Научные публикации

Наиболее важные публикации начиная с 2020 г.

1. Logachev, K.I., Ziganshin, A.M., Huang, Y., Wang, Y., Averkova, O.A., Popov, E.N., & Kozlov, T.A. (2023). Developing a mathematical simulation method for three-dimensional separated airflow at inlet of local exhaust devices. Journal of Building Engineering, 63. P 105490. doi:10.1016/j.jobe.2022.105490

Impact Factor JCR 6.7 / Q1 / Web of Science Core Collection, Scopus

2. Logachev, K.I., Ziganshin, A.M., Huang, Y., Wang, Y., Averkova, O.A., Popov, E.N., . . . Tiron, O. V. (2022). Investigating changes in geometric dimensions of vortex zones at the inlet of an exhaust hood set over a plane. Building and Environment, 222. P 109377. doi:10.1016/j.buildenv.2022.109377

Impact Factor JCR 7.4 / Q1 / Web of Science Core Collection, Scopus

3. Logachev, K. I., Ziganshin, A. M., Popov, E. N., Averkova, O. A., Kryukova, O. S., & Gol'tsov, A. B. (2021). Experiment determining pressure loss reduction using a shaped round exhaust hood. Building and Environment, 190 doi:10.1016/j.buildenv.2020.107572

Impact Factor JCR 7.4 / Q1 / Web of Science Core Collection, Scopus

4. Logachev, K., Ziganshin, A., Kryukova, O., Averkova, O., Kryukov, I., & Gol'tsov, A. (2020). Improving dust capture efficiency with local exhaust hoods in manicure shops. Building and Environment, 181 doi:10.1016/j.buildenv.2020.107124

Impact Factor JCR 7.4 / Q1 / Web of Science Core Collection, Scopus

5. Logachev, I. N., Popov, E. N., Logachev, K. I., & Averkova, O. A. (2020). Refining the method for determining the flow rate of air entrained by freely falling polydisperse loose material. Powder Technology, 373, 323-335. doi:10.1016/j.powtec.2020.06.055

Impact Factor JCR 4.5 / Q1 / Web of Science Core Collection, Scopus

6. Logachev, K. I., Ziganshin, A. M., & Averkova, O. A. (2020). A study of separated flows at inlets of flanged slotted hoods. Journal of Building Engineering, 29 doi:10.1016/j.jobe.2019.101159

Impact Factor JCR  6.7 / Q1 / Web of Science Core Collection, Scopus

7. Averkova, O. A., Logachev, K. I., Kozlov, T. A., & Popov, E. N. (2022). Simulation of flow separation at the entrance to round exhaust hoods with a protrusion. Refractories and Industrial Ceramics, 63(2), 235-240. doi:10.1007/s11148-022-00713-w

Impact Factor JCR 0.4 / Q3 / Web of Science Core Collection, Scopus

8. Kochetov, V. V., Gol’tsov, A. B., Logachev, K. I., Averkova, O. A., & Kireev, V. M. (2021). Numerical simulation of the dynamics of dust in a rotary dust collector with an adjustable air flow. Refractories and Industrial Ceramics, 62(3), 361-365. doi:10.1007/s11148-021-00608-2

Impact Factor JCR 0.4 / Q3 / Web of Science Core Collection, Scopus

9. Seminenko, A. S., Logachev, K. I., Goltsov, A. B., & Averkova, O. A. (2021). Reduced dust generation when loading a bunker with powdery material. part 2. results of numerical and experimental studies. Refractories and Industrial Ceramics, 62(2), 236-243. doi:10.1007/s11148-021-00589-2

Impact Factor JCR 0.4 / Q3 / Web of Science Core Collection, Scopus

10. Seminenko, A. S., Logachev, K. I., Goltsov, A. B., & Averkova, O. A. (2021). Reduced dust generation when loading a bunker with powdery material. part 1. research methods. Refractories and Industrial Ceramics, 62(1), 116-121. doi:10.1007/s11148-021-00569-6

Impact Factor JCR 0.4 / Q3 / Web of Science Core Collection, Scopus

11. Averkova, O. A., Goltsov, A. B., Logachev, K. I., & Minko, A. V. (2020). Reduction of dust extraction from an aspiration hood via mechanical shielding. Refractories and Industrial Ceramics, 61(2), 228-233. doi:10.1007/s11148-020-00462-8

Impact Factor JCR 0.4 / Q3 / Web of Science Core Collection, Scopus

12. Shaptala, V.V., Logachev, K.I., Averkova, O.A., & Krutikova, D.N. (2020). Modeling of convective vapor-air flows near onboard suction from open-surface reservoirs. Refractories and Industrial Ceramics, 60(6), 636-641. doi:10.1007/s11148-020-00420-4

Impact Factor JCR 0.4 / Q3 / Web of Science Core Collection, Scopus

13. Averkova O.A., Logachev K.I., Tiron O.V. Mathematical Model of Separation Flow near a Suction Channel Embedded in the Side Surface of the Cylinder with an Open Part of the Base (2023) Refractories and Industrial Ceramics, 63 (5), pp. 572 - 577, DOI: 10.1007/s11148-023-00770-9

Impact Factor JCR 0.4 / Q3 / Web of Science Core Collection, Scopus

14. Моделирование отрывного воздушного потока при входе в квадратный отсос сообщение 1. Методы исследования / К.И. Логачев, Е.Н. Попов, Т.А. Козлов, А.М. Зиганшин, О.А. Аверкова // Известия высших учебных заведений. Строительство. – 2023. – № 6(774). – С. 39-53. – DOI 10.32683/0536-1052-2023-774-6-39-53.

RSCI

15. Моделирование отрывного воздушного потока при входе в квадратный отсос сообщение 2. Результаты расчета и их обсуждение / К. И. Логачев, Е. Н. Попов, Т. А. Козлов, А. М. Зиганшин, О. А. Аверкова// Известия высших учебных заведений. Строительство. – 2023. – № 7(775). – С. 61-71. – DOI 10.32683/0536-1052-2023-775-7-61-71.

RSCI

16. K.I. Logachev, E.N. Popov, T.A. Kozlov, A.M. Ziganshin, O.A. Averkova, O.V. Tiron, Improved aerodynamic performance of the exhaust hood with triple-faced flange, Journal of Building Engineering, Volume 91, 2024, 109664, ISSN 2352-7102, https://doi.org/10.1016/j.jobe.2024.109664.

Impact Factor JCR  6.7 / Q1 / Web of Science Core Collection, Scopus

17. Logachev K.I., Popov E.N., Kozlov T.A., Ziganshin A.M., Gao R., Averkova O.A., Tiron O.V.

Numerical and experimental studies of airflows at exhaust hoods with inlet extensions (2024) Building and Environment, 261, art. no. 111753. DOI: 10.1016/j.buildenv.2024.111753

Impact Factor JCR 7.4 / Q1 / Web of Science Core Collection, Scopus

18. Численное моделирование воздушного потока в аспирационной воронке с выравнивающим устройством / А. Б. Гольцов, К. И. Логачев, О. А. Аверкова [и др.] // Известия высших учебных заведений. Строительство. – 2024. – № 7(787). – С. 64-75. – DOI 10.32683/0536-1052-2024-787-7-64-75.

RSCI

19. Logacheva A.K., Averkova O.A., Ziganshin A.M., Logachev K.I., Popov E.N. Determination of the Influence of Oncoming Flow on the Vortex Zones at the Inlet of the Suction Sockets. Part 2. Axisymmetric Problem (2023) Refractories and Industrial Ceramics, 64 (3), pp. 346 - 350.

DOI: 10.1007/s11148-024-00849-x

Impact Factor JCR 0.4 / Q3 / Web of Science Core Collection, Scopus

20. Logacheva A.K., Averkova O.A., Ziganshin A.M., Logachev K.I., Popov E.N. Determination of the Influence of the Oncoming Flow on the Vortex Zones at the Inlet to the Suction Sockets. Part 1. Flat Problem (2023) Refractories and Industrial Ceramics, 64 (2), pp. 221 - 228.

DOI: 10.1007/s11148-023-00829-7

Impact Factor JCR 0.4 / Q3 / Web of Science Core Collection, Scopus

21. Averkova O.A., Goltsov A.B., Logachev K.I., Uvarov V.A. Numerical Study of Aspiration Efficiency of Local Exhaust Devices under Action of Cross Draughts of Dust-Laden Airflow (2023) AIP Conference Proceedings, 2758, art. no. 040003, Cited 0 times.

DOI: 10.1063/5.0130640

Scopus

22. Averkova O.A., Logachev K.I., Kozlov T.A., Popov E.N., Dmitrienko V.G. Numerical Calculation of the Boundaries of Vortex Zones at the Inlet to Round Exhaust Hoods with Three Shelves (2023) Refractories and Industrial Ceramics, 63 (6), pp. 681 - 686.

DOI: 10.1007/s11148-023-00791-4

Impact Factor JCR 0.4 / Q3

23. Logachev K., Ziganshin A., Huang Y., Wang Y., Averkova O., Gol'Tsov A., Sedova A. Development of a method for numerical modeling of the separation flow at the entrance to a rectangular exhaust channel with sharp edges (2022) E3S Web of Conferences, 356, art. no. 01014.

DOI: 10.1051/e3sconf/202235601014

24. Averkova, O. A., Golyshev, A. A., Logachev, K. I., & Uvarov, V. A. (2021). Local exhaust ventilation with reduced energy consumption during bulk materials overloads into receiving cones of coarse crushing plants. Paper presented at the Journal of Physics: Conference Series,  1926(1) doi:10.1088/1742-6596/1926/1/012022

Scopus

25. Averkova, O. A., Logachev, I. N., Logachev, K. I., Tolmacheva, E. I., & Uvarov, V. A. (2021). Development of methods for reducing the volume of aspiration during overloads of granular materials. Paper presented at the 8th International Conference on Computational Methods for Coupled Problems in Science and Engineering, COUPLED PROBLEMS 2019, 517-528.https://congress.cimne.com/coupled2019/frontal/doc/EbookCoupled2019.pdf

Web of Science Core Collection, Scopus

26. Averkova, O. A., Logachev, I. N., Logachev, K. I., Kryukov, I. V., Uvarov, V. A., Tolmacheva, E. I., & Tkachenko, V. A. (2021). Development of engineering method for calculation of ejected and recirculated air flow rates during reload of bulk materials. Paper presented at the 8th International Conference on Computational Methods for Coupled Problems in Science and Engineering, COUPLED PROBLEMS 2019, 505-516.https://congress.cimne.com/coupled2019/frontal/doc/EbookCoupled2019.pdf

Web of Science Core Collection, Scopus

27. Математическое моделирование свободно-конвективного течения над круглым теплоисточником / К. И. Логачев, А. М. Зиганшин, А. К. Степанова [и др.] // Известия высших учебных заведений. Строительство. – 2025. – № 6(798). – С. 106-123. – DOI 10.32683/0536-1052-2025-798-6-106-123. – EDN ZAKWPV.

28. Рязанов, М. Ю. Моделирование улавливания теплового потока бортовым щелевым отсосом от плоской нагретой поверхности / М. Ю. Рязанов, О. А. Аверкова, Е. Н. Попов // Экология промышленного производства. – 2025. – № 2(130). – С. 42-50. – DOI 10.52190/2073-2589_2025_2_42. – EDN RNEANL.

29. Оценка надежности работы инженерных систем с учетом прогнозирования / Н. Ю. Саввин, В. В. Строкова, О. А. Аверкова, К. И. Логачев // Вестник Белгородского государственного технологического университета им. В.Г. Шухова. – 2025. – № 11. – С. 78-87. – DOI 10.34031/2071-7318-2025-10-11-78-87. – EDN YORMJZ.