Dynamics of adaptive structures: Design through simulations
Abstract
The use of a helical bi-morph actuator/sensor concept by mimicking the change of helical waveform in bacterial flagella is perhaps the first application of bacterial motions (living species) to longitudinal deployment of space structures. However, no dynamical considerations were analyzed to explain the waveform change mechanisms. The objective is to review various deployment concepts from the dynamics point of view and introduce the dynamical considerations from the outset as part of design considerations. Specifically, the impact of the incorporation of the combined static mechanisms and dynamic design considerations on the deployment performance during the reconfiguration stage is studied in terms of improved controllability, maneuvering duration, and joint singularity index. It is shown that intermediate configurations during articulations play an important role for improved joint mechanisms design and overall structural deployability.
- Publication:
-
NASA STI/Recon Technical Report N
- Pub Date:
- 1993
- Bibcode:
- 1993STIN...9413112P
- Keywords:
-
- Bacteria;
- Dynamic Structural Analysis;
- Flexible Spacecraft;
- Mathematical Models;
- Momentum Theory;
- Spacecraft Design;
- Controllability;
- Deployment;
- Large Space Structures;
- Simulation;
- Spacecraft Structures;
- Trusses;
- Spacecraft Design, Testing and Performance