Coordinatore | ARQUIMEA INGENIERIA S.L
Organization address
address: CALLE MARGARITA SALAS 16 BAJO A contact info |
Nazionalità Coordinatore | Spain [ES] |
Sito del progetto | http://www.stamas.eu/ |
Totale costo | 2˙119˙166 € |
EC contributo | 1˙460˙287 € |
Programma | FP7-SPACE
Specific Programme "Cooperation": Space |
Code Call | FP7-SPACE-2012-1 |
Funding Scheme | CP-FP |
Anno di inizio | 2013 |
Periodo (anno-mese-giorno) | 2013-01-01 - 2015-12-31 |
# | ||||
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1 |
ARQUIMEA INGENIERIA S.L
Organization address
address: CALLE MARGARITA SALAS 16 BAJO A contact info |
ES (LEGANES MADRID) | coordinator | 431˙231.20 |
2 |
SENSODRIVE GmbH
Organization address
address: Argelsrieder Feld 20 contact info |
DE (WESSLING) | participant | 325˙000.00 |
3 |
DEUTSCHES ZENTRUM FUER LUFT - UND RAUMFAHRT EV
Organization address
address: Linder Hoehe contact info |
DE (KOELN) | participant | 291˙930.25 |
4 |
EIDGENOESSISCHE TECHNISCHE HOCHSCHULE ZURICH
Organization address
address: Raemistrasse 101 contact info |
CH (ZUERICH) | participant | 168˙038.40 |
5 |
UNIVERSIDAD CARLOS III DE MADRID
Organization address
address: CALLE MADRID 126 contact info |
ES (GETAFE (MADRID)) | participant | 150˙937.50 |
6 |
UNIVERSITA DI PISA
Organization address
address: Lungarno Pacinotti 43/44 contact info |
IT (PISA) | participant | 93˙150.00 |
Esplora la "nuvola delle parole (Word Cloud) per avere un'idea di massima del progetto.
'In the context of European Space Policy and its requirements regarding achieving solid technological basis and industry competitiveness, SMEs play an integral role in the research and development of new technology. To prepare for the long-term expeditions of space programmes, some critical factors should be taken into account before the launching: ensuring that astronauts are mentally and physically prepared for the missions’ demands, and maintaining them in good health during and after the mission. Unfortunately, the space environment continues to have a negative effect on the astronauts’ health. Therefore, the STAMAS consortium has identified the need for developing a new type of astronauts’ suit, a “smart-suit”, which will mitigate the pernicious effects of weightlessness and motor inactivity. The project will utilise existing terrestrial experience in Shape Memory Alloys (SMA)/Electroactive Polymer (EAP) technology, and built upon this knowledge to develop an effective solution for usage in space. This adaptation will include substituting conventional hydraulic actuators for those based on biometric sensors, and control features. The overall objective is to analyse the suitability and to bring experience on the SMA and EAP based actuation technologies addressing terrestrial applications, to research in new concepts of artificial muscles for biofeedback astronauts’ suits, as an alternative to current technologies. To effectively adapt the current technology to on-board space requirements, and to make the electromechanical actuators of the developed artificial muscles for biofeedback suits more efficient, safer, smaller, and lighter, the consortium will take full advantage of smart technology. Finally, the Consortium, led by ARQUIMEA, is a balanced group of SMEs and Research Institutions that will develop validated devices to have strong impact on the space industry, facilitate high-risk/high-impact research and innovation, and contribute to new research alliances'
Future explorers on the Moon and Mars could be outfitted in a new type of astronaut's suit, a 'smartsuit' that will mitigate the pernicious effects of weightlessness and motor inactivity.
On Earth, gravity is a force our bodies have to work against, which keeps our cells, bones and muscles strong. Over a long-term space flight, human bodies undergo dramatic changes. As there is no need to walk, stand or lift in microgravity, their muscles atrophy. Furthermore, the cardiovascular system doesn't work as hard, resulting in fluids such as blood moving up from the lower body to the trunk. The heart rate increases and blood pressure rises.
Within the EU-funded 'Smart technology for artificial muscle applications in space' (http://www.stamas.eu/ (STAMAS)) project, research is underway on a new type of astronaut's suit designed to apply pressure to the entire body. Wearable technologies will be embedded into the suit to monitor and help maintain the astronaut's health and physical fitness during a space mission. The research is multi-pronged and intended to explore improvements to current spacesuit designs and to generate new ideas.
Specifically, STAMAS researchers are looking into cutting-edge materials such as shape memory alloys and electro-active polymers to turn their smart suit vision into working prototypes suitable for human space explorers. Electro-active polymers change size and shape when simulated by the right external electrical activation, enable movement and generate force. Shape memory alloys that 'remember' their original shape are also being explored as candidate materials that may replicate natural muscles.
So far, discussions between the medical experts and the technical team have concluded with a detailed description of on-board space requirements. To effectively adapt the current electromechanical actuator technology, new concepts of artificial muscles for biofeedback astronaut suits have been tested on the International Space Station (ISS) and in space.
In this line of research, two demonstrators will be developed: one to address physiological degradation of legs due to the effect of microgravity, and another for the hands' fatigue during extra-vehicular activities. The validated devices will have a strong impact on the space industry and could also find valuable terrestrial applications in rehabilitation.