Open AccessWake flow about the Mars Pathfinder entry vehicle
Author(s) -
Robert Mitcheltree,
Peter A. Gnoffo
Publication year - 1995
Publication title -
journal of spacecraft and rockets
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 0.758
H-Index - 79
eISSN - 1533-6794
pISSN - 0022-4650
DOI - 10.2514/3.26682
Subject(s) - pathfinder , aerospace engineering , spacecraft , mars exploration program , wake , aeronautics , space research , space shuttle , space (punctuation) , spacecraft design , systems engineering , space suit , missile , rocket (weapon) , computer science , engineering , physics , astrobiology , library science , operating system
A computational approach is used to describe the aerothermodynamics of the Mars Pathfinder vehicle entering the Mars atmosphere at the maximum heating and maximum deceleration points in its trajectory. Ablating and nonablating boundary conditions are developed which produce maximum recombination of CO2 on the surface. For the maximum heating trajectory point, an axisymmetric, nonablating calculation predicts a stagnation-point value for the convective heating of 115 W/cm(exp 2). Radiative heating estimates predict an additional 5-12 W/cm(exp 2) at the stagnation point. Peak convective heating on the afterbody occurs on the vehicle's flat stern with a value of 5.9% of the stagnation value. The forebody flow exhibits chemical nonequilibrium behavior, and the flow is frozen in the near wake. Including ablation injection on the forebody lowers the stagnation-point convective heating 18%.
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