• Home
  • Current congress
  • Public Website
  • My papers
  • root
  • browse
  • IAC-05
  • D2
  • 6
  • paper

    • Preparing for Next Generation Launcher: In-flight Experimentation Activities

    Paper number

    IAC-05-D2.6.06

    Author

    Mr. Giorgio Tumino, European Space Agency/Headquarters, France

    Coauthor

    Mr. Dario Boggiatto, NGL Prime SpA, Italy

    Coauthor

    Mr. Yves Gerard, EADS Astrium, France

    Year

    2005

    Abstract

    High-velocity kinetic penetrators have been proposed and developed as a modest-cost exploration tool to sample geophysical data and perform in-situ scientific analysis both at the surface and to depths ranging from 1 to 5 meters. Previous penetrator concepts (Mars ’96, Deep Space 2, Lunar-A) each used unique EDL mechanisms for deceleration, impact mitigation, surface deployment, etc. designed specifically to operate in the environment targeted for exploration. Re-targeting a penetrator for deployment to a significantly different environment could require equally significant changes to the unique mechanisms - a potentially lengthy and costly re-design.

    A different approach is proposed whereby the core spacecraft components (propulsion, EDL, structure, etc.) would be designed modularly; components could be added, altered, or removed where necessary allowing the overall concept to be tailored to fit a variety of mission scenarios. The goal of this approach is to create a flexible penetrator design capable of rapid response to flight opportunities by reducing overall design time and cost.

    While aerobraking devices such as those utilised by the Mars ’96 and DS2 penetrators provide deceleration mechanisms in atmospheric bodies, deployment to airless bodies (asteroids, comets, or planetary moons) will require the use of an on-board propulsion system to reduce the penetrator impact velocity to within survivable limits (<300 m/s). As a first step in this design, deceleration requirements are quantified by determining arrival velocities at various target bodies including the Moon, Mars, NEA Apophis, Europa and Enceladus. This investigation is achieved through solutions to Lambert’s problem and iterative impulsive/finite trajectory simulations in STK, and indicates that propulsion will have to deliver at least 1.0-1.5 km/s Δv in order to achieve the required impact velocity. Propulsion therefore becomes a key driver to the overall concept mass.

    The following paper discusses the approach and algorithms used in the simulations and presents arrival velocity ranges/deceleration Δv’s for each body investigated. The resulting implications on propulsion system design and overall concept design is discussed, and a propulsion system concept is presented.

    Preparing for Next Generation Launcher: In-flight Experimentation Activities

    G. Tumino(1), D. Boggiatto(2), Y. Gerard(2), H. Grallert(2) 1)ESA Directorate of Launchers, 8-10 rue Mario-Nikis, F-75738 Paris Cedex 15 (F) 2) NGL Office c/o Alenia Spazio SpA, Strada Antica di Collegno 253, I-10146 Torino (I)

    In the past decade Europe has invested significant efforts in the development of critical key technologies (e.g. advanced materials, cold/hot structural concepts, thermal protection systems, etc.), challenging the ambitious requirements of next generation launchers (NGL), including re-entry and reusable systems.

    Building upon the past European activities and achievements, today’s development activities are focusing on in-flight experimentation, considered the next step to advance such critical key technologies state-of-the-art in a consistent manner up to flight qualification.

    The ESA Future Launchers Preparatory Programme (FLPP) provides a structured European frame programme with a dedicated line of activities focusing on in-flight experimentation.

    More precisely, while performing a series of system trade-offs and subsystem preliminary definition activities aimed at designing an overall technology roadmap for NGL developments, including on-ground demonstrations, the programme is currently defining:

    - An optimised strategy for in-flight experimentation of NGL critical technologies; - Candidate concepts for in-flight experimentation of NGL re-entry technologies; - Candidate concepts for in-flight experimentation of NGL reusability technology.

    The paper will present the FLPP technical and programmatic objectives for in-flight experimentation, and the status and the interim results of the running industrial activities for the definition of the above strategy/concepts.

    Abstract document

    IAC-05-D2.6.06.pdf

    Manuscript document

    IAC-05-D2.6.06.pdf (🔒 authorized access only).

    To get the manuscript, please contact IAF Secretariat.