WASTEWATERS POLLUTION CONTROL USING TWO-FREQUENCY LASER SOUNDING
Abstract and keywords
Abstract (English):
Optical methods for analysis of non-uniform liquid mediums have been considered, correlational and functional connections between the optical density and parameters characterizing industrial wastewaters’ type, content and pollution level have been investigated. Have been demonstrated main tendencies related to development of technology and equipment for optoelectronic control of industrial wastewaters’ pollution. Approximation of emission and absorption spectra for optical radiation’s emitter and receiver using the known Laplace function allows carry out calculations for a choice of optical couples’ coordinated parameters for two-frequency optical control, and as a result to increase reliability of identification for a type and degree of pollution for wastewaters and industrial effluents in comparison with use of one emission source. The method of pollution two-frequency laser sounding differs in improved control characteristics compared with the ones offered in patents, as well as in scientific and technical literature.

Keywords:
pollution control, laser sounding, wastewaters.
Text

1. Введение
Степень вредности сточных вод зависит от токсичности загрязняющих их веществ. Чтобы определить состав сточных вод, проводится множество различных анализов, как химических, так и санитарно-бактериологических [1, 2].

References

1. Voronov Yu.V., Yakovlev S. V. Vodootvedenie i ochistka stochnykh vod [Waste water treatment and treatment]. Moscow, ASV Publ., 2006. 704 p. (in Russian)

2. Yakovlev S. V., Gubiy I. G., Pavlinova I. I. Kompleksnoe ispol’zovanie vodnykh resursov [Integrated use of water resources]. Moscow, Vysshaya shkola Publ., 2008. 383 p. (in Russian)

3. Kozintsev V. I., Orlov V. M., Belov M. L. Optiko-elektronnye sistemy ekologicheskogo monitoringa prirodnoy sredy [Optoelectronic systems for environmental monitoring of the natural environment]. Moscow, MGTU im. N. E. Baumana Publ., 2002. 528 p. (in Russian)

4. Alekseev V. A., Usol’tsev V.P., Yuran S. I. Identifikatsiya vida i stepeni zagryazneniy stochnykh vod v tekhnologicheskom protsesse promyshlennogo proizvodstva [Identification of the type and degree of contamination of sewage in the technological process of industrial production]. Vestnik PNIPU. Prikladnaya ekologiya. Urbanistika [Herald of the PNIPU. Applied ecology. Urbanistics]. 2015, I. 4, pp.107-121. DOhttps://doi.org/10.15593/2409-5125.04.08 (in Russian)

5. Alekseev V. A., Devyatov N.A, Yuran S. I., Usol’tsev V. P. Patent № 153362 na poleznuyu model’. MPK G01N15/06. Ustroystvo ustraneniya avariynogo vybrosa [Patent No. 153362 for utility model. IPC G01N15/06. Device for elimination of emergency emissions]. 2015, I. 20.

6. Okatov M. A., Antonov E. A., Baygozhin A. Spravochnik tekhnologa-optika [Handbook of the technologist-optics]. St. Petersburg, Politekhnika Publ., 2004. 679 p. (in Russian)

7. Kuz’min V.L., Romanov V. P., Kozhevnikov S. V. Modelirovanie rasprostraneniya svetovogo impul’sa v sluchayno-neodnorodnoy srede [Modeling the propagation of a light pulse in a randomly inhomogeneous medium]. Optika i spektroskopiya [Optics and spectroscopy]. 2006, V. 100, I. 5, pp. 833-841. (in Russian)

8. Venttsel’ E.S., Ovcharov L. A. Teoriya veroyatnostey i ee inzhenernye prilozheniya [Theory of probability and its engineering applications]. Moscow, Vyssh. shk. Publ., 2000. 480 p. (in Russian)

9. Niemz M. H. Laser - Tissue Interactions: Fundamentals and Applications. - Berlin: Springer, 1996. - 302 p.

10. Evdokimov I. N., Losev A. P. Primenenie UF-vidimoy absorbtsionnoy spektroskopii dlya opisaniya prirodnykh neftey [Visible Absorption Spectroscopy for Descriptions of Natural Oils]. Neftegazovoe delo. Elektronnyy nauchnyy zhurnal [Oil and Gas. Electronic scientific journal]. 2007, I. 1. Available at: http://ogbus.ru/ (in Russian)

11. Alekseev V. A., Usol’tsev V.P., Yuran S. I. Avtomatizirovannoe upravlenie avariynymi sbrosami v sistemakh ochistki stochnykh vod [Automated management of emergency discharges in wastewater treatment systems]. Intellektual’nye sistemy v proizvodstve [Intellectual systems in production]. 2015, I. 1(25). Izhevsk: IzhGTU Publ., 2015, pp. 133-139. (in Russian)

12. Alekseev V. A., Usol’tsev V.P., Yuran S. I. Obobshchennaya veroyatnostnaya matematicheskaya model’ postupleniya stochnykh vod na ochistnye sooruzheniya pri zalpovykh sbrosakh [Generalized probabilistic mathematical model of sewage water supply to sewage treatment plants at volley discharges]. Intellektual’nye sistemy v proizvodstve [Intellectual systems in production]. 2014, I. 1(23). Izhevsk: IzhGTU Publ., 2014, pp. 108-113. (in Russian)

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