面向城市作战的枪械复杂环境适应性与边界性能试验技术分析

罗建华; 张俊斌; 彭天辉; 林洋; 谢典昆

doi:10.7643/ issn.1672-9242.2025.11.002

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装备环境工程 ›› 2025, Vol. 22 ›› Issue (11) : 10-18. DOI: 10.7643/ issn.1672-9242.2025.11.002

武器装备

面向城市作战的枪械复杂环境适应性与边界性能试验技术分析

罗建华, 张俊斌^*, 彭天辉, 林洋, 谢典昆

作者信息 +

Analysis of Testing Technologies for Urban Combat-oriented Firearms Complex Environmental Worthiness and Boundary Performance

LUO Jianhua, ZHANG Junbin^*, PENG Tianhui, LIN Yang, XIE Diankun

Author information +

文章历史 +

摘要

从城市复杂环境、作战任务特点和城市作战对枪械实战性能需求分析出发,对城市实战环境下的复杂环境适应性与边界性能考核试验方案进行了分析。基于系统效能评估要求进行了指标体系分析,基于环境效应进行了试验环境因素分析,基于能力提升需求进行了试验评估方法分析,并通过实例对模糊综合评估方法的应用进行了分析,针对试验标准化要求进行了标准化建设需求分析。通过理论分析,明确了枪械城市复杂环境适应性与边界性能考核方案,为枪械复杂环境适应性与边界性能试验标准化建设提供了理论参考。

Abstract

Starting from an analysis of complex urban environments, operational mission characteristics, and the practical performance requirements of firearms in urban combat, the testing protocols for worthiness and boundary performance assessments in urban combat scenarios are examined. The evaluation index system is analyzed based on system effectiveness requirements. An examination of environmental factors is conducted based on environmental effects. Furthermore, an evaluation methodology analysis was performed in accordance with capability enhancement needs. And the application of the fuzzy comprehensive evaluation method was illustrated through examples. Finally, standardization requirements to meet the need for standardized testing protocols are analyzed. Through theoretical analysis, the study clarifies the testing framework for firearms worthiness and boundary performance in complex urban environments, providing a theoretical reference for the standardization of performance testing under such conditions.

导出引用

罗建华, 张俊斌, 彭天辉, 林洋, 谢典昆. 面向城市作战的枪械复杂环境适应性与边界性能试验技术分析[J]. 装备环境工程. 2025, 22(11): 10-18 https://doi.org/10.7643/ issn.1672-9242.2025.11.002

LUO Jianhua, ZHANG Junbin, PENG Tianhui, LIN Yang, XIE Diankun. Analysis of Testing Technologies for Urban Combat-oriented Firearms Complex Environmental Worthiness and Boundary Performance[J]. Equipment Environmental Engineering. 2025, 22(11): 10-18 https://doi.org/10.7643/ issn.1672-9242.2025.11.002

中图分类号： TJ012

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