Microgravity Simulator Based on Air Levitation for Astronauts EVA Operation Training

Ming Lian Zhou; Hao Chen Hu; Shu Hui Xu

doi:10.4028/www.scientific.net/AMM.577.443

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Application of Repeater Jamming Technology Aiming at Doppler Fire Control Radar on Ship-to-Ship Missile Penetration
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Calibration and Evaluation of Steering Wheel Torque Signal for EPS System
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How to Get the Solar Direction from Skylight Polarization for Satellite Autonomous Navigation
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Hydraulic System Fault Diagnosis Method Based on HPSO AND WP-EE
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Microgravity Simulator Based on Air Levitation for Astronauts EVA Operation Training
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LQR Based Trajectory Tracking Control for Forked AGV
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Research on the Visual Self-Stabilization System of the Automated Guided Vehicle (AGV)
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Development of Retrieve/Storage Cabinets for Chemical Reagents
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A Key Strategy for Controlling the High-Power Photovoltaic Inverter
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HomeApplied Mechanics and MaterialsApplied Mechanics and Materials Vol. 577Microgravity Simulator Based on Air Levitation for...

Microgravity Simulator Based on Air Levitation for Astronauts EVA Operation Training

Abstract:

Because of the microgravity environment of the space and mobility restriction by pressurized spacesuit, astronaut extravehicular operation is quite different from that in the ground. For ensuring high reliability of extravehicular operations, the astronauts need to do a great deal of training in simulated environments. A 3-dof of micro-gravity operation training system is designed in the paper, and the kinematics and dynamics of the interaction between the space station system and spacesuit system were simulated. Pressure and flow velocity distributions in the air orifice and air cavity were calculated by FLUENT. Experiments on the bearing capacity characteristic were carried out. The carrying capacities of the air bearing in different air pressures were achieved. Experiments validated the simulation analysis. The research provides the basis for the development of multi-degree of freedom space microgravity ground simulation technology, provides a basis for further development and application of flotation technology as well.

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Periodical:

Applied Mechanics and Materials (Volume 577)

Pages:

443-446

DOI:

https://doi.org/10.4028/www.scientific.net/AMM.577.443

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Online since:

July 2014

Authors:

Ming Lian Zhou*, Hao Chen Hu, Shu Hui Xu

Keywords:

Air Levitation, EVA Spacesuit, Microgravity Simulator, Operation Training, Space Station

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* - Corresponding Author

References

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