Numerical Analysis of Smoke Behavior and Detection of Solid Combustible Fire Developed in Manned Exploration Module Based on Exploration Gravity

A fire during manned space exploration can cause serious casualties and disrupt the mission if the initial response is delayed. Therefore, measurement technology that can detect fire in the early stage of ignition is important. There have been a number of works that investigate the smoke behaviors i...

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Bibliographic Details
Published in:Fire (Basel, Switzerland) Switzerland), 2021-12, Vol.4 (4), p.85
Main Authors: Hong, Ter-Ki, Park, Seul-Hyun
Format: Article
Language:English
Subjects:
Casualties
Earth gravitation
Experiments
Exploration
Extinction
Fire detection
Fire Dynamics Simulator
Flammability
Grand Tours
Gravity
Heat
international space station
Laboratories
Manned space flight
Mars
Mars missions
Microgravity
Modules
Morphology
Numerical analysis
Optical properties
Smoke
smoke detector
Smoke detectors
Space exploration
space fire
Space flight
Space missions
Ventilation
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Summary:A fire during manned space exploration can cause serious casualties and disrupt the mission if the initial response is delayed. Therefore, measurement technology that can detect fire in the early stage of ignition is important. There have been a number of works that investigate the smoke behaviors in microgravity as the foundation for a reliable method for sensing a fire during spaceflight. For space missions to the outer planets, however, a strategy of detecting smoke as an indicator of fire should be adjusted to cover the fire scenario that can be greatly affected by changes in gravity (microgravity, lunar, Mars, and Earth gravity). Therefore, as a preliminary study on fire detectors of the manned pressurized module, the present study examined the smoke particle behavior and detection characteristics with respect to changes in gravity using numerical analysis. In particular, the effects of the combination of buoyancy and ventilation flow on the smoke particle movement pattern was investigated to further improve the understanding of the fire detection characteristics of the smoke detector, assuming that a fire occurred in different gravity environments inside the pressurized module. To this end, we modeled the internal shape of Destiny and performed a series of numerical analysis using the Fire Dynamics Simulator (FDS). The findings of this study can provide basic data for the design of a fire detection system for manned space exploration modules.
ISSN:2571-6255
2571-6255
DOI:10.3390/fire4040085