Research of the homogenization process in the operation of a three-level closed turbine mixer

Authors

DOI:

https://doi.org/10.15587/2312-8372.2019.186654

Keywords:

cultivation of microorganisms in a bioreactor, homogenizing device, closed turbine mixer, flow hydrodynamics

Abstract

The object of research is a three-level turbine mixer of the closed type, designed and manufactured in full size using a 3D printer.

One of the most problematic places of the fermentation process in a bioreactor is the homogenization of the medium. During mixing, stagnant zones form in most fermenters, in these zones the medium is heterogeneous, warms up worse, receives insufficient air (if the medium is aerobic) and causes the death of cultivated microorganisms. Thus, the final product is not 100 % of the same structure, and, accordingly, quality, which is critical for pharmaceutical products.

In the course of the study, 2 different methods were used, which were designed to confirm or refute each other, namely: the computer simulation method and the experimental method. The experiment consists in manufacturing the developed mixer model and carrying out the mixing process with its use. Mixing is carried out at different velocities, with different types of mixers and using a contrast tracer to visualize the type of formed streams. Graphical modeling consisted of creating a similar experimental model of the mixer and carrying out graphical modeling in the CFX block of the ANSYS program. This method makes it possible to see the created flows from different angles, find the most dynamic zones and study the physics of the process from the inside.

The obtained result shows that a three-level closed turbine mixer shows better homogenization speed results than a typical closed turbine. This is due to the fact that the proposed solution has a number of features, in particular, the cellular structure of the shaft. The proposed computational models in ANSYS make it possible to obtain velocity fields and establish the magnitude and direction of velocity vectors.

A similar technique for evaluating the effectiveness of homogenization can be used in the design of new designs of mechanical mixing devices.

Author Biographies

Mykhailo Yaremchuck, National Technical University of Ukraine «Igor Sikorsky Kyiv Polytechnic Institute», 37, Peremohy ave., Kyiv, Ukraine, 03056

Department of Biotechnics and Engineering

Sergii Kostyk, National Technical University of Ukraine «Igor Sikorsky Kyiv Polytechnic Institute», 37, Peremohy ave., Kyiv, Ukraine, 03056

PhD, Associate Professor

Department of Biotechnics and Engineering

Vladyslav Shybetskуу, National Technical University of Ukraine «Igor Sikorsky Kyiv Polytechnic Institute», 37, Peremohy ave., Kyiv, Ukraine, 03056

PhD, Associate Professor

Department of Biotechnics and Engineering

References

  1. Kafarov, V. V., Vinarov, A. Iu., Gordeev, L. S. (1979). Modelirovanie bioximicheskix reaktorov. Moscow: Lesnaia promyshlennost, 344.
  2. Barabash, V. M., Begichev, V. I., Belevickaia, M. A., Smirnov, N. N. (2007). Problemy i tendencii razvitiia teorii i praktiki peremeshivaniia zhidkikh sred. Teoreticheskie osnovy khimicheskoi tekhnologii, 41 (2), 140–147.
  3. Kostyk, S. I., Ruzhynska, L. I., Shybetskyi, V. Yu., Revtov, O. O. (2016). Mathematical simulation of hydrodynamics of the mixing device with magnetic drive. ScienceRise, 4 (2 (21)), 27–31. doi: http://doi.org/10.15587/2313-8416.2016.67275
  4. Ruzhynska, L. I., Povodzynskyi, V. N., Cherednyk, Ye. M., Morozova, Ye. V. (2013). Mathematical modeling of mixing atcultivation of biological agents sensitive to transverse strain. Eastern-European Journal of Enterprise Technologies, 1 (4 (61)), 27–30. Available at: http://journals.uran.ua/eejet/article/view/9148
  5. Viestur, U. E. (1972). Aeraciia i peremeshivanie v processakh kultivirovaniia mikroorganizmov. Moscow, 54–67.
  6. Shybetskiy, V., Semeniuk, S., Kostyk, S. (2017). Design of consrtuction and hydrodynamic modeling in a roller bioreactor with surface cultivation of cell cultures. ScienceRise, 7 (36), 53–59. doi: http://doi.org/10.15587/2313-8416.2017.107176
  7. Zakomornyi, D. M., Kutovyi, M. H., Kostyk, S. I., Povodzynskyi, V. M., Shybetskyi, V. Yu. (2016). Hydrodynamics of fermenter with multi-shaft stirrer. ScienceRise, 5 (2 (22)), 65–70. doi: http://doi.org/10.15587/2313-8416.2016.69451
  8. Viestur, U. E., Kuznecov, A. M., Savenkov, V. V. (1988). Sistemy fermentacii Viestur. Riga: Zinatne, 368.
  9. Lure, Iu. Iu. (1975). Spravochnik po analiticheskoi khimii. Moscow: Khimiia, 488.
  10. Rukovodiaschii dokument RD 26.260.008-92. Fermentatory dlia proizvodstv mikrobiologicheskogo sinteza. Metodiki rascheta osnovnykh konstruktivnykh elementov i rezhimov raboty (1993). Izdanie oficialnoe.

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Published

2019-11-21

How to Cite

Yaremchuck, M., Kostyk, S., & Shybetskуу V. (2019). Research of the homogenization process in the operation of a three-level closed turbine mixer. Technology Audit and Production Reserves, 6(1(50), 26–28. https://doi.org/10.15587/2312-8372.2019.186654

Issue

Vol. 6 No. 1(50) (2019): Industrial and technology systems

Section

Reports on research projects

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Copyright (c) 2019 Mykhailo Yaremchuck, Sergii Kostyk, Vladyslav Shybetskуi

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