Abstract
The galactic and solar radiation effect on astronauts in space during manned-space missions is one of the issues that scientists are dealing with to overcome this disaster. Furthermore, in space missions to Mars, Titan, and beyond, a powerful propulsion system is required. Recently, with the enhancement of technology in plasma generation, scientists tried to design and build a plasma radiation shield and plasma propulsion system to create a safe and reliable space-craft for long-term space missions. In the present research, an attempt is made to estimate the thermal fatigue life of unidirectional carbon fiber/epoxy composite in the presence of plasma radiation shield and/or plasma propulsion systems. In order to produce a plasma radiation shield and/or plasma propulsion system, a strong magnet that generates a magnetic field for electron cloud is required. For charging magnets, appropriate power supplies are needed. Each of the different power supplies has different operating temperatures that have effect on the thermal fatigue life of space-vehicles structure. In this study, with a new method, thermal fatigue life of unidirectional carbon fiber/epoxy composite which is exposed to different power supplies thermal cycles is predicted. The results have indicated that the new method represents 32.2 % less thermal fatigue life when compared to the previous method. Space-crafts are currently being built with carbon materials such as unidirectional carbon fiber/epoxy composite, due to their lightweights and high strength. Key words: Plasma shield, plasma propulsion, power supply, astronauts’ health, composites, thermal fatigue life.  
Highlights
Thermal fatigue life of unidirectional carbon fiber/epoxyThermal fatigue life of Unidirectional Carbon Fiber/Epoxy Composite (UD CF/EP) in Low Earth Orbit (LEO) has been analyzed previously (Anvari, 2014)
Because the thermal cycles to failure generated by this power supply is maximum for UD CF/EP which creates the longest thermal fatigue life for the space craft made with UD CF/E(P1.3)
In conditions in which ΔTFC is greater than ΔTLEO, the difference between the thermal cycle numbers to failure derived by methods Extended Convex Curves Method (ECCM) and Compatible Steady-Linear Method (CSLM) increases
Summary
Thermal fatigue life of unidirectional carbon fiber/epoxy. Thermal fatigue life of Unidirectional Carbon Fiber/Epoxy Composite (UD CF/EP) in Low Earth Orbit (LEO) has been analyzed previously (Anvari, 2014). As Mars appears to be the closest planet to Earth in the solar system, the thermal fatigue life of UD CF/EP on Mars was investigated in 2017 (Anvari, 2017a). It is important to note that due to the similarity and closeness of Mars to Earth, one-way human mission to Mars was proposed (Schulze-Makuch and Davies, 2010). Due to the characteristics of the atmosphere of Titan, Saturn’s moon, which is a great shield against solar and cosmic radiation and being safe in this aspect for human-life, thermal fatigue life of UD CF/EP in Titan.
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