The Application of Fluid Mechanics in Engineering

Research Article
Open access

The Application of Fluid Mechanics in Engineering

Yu’an Zhou 1*
  • 1 Shanghai World Foreign Academy, Shanghai, 200030, China    
  • *corresponding author 2728562084@qq.com
TNS Vol.5
ISSN (Print): 2753-8826
ISSN (Online): 2753-8818
ISBN (Print): 978-1-915371-53-9
ISBN (Online): 978-1-915371-54-6

Abstract

Whether an item is popular or not depends largely on its cost performance. For manufacturers, it is very important to create the most high-quality items with the least amount of money. For example, in the case of the same material, what kind of bridge structure is the most material-saving and long-life, what specific design can make the car more fuel-efficient and faster, and what kind of special pipeline design can make the flow of water resources more efficient are problems that manufacturers need to constantly explore, and fluid mechanics can help and solve these problems to a large extent. This paper mainly introduces the application of fluid mechanics in bridge engineering, automobile design, and agricultural production. The author analyzes the working principle of fluid mechanics, including some speculations on the future development direction of fluid mechanics.

Keywords:

fluid mechanics, bridge engineering, automobile engineering, agricultural, water circulation.

Zhou,Y. (2023). The Application of Fluid Mechanics in Engineering. Theoretical and Natural Science,5,294-298.
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References

[1]. Wang, Z. D. A good textbook for fluid mechanics: Fluid mechanics (second edition). Mechanics and Practice (06), 1476-1478 (2022).

[2]. Liu, Z. J., Sun, D. Z., Wang, F. M., Du, B. Y. Application of computational fluid dynamics in bridge engineering. Heilongjiang Transportation Technology (03), 44-45 (2000). doi:10.16402/j.cnki.issn1008-3383.2000.03.025.

[3]. Ge, Y. J., Xia, Q., Zhao, L. Evaluation of wind resistance and vibration of large span bridge. Journal of Civil Engineering (11), 66-70+119 (2019). doi:10.15951/j.tmgcxb.2019.11.007.

[4]. Huang, Z. H., Peng, X. W. Control measures for wind-induced damage and induced vibration of bridge structure. The Traffic World (12), 138-139 (2021). doi:10.16248/j.cnki.11-3723/u.2021.12.065.

[5]. Jie, X. Q., Chen, P. Application of fluid mechanics in automobile body design. Journal of Sichuan Vocational and Technical College (06), 165-167 (2015). doi:10.13974/j.cnki.51-1645/z.2015.06.047.

[6]. Hucho, W. H. Aerodynamics of road vehicles, 4th edition, Society of Automotive Engineers (SAE) International, Warrendale (1997).

[7]. Kajiwara, S. Passive variable rear-wing aerodynamics of an open-wheel racing Car. Automot Engine Technol 2(1–4), 107–117 (2017). https://doi.org/10.1007/s41104-017-0021-9.

[8]. Peng, Z. W. Optimized design of siphon flow channel shape based on computational fluid dynamics. Hunan University (2009). https://kns.cnki.net/KCMS/detail/detail.aspx?dbname=CDFD1214&filename=1011264241.nh.

[9]. Dey, A. K. Siphon: Definition, Working Principle, Uses or Application. Fluid Mechanics and Hydraulic Machines (2022). https://learnmechanical.com/siphon/.

Cite this article

Zhou,Y. (2023). The Application of Fluid Mechanics in Engineering. Theoretical and Natural Science,5,294-298.

Data availability

The datasets used and/or analyzed during the current study will be available from the authors upon reasonable request.

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About volume

Volume title: Proceedings of the 2nd International Conference on Computing Innovation and Applied Physics (CONF-CIAP 2023)

ISBN:978-1-915371-53-9(Print) / 978-1-915371-54-6(Online)
Editor:Marwan Omar, Roman Bauer
Conference website: https://www.confciap.org/
Conference date: 25 March 2023
Series: Theoretical and Natural Science
Volume number: Vol.5
ISSN:2753-8818(Print) / 2753-8826(Online)

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References

[1]. Wang, Z. D. A good textbook for fluid mechanics: Fluid mechanics (second edition). Mechanics and Practice (06), 1476-1478 (2022).

[2]. Liu, Z. J., Sun, D. Z., Wang, F. M., Du, B. Y. Application of computational fluid dynamics in bridge engineering. Heilongjiang Transportation Technology (03), 44-45 (2000). doi:10.16402/j.cnki.issn1008-3383.2000.03.025.

[3]. Ge, Y. J., Xia, Q., Zhao, L. Evaluation of wind resistance and vibration of large span bridge. Journal of Civil Engineering (11), 66-70+119 (2019). doi:10.15951/j.tmgcxb.2019.11.007.

[4]. Huang, Z. H., Peng, X. W. Control measures for wind-induced damage and induced vibration of bridge structure. The Traffic World (12), 138-139 (2021). doi:10.16248/j.cnki.11-3723/u.2021.12.065.

[5]. Jie, X. Q., Chen, P. Application of fluid mechanics in automobile body design. Journal of Sichuan Vocational and Technical College (06), 165-167 (2015). doi:10.13974/j.cnki.51-1645/z.2015.06.047.

[6]. Hucho, W. H. Aerodynamics of road vehicles, 4th edition, Society of Automotive Engineers (SAE) International, Warrendale (1997).

[7]. Kajiwara, S. Passive variable rear-wing aerodynamics of an open-wheel racing Car. Automot Engine Technol 2(1–4), 107–117 (2017). https://doi.org/10.1007/s41104-017-0021-9.

[8]. Peng, Z. W. Optimized design of siphon flow channel shape based on computational fluid dynamics. Hunan University (2009). https://kns.cnki.net/KCMS/detail/detail.aspx?dbname=CDFD1214&filename=1011264241.nh.

[9]. Dey, A. K. Siphon: Definition, Working Principle, Uses or Application. Fluid Mechanics and Hydraulic Machines (2022). https://learnmechanical.com/siphon/.

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