Modernization of the process of disposal of capsule bushings for artillery shots

Neklonskyi Ihor

National University of Civil Protection of Ukraine

http://orcid.org/0000-0002-5561-4945

Smyrnov Oleg

National University of Civil Protection of Ukraine

https://orcid.org/0000-0002-1237-8700

DOI: https://doi.org/10.52363/2524-0226-2025-42-2

Keywords: ammunition, capsule sleeves, disposal, technology, agent, dynamic model, transfer function, work rate

Аnnotation

          To increase the level of efficiency, technogenic and environmental safety during the disposal of ammunition, it is proposed to modernize the existing technological process of discharging artillery ammunition capsule shells by introducing a special installation into the technological line, which operates in an automated mode. To increase the efficiency of the technological process management process during the implementation of the corresponding technology, a dynamic model of operational support of the pace of work performance by adjusting the pace of resource consumption is proposed. The description of the relationship between the management body and functional units that will directly implement the technological scheme is carried out on the basis of structural-functional and multi-agent concepts. The control system is presented in the form of a set of interconnected and interacting agents (active elements) that have their own local goals and resources that are consistent with the general goal of the sys-tem and available resources. It is determined that one of the most important elements in this structure is the functional unit. It implements the corresponding disposal technology as an active agent of the system. The activity of the executive element of the functional unit is described by a differential equation. The Laplace transform was used as a tool for solving the differential equation. This made it possible to obtain the corresponding transfer function. The use of methods for constructing multi-agent dynamic models taking into account the mathematical definition of the concept of system stability according to Rous-Hurwitz made it possible to analytically determine the condition for coordinating the inertia of work execution and resource delivery with the inertia of request implementation. The implementation of this model in the decision-making support process for organizing the technological process of discharging capsule sleeves will allow achieving the best balance of safety and efficiency of this process.

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