Article
Article name Analysis of Heat Removal Efficiency of Heating Surfaces
Authors Batukhtin A.G. doctor of technical sciences, associate professor, batuhtina_ir@mail.ru
Batukhtin S.G. candidate of technical sciences, associate professor, batihtin1@mail.ru
Yakubovich A.I. master degree student, TESm-22 group, alexander_yakubovich75@mail.ru.
Kuznetsova N.S. candidate of biological sciences, associate professor, kuznetsovans@zabgu.ru;
Bibliographic description Batukhtin A.G, Batukhtin S. G., Yakubovich A. I., Kuznetsova N. S. Analysis of the heat removal efficiency of heating surfaces // Transbaikal State University Journal. 2023. Vol. 29, no. 4. P. 65–72. DOI: 10.21209/2227- 9245-2023-29-4-65-72.
Category Subsoil Use, Mining Sciences
DOI 536.46; 622.7; 533.6; 522.7
DOI 10.21209/2227-9245-2023-29-4-65-72
Article type Original article
Annotation The study of energy efficiency and energy saving of industrial boiler units, including those used at mining enterprises of the Transbaikal Territory, is an urgent scientific task. The purpose of the work is to study the efficiency of the heating surfaces of boiler units. The following tasks have been consistently solved: assessment of heat transfer on heating surfaces in a convective shaft depending on the flue gas velocity, their volume; identification of the dependence of heat removal of heating surfaces on steam and ampere load. The object of the research is a boiler unit of the BKZ type- 210-140-10. The subject of the study is the characteristics of heating surfaces and their aerodynamic resistance. The main tasks of the study are determined; the dependences of the heat removal from heating surfaces on the steam load, the resistance of the convective shaft and the ampere load of the smoke pumps are studied. The experimental results concerning the study of heat transitions on heating surfaces, heat removal from the initial temperature, ampere load of draft mechanisms, temperature dynamics of exhaust gases and aerodynamic drag behind heating surfaces at superheated steam consumption from 90 to 210 tons/hour are presented. An inversely proportional dependence of the heat transfer on the heating surfaces and the steam flow is established. The reduction of the ampere load on the flue pumps and the exhaust gas flow rate in the convective shaft during unloading of the boiler unit is shown. A decrease in the aerodynamic drag of the convective shaft is determined, which is the result of a decrease in the volume of gases and their velocity. Conclusions are drawn about an increase in the efficiency of heat removal of surfaces with a decrease in the velocity of gases in the convective part of the boiler, which directly depends on the ampere loading of the flue pumps, which is due to a change in the velocity of feed water and air in the heating surfaces that is not proportional to the velocity of gases passing through the convective shaft. It is determined that the lower the velocity of the exhaust gases in the convective shaft, the more efficient the heat transfer in the furnace and the higher the efficiency.
Key words boiler unit, heating surface,temperature, heat removal,steam and ampere load,convective shaft, smokepump, aerodynamic drag,discharge, exhaust gastemperature
Article information
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