Abstract
During ascent of space launch vehicle in atmosphere, the payload compartment pressure should be leveled with the atmospheric pressure. At high altitudes, this pressure difference becomes more destructive. It produces crushing or bursting loads in the form of tension, compression or shear on satellite and launch vehicle. Even small differentials may be critical when imposed with compressive axial loads. In history of launch vehicles, at least two flights were failed due to improper depressurization of fairing [1]. Pressure equalization is attained through venting ports located on the periphery of fairing. The main constraint of depressurization system is to ensure the minimal pressure difference between fairing payload compartment and the atmosphere. However, fulfilling this constraint is difficult due to the continuous variation in flow velocity, from subsonic to hypersonic, during flight. The size, location and number of venting ports dictate effectiveness of depressurization system. In this paper, an innovative approach is used for the design and mathematical model development of depressurization system of launch vehicle fairing. For this purpose, MATLAB/SIMULINK toolbox Simscape is customized as per requirement. The quantity and size of venting ports are estimated by considering minimum pressure differential during atmospheric flight and at fairing separation. The suitable location of ports is estimated where static pressure at the port location over the fairing surface and the uninterrupted atmospheric pressure are equal. In order to verify the results, a scale down experimental setup is developed. One-way solenoid valves with three different orifice sizes are used as venting ports. Depressurization is performed at highest pressure difference, expected during flight. Numerical and experimental results are compared and it is found that numerical results are in good agreement with the experiment.

Muhammad Tanveer Iqbal, Abdul Majid. (2018) Design and Development of Depressurization System of Launch Vehicle Fairings, Journal of Space Technology , Volume 8, Issue 1.
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