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HVI Ballistic Limit Characterization of Fused Silica Thermal Panes (2015)

Bohl, W. D. ; Christiansen, E. L. ; Miller, J. E. ; [et al.]

In: CASI

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Publication Date: 2019-07-13

Description: Fused silica window systems are used heavily on crewed reentry vehicles, and they are currently being used on the next generation of US crewed spacecraft, Orion. These systems improve crew situational awareness and comfort, as well as, insulating the reentry critical components of a spacecraft against the intense thermal environments of atmospheric reentry. Additionally, these materials are highly exposed to space environment hazards like solid particle impacts. This paper discusses impact studies up to 10 km/s on a fused silica window system proposed for the Orion spacecraft. A ballistic limit equation that describes the threshold of perforation of a fuse silica pane over a broad range of impact velocities, obliquities and projectile materials is discussed here.

Keywords: Space Transportation and Safety

Type: JSC-CN-32614 , Hypervelocity Impact Symposium; Apr 26, 2015 - Apr 30, 2015; Boulder, CO; United States

Format: application/pdf

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Ballistic Performance Model of Crater Formation in Monolithic, Porous Thermal Protection Systems (2014)

Deighton, K. D. ; Christiansen, E. L. ; Miller, J. E.

In: CASI

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Publication Date: 2019-07-13

Description: Porous monolithic ablative systems insulate atmospheric reentry vehicles from reentry plasmas generated by atmospheric braking from orbital and exo-orbital velocities. Due to the necessity that these materials create a temperature gradient up to several thousand Kelvin over their thickness, it is important that these materials are near their pristine state prior to reentry. These materials may also be on exposed surfaces to space environment threats like orbital debris and meteoroids leaving a probability that these exposed surfaces will be below their prescribed values. Owing to the typical small size of impact craters in these materials, the local flow fields over these craters and the ablative process afford some margin in thermal protection designs for these locally reduced performance values. In this work, tests to develop ballistic performance models for thermal protection materials typical of those being used on Orion are discussed. A density profile as a function of depth of a typical monolithic ablator and substructure system is shown in Figure 1a.

Keywords: Spacecraft Design, Testing and Performance

Type: JSC-CN-30960 , Hypervelocity Impact Symposium; Apr 27, 2015 - May 01, 2015; Boulder, CO; United States

Format: application/pdf

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Orion Exploration Flight Test Post-Flight Inspection and Analysis (2017)

Enriquez, P. A. ; Bohl, W. E. ; Christiansen, E. L. ; [et al.]

In: CASI

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Publication Date: 2019-07-13

Description: The multipurpose crew vehicle, Orion, is being designed and built for NASA to handle the rigors of crew launch, sustainment and return from scientific missions beyond Earth orbit. In this role, the Orion vehicle is meant to operate in the space environments like the naturally occurring meteoroid and the artificial orbital debris environments (MMOD) with successful atmospheric reentry at the conclusion of the flight. As a result, Orion's reentry module uses durable porous, ceramic tiles on almost thirty square meters of exposed surfaces to accomplish both of these functions. These durable, non-ablative surfaces maintain their surface profile through atmospheric reentry; thus, they preserve any surface imperfections that occur prior to atmospheric reentry. Furthermore, Orion's launch abort system includes a shroud that protects the thermal protection system while awaiting launch and during ascent. The combination of these design features and a careful pre-flight inspection to identify any manufacturing imperfections results in a high confidence that damage to the thermal protection system identified post-flight is due to the in-flight solid particle environments. These favorable design features of Orion along with the unique flight profile of the first exploration flight test of Orion (EFT-1) have yielded solid particle environment measurements that have never been obtained before this flight.

Keywords: Spacecraft Design, Testing and Performance

Type: JSC-CN-38175 , Hypervelocity Impact Symposium; Apr 24, 2017 - Apr 28, 2017; Canterbury; United Kingdom

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Orion Exploration Flight Test Post-Flight Inspection and Analysis (2017)

Oliveras, O. M. ; Davis, B. A. ; Berger, E. L. ; [et al.]

In: CASI

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Publication Date: 2019-07-13

Description: The principal mechanism for developing orbital debris environment models, is to make observations of larger pieces of debris in the range of several centimeters and greater using radar and optical techniques. For particles that are smaller than this threshold, breakup and migration models of particles to returned surfaces in lower orbit are relied upon to quantify the flux. This reliance on models to derive spatial densities of particles that are of critical importance to spacecraft make the unique nature of the EFT-1's return surface a valuable metric. To this end detailed post-flight inspections have been performed of the returned EFT-1 backshell, and the inspections identified six candidate impact sites that were not present during the pre-flight inspections. This paper describes the post-flight analysis efforts to characterize the EFT-1 mission craters. This effort included ground based testing to understand small particle impact craters in the thermal protection material, the pre- and post-flight inspection, the crater analysis using optical, X-ray computed tomography (CT) and scanning electron microscope (SEM) techniques, and numerical simulations.

Keywords: Spacecraft Design, Testing and Performance

Type: JSC-CN-39277 , Hypervelocity Impact Symposium 2017 (HVIS2017); Apr 24, 2017 - Apr 28, 2017; Canterbury, Kent; United Kingdom

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