The development and study of immersed burning apparatus with multiple phases inversion

Authors

  • Валерий Евгеньевич Никольский Ukrainian State Chemical-Technology University, Gagarina 8, Dnepropetrovsk, Ukraine, 49005, Ukraine https://orcid.org/0000-0001-6069-169X

DOI:

https://doi.org/10.15587/2312-8372.2015.47791

Keywords:

heat transfer, immersed burning apparatus, bubbling, phase inversion, energy efficiency, contact-modular system, separation zone

Abstract

The results of researches the phenomenon of multiple phase inversion for ascending gas-liquid flow in immersed burning apparatus (IBA) is given in the article. For the first time it is shown that the organization of multiple inversions of gas-liquid contacting phases in the direct-flow gas-liquid by heightwise installation of separation grids or valve plates intensifies heat and mass transfer and favorably distinguishes them from bubbling devices of similar purpose. This ensures high efficiency of contact phases; stable operation over a wide load range gas and liquid; high transporting property of liquids by gas, which simplifies heating technology; high intensity of processes in the gas – liquid system; reducing fuel consumption for heating the coolant (or technological product).

Author Biography

Валерий Евгеньевич Никольский, Ukrainian State Chemical-Technology University, Gagarina 8, Dnepropetrovsk, Ukraine, 49005

Candidate of Technical Sciences, Associate Professor

Department of Energetic

References

  1. Tovazhniansky, L. L., Pertzev, L. P., Shaporev, V. P. et al. (2004). Teploenergetika pogruzhnogo gorenija v reshenii problem teplosnabzheniya i ekologiyi Ukrainy. Integrirovanniye technologii i enerosberezheniye, 3, 3–12.
  2. Alabovsky, A. N., Udima, A. N. (1994). Apparaty pogruzhnogo goreniya. M.: MEI, 256.
  3. ТУ У 29.7-02070758-001:2008. Universal heater of technological liquids UHTL-101.01. (2008). Dnepropetrovsk.
  4. Kafarov, V. V. (1979). Osnovi masoperedachi. Sistemy gas-zhidkost, par-zhidkost, zhidkost-zhidkost. M.: Vischaya shkola, 439.
  5. Zadorsky, V. M. (1979). Intensificatsiya gasozhidostnikh protsessov v khimitcheskoi tehnologii. Kyiv: Tehnica, 198.
  6. Reihshfeld, V. S., Shein, V. S., Yermakov, V. I.; Reihshfeld, V. S. (1975). Reactsionnaya apparatura i mashini zavodov osnovnogo organicheskogo sinteza i sinteticheskogo kauchuka. Leningrad: Khimiya, 391.
  7. Bautner, L. M. (1966). Processi i apparaty organicheskogo sinteza i biokhimicheskoi tehnologii. Methody raschota. Moskwa, Leningrad: Khimiya, 520.
  8. Zhorov, Y. M. (1973). Raschoty i issledovaniya khimicheskikh protsessov nephtepererabotki. Мoskwa: Khimiya, 213.
  9. Zadorsky, V. M., Tarat, E. E., Vasin, N. V., Olemberg, V. I. (1982). Sovershenstvovaniye konstruktsii regularnikh nasadok dlya promishlennikh massoobmennikh apparatov. Zhurnal Prikladnoi Khimii, 8, 1784–1790
  10. Nikolsky, V. Y., Zadorsky, V. M. (15.04.2015). Aparat zanurenoho zghorannia. Decision on the grant of a patent № 6195/ЗУ/15 Ukraine.

Published

2015-07-23

How to Cite

Никольский, В. Е. (2015). The development and study of immersed burning apparatus with multiple phases inversion. Technology Audit and Production Reserves, 4(1(24), 60–64. https://doi.org/10.15587/2312-8372.2015.47791