Supersonic Retropropulsion Thrust Vectoring for Mars Precision Landing

Mandalia, Amit B.; Braun, Robert D.

doi:10.2514/1.a33119

Cited by 9 publications

(2 citation statements)

References 18 publications

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“…In recent years, SpaceX has realized the recycling of the first stage through the retro-propulsion and attitude control technology of the launch vehicle, which effectively reduces the launch cost and the launch cycle and promotes the development of the reusable launch vehicle (RLV). But a certain amount of propellant is reserved for the reentry process, which results in the loss of carrier capability [2]. In this situation, the inflatable aerodynamic decelerator (IAD) is noticed gradually due to its small size, foldable, and lightweight [3].…”

Section: Introductionmentioning

confidence: 99%

Simulation and analysis of drag for inflatable aerodynamic decelerator

Yun

Liu

2023

J. Phys.: Conf. Ser.

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Inflatable aerodynamic decelerator, as a novel deceleration and recovery technology, has received attention due to its lightweight and freedom from the launch vehicle fairing size constraints for the space mission. Aimed at the aerodynamic characteristics of the inflatable aerodynamic decelerator, this work studied the effect of the cone angle on its drag and discussed the drag varied with the angle of attack under the different cone angles. The simulation showed that the drag was affected by the cone angle and increased locally with the angle of attack. Furthermore, the larger cone angle was beneficial to the stability of the flow field on its leeward in the case of a high Mach number. The math model of drag with the Mach number and the angle of attack was obtained by fitting the data, which provided favorable support for the prospective discussion of the flight dynamics characteristics.

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Section: Introductionmentioning

confidence: 99%

Simulation and analysis of drag for inflatable aerodynamic decelerator

Yun

Liu

2023

J. Phys.: Conf. Ser.

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“…SRP can also be utilized as additional control authority for precision landing. 17 Computational fluid dynamics tools have been shown capable of capturing major flowfield features, including unsteadiness, albeit at considerable computational expense. [13][14] Recent computational and experimental efforts have demonstrated that, in Mars relevant conditions, thrust requirements are sufficiently high to render the aerodynamic axial force contribution negligible.…”

Section: Introductionmentioning

confidence: 99%

Advancing Supersonic Retropropulsion Using Mars-Relevant Flight Data: An Overview

Braun¹,

Sforzo

Campbell

2017

AIAA SPACE and Astronautics Forum and Exposition

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Advanced robotic and human missions to Mars require landed masses well in excess of current capabilities. One approach to safely land these large payloads on the Martian surface is to extend the propulsive capability currently required during subsonic descent to supersonic initiation velocities. However, until recently, no rocket engine had ever been fired into an opposing supersonic freestream. In September 2013, SpaceX performed the first supersonic retropropulsion (SRP) maneuver to decelerate the entry of the first stage of their Falcon 9 rocket. Since that flight, SpaceX has continued to perform SRP for the reentry of their vehicle first stage, having completed multiple SRP events in Mars-relevant conditions in July 2017. In FY 2014, NASA and SpaceX formed a three-year public-private partnership centered upon SRP data analysis. These activities focused on flight reconstruction, CFD analysis, a visual and infrared imagery campaign, and Mars EDL design analysis. This paper provides an overview of these activities undertaken to advance the technology readiness of Mars SRP.

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Entry, Descent, and Landing technological barriers and crewed MARS vehicle performance analysis

Subrahmanyam

Rasky

2017

Progress in Aerospace Sciences

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Supersonic Retropropulsion Thrust Vectoring for Mars Precision Landing

Cited by 9 publications

References 18 publications

Simulation and analysis of drag for inflatable aerodynamic decelerator

Simulation and analysis of drag for inflatable aerodynamic decelerator

Advancing Supersonic Retropropulsion Using Mars-Relevant Flight Data: An Overview

Entry, Descent, and Landing technological barriers and crewed MARS vehicle performance analysis

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