Improving of boiler efficiency by controlling the harmful substances concentration in the combustion products

• Autorzy: Szkarowski A. , Janta-Lipińska S.
• Języki publikacji: EN

Abstrakty

EN

Working for many years on theory and practice of effective and environment friendly fuel combustion, authors constantly promote the principle of energy-ecological optimisation [1]. Such approach means that optimum result of fuel combustion is qualified not only by direct efficiency of fuel consumption but also by minimal damage made to people and natural environment [2, 14]. One of the simplest, cheapest and at the same time highly effective ways of such optimisation is the burning of fuel in a zone of controllable, remnant chemical underburn (RCU) [3, 9, 10]. This may sound paradoxically for many specialists. Most boiler operation specialists are used to obey the unquestionable rule: products of non complete fuel combustion, especially when burning gas fuel, shall not be present in flue gases. This publication is intended to evaluate this question from the energy-ecological optimisation point of view, that is optimisation regarding fuel savings as well as environment protection.

Słowa kluczowe

EN

fuel combustion; energy-ecological optimisation; environmental protection; boiler operation

• Wydawca: Kielce University of Technology
• Czasopismo: Journal of New Technologies in Environmental Science
• Rocznik: 2017
• Tom: Vol. 1, nr 2
• Strony: 61--67
• Opis fizyczny: Bibliogr. 15 poz., wykr., wzory

Twórcy

autor

Szkarowski A.

• Koszalin University of Technology, Koszalin, Poland
• Saint-Petersburg State Polytechnical University, Russia

autor

Janta-Lipińska S.

• Koszalin University of Technology, Koszalin, Poland

Bibliografia

• [1] Szkarowski A., Estimation of modern tendencies In Environment Pollution. The Environment Protection. Ann. Set. Vol. 5, 2003. Koszalin. Poland: 67-78.
• [2] Novikov O., Artamonov D., Shkarowski A., Energy and ecological optimization of fuel combustion in boiler and furnace via regulation of fuel-air ratio. Energy Power Engineering 2000; 5: 57-60.
• [3] Baryshev V., Beloselskiy B., Zenkevich L., Shpolivskaya L., Decrease of nitrogen oxides emission via adjustable residual chemical underburn. Heating Engineering 1996; 4.
• [4] Trembovla V., Finger E., Avdeyeva A., Thermal Tests of Boilers. Moscow: Energoatomizdat, 1991.
• [5] Sigal I., Environment Protection at Fuel Burning. Leningrad: Nedra, 1988.
• [6] Bezrukih V., Choice of Optimum Parameters of a Gas-air Mix in Burners of Low Power Boilers for Fuel saving and Reduction Harmful Substances Emission. The thesis for a doctor's degree. Leningrad: LISI, 1988.
• [7] Komina G., Research of Products of Hydrocarbon Gases burning and Reduction Harmful Emissions. The thesis for a doctor's degree. Leningrad, 1971.
• [8] Szkarowski A., Nowikow O., Okatjew A., Kociergin M., The Intellectual System of a Combustion Quality Control. In Proceedings of IV National Polish Scientific Conference on Complex and Detailed Problems of Environmental Engineering. Koszalin-Ustronie Morskie, Poland, 2003: 117-126.
• [9] Szkarowski A., Janta-Lipińska S., Automatic Control of Burning Quality of Solid Fuel in Industrial Heating Boilers. Annual Set The Environment Protection. Vol. 11, 2009. Koszalin, s. 241-255.
• [10] Szkarowski A., Janta-Lipińska S., Modeling of Optimum Burning of Fuel in Industrial Heating Boilers. Annual Set The Environment Protection. Vol. 13, 2011. Koszalin, s. 511-524.
• [11] Szkarowski A., Janta-Lipińska S., Examination of boiler operation energy-ecological indicators during fuel burning with controlled residual chemical underburn. Annual Set The Environment Protection. Vol. 15, 2013. Koszalin, s. 981-995.
• [12] Szkarowski A., Janta-Lipińska S., Experimental Research Vs. Accuracy of the Elaborated Model. Annual Set The Environment Protection. Vol. 17, 2015. Koszalin, s. 576-584.
• [13] Szkarowski A., Janta-Lipińska S., Gawin R., Reducing Emissions of Nitrogen Oxides from DKVR Boilers. Annual Set The Environment Protection. Vol. 18, 2016. Koszalin, s. 565-578.
• [14] Pavlenko A., Szarowski A., Janta-Lipińska S., Research on Burning of Water Black Oil Emulsions. Annual Set The Environment Protection. Vol. 16, 2014. Koszalin, s. 376-385.
• [15] Orłowska M., Czapp M., Analiza numeryczna wydajności cieplnej konwekcyjnego wymiennika ciepła obudowanego poziomymi płytami. Annual Set The Environment Protection. Vol. 14, 2012. Koszalin, s. 582-585.

Uwagi

Opracowanie rekordu w ramach umowy 509/P-DUN/2018 ze środków MNiSW przeznaczonych na działalność upowszechniającą naukę (2018).