Spine injury assessment under spaceflight landing conditions using multibody model

The novelty of the study relies on the fact that current simulations of human body to assess spine injury are based on finite element method. Spine injury assessment is an important point in designing spacecraft seat especially during landing. The finite element-based human body simulations are very...

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Bibliographic Details
Published in:Proceedings of the Institution of Mechanical Engineers. Part K, Journal of multi-body dynamics Journal of multi-body dynamics, 2018-12, Vol.232 (4), p.555-567
Main Authors: Pasha Zanoosi, AA, Kalantarinejad, R, Haghpanahi, M
Format: Article
Language:English
Subjects:
Astronauts
Computer simulation
Dynamic models
Femur
Finite element method
Human body
Landing conditions
Mathematical analysis
Modal analysis
Model accuracy
Multibody systems
Occupant injuries
Pelvis
Polyurethane foam
Rigid structures
Sensitivity analysis
Shock loads
Simulation
Space flight
Spine
Vertebrae
Viscera
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Summary:The novelty of the study relies on the fact that current simulations of human body to assess spine injury are based on finite element method. Spine injury assessment is an important point in designing spacecraft seat especially during landing. The finite element-based human body simulations are very time-consuming and computationally expensive. These problems make it difficult to perform high computational simulations such as optimization, sensitivity analysis, and so forth. Hence, in this study, it is tried to resolve these problems by developing a multibody model of human body in landing phase of spacecraft. This model makes designers able to perform corresponding simulations faster with acceptable accuracy. This study presents a dynamic multibody model of spacecraft seat-occupant system for spine injury assessment under landing conditions. The landing situation of spacecraft exposes shock loads to the spacecraft and astronaut. Hence, spine injury assessment under landing conditions enables optimal injury design of seat-occupant system. The modeling method is based on using the multibody modeling to achieve a detailed description containing the nonlinear properties and the accuracy of a multibody dynamic model considering whole body comprising stretching of vertebrae. The human body model comprises head, spine, femur, and shank lying on a flexible polyurethane foam as seat cushion. To model the spine, viscera, and pelvis in the sagittal plane, the spine column considered to be rigid bodies accompanied by spring-damper elements. To validate the developed model, the modal analysis and seat-to-head transmissibility of the spine has been validated by comparing with previously published models. Finally, as an application, the developed model has been exposed to a landing shock load for spine injury assessment.
ISSN:1464-4193
2041-3068
DOI:10.1177/1464419318757782