IMPROVING THE EFFICIENCY AND RELIABILITY OF BOILER PLANTS OPERATION WITH FLUE GAS RECIRCULATION
Abstract
The paper the ways of improving the technologies of heat production in gas-consuming heating boiler plants to improve their environmental efficiency and increase the reliability of operation are investigated. The work purpose is to increase the thermal efficiency of environmentally efficient heating boiler plants and the prevention of condensate formation in their air-supply ducts by using complex heat recovery systems equipped with air heaters. The main objectives of the study are: determination the thermal parameters of a 2 MW heating boiler with a exhaust gas recirculation system into the blown air under the conditions of using complex heat recovery systems; determination and analysis the thermal and humidity parameters of the mixture of recirculation gases and blown air and the levels of increase the boiler units efficiency in different operating modes of boiler plants with the proposed heat recovery systems. Known thermal calculation methods of boiler plants and data from our own experimental studies of heat transfer in heat recovery exchangers of complex systems during deep cooling of boiler plant exhaust gases were used. The thermal calculation results of a heating boiler with the exhaust gas recirculation system mixed with blown air using the proposed heat recovery system are presented. Based on the data obtained, the regularities of changes in the thermal and humidity characteristics (temperature, dew point, and their difference) of the mixture of recirculated gases and air in different boiler modes during the heating period, at the studied particles of recirculation (from 10 to 20%) and various flue gas selection options were established. The research results show that the use of the proposed system by heating the air by 38-42 °C prevents condensation and icing in the air-supply ducts of the boiler plant in all modes of its operation during the heating period under all considered conditions. It is shown that the use of the proposed heat recovery system increases the efficiency of fuel use in such installations. Thus, the use of heat recovery systems with heating of return heating water and blast air under the conditions under consideration provides a resulting increase of efficiency factor in the range of 1.0 - 3.8%.
References
2. Mikhailenko V.S., Shcherbinin V.A., Leshchenko V.V., Kharchenk R.Yu., Lozhechnikova N.V. [Modeling the process of hazardous emissions formation in the exhaust gases of ship's steam boilers]. Informatics and Mathematical Methods in Simulation. 2020. V.10, №3–4. P. 154–166. DOI 10.15276/imms.v10.no 3-4.154 (in Ukr.)
3. Kisilitsa А.О. Ekolohichne obgruntuvannia tekhnolohichnykh rishen modernizatsii obladnannia kotelnoy [Ecological substantiation of technological solutions for the modernization of boiler plant equipment]: master's thesis / National Aerospace University "Kharkiv Aviation Institute". Kharkiv, 2020. 84 p. Available at http://dspace.library.khai.edu/xmlui/handle/123456789/843 (in Ukr.)
4. Yepifanov A.A., Dymo B.V., Patsurkovskyi P.A., Yazlovetskyi A.V. [Influence of flue gases recirculation on technical and ecological indicators of ship auxiliary boiler performance]. Shipbuilding & marine infrastructure. 2020. №2 (14). P. 4–16. DOI https://doi.org/10.15589/smi2020.2(14).1 (in Rus.)
5. Fialko N.М., Navrodska R.О., Shevchuk S.I., Abdulin М. Z. Osoblyvosti ekspluatatsii ekolohoefektyvnykh kotelnykh ustanovok komunalnoi teploenerhetyky [Operation features of environmentally efficient boiler plants of municipal thermal power engineering]. Thermophysics and Thermal Power Engineering. 2023. Vol. 45, №2, P. 55–62. https://doi.org/10.31472/ttpe.2.2023.6 (in Ukr.)
6. Fialko N.М., Navrodska R.О., Stepanova А.І., Shevchuk S.I., Serhiienko R.V. Teplovi aspekty ekspluatatsii opaliuvalnykh kotelnykh ustanovok z teploutylizatsiieiu ta retsyrkuliatsiieiu dymovykh gaziv [Thermal aspects of heating boiler plants operation with heat-recovery and exhaust gas recirculation]. Energy and automation. 2023. №2. P. 5–17. (in Ukr.)
7. Kuznetsov N. V., Mitor V. V., Dubovsky I. E. Teplovoy raschet kotelnykh agregatov. Normativnyy metod [Thermal calculation of boiler units. Normative method] / Ed. N.V. Kuznetsov. Moscow, Ekolit. 296 p.
8. Navrodska R. A., Stepanova A. I., Shevchuk S. I., Gnedash G. A., Presich G. A. Eksperimentalnoe issledovanie teploobmena pri glubokom okhlazhdenii produktov sgoraniia gazopotreblyaushchikh kotlov [Experimental investigation of heat-transfer at deep cooling of combustion materials of gas-fired boilers]. Scientific Bulletin of UNFU, 2018, vol. 28, no 6. P. 103–108. https://doi.org/10.15421/40280620 (in Ukr.)
9. Lipa А. I. Konditsionirovanie vozdukha. Osnovy teorii. Sovremennye tekhnolohii obrabotki vozdukha [Air conditioning. Theory basics. Modern air treatment technologies]. 2010. Odessa: ВМВ. ISBN 978-966-413-146-6. (in Rus.)
Abstract views: 327 PDF Downloads: 145
If the article is accepted for publication in the journal «Thermophysics and Thermal Power Engineering» the author must sign an agreementon transfer of copyright. The agreement is sent to the postal (original) or e-mail address (scanned copy) of the journal editions.



