Analysis of deposits in superheater tubes at coal-fired thermal power plants by Fourier IR spectroscopy

THE PURPOSE. Determination of the qualitative composition of deposits on the inner surface of the superheater tubes of the Aksuskaya GRES and CHPP stations of Aluminum Kazakhstan JSC located in the Republic of Kazakhstan.
METHODS. The most modern method of analysis is IR spectrophotometry, which is based on the absorption of IR radiation. Sediment analysis was carried out on an infrared spectrophotometer with Fourier transform of Shimadzu IRAffinity-1S. The peculiarity and justification of using this device is based on the high throughput of optics. A complementary function is a combination with a dynamic digital adjustment system. The DLATGS detector is used as a powerful ceramic radiation source. This detector is highly sensitive and thermally stabilized.
RESULTS. As a result of the analysis, it was found that the deposits on the inner surface are represented by metal corrosion products and heat-resistant humus substances. The latter easily pass into steam from boiler water (steam distillation) and settle on the surface of the tubes. Also, mineral substances and silicates are present as impurities, which also pass into steam in a small amount.
CONCLUSION. As a result of the analysis of deposits in superheater tubes at the stations of Aksuskaya GRES and CHPP of Aluminum Kazakhstan JSC located in the Republic of Kazakhstan, it was found that corrosion processes are quite intense, therefore corrosion products predominate in the deposits. To reduce the internal wear of the tubes, it is necessary to adjust the VCR, analyze the reagents used, and perform a step-by-step analysis of the coolant at each stage of cleaning.

1. Vlasova AYu, Rakhmatullin SS, Okuneva LA. Greening and improving the efficiency of traditional power engineering in Poland on the example of the project of brown coal thermal power plant «TUROW». Ecological safety in the technosphere space. 2021, pp. 45-49.

2. Barochkin EV, Vinogradov VN, Barochkin AE. Boiler plants and steam generators. Proc. Allowance. FGBOU VO «Ivanovo State Power Engineering University named after V.I. Lenin». 2018. P. 339. ISBN 978-5-00062-308-4.

3. Barochkin AE, Zhukov VP, Shumilova MS. et al. Optimization of the structure and operation mode of complex heat and mass transfer systems with multicomponent heat carrier. Bulletin of the Ivanovo State Power Engineering University. 2020.pp. 55-63.

4. Isaev VL, Koryabkin AA, Konekov AM. Influence of high-temperature corrosion of heat exchange surfaces in boiler furnaces. Karaganda State Technical University. Technical science. 2019. S. 183-191 doi: 10.24411/2500-1000-2019-11780.

5. Naboko EP, Chernyshova TI. On the issue of operation of heating surfaces of a steam generator. Karaganda State Technical University. Topical issues of technical sciences. 2014. pp. 182-191.

6. Vlasov SM, Vlasova AY, Chichirova ND. et al. Research into bacterial contamination of the coolant of the chemical demineralization scheme at Kazan CHPP-1. Thermal engineering. 2022; 3 (69): 222-226.

7. Khodyrev BN, Fedoseev BS. Rationing of the content of organic substances in the steam-water path of power units operating at NKVR. Elektricheskie stantsii. 2003;8:16-19.

8. Khodyrev BN, Krichevtsov AL, Sokolyuk AA. Investigation of the processes of oxidation of organic substances in the heat carrier of thermal power plants and nuclear power plants. Teploenergetika. 2010;7:11-16.

9. Khodyrev. BN, Korovin VA, Shcherbinina SD. et al. Problems of thermolysis of organic substances in the steam-water circuit of TPP. Energetik. 1998;7:23.

10. Martynova OI, Petrov AYu. Influence of water-chemical regimes on the behavior of organic compounds (acetates and formates) in the phase transition zone of steam turbines.Teploenergetika. 1977;12:62-65.

11. Semenov NN. Selected works. T.1. Chain reactions. Book.2.M.: Science. 2004.

12. Semenov NN. Selected works. T.3. On some problems of chemical kinetics and reactivity. M.: Science. 2005.

13. Kot A.A. Steam quality and salt deposition in superheaters and turbine blades. Power stations. 1950;11:178.

14. Lipov YuM., Tretyakov YuM. Boiler installations and steam generators. Moscow ; Izhevsk: Regular and chaotic dynamics. 2006. P. 591.

15. Filimonova AChichirov A, Chichirova N. et al Organic substances in process waters of a thermal power plant with a combined cycle gas turbine plant and methods for their detection. Lecture notes in civil engineering. 2022:247-256.

16. Filimonova AA, Chichirova ND, Chichirov AA. et al Physical and chemical methods of organic impurities control in the feed water of waste heat boilers of thermal power plants. Journal of physics: conference series. 2020. doi: 10.1088/1742-6596/1565/1/012028.

17. Chichirova ND, Chichirov AA, Vafin T.F. et al. Technical and economic assessment of the efficiency of using electromembrane technologies at domestic thermal power plants. Energy problems. 2012;11-12:14-26.

18. Chichirova ND, Chichirov AA, Filimonov AG. et al. Improving the efficiency of reagent pretreatment of water at Kazan CHPP-3. Energy problems. 2010;11-12:53-60.