Geometric modeling of blast waves reflected from the cylindrical surface of a sineusidal profile
Kutsenko Leonid
National University of Civil Defenсe of Ukraine
https://orcid.org/0000-0003-1554-8848
Sukharkova Elena
National University of Civil Defenсe of Ukraine
https://orcid.org/0000-0003-1033-4728
Saveliev Dmytro
National University of Civil Defenсe of Ukraine
https://orcid.org/0000-0002-4310-0437
Kokhanenko Vladimir
National University of Civil Defenсe of Ukraine
https://orcid.org/0000-0001-5555-5239
Zhuravskij Maxim
National University of Civil Defenсe of Ukraine
https://orcid.org/0000-0001-8356-8600
DOI: https://doi.org/10.52363/2524-0226-2023-38-15
Keywords: blast wave, cylindrical surface, reflector, sinusoidal profile, reflected wave front
Аnnotation
A method is proposed for geometric modeling of a family of blast wave fronts reflected from a cylindrical surface of a sinusoidal profile. The model of “optical” reflection is adopted as a basis, when for each incident virtual explosive “ray” the angle of reflection is equal to the angle of incidence. To illustrate the graphic-analytical approach, a test model of the formation of a family of reflected wave fronts for a cylindrical parabolic surface has been developed. A cylindrical surface of a sinusoidal profile obtained by bending a rectangular metal sheet by longitudinal forces is considered. Geometric models of a family of blast wave fronts reflected from a cylindrical surface of a sinusoidal profile are described. Maple has been compiled – programs for visualizing models of a family of blast wave fronts reflected from a cylindrical surface. Conducted studies of sinusoidal cylindrical reflectors designed to demonstrate the effect of multiplying the effects of shock blast waves directed towards the fire zone. For their practical use, it is necessary to find the bending parameters of the cylinder such that the virtual beams of the “point” explosive are transformed into a system of beams that are close to parallel in the fire zone. As a result of the research, the parameters of bending of a metal rectangular sheet by longitudinal forces were calculated, and the coordinates of the location of the “point” explosive substance were determined. It is taken into account that cylindrical reflectors with a sinusoidal profile can be manufactured at the site of their use. To do this, a rectangular sheet of metal must be bent by longitudinal forces and the bend must be fixed by welding reinforcement rods. The research carried out is aimed at developing the technology of extinguishing forest fires with directed explosions.
References
- Dubinin, D., Korytchenko, K., Lisniak, A. (2017). Zastosuvannia zariadiv z sumishi vybukhonebezpechnykh haziv dlia lokalizatsii lisovykh pozhezh shliakhom stvorennia protypozhezhnykh barieriv: monohrafiia. Kharkiv: NUTsZU, 128. Available at: http://repositsc.nuczu.edu.ua/handle/123456789/984
- Reva, H. (2000). Metod rozrakhunku synusoidalnoi vidbyvalnoi systemy. Prykladna heometriia ta inzhenerna hrafika, 67, 226–230.
- Reva, H., Kutsenko, L. (1998). Metod otsinky intensyvnosti dii udarnoi khvyli napravlenoho vybukhu dlia hasinnia lisovykh pozhezh. Kharkiv: KhIPB MVS Ukrainy, 80.
- Feynman, R., Leighton, R., Sands, M. (2009). The Feynman Lectures on Physics Problems and exercises with answers and solutions to produce 5–9 Manual – 5 th ed. Knizhnyy dom «LIBROKOM», 512.
- Nalysko, M. (2019). Rozvytok naukovykh osnov pidvyshchennia bezpeky u protiazhnykh sporudakh pry rozpovsiudzhenni udarnykh povitrianykh khvyl: dys. doktora tekh. nauk: 05.26.2001. Dnipro, 422.
- Dey, S., Murugan, T., Chatterjee, D. (2018). Numerical Visualization of Blast Wave Interacting with Objects. Journal of Applied Fluid Mechanics, 11, 5, 1201–1206. doi:10.29252/jafm.11.05.28240
- Vaishnavi, J., Krishna, B. (2022). Determination of response of multistorey structure subjected to blast loading. Journal of Building Pathology and Rehabilitation, 7, 1. doi: 10.1007/s41024-022-00218-6
- Figuli, L., Cekerevac, D., Bedon, C., Leitner, B. (2020). Numerical Analysis of the Blast Wave Propagation due to Various Explosive Charges. Advances in Civil Engineering, 2020, 1–11. doi:10.1155/2020/8871412
- Gautier, A., Sochet, I., Courtiaud, S. (2022). Analysis of Shock Wave Interaction with an Obstacle by Coupling Pressure Measurements and Visualization. Sensors, 22, 9, 3325. doi:10.3390/s22093325
- Tai, C., Teng, J., Lo, S., Chou, H. (2008). Two-Dimensional Numerical Visualization on the Interaction of Blast Waves with Obstacles. Journal of Visualization, 11, 1, 87–94. doi: 10.1007/BF03181918