With the passage of the 2010 NASA Authorization Act, NASA was directed to begin the development of the Space Launch System (SLS) as a follow-on to the Space Shuttle Program. The SLS is envisioned as a heavy lift launch vehicle that will provide the foundation for future large-scale, beyond low Earth orbit (LEO) missions. Supporting the Mission Concept Review (MCR) milestone, several teams were formed to conduct an initial Requirements Analysis Cycle (RAC). These teams identified several vehicle concept candidates capable of meeting the preliminary system requirements. One such team, dubbed RAC Team 2, was tasked with identifying launch vehicles that are based on large stage diameters (up to the Saturn V S-IC and S-II stage diameters of 33 ft) and utilize high-thrust liquid oxygen (LOX)/RP engines as a First Stage propulsion system. While the trade space for this class of LOX/RP vehicles is relatively large, recent NASA activities (namely the Heavy Lift Launch Vehicle Study in late 2009 and the Heavy Lift Propulsion Technology Study of 2010) examined specific families within this trade space. Although the findings from these studies were incorporated in the Team 2 activity, additional branches of the trade space were examined and alternative approaches to vehicle development were considered. Furthermore, Team 2 set out to define a highly functional, flexible, and cost-effective launch vehicle concept. Utilizing this approach, a versatile two-stage launch vehicle concept was chosen as a preferred option. The preferred vehicle option has the capability to fly in several different configurations (e.g. engine arrangements) that gives this concept an inherent operational flexibility which allows the vehicle to meet a wide range of performance requirements without the need for costly block upgrades. Even still, this concept preserves the option for evolvability should the need arise in future mission scenarios. The foundation of this conceptual design is a focus on low cost and effectiveness rather than efficiency or cutting-edge technology. This paper details the approach and process, as well as the trade space analysis, leading to the preferred vehicle concept.
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机译:随着2010年NASA授权法的通过,NASA被指示着手开发航天发射系统(SLS),作为航天飞机计划的后续行动。 SLS被设想为重型举升运载工具,将为未来的低空轨道(LEO)以外的大型任务提供基础。为了支持任务概念审查(MCR)里程碑,成立了多个团队来进行初始的需求分析周期(RAC)。这些团队确定了一些能够满足初步系统要求的候选车辆概念。这样一个被称为RAC Team 2的团队的任务是识别基于大载物台直径(高达Saturn V S-IC和S-II载物台直径为33 ft)并利用高推力液氧(LOX)的运载火箭)/ RP发动机作为第一级推进系统。尽管此类LOX / RP车辆的贸易空间相对较大,但美国航空航天局的近期活动(即2009年底的重型运载火箭研究和2010年的重型推进技术研究)在该贸易空间中检查了特定的家庭。尽管这些研究的结果已纳入第2小组的活动,但仍对贸易空间的其他分支机构进行了研究,并考虑了车辆开发的替代方法。此外,第2小组着手定义功能强大,灵活且具有成本效益的运载火箭概念。利用这种方法,多功能两阶段运载火箭概念被选为首选方案。优选的车辆选件具有以几种不同构型(例如发动机布置)飞行的能力,这赋予了该概念固有的操作灵活性,该灵活性允许车辆满足广泛的性能要求而无需进行昂贵的机体升级。即使在将来的任务场景中需要时,该概念仍保留了可扩展性的选项。这种概念设计的基础是注重低成本和有效性,而不是效率或尖端技术。本文详细介绍了方法和过程以及交易空间分析,从而得出了首选的车辆概念。
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