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Future Launchers Preparatory Programme

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The Future Launchers Preparatory Programme (FLPP) is a technology development and maturation programme of the European Space Agency (ESA). It develops technologies for the application in future European launch vehicles (launchers) and in upgrades to existing launch vehicles. By this it helps to reduce time, risk and cost of launcher development programmes.
Started in 2004, the programmes initial objective was to develop technologies for the Next Generation Launcher (NGL) to follow Ariane 5. With the inception of the Ariane 6 project, the focus of FLPP was shifted to a general development of new technologies for European launchers.
FLPP develops and matures technologies that are deemed promising for future application but currently do not have a sufficiently high technology readiness level (TRL) to allow a clear assessment of their performance and associated risk. Those technologies typically have an initial TRL of 3 or lower. The objective is to raise the TRL up to about 6, thus creating solutions which are proven under relevant conditions and can be integrated into development programmes with reduced cost and limited risk.[1]

Purpose

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Main objectives

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The main objectives of FLPP are:

  • To identify and prepare the system competence and technology for development with the aim of confining launcher time-to-market within 5 years, reducing recurring cost and development risk, while keeping long-term industry competitiveness.[1]
  • To promote reusability of existing and new technologies to reduce development costs globally.[1]
  • To perform system studies to assess evolutions of operational launchers, future launcher architectures, advanced concepts, select technology and elaborate technology requirements.[1]
  • To safeguard critical European industrial capabilities for the safe exploitation of the current launchers and guaranteed access to space.[1]
  • To develop environmentally friendly technologies.[1]

Approach

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FLPP addresses the problem that in many cases, promising new technologies for future launcher applications possess a low TRL. At this stage, an implementation of such a technology into a development programme poses a significant risk. If it turns out, that the technology does not perform as expected in the later stages of the development or the concept using that technology is not feasible, a redesign of the complete system often has severe impacts on time, quality and cost.[1]
FLPP addresses this issue via a system driven approach. Based on system studies for future launch systems or upgrades of current systems, promising technologies, which will provide benefits in line with the objectives of FLPP and have a low TRL (typically 2–3), are selected. These technologies are then developed to reach a TRL high enough (at least 5, typically 6) to allow their implementation into current or future development programmes with largely reduced risks. As technology maturation has already been performed in FLPP, the necessary time span to develop a new launcher is also reduced significantly.[1]
The approach to mature a technology in a demonstrator based on system studies largely reduces the impact of worse than anticipated performance (e.g. in weight, efficiency, complexity) compared to a launcher development, were often a large part of the launcher design is affected by a change in the characteristics of a subsystem. After this "high risk" maturation phase the technology can then be transferred to a launcher development. A major change in the anticipated characteristics of a technology during the course of a development is much less likely when already starting with a high TRL (i.e. TRL 6) as compared to a technology of low readiness.[1]

Demonstrators

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To increase the technology readiness level to 6, a technology has to be tested in a model or prototype in a relevant environment. Performing this in a cost-effective way, one or several technologies are integrated into a demonstrator and tested in a relevant environment, considering such parameters as media, pressures and temperatures.
These demonstrators are based on requirements which are derived from current or future launch systems as well as general experience. The requirements are tailored to be representative of a launch system and provide the possibility to test the maximum attainable performance of the integrated technologies as well as safety margins.
The demonstrators usually represent a sub-system of the complete launcher, e.g. a tank, a stage structure or an engine.[1]

Collaboration

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The projects performed by FLPP rely heavily on the collaboration with external partners. As the increase of TRL which is pursued is linked to the later application of the technology, these partners are usually industrial. If deemed beneficial, institutional partners or subcontractors will be chosen as well.

Structure

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The FLPP is a development programme within the directorate of launchers at ESA.
FLPP is funded by ESA member states on an optional basis. Participating states sign their contribution to FLPP during the ESA ministerial council.
Chronologically, FLPP is structured in successive periods, which usually correspond to the time between ministerial councils. To maintain a continuity of work, these periods are overlapping. [2]

History

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Inception

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FLPP was started in February 2004[3] with the subscription to its declaration by 10 ESA member states.

Period 1 (2004-2006)

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Period 1 was focused on studies for future reusable launch vehicles (RLV). Several different RLV concepts were investigated to select feasible, cost-effective options. In addition, upgrades to reduce the cost of existing launchers were investigated.[1]

Period 2 Step 1 (2006-2009)

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During this period, the work on reusable as well as expendable launch concepts was continued with system studies on several promising launcher configurations. In addition, key technologies for future launchers were integrated into demonstrators to increase their TRL sufficiently for an efficient integration into a launcher development. A major demonstrator project started in this period was the Intermediate eXperimental Vehicle (IXV). In addition, the development of the launcher upper stage engine Vinci was financed and managed by the FLPP programme during this time.[1]

Period 2 Step 2 (2009-2013)

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The second step of period 2 completed the system studies on expendable launchers. The technology development activities, especially on upper stage and re-entry technologies as well as propulsion were continued. While the Vinci engine was transferred to Ariane 5 ME development, a demonstrator project for a high thrust first stage engine called Score-D was started. In addition a demonstrator project for an upper stage engine using storable propellants was created. The later part of this phase saw the inception of a cryogenic expander cycle demonstrator project.[1]
Multiple technology development and demonstrator projects were started concerning a wide range of promising technologies. These were in the fields of stage and interstage structures, tanks, avionics as well as hybrid and solid propulsion.

Period 3/FLPP NEO (2013-2019)

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Period 3 was started in 2013 and is overlapping with the FLPP NEO (New Economic Opportunities) period, initiated in 2016. With the inception of a dedicated Ariane 6 project, FLPP broadened its scope from the preparation of technologies for a specific next generation launcher to the general identification and maturation of promising technologies for future launchers as well as upgrades of current launch vehicles. The identification and maturation process of key technologies is still system driven and relies mainly on system studies and integrated demonstrators. An important objective is to foster synergies between different applications and launchers (e.g. Ariane and Vega). FLPP NEO continues the technology approach of the previous periods with emphasis on flagship demonstrators and very low cost launcher concepts.[1]

Projects

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FLPP consists of multiple coordinated technology development projects.

Past Projects

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This section lists notable past projects in FLPP. This list includes only some major projects and is not exhaustive.

NGL-ELV System studies

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The NGL-ELV system studies were performed to identify promising configurations for a Next Generation Launcher to follow Ariane 5 as well as technologies which should be integrated into this launcher, to achieve high reliability, high performance and cost efficiency. If identified technologies did not have a sufficient TRL for efficient integration into a launcher development programme, those could then be matured within FLPP.

Score-D

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The Staged Combustion Rocket Engine Demonstrator (SCORE-D) was a project to develop key technologies and tools for the High Thrust Engine (HTE) which was planned to power the next generation launcher. As propellant combinations liquid oxygen/hydrogen and liquid oxygen/methane were considered. Several sub-scale tests were performed in the preparation of the demonstrator project.
As solid propulsion was initially selected as a baseline for the first stage of Ariane 6, the project was stopped at the stage of an SRR.

Vinci

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The development of the re-ignitable cryogenic upper stage engine Vinci was financed and managed by FLPP from 2006 until 2008.
Vinci was conceived as the engine for the new upper stage of the Ariane 5, the ESC-B (Etage Supérieur Cryotechnique B/Cryogenic Upper Stage B). It is a re-ignitable expander cycle engine, powered by liquid oxygen and liquid hydrogen.
After the failed first flight of its predecessor ESC-A (V-157) in 2002, the development of ESC-B was stopped, but the Vinci development was continued and later transferred to FLPP. In FLPP the technology was matured and extensively tested. In the end of 2008, Vinci was transferred to Ariane 5 ME and after the stop of that programme on to Ariane 6.

IXV

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The Intermediate eXperimental Vehicle (IXV) is a re-entry demonstrator to test technologies for reusable launchers and spacecraft. The main focus in this project lies on the thermal protection, as well as flight mechanics and control. It was launched by a Vega rocket in February 2015. The re-entry was controlled via two movable flaps, prior to the deployment of parachutes and a splashdown into the ocean.

Current Projects

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This section lists notable current projects in FLPP. As FLPP manages a multitude of projects in the main domains of "Propulsion", "Systems and Technologies" and "Avionics and Electronics", the following list includes only some major projects and is not exhaustive.[1]

Expander-cycle Technology Integrated Demonstrator

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The Expander-cycle Technology Integrated Demonstrator (ETID) is based on an advanced upper stage engine concept partially derived from Vinci technology. It shall incorporate several new technologies to improve the performance of the engine (esp. thrust/weight) and reduce the cost per unit. Some of those technologies could also be beneficial for activities outside of the propulsion sector.[4] As of 2016, the project is in the design and manufacturing phase.[5]

Storable Propulsion Technology Demonstrator

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The Storable Propulsion Technology Demonstrator shall help develop technologies for a rocket engine in the thrust range between 3 and 8 kN. The technology developed in this project could be used in upper stages of small launchers or applications with similar thrust requirements. The demonstrator uses novel cooling, injector and damping technologies.[4] As of 2016, the demonstrator has successfully performed two test campaigns, performing both ground level as well as vacuum ignitions. Steady state behaviour was tested in a large range of operating points and for durations of up to 110s. In addition, combustion stability and thrust chamber length variations were tested.[5]

Solid propulsion

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Current efforts concerning solid propulsion focus on the development of technologies for future motor casings and the investigation of the physics of solid rocket motors, especially pressure oscillations. Both of these goals are pursued via demonstrators. The “Pressure Oscillation Demonstrator eXperimental” (POD-X) is dedicated to the investigation of combustion physics and has already made a test firing, yielding valuable information into solid propulsion combustion processes.[4] The “Fibre Reinforced Optimized Rocket Motor Case” (FORC) is dedicated to the development of the dry fibre winding combined with automated dry fibre placement and subsequent resin infusion technology for the manufacturing of large carbon fibre reinforced polymer solid rocket motor cases, including the production of a full-scale and representative test article featuring an outer diameter of 3.5 meters. As of September 2016, multiple sub-scale specimens have already been produced during the process development for FORC. Furthermore, the test article is in the manufacturing phase, with extensive mechanical load and pressure testing scheduled before the end of the year.[5]

Hybrid propulsion

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Hybrid propulsion activities in FLPP are centred around a demonstrator project in collaboration with Nammo. This demonstrator, which has dimensions suitable for later flight applications, has as of September 2016 performed one hot fire test campaign. A second test campaign is on-going, leading to a design which is planned to be flown on a sounding rocket demonstrator.[5]

Cryogenic tank demonstrator

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The cryogenic tank demonstrator is a series of demonstrators, which shall be used to develop and test technologies for future lightweight cryogenic tank systems. As of September 2016 a sub-scale demonstrator has been manufactured and tested, with a full-scale version currently in the design phase. The demonstrators can also be used as a test platform for other tank equipment and adjacent structure.[6]

Additive Manufacturing (AM)

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FLPP is developing additive layer manufacturing technologies - also known as 3D printing - for the application in launch vehicles. These technologies aim to provide faster and cheaper means of small scale production as well as additional design possibilities, leading to lighter more efficient structures.
Apart from the application of AM in several other projects, a dedicated project was started to mature the technology and develop applications for future launchers.[6]

CFRP technologies

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There are several projects within FLPP for advanced technologies to produce a wide range of structures out of carbon-fiber-reinforced polymer (CFRP). These structures cover the range from cryogenic feed lines and cryogenic tanks over upper stage structures to interstage structures.[6]

Fairing technologies

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Several future technologies concerning fairings are developed within FLPP. These include a membrane to seal the inside of the fairing from the outside to keep environmental conditions and cleanliness at a desired level and technologies to minimize shock during the separation of the fairing.[6]

Deorbitation Observation Capsule

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The deorbitation observation capsule will provide detailed data about the disintegration of launcher upper stages during re-entry into the atmosphere. This will help to design future stages for a safe and efficient deorbit manoeuvres.
To collect this data, the capsule will be launched on a launcher and after separation of the concerned stage, will observe the behaviour and disintegration of that stage during re-entry.[6]

Auto-propulsive multi payload adapter system

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The scope of this activity is to analyse the needs, verify the feasibility, and provide a preliminary definition of a propulsive orbital module (APMAS), based on an existing multi-payload dispenser system, to enhance the mission and performance envelope of existing launch vehicle upper stages for both, Vega and Ariane 6.[6]

Secondary payload adapter

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The objective of this project is to develop a structural and thermal model for a secondary payload adapter ring for payloads of up to 30 kg. This could help maximise the payload mass for the Vega, Ariane 6 and Soyuz launchers.[6]

Design for demise

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The design for demise (D4D) project investigates the processes that launch vehicle components undergo during re-entry. Special focus lies on the fragmentation behaviour of components like depleted stages, boosters, fairings or payload adapters. The goal is to better understand the behaviour via numeric simulations, the creation of material databases and plasma wind tunnel tests. The findings contribute to a reduced risk of debris impacting on the ground in compliance with ESA debris mitigation requirements.[6]

Power over Ethernet

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Power over Ethernet technology allows mixing of power and signal transmission on the same cable and has the potential to save mass and cost, as well as to decrease operational complexity for launcher telemetry. A project to define a modular launcher telemetry architecture based on this technology is currently on-going. It aims to utilise off-the-shelf components to reduce cost and development time. In the future, the system could be integrated into a larger avionics demonstrator and power other subsystems on the avionic bus.[7]

Advanced Avionics Test Bed

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The advanced avionics test bed features several innovative technologies such as: harness fault detection, power over Ethernet, optoelectronic telemetry systems and fibre Bragg grating sensor modules that allow the connection of multiple sensors via a single fibre. On ground and in-flight demonstrations are foreseen.[7]

Space Rider spaceplane

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The Space RIDER is a planned uncrewed orbital spaceplane under development aimed to provide the European Space Agency (ESA) with affordable and routine access to space.[8] Development of Space RIDER is being led by the Italian PRIDE programme for ESA, and it inherits technology from the Intermediate eXperimental Vehicle (IXV).[9] It is to launch atop a Vega-C rocket from the French Guiana in 2023,[10] and land on a runway on Santa Maria Island, in the Azores.[11]

Coordination with other programmes

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As a technology development programme for future launchers and upgrades to existing launchers, there is a close coordination between FLPP and the launcher development programmes for Ariane and Vega. Many of the technologies matured in FLPP are baselined for the configurations of Ariane 6 and Vega C.

See also

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References

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  1. ^ a b c d e f g h i j k l m n o "ESA FLPP". ESA. 30 November 2016. Retrieved 30 November 2016.
  2. ^ Underhill, K.; Caruana, J.-N.; De Rosa, M.; Schoroth, W. (May 2016). Status of FLPP Propulsion Demonstrators – Technology Maturation, Application Perspectives. Space Propulsion Conference. Rome, Italy.
  3. ^ Caisso, Philippe; et al. (December 2009). "A liquid propulsion panorama". Acta Astronautica. 65 (11). Acta Astronautica, Volume 65, Issues 11–12, Pages 1723–1737: 1723. Bibcode:2009AcAau..65.1723C. doi:10.1016/j.actaastro.2009.04.020.
  4. ^ a b c Caruana, Jean-Noel; De Rosa, Marco; Kachler, Thierry; Schoroth, Wenzel; Underhill, Kate (2015). Delivering Engine Demonstrators for Competitive Evolutions of the European Launchers. 6th European Conference for Aeronautics and Space Sciences (EUCASS). Kraków, Poland.
  5. ^ a b c d "Propulsion activities". ESA. 30 November 2016. Archived from the original on 13 August 2022. Retrieved 30 November 2016.
  6. ^ a b c d e f g h "ESA FLPP Systems and Technologies". ESA. 30 November 2016. Retrieved 30 November 2016.
  7. ^ a b "ESA FLPP Electronics and Avionics". ESA. 30 November 2016. Retrieved 30 November 2016.
  8. ^ "Space Rider". ESA. ESA. Retrieved 19 December 2017.
  9. ^ Space RIDER PRIDE. Italian Aerospace Research Centre (CIRA). Accessed: 15 November 2018.
  10. ^ "ESA signs contracts for reusable Space RIDER up to maiden flight". ESA. 9 December 2020.
  11. ^ Coppinger, Rob (22 June 2017). "ESA aims to privatize Space Rider unmanned spaceplane by 2025". Space News. Retrieved 19 December 2017.
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