Physiologically constrained aerocapture for manned Mars missions

Aerobraking has been proposed as a critical technology for manned missions to Mars. The variety of mission architectures currently under consideration presents aerobrake designers with an enormous range of potential entry scenarios. Two of the most important considerations in the design of an aerobrake are the required control authority (lift-to-drag ratio) and the aerothermal environment which the vehicle will encounter. Therefore, this study examined the entry corridor width and stagnation-point heating rate and load for the entire range of probable entry velocities, lift-to-drag ratios, and ballistic coefficients for capture at both Earth and Mars. To accomplish this, a peak deceleration limit for the aerocapture maneuvers had to be established. Previous studies had used a variety of load limits without adequate proof of their validity. Existing physiological and space flight data were examined, and it was concluded that a deceleration limit of 5 G was appropriate. When this load limit was applied, numerical studies showed that an aerobrake with an L/D of 0.3 could provide an entry corridor width of at least 1 degree for all Mars aerocaptures considered with entry velocities up to 9 km/s. If 10 km/s entries are required, an L/D of 0.4 to 0.5 would be necessary to maintain a corridor width of at least 1 degree. For Earth return aerocapture, a vehicle with an L/D of 0.4 to 0.5 was found to provide a corridor width of 0.7 degree or more for all entry velocities up to 14.5 km/s. Aerodynamic convective heating calculations were performed assuming a fully catalytic, 'cold' wall; radiative heating was calculated assuming that the shock layer was in thermochemical equilibrium. Heating rates were low enough for selected entries at Mars that a radiatively cooled thermal protection system might be feasible, although an ablative material would be required for most scenarios. Earth return heating rates were generally more severe than those encountered by the Apollo vehicles, and would require ablative heat shields in all cases.

[1]  J. G. Marvin,et al.  Convective heat transfer in planetary gases , 1966 .

[2]  Richard W. Powell,et al.  Aerodynamic requirements of a manned Mars aerobraking transfer vehicle , 1991 .

[3]  W. J. White,et al.  The effect of gravitational stress upon visual acuity , 1959 .

[4]  C. B. Cohen,et al.  THE USE OF AERODYNAMIC LIFT DURING ENTRY INTO THE EARTH'S ATMOSPHERE, , 1959 .

[5]  Stanley W. Shepperd,et al.  An onboard navigation system which fulfills Mars aerocapture guidance requirements , 1989 .

[6]  S. K. Ride Leadership and America's future in space , 1987 .

[7]  N S CHERNIACK,et al.  Some aspects of respiratory physiology during forward acceleration. , 1961, Aerospace medicine.

[8]  Robert D. Braun,et al.  Propulsive options for a manned Mars transportation system , 1989 .

[9]  H A SMEDAL,et al.  The physiological limitations of performance during acceleration. , 1963, Aerospace medicine.

[10]  Egorov Ad,et al.  Medical results of Salyut-6 manned space flights. , 1983 .

[11]  D. R. Rushneck,et al.  The composition of the atmosphere at the surface of Mars , 1977 .

[12]  O G Gazenko,et al.  Summary of medical investigations in the U.S.S.R. manned space missions. , 1981, Acta astronautica.

[13]  Grant Palmer,et al.  Earth atmospheric entry studies for manned Mars missions , 1990 .

[14]  Aerobraking in a dusty Martian atmosphere , 1990 .

[15]  Wood Eh,et al.  Development of anti-G suits and their limitations. , 1987 .

[16]  Steven W. Peterson,et al.  Local and overall aerodynamic coefficients for bodies in hypersonic, rarefied flow , 1991 .

[17]  A R Kotovskaya,et al.  +Gx-tolerance in the final stage of space flights of various durations. , 1991, Acta astronautica.

[18]  J. D. Lem,et al.  Results of Skylab medical experiment M171-metabolic activity , 1977 .

[19]  H Sandler,et al.  Tolerance of females to +GZ centrifugation before and after bedrest. , 1977, Aviation, space, and environmental medicine.

[20]  Victor A. Convertino,et al.  Exercise Training: Blood Pressure Responses in Subjects Adapted to Microgravity , 1991 .

[21]  V V Polyakov,et al.  Preliminary medical results of the Mir year-long mission. , 1991, Acta astronautica.

[22]  H Sandler,et al.  Effects of rehydration of +G z tolerance afterr 14-days' bed rest. , 1973, Aerospace medicine.

[23]  A. Seiff,et al.  Structure of the atmosphere of Mars in summer at mid-latitudes , 1977 .

[24]  H. Kabat,et al.  ACUTE ARREST OF CEREBRAL CIRCULATION IN MAN: LIEUTENANT RALPH ROSSEN (MC), U.S.N.R. , 1943 .

[25]  H Sandler,et al.  Effects of simulated weightlessness on responses of untrained men to +Gz acceleration. , 1974, Journal of applied physiology.

[26]  Robert D. Braun,et al.  On the computation of near wake, aerobrake flowfields , 1991 .

[27]  Robert M. Zubrin,et al.  Humans to Mars in 1999 , 1991 .

[28]  Richard W. Powell,et al.  Aerodynamic requirements of a manned Mars aerobraking transfer vehicle , 1990 .

[29]  G. W. Hoffler,et al.  Hemodynamic studies of the legs under weightlessness , 1977 .

[30]  Berry Ca Medical legacy of Skylab as of May 9, 1974: the manned Skylab missions. , 1976 .

[31]  E. Wood,et al.  Regional pulmonary arterial-venous shunting caused by gravitational and inertial forces. , 1968, Journal of applied physiology.

[32]  S D LEVERETT,et al.  TOLERANCE TO TRANSVERSE (+GX) AND HEADWARD (+GZ) ACCELERATION AFTER PROLONGED BED REST. , 1965, Aerospace medicine.

[33]  G W Hoffler,et al.  Lower body negative pressure: the second manned Skylab mission. , 1976, Aviation, space, and environmental medicine.

[34]  O G Gazenko,et al.  Medical results of Salyut-6 manned space flights. , 1983, Aviation, space, and environmental medicine.

[35]  Hershgold Ej Roentgenographic study of human subjects during transverse accelerations. , 1960 .

[36]  E J HERSHGOLD Roentgenographic study of human subjects during transverse accelerations. , 1960, Aerospace medicine.

[37]  Egorov Ad,et al.  Summary of medical investigations in the U.S.S.R. manned space missions. , 1981 .

[38]  M. Tauber,et al.  The use of atmospheric braking during Mars missions , 1989 .

[39]  J. Greenleaf,et al.  Orthostatic responses following 30-day bed rest deconditioning with isotonic and isokinetic exercise training. , 1989, Aviation, space, and environmental medicine.

[40]  M. E. Tauber,et al.  Stagnation-point radiative heating relations for earth and Mars entries , 1991 .

[41]  C. A. Syvertson,et al.  Trends in high-speed atmospheric flight , 1964 .

[42]  V V Polyakov The physician-cosmonaut tasks in stabilizing the crew members health and increasing an effectiveness of their preparation for returning to Earth. , 1991, Acta astronautica.

[43]  G Leonid,et al.  Manned expedition to Mars: concepts & problems. , 1991, Acta astronautica.

[44]  H. Miura,et al.  Aerobrake design studies for manned Mars missions , 1991 .

[45]  Gerald D. Walberg,et al.  A review of aerobraking for Mars missions , 1988 .

[46]  Lily Yang,et al.  Atmospheric environment during maneuvering descent from Martian orbit , 1989 .

[47]  M. Cohen Combining techniques to enhance protection against high sustained accelerative forces. , 1983, Aviation, space, and environmental medicine.

[48]  Dean R Chapman,et al.  An approximate analytical method for studying entry into planetary atmospheres , 1958 .

[49]  E L Michel,et al.  Exercise cardiac output following Skylab missions: the second manned Skylab mission. , 1976, Aviation, space, and environmental medicine.

[50]  Richard W. Powell,et al.  The effect of interplanetary trajectory options on a manned Mars aerobrake configuration , 1990 .

[51]  James Evans Lyne,et al.  A parametric study of manned aerocapture at Mars , 1991 .

[52]  E H Wood,et al.  Development of anti-G suits and their limitations. , 1987, Aviation, space, and environmental medicine.

[53]  Lincoln J. Wood,et al.  High-accuracy Mars approach navigation with radio metric and optical data , 1990 .

[54]  P. Barr Hypoxemia in man induced by prolonged acceleration. , 1962, Acta physiologica Scandinavica.

[55]  C. Justus,et al.  A Mars Global Reference Atmospheric Model (MARS-GRAM) for mission planning and analysis , 1990 .

[56]  Richard W. Powell,et al.  Manned Mars aerobrake vehicle design issues , 1990 .

[57]  D. Curry,et al.  Apollo ablator thermal performance at superorbital entry velocities , 1970 .

[58]  M. I. Cruz,et al.  The aerocapture vehicle mission design concept. [aerodynamically controlled capture of payload into Mars orbit] , 1979 .

[59]  Richard W. Powell,et al.  A predictor-corrector guidance algorithm for use in high-energy aerobraking system studies , 1991 .

[60]  M. Tauber,et al.  Heatshield erosion in a dusty Martian atmosphere , 1993 .

[61]  Richard W. Powell,et al.  Earth aerobraking strategies for manned return from Mars , 1991 .

[62]  J B Charles,et al.  Cardiovascular deconditioning during space flight and the use of saline as a countermeasure to orthostatic intolerance. , 1985, Aviation, space, and environmental medicine.