共查询到19条相似文献,搜索用时 46 毫秒
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航母弹药贮运作业直接关系着舰载机出动能力和母舰安全。基于美军航母弹药安全作业的经验与教训,总结了人员管理、弹药和环境安全等作业要求,分析了弹药存储、转运和维护等安全作业要点,并重点阐述了航母弹药在舰检测技术与接地作业规程。 相似文献
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针对常规弹药生产特点,通过对近年来国内外常规弹药的设计安全技术进行分析,着重对不敏感弹药的
设计安全技术、引信的设计安全技术和战斗部的设计安全技术等3 方面进行梳理,总结出我国常规弹药设计安全技
术的未来发展方向。该研究对我国常规弹药安全技术水平的提升具有参考意义。 相似文献
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德国联邦国防技术与采办局(BWB)武器与弹药技术处负责发展与采办除火箭、导弹、水雷和鱼雷以外的各种武器与弹药.第一处长乌尔利希·福格尔博士(Dr.UlrichVogel)撰文举例介绍了他的业务范围,从而透露了德国目前正在发展的一些军工科研项目.福格尔博士还强调了在新形势下应重点保留军工技术关键部门的观点. 相似文献
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武器弹药的安全问题十分重要,关乎装备的生存力和战斗力。弹药面对的复杂恶劣环境,对弹药安全性提出更高要求,发展安全弹药是必由之路。弹药安全性主要取决于固有安全性和安全性增强技术。不敏感炸药是提高弹药固有安全性的关键途径,装药和结构增强与防护是提高弹药安全性的重要手段。为满足弹药高毁伤威力和安全性要求,需要从炸药的分子、晶体、混合体系等多尺度结构上平衡协调炸药高能量与不敏感之间的突出矛盾;装药结构、弹体弱链结构和防护增强等安全性增强技术可有效控制弹药装药意外点火和反应烈度及其演化,进一步提高弹药在异常环境及事故条件下的安全性。为此,提出了安全弹药系统设计思路与技术方法:加强不敏感炸药多尺度材料设计与性能调控基础,补齐装药结构与防护增强及装药异外点火反应控制短板,探索发展材料—结构—功能一体化设计。 相似文献
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通过发烟弹扩爆和烟幕在大气中扩散两个过程的分析,就影响发烟弹烟幕形成及其浓度分布的主要因素进行了探讨,提出了发烟弹扩爆后烟云形成时初始参数及相关气象条件的估算方法,分析结论为烟幕浓度的估算提供了理论依据。 相似文献
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1 IntroductionThe development and fielding of Insensitive Munitions(IM)has been occurring over the last 30 years.Thehigh profile accidents on the USN aircraft carriers Oriska-ny,Forrestal and Enterprise spurred the US Navy to ac-tion.The toll that these accidents took in terms of loss ofhuman life,and loss of platforms,impressed upon the Na-vy the critical importance of taking into account not onlythe performance of munitions but also their vulnerability toaccidental initiation.However,t… 相似文献
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The development of Insensitive Munitions (IM) has been progressing for over three decades. Ever since the highly publicized US Navy aircraft carrier accidents in the 1960s to 1980s, there has been a growing recognition of the value of IM. Reminders of the need for IM have been provided all too often in the form of accidents, such as experienced by the US Army at Camp Doha and the prevalence of attacks on military installations around the world.
The process for developing IM has improved over the years as technology for mitigating the consequences of accidental initiation has emerged. Early IM developments were based upon replacement of the traditional TNT-based explosives, with their high vulnerability, with reduced vulnerability PBXs. This led to significant improvements, such as that observed with the replacement of H-6 with PBXN-109 in the US Navy Mk82 GP bomb. From the early 1990s, the use of a complete systems approach was highlighted as the optimum method to achieve IM compliance while maintaining or enhancing operational performance. The use of a systems approach has resulted in the fielding of a number of munition systems with significant IM properties. The challenge for the future is to continue the development and fielding of improved performance IM munitions with limited funding for research and the high cost of introducing new ingredients into energetic formulations. A key development to allow continued progress to occur is the introduction of improved versions of current explosive ingredients. The attention focused in the past few years on forms of RDX with reduced shock sensitivity has highlighted the possibility of improving well-known materials. In the near future, the application of materials technology may provide improved versions of other important crystalline energetic materials currently in production or advanced development, including HMX, NTO, CL-20 and ADN and help advance the development of further explosive ingredients such as FOX-7 and LLM-105. Advances in the development and application of computer modeling must be made if we are to move forward from our current reliance on a limited number of canonical tests that are held to be representative of the hazards likely to be encountered. The availability of verified and validated models describing the response of energetic materials to various thermal and mechanical threats will enable us to perform parametric studies on systems. This will allow us to estimate their response to hazards that are characteristic of the specific environment experienced by that system, and so to tailor the materials and packaging to minimize risk and maximize performance. 相似文献
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