Penzin Aleksey Sergeevich, Student, sub-department No. 1, Penza branch of the Military Academy of material logistics named after army general A. V. Khrulyov (Penza-5, Russia), email@example.com
Bogomolov Aleksey Ivanovich, Doctor of engineering sciences, professor, sub-department №1, Penza branch of the Military Academy of material logistics named after army general A. V. Khrulyov (Penza-5, Russia), firstname.lastname@example.org
Muyzemnek Aleksandr Yur'evich, Doctor of engineering sciences, professor, head of sub-department of theoretical and applied mechanics and graphics, Penza State University (40 Krasnaya street, Penza, Russia), email@example.com
Background. The use of different models of artillery armament on purpose in the Arctic regions can be complicated by climatic conditions, the main of which are the wind speed and ambient temperature. The task is to determine the wind load on the
samples of artillery weapons with the light of these characteristics. Currently, there are normative documents on calculation of wind load only in the construction and crane construction. The purpose of the study is to analyze the existing methods of
calculating wind loads and to provide a method for its determination based on computer simulation.
Materials and methods. To solve the set tasks were used the regulations for the calculation of wind load: SNiP 2.01.07-85, state standart GOST 1451-77 and offer the software package XFlow.
Results. The proposed method of calculating the wind load on the samples of artillery weapons based on the application of the proposed software complex XFlow. Comparative calculations of wind load on the regulations and XFlow.
Conclusions. Identification of wind load applied on the samples of artillery weapons with the use of computers and software XFlow allows to take into account the climatic features of the Arctic region and the geometric shape of a particular object. The execution time of calculations is significantly reduced.
wind, wind load, artillery canon, factors, temperature, wind speed
1. Podobed V. A. Vestnik Murmanskogo gosudarstvennogo tekhnicheskogo universiteta [Proceedings of Murmansk State Technical University]. 2006, vol. 9, no. 2, pp. 318–331.
2. Rukovodstvo po raschetu zdaniy i sooruzheniy na deystvie vetra [Guidelines on the calculation of buildings and structures to the effect of wind]. Moscow: Stroyiz-dat, 1978, 216 p.
3. Gandin L. S. Trudy glavnoy geofizicheskoy observatorii im. A. I. Voeykova [Proceedings of the Voeikov main geophysical observatory]. 1950, no. 23 (85).
4. Lugovskiy V. V. Dinamika morya [Sea dynamics]. Leningrad: Sudostroenie, 1976, 200 p.
5. Stroitel'nye normy i pravila 2.01.07–85. Nagruzki i vozdeystviya [Building regulations 2.01.07-85. Load and impact]. Moscow, 1985.
6. GOST 1451–77. Mezhgosudarstvennyy standart. Krany gruzopod"emnye. Nagruzka vetrovaya. Normy i metod opredeleniya [State standart GOST 1451-77. International standart. Lifting cranes. Wind load. Norms and method of determination]. Moscow,
7. Programmnyy kompleks XFlow.-ver. 2015 [Software packageXFlow.-version 2015].
8. Bogomolov A. I., D'yachkov Yu. A., Penzin A. S. Nauchnye trudy 3 TsNII MO RF. Kniga 42 [Proceedings of the Third Central Research Institute of Ministry of Defence of the Russian Federation]. Moscow : Tipografiya 3 TsNII MO RF, 2017.
9. Malyshev V. P. Matematicheskoe planirovanie metallurgicheskogo i khimicheskogo eksperimenta [Mathematical planning of metallurgical and chemical experiments]. Alma-Ata: Nauka KazSSr, 1977, 37 p.
10. Kir'yanov D. V. Mathcad 15/Mathcad Prime 1.0. Saint-Petersburg: BKhV-Peterburg, 2012, 432 p.