VEGA SATELLITE LAUNCHER AVIO IN WITH VEGA LAUNCHER Avio strengthened its presence in the space sector through its ELV subsidiary, a company jointly owned by Avio with a 70% share and the Italian Space Agency with a 30% share. ELV is the prime contractor for the Vega launcher, which received its go ahead from the European Space Agency (ESA) in December 2000. Twelve years later, on Monday 13 February 2012, at 10am, Vega successfully completed its maiden flight from the European Space Centre in Kourou, French Guiana. The new launcher successfully placed nine scientific and research satellites into orbit, making Vega a great success for both Avio and the over 40 companies that contributed to the project. On February 11th 2015 the fourth successful flight was performed from the European Space Center in French Guiana. In these four flight the flexibility of the launcher was demonstrated through the different missions required by the payloads. Avio, after the first five launchers awarded by ESA for institutional payloads (the last flight is scheduled within 2015), was awarded with a contract of 10 new launchers by Arianespace in 2014. ELV is the lead designer for the launch vehicle, also acting as systems integrator. ELV manages Vega s industrial supply chain, which includes companies from seven European countries. 65% of Vega is developed and manufactured in Italy, and the remaining 35% is made in Spain, Belgium, the Netherlands, Switzerland, Sweden and France. ELV draws on Avio s heritage in the technology and manufacturing sectors, achieved through initiatives sponsored by the Italian Space Agency and the Italian Ministry of Defence, such as SCOUT (1990), launched from the San Marco Range in Malindi, Kenya, and the IRIS upper stage, which was successfully launched with the Space Shuttle.
Vega launcher s main characteristics Vega is the ESA s satellite launch vehicle designed to send small satellites into Low Earth Orbit (LEO). It provides great flexibility of mission at an affordable cost. Vega can carry up to multiple payloads at a time in any orbit up to 1,500 km (reference performance is 1,500 kg at a circular polar orbit of 700 km). Vega is a four stage vehicle powered primarily through solid propulsion. It is 30m high and weighs 137 tonnes at lift-off. It hosts a payload dynamic envelope of 2.3 m diameter and 6.3 m height. Payload Mass (Kg) 2350 2100 1850 1600 300 Km 500 Km 1350 1100 850 700 Km 1200 Km 1500 Km 0 10 20 30 40 50 60 70 80 90 100 Orbit Inclination (degrees) Vega Guidance, Navigation (VGN) and Control Vega Performance Requirement: 1500 Kg in a 700 Km circular polar orbit With navigation and routing algorithms and on-board computer control, the Vega launcher can run trajectories at different angles (from equatorial to Sun-synchronous) and at different heights. Moreover, thanks to the re-ignition ability of the upper stage, is able to release the satellites in different orbital planes with extremely high precision orbital. The skills of the ELV teams ranging from the definition of the mission s strategy to optimize the same, the development of algorithms CNG to filling in the flight software, and culminate in the simulation of the final mission in real time within the structure Hardware in the Loop, where all phases of the mission are simulated and validated before the flight. Vega s propulsion The launcher s first three stages are based on solid propulsion motors and are manufactured using advanced technologies which deliver high performance at a lower cost. The engine cases, made of strong graphite fibre and epoxy resin, provide significant savings compared to conventional metal cases. The first stage motor case is produced using filament winding manufacturing devised for large diameters (3 m) and lengths (10 m), never before used in Europe. The P80 engine (first stage of the launcher) is another example of how this technology can be applied to solid propellant boosters of Ariane launchers, creating important synergies between Vega and Ariane family. Vega holds two technological world records, the P80, is the largest single launcher engine ever built made of carbon fibre (3 m diameter, 10 m length), while the third stage engine, Zefiro 9, is the most efficient solid propulsion launcher engine in terms of performance. The fourth stage is a liquid-propulsion system: a bipropellant system using storable fuel, unsymmetrical di-methyl hydrazine (UDMH) and nitrogen tetroxide (NTO). The LPS uses the YUZHNOYE RD869 engine as its main engine (MEA), which is capable of at least five ignitions during a nominal flight with a single payload (the five ignitions of the engine were successfully demonstrated by the second flight during which two payloads were released in different orbit). The new industrial plant dedicated to Vega s propulsion systems, with a surface area of 7,000 m2, and a height 22 m, is an important investment for Avio. The plant is dedicated to manufacturing the composite case and thermal protection for the three solid propulsion engines, the P80, Zefiro 23 and Zefiro 9. State-of-the-art machinery specifically designed for the P80 motor case applies filament-winding technology.
Engine testing The three solid rocket engines have been successfully tested. The third stage Zefiro 9 and second stage Zefi23 were tested respectively in December 2005 and June 2006 in Sardinia s Military Testing Range, PISQ, at Salto di Quirra. The fist stage P80 engine test was completed in November 2006 at the Kourou Space Centre French Guiana. Qualification phase began with a second engine test for the Zefiro 9 in March 2007. The second P80 test was successfully completed in December 2007, while the second Z23 test was carried out in March 2008 and the second Zefiro 9 test was completed in October 2008. The AVUM propulsion module was also tested during the propulsion system test campaign, at Astrium s facilities in Lampoldahusen, Germany, in November 2008. It was concluded successfully in April 2009. Main characteristics of Vega s propulsion system 1st 2nd 3rd 4th stage stage stage stage P 80FW Zefiro23 Zefiro9 AVUM Motor length (m) 10.6 7.5 3.5 1.7 Diameter (m) 3 1.9 1.9 2.00 Propellant mass (tons) 88 24 10.5 0.55 Motor dry mass (kg) 7,330 1,935 906 538.6 Motor case mass (kg) 3,260 900 400 16 Average thrust (kn) 2,200 1122 314 2.42 Specific impulse (s) 280 287.5 295.2 314.6 Combustion time (s) 110 77 117.1 7,23 Design leader Avio Avio Avio ELV
VEGA LAUNCHER NEW PROGRAMMES: WORK IN PROGRESS Lyra programme The Lyra programme, financed by the Italian Space Agency, allowed Avio to study the potential evolution of the Vega launcher in order to achieve a 30% increase in satellite loads of up to 2,000 kg in LEO of 700 km. The objective of this program was the performance increasing of the VEGA launcher through the substitution of the third and AVUM stage with an innovative LOX/LHC liquid propulsion system. This new engine, called Mira, has been designed for a thrust of approximately 10 tonnes by using an expanded cycle. During the Lyra programme, a full scale demonstrator of this new cryogenic propulsion system was successfully produced and tested. Innovative GNC algorithms were developed and tested as part of Lyra. The results obtained and the experience gained during the Demonstrator Engine activities create the reliable technical basis to start development activities linked to the LM10-MIRA Flight Engine. Future Launcher Preparatory Programme (FLPP) ELV participates in the FLPP, an ESA programme which began in February 2004 aimed at developing a next-generation launcher (NGL). The programme s goal is to be operational by around 2020. Within the programme, ELV has the responsibility to research Medium Class Launchers in the two to six tonne range, able to carry P/Ls into GTO orbit in a cost-effective way. ELV will also be involved in the specifications of innovative technologies to be applied on NGLs, looking at the reliability and competitiveness of European launchers. PHOTO: Marco Di Lauro/Verbatim Agency Via Ariana Km 5,2 00034 Colleferro Roma (Italy) Tel.+39 06 97285111 www.avio.com
VEGA LAUNCHER VEGA EVOLUTION In the Ministerial Conference of the ESA Member States held in Luxemburg at the beginning of December 2014, a first step of the VEGA launcher evolution has been approved and subscribed. The new configuration of the VEGA launcher will allow an increase of the performance up to 1800 kg in LEO and the maiden flight is scheduled in 2018. The VEGA evolution configuration includes, as first stage, the Solid Rocket Motor (SRM) named P120C that will be also used as lift-off booster for the new European Heavy Launcher Ariane 6. AVIO FOR VEGA EVOLUTION Avio will be responsible, in cooperation with Airbus Safran Launchers, of the new Solid Rocket Motor, named P120C and derived from P80 VEGA launcher first stage, that will be manufactured with the carbon fibres prepreg material and filament winding technology. It will carry about 120 tons of solid propellant. In order to have the maximum synergy between the European launchers the P120C is designed to be used as lift-off booster for Ariane 6 and to be integrated on the evolution of the VEGA program (named VEGA C) subscribed by the ESA Member States in the Ministerial Conference of 2014 as well. Furthermore, Avio will be responsible of the Z40 SRM that will be included in the VEGA evolution configuration as second stage propulsive system; its design will take benefit of the heritage coming from the development of Vega SRMs as well as from initial development activities self-financed by Avio for Z40 SRM as a demonstrator of new technologies for solid propulsion applications. Through its evolution, Vega will be able to increase its financial competitiveness and launch performance through the implementation of cost reduction activities, systems architecture, design and supply chain rationalization. With regards design, Vega s evolved launcher will be even more flexible and versatile, extending Vega s market from 50% of accessible LEO satellites to up to 90% with a consistent part covered by dual P/L launch. During the strategic planning for Vega, evolution-enabling technologies were identified focusing on performance improvement through to cost reduction, payload comfort and the consolidation of ELV system integration capabilities within the Europe s industry.