Original Scientific Paper, Volume 22, Number 2, Year 2024, No 1204, pp 393-401

Published: Jun 16, 2024

DOI: 10.5937/jaes0-46355

SIMULATION MODELing AND IMPROVEMENT OF THE WINDing DRUM COOLing CONDITIONS

Toty Buzauova 1
Toty Buzauova
Affiliations
Karaganda Technical University named after Abylkas Saginov, Karaganda, Kazakhstan
Search for articles by this author
Leonid Sivachenko 2
Leonid Sivachenko
Affiliations
Belarusian-russian university, Mogilev, Belarus
Search for articles by this author
Erlan Amanov 3
Erlan Amanov
Affiliations
«Kaz-Metiz» LLP, Karaganda city administration Kazakhstan
Search for articles by this author
Vladimir Mudrakov 3
Vladimir Mudrakov
Affiliations
«Kaz-Metiz» LLP, Karaganda city administration Kazakhstan
Search for articles by this author
Zhuldyzay Kaizaitv 1
Zhuldyzay Kaizaitv
Affiliations
Karaganda Technical University named after Abylkas Saginov, Karaganda, Kazakhstan
Search for articles by this author
Open PDF

Abstract

At the Kaz-Metiz LLP plant, there has long been a problem of insufficient drums cooling due to the scale formation, which led to the need for frequent production stops to cool them. To solve this problem, simulation modeling of cooling drums with and without scale was carried out to investigate the heat spread over the body. The results of the stationary analysis in the Ansys application showed the heat propagation across the cross-section of the drum and proved that the resulting scale, having a low thermal conductivity, significantly reduces the heat exchange from the drum wall to water, as a result, the surface of the drum is significantly overheated. Subsequently, the improved drum cooling system was implemented in «Kaz-Metiz» LLP.

Keywords

winding drums temperature simulation modeling Ansys application program thermal conductivity cooling thermal analysis

References

1.      Antony, A., How Low, J., Gray, S., Amy, E. (2011). Scale formation and control in high-pressure membrane water treatment systems. Journal of Membrane Science, vol. 383, no. 1-2, 1-16.

2.      Bozorgian, A., Ghazinezhad, M. (2018). A Case Study on Causes of Scale Formation- Induced Damage in Boiler Tubes. J Biochem Tech, Special Issue 2, pp.  149-153.

3.      Tyusenkov, A. S., Cherepashkin, S. E. (2014). Scale inhibitor for boiler water systems. Russian Journal of Applied Chemistry, vol.87, no. 1, 1240-1245.

4.      Luo, F., Bin, D., Jiacai, X., Jiang, Sh. (2012). Scaling tendency of boiler feedwater without desalinization treatment. Desalination, vol. 302, no. 3, 50-54. https://doi.org/10.1016/j.desal.2012.06.020.

5.      Chiran, D.M., Ranaraja, J.W., Maduwantha, M.I., Madhuwantha, G.A. Hansa, R.Y. (2020). Optimization of an Industrial Boiler Operation. Journal of Research Technology and engineering, vol. 1, no. 3, 2-10.

6.      Minko, V. A., Semenenko, A. S., Gunko, I. V., Elistratova, Yu. V. (2014). The influence of deposits on the working surfaces of the heating system on the performance of the system elements. Bulletin of BSTU, vol. 1, no. 5, 32-35.

7.      Dyer, S. J., Graham, G. M. (2002). The effect of temperature and pressure on oilfield scale formation. Journal of Petroleum Science and Engineering, vol. 35, no. 1, 95-107. DOI: 10.1016/S0920-4105(02)00217-6.

8.      Encyclopedia of Mechanical Engineering XXL, https://mash-xxl.info/page/107108033134021005187023222100176132228183072132/, accessed on 10.09.2023