Numerical analysis of geometric shapes of energy-efficient complexes with integrated wind turbines

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Authors: Khazov P.A.¹, Vediaikina O.I.¹, Konovalova V.A.¹, Starikova M.V.¹, Shilov S.S.¹
Affiliations:
1. Nizhny Novgorod State University of Architecture and Civil Engineering
Issue: No 10 (2025)
Pages: 69-75
Section: Articles
URL: https://gynecology.orscience.ru/0044-4472/article/view/695929
DOI: https://doi.org/10.31659/0044-4472-2025-10-69-75
ID: 695929

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Abstract
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Abstract

The article is about the analysis of the various cross-sectional shapes of energy-efficient high-rise buildings towers equipped with integrated wind turbines influence on their aerodynamic parameters. Three variants of the tower base plan shape are proposed: rectangular, triangular and triangular with rounded corners. Modeling of the models aerodynamic flow was simulated in the ANSYS software and computing complex using the ANSYS CFX computational fluid dynamics module for two wind attack directions of 0^о and 45^о to the main facade. A comparative analysis of the high-rise complex towers models was carried out to identify the optimal configuration ensuring the stable air flow formation in the wind turbines vicinity and maximizes energy production. It was found that the triangular cross-section with rounded corners of the tower provides the best combination of aerodynamic characteristics, power generation efficiency and minimizes the vortex shedding likelihood.

Keywords

energy efficient buildings, wind turbine, building aerodynamics, computer modeling, air flow stability, building geometry, ecology

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About the authors

P. A. Khazov

Nizhny Novgorod State University of Architecture and Civil Engineering

Author for correspondence.
Email: khazov.nngasu@mail.ru

Doctor of Sciences (Engineering)

Russian Federation, 65, Ilyinskaya Street, Nizhny Novgorod, 603000

O. I. Vediaikina

Nizhny Novgorod State University of Architecture and Civil Engineering

Email: razvnauki@rambler.ru

Candidate of Sciences (Physics and Mathematics)

Russian Federation, 65, Ilyinskaya Street, Nizhny Novgorod, 603000

V. A. Konovalova

Nizhny Novgorod State University of Architecture and Civil Engineering

Email: K0n0val0vaVika@yandex.ru

Student

Russian Federation, 65, Ilyinskaya Street, Nizhny Novgorod, 603000

M. V. Starikova

Nizhny Novgorod State University of Architecture and Civil Engineering

Email: marina.starick0va@yandex.ru

Student

Russian Federation, 65, Ilyinskaya Street, Nizhny Novgorod, 603000

S. S. Shilov

Nizhny Novgorod State University of Architecture and Civil Engineering

Email: sergey.shilov.1997@mail.ru

Postgraduate Student

Russian Federation, 65, Ilyinskaya Street, Nizhny Novgorod, 603000

References

Asrar K., Okolnikova G.E., Hesam A.A.R., Svintsov A.P. On the role of nanotechnology in the construction industry and energy efficiency of buildings. International Research Journal. 2021. No. 5–1 (107), рр. 125–131. EDN: WSJJNI. https://doi.org/10.23670/IRJ.2021.107.5.020
Sarbaeva N.M., Omurbekova M.O., Jeenbaev U.K. The problems of increasing energy efficiency in residential buildings. The Herald of Kyrgyz state university of construction, transport and architecture named after N.Isanov. 2021. No. 1 (71), рр. 142–146. EDN: HNTGWG. https://doi.org/0.35803/1694-5298.2021.1.142-146
Olen’kov V.D., Kolmogorova A.O., Sapogova A.E. Determination of the coefficients of transformation of the air flow when exposed to a single building using computer modeling technologies. Vestnik of the South Ural State University. Construction and Architecture. 2019. Vol. 21. No. 1, pp. 5–12. (In Russian). EDN: YJXEZG. https://doi.org/10.14529/build210101
Khazov P.A., Shilov S.S. Geometrical optimization of aerodynamics of a high-rise building with integrated wind turbines. Vestnik of the South Ural State University. Construction and Architecture. 2024. No. 3, pp. 73–82. (In Russian). EDN: VJYQQC. https://doi.org/10.14529/build240307
Erofeev V.I., Satanov A.A., Hazov P.A., et al. Rational orientation of facilities with integrated wind turbines according to the criterion of maximizing the generated electricity. Mashinostroyeniye i inzhenernoye obrazovaniye. 2023. No. 4 (73), pp. 39–46. (In Russian). EDN: EOQUZZ. https://doi.org/10.52261/18151051_2023_3_39
Vediaikina O.I., Konovalova V.A., Starikova M.V., Khazov P.A., Satanov A.A. Aerodynamics of high-altitude complexes with integrated wind generating units. Zhurnal teoreticheskoy i prikladnoy mekhaniki. 2025. No. 1 (90), pp. 62–72. (In Russian). EDN: BKLZOE. https://doi.org/10.24412/0136-4545-2025-1-62-72
Lampsi B.B., Shilov S.S., Khazov P.A. Numerical and physical modeling of wind flows on a large-span coating. Vestnik MGSU. 2022. Vol. 17. Iss. 1, pp. 21–31. (In Russian). EDN: NPDHUS. https://doi.org/10.22227/1997-0935.2022.1.21-31

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2. Fig. 1. Three-dimensional visualization of a model with a linearly decreasing profile in height

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3. Fig. 2. Shapes under study (a), profile (b), tower plans (c) of the high-rise buildings complex with integrated wind turbines

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4. Fig. 3. Pressures and velocities distribution in wind turbine levels for digital model No. 1 at a wind angle of 0o

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5. Fig. 4. Pressures and velocities distribution in wind turbine levels for digital model No. 2 at a wind angle of 0o

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6. Fig. 5. Pressures and velocities distribution in wind turbine levels for digital model No. 3 at a wind angle of 0o

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7. Fig. 6. Diagrams of velocity distribution (a) and velocity increase coefficients k=vк/vвх (b) for digital models under flow attack perpendicular to the main facade

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8. Fig. 7. Pressures and velocities distribution in wind turbine levels for digital model No. 1 at a wind angle of 45o

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9. Fig. 8. Pressures and velocities distribution in wind turbine levels for digital model No. 2 at a wind angle of 45o

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10. Fig. 9. Pressures and velocities distribution in wind turbine levels for digital model No. 3 at the wind angle of 45o

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11. Fig. 10. Diagrams of velocity distribution (a) and velocity increase coefficients k=vк/vвх (b) for digital models at the wind angle of 45o

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12. Fig. 11. Diagrams of total reactions for each model at wind attack angles of 0o (a) and 45o (b)

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13. Fig. 12. Pressures and velocities distribution in wind turbine levels for digital model No. 4 at a wind angle of 0o

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14. Fig. 13. Pressures and velocities distribution in wind turbine levels for digital model No. 4 at a wind angle of 45o

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15. Fig. 14. Diagrams of velocity distribution, velocity increase coefficients, and total reactions at wind attack angles of 0o (a) and 45o (b) for models No. 3 and No. 4

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