Abstract The main aim of this paper is to set up a many-parameter model of mass breakdown to be applied to a reusable Earth–Mars–Earth solar-photon sail shuttle, and analyze the system behavior in two sub-problems: (1) the zero-payload shuttle, and (2) given the sailcraft sail loading and the gross payload mass, find the sail area of the shuttle. The solution to the subproblem-1 is of technological and programmatic importance. The general analysis of subproblem-2 is presented as a function of the sail side length, system mass, sail loading and thickness. In addition to the behaviors of the main system masses, useful information for future work on the sailcraft trajectory optimization is obtained via (a) a detailed mass model for the descent/ascent Martian Excursion Module, and (b) the fifty–fifty solution to the sailcraft sail loading breakdown equation. Of considerable importance is the evaluation of the minimum altitude for the rendezvous between the ascent rocket vehicle and the solar-photon sail propulsion module, a task performed via the Mars Climate Database 2014–2015. The analysis shows that such altitude is 300 km; below it, the atmospheric drag prevails over the solar-radiation thrust. By this value, an example of excursion module of 1500 kg in total mass is built, and the sailcraft sail loading and the return payload are calculated. Finally, the concept of launch opportunity-wide for a shuttle driven by solar-photon sail is introduced. The previous fifty–fifty solution may be a good initial guess for the trajectory optimization of this type of shuttle.
[1]
Christian Circi,et al.
Dynamic and Structural Performances of a New Sailcraft Concept for Interplanetary Missions
,
2015,
TheScientificWorldJournal.
[2]
Max Born,et al.
Principles of optics - electromagnetic theory of propagation, interference and diffraction of light (7. ed.)
,
1999
.
[3]
Les Johnson,et al.
Solar Sails: A Novel Approach to Interplanetary Travel
,
2008
.
[4]
Colin R. McInnes,et al.
Distributed reflectivity solar sails for extended mission applications
,
2014
.
[5]
E. Millour,et al.
The Mars Climate Database (MCD version 5.2)
,
2015
.
[6]
Ron Portz,et al.
Performance Optimization of Storable Bipropellant Engines to Fully Exploit Advanced Material Technologies
,
2007
.
[7]
H. Demiryont,et al.
Electrochromic emissivity modulator for spacecraft thermal management
,
2009
.