 1983. 301 p.

12. Darbe A. Practical Protein Chemistry: A Handbook. Chichester, John Wiley and Sons, 1986, 620 p. (Russ. ed.: Darbe A. Prakticheskaya khimiya belka. Moscow, Mir Publ., 1989. 623 p.).

13. Smit A. Applied Infrared Spectroscopy. Chichester, John Wiley and Sons, 1979, 336 p. (Rus ed.: Smit A. Prikladnaya IKspektroskopiya. Moscow, Mir Publ., 1982. 327 p.).

14. Solomon P.R., Hamblen D.G., Serio M.A., et al. A characterization method and model for prediction coal conversion behaviour. Fuel, 1993, vol. 72, pp. 469-488.

15. Landais P., Rochdi A. In situ examination of coal macerals oxidation by micro-FT-i.r. spectroscopy. Fuel, 1993, vol. 72, pp. 1393-1401.

16. Painter P.C., Coleman M.M. Application of Fouriertransform spectroscopy to the characterization of infrared of fractionation coal liquids. Fuel, 1979, vol. 58, pp. 301- 308.