Space structures nowadays are often designed to serve just one objective during their mission life, examples include truss structures that are used as support structures, solar sails for propulsion or antennas for communication. Each and every single one of these structures is optimized to serve just their distinct purpose and are more or less useless for the rest of the mission and therefore dead weight. By developing a smart structure that can change its shape and therefore adapt to different mission requirements in a single structure, the flexibility of the spacecraft can be increased by greatly decreasing the mass of the entire system. This paper will introduce such an adaptive structure called the Self-inflating Adaptive Membrane (SAM) concept which is being developed at the Advanced Space Concepts Laboratory of the University of Strathclyde. An idea presented in this paper is to adapt these basic changeable elements from nature’s heliotropism. Heliotropism describes a movement of a plant towards the sun during a day; the movement is initiated by turgor pressure change between adjacent cells. The shape change of the global structure can be significant by adding up these local changes induced by local elements, for example the cell’s length. To imitate the turgor pressure change between the motor cells in plants to space structures, piezoelectric micro pumps are added between two neighboring cells. A passive inflation technique is used for deploying the membrane at its destination in space. The trapped air in the spheres will inflate the spheres when subjected to vacuum, therefore no pump or secondary active deployment methods are needed. The paper will present the idea behind the adaption of nature’s heliotropism principle to space structures. The feasibility of the residual air inflation method is verified by LS-DYNA simulations and prototype bench tests under vacuum conditions. Additionally, manufacturing techniques and folding patterns are presented to optimize the actual bench test structure and to minimize the required storage volume. It is shown that through a bio-inspired concept, a high ratio of adaptability of the membrane can be obtained. The paper concludes with the design of a technology demonstrator for a sounding rocket experiment to be launched in March 2013 from the Swedish launch side Esrange.
[1]
Marco Straubel,et al.
On-Ground Rigidised, Inflatable CFRP Booms for Various Deployable Space Structures
,
2010
.
[2]
Massimiliano Vasile,et al.
REXUS 12 Suaineadh experiment: deployment of a web in microgravity conditions using centrifugal forces
,
2011
.
[3]
Edward F. Crawley,et al.
Intelligent structures for aerospace - A technology overview and assessment
,
1994
.
[4]
Champagne Ardenne,et al.
POLYMERIZATION OF COMPOSITE MATERIALS IN FREE SPACE ENVIRONMENT
,
2009
.
[5]
Wolfgang Seboldt,et al.
Solar sail technology development and demonstration
,
2003
.
[6]
Mac Neal.
Meteoroid damage to filamentary structures
,
1967
.
[7]
Thomas Sinn,et al.
Shape memory alloy post buckled precompressed (SMAPBP) actuator concepts and theory
,
2010,
Smart Structures and Materials + Nondestructive Evaluation and Health Monitoring.
[8]
E. Wilson,et al.
The Heliotropism of Hydra
,
1891,
The American Naturalist.
[9]
B. K. Wada,et al.
Overview of NASA's Adaptive Structures program
,
1993
.
[10]
C. Galen.
SUN STALKERS : HOW FLOWERS FOLLOW THE SUN
,
1999
.
[11]
Colin R. McInnes,et al.
A passive de-orbiting strategy for high altitude CubeSat missions using a deployable reflective balloon
,
2011
.
[12]
Helen Page,et al.
REXUS/BEXUS: launching student experiments -a step towards a stronger space science community
,
2010
.
[13]
M. M. Mikulas,et al.
Inflatable Deployable Space Structures Technology Summary
,
1998
.
[14]
Carl Knoll,et al.
DEVELOPMENT OF A MULTIFUNCTIONAL INFLATABLE STRUCTURE FOR THE POWERSPHERE CONCEPT
,
2002
.
[15]
Gokhan Kiper,et al.
Deployable space structures
,
2009,
2009 4th International Conference on Recent Advances in Space Technologies.