推进早期海军舰艇系统设计自动化

J. Chalfant
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引用次数: 0

摘要

船舶系统,如配电和热管理系统,比以往任何时候都更大、更复杂、更集成,这是由于新型传感器和武器系统所使用的电力急剧增加,导致冷却系统的大热负荷,以及船舶、任务和机械控制系统集成的进步。因此,在船舶设计过程的早期提供船舶系统设计的更多细节是非常必要的。近年来,计算能力的进步使得早期船舶设计的细节增加,同时探索的船舶设计数量也增加,从而促进了设计过程,如基于集合的设计。本文描述了一系列工作,为船舶系统的半自动化设计提供了一种方法,允许在用户的指导下对船舶系统进行程序化的创建和分析,从预先设计的模板中组装,并根据船舶设计进行定制。我们将这种整体方法称为template。最终目标是一个软件工具,它将一组预先设计的系统部分(称为模板)作为输入,并将它们集成到船舶设计中的全功能系统模型中,所有组件都具有适当的大小和位置。生成的系统模型提供了诸如大小、重量和复杂性之类的度量。此外,该模型可用于各种操作条件下的系统仿真,以提供诸如效率和生存能力等度量,同时还允许探索可重构性、可靠性、可维护性和许多其他“能力”。模板过程和软件完全集成到美国海军的早期设计工具套件中。从模板中创建功能齐全的船舶系统的过程需要几个步骤:通过将相关模板复制到船舶设计中,并将它们适当地相互连接,将模板组装成逻辑连接的系统。这产生了一个逻辑上合适的单线图,其中组件放置在船上的大致地理位置。确定每个组件的容量。由于模板功能有助于从部件或系统子部分的组装中创建船舶系统,因此在系统完全组装并将所有负载和源连接并放置在三维空间中之前,不可能确定系统中每个元素的所需容量。已经开发出一种算法来确定给定系统任何可能的对齐方式下每个组件处理的最大能量。根据所需容量确定每个组件的尺寸。各种组件类型的基于物理的分级算法正在探索中。组件在三维空间中的最终位置。一种在船舶设计中自动排列组件的方法已经开发出来,该方法可以消除重叠,提供组件之间的间距,并最大限度地减少连接长度。本文概述了模板化过程和每个步骤的基本算法,并举例说明了模板化的方法,并论证了模板化所带来的功能促进了船舶早期设计过程中的自动化系统设计。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Advancing Automation in Early-Stage Navy Ship System Design
Ship systems, such as the electrical distribution and thermal management systems, are larger, more complex, and more integrated than ever before due to the radical increase in electrical power used by new sensor and weapons systems, the resulting large thermal load placed on cooling systems, and the advances in integration of ship, mission and machinery control systems.  Thus, there is a significant need for greater detail in ship system design to be provided earlier in the ship design process.  Advances in computing capability over recent years allow an increase in detail of early-stage ship designs along with a simultaneous increase in the number of ship designs explored, facilitating design processes such as set-based design. This paper describes a body of work that provides a methodology for semi-automated design of ship systems, allowing the programmatic creation and analysis of ship systems under the guidance of the user, assembled from pre-designed templates and tailored to the ship design.  We refer to this overall methodology as Templating. The ultimate goal is a software tool which takes as input a set of pre-designed system segments, termed templates, and integrates them into a fully functioning system model in a ship design, with all components appropriately sized and located. The resultant system model provides metrics such as size, weight and complexity. Further, the model is available for system simulation under various operational conditions to provide metrics such as efficiency and survivability while also allowing exploration of reconfigurability, reliability, maintainability, and a host of other “ilities.” The Templating process and software is fully integrated into the U.S. Navy’s early-stage design tool suite. The process for creating a fully functional ship system from templates requires several steps: Assembly of the templates into a logically connected system by copying relevant templates into the ship design and connecting them appropriately to one another. This yields a logically appropriate one-line diagram with components placed in an approximate geographic position within the ship. Determination of the capacity of each component. Since the templating capability facilitates the creation of ship systems from an assembly of parts or system sub-sections, it is not possible to determine the required capacity of each element of a system until the system is fully assembled with all loads and sources connected and placed in three-dimensional space. An algorithm has been developed to determine the maximum amount of energy handled by each component given any possible alignment of the system. Dimensioning of each component based on the capacity required. Physics-based sizing algorithms for a variety of component types are under exploration. Final placement of the components in three-dimensional space. A methodology for automatically arranging components in a ship design in a manner that eliminates overlaps, provides spacing between components, and minimizes connection length has been developed. This paper provides an overview of the templating process and the algorithms underlying each step, provides examples to elucidate the methodologies, and demonstrates that the functionality brought about by Templating advances automated system design in the early-stage ship design process.
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