Rachel R. Kamenetzky
Marshall Space Flight Center
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Featured researches published by Rachel R. Kamenetzky.
SPIE's International Symposium on Optical Science, Engineering, and Instrumentation | 1998
James M. Zwiener; Rachel R. Kamenetzky; Jason A. Vaughn; Miria M. Finckenor
The passive optical sample assembly-I (POSA-I), part of the Mir Environmental Effects Payload (MEEP), was designed to study the combined effects of contamination, atomic oxygen, UV radiation, vacuum, thermal cycling, and other constituents of the space environment on spacecraft materials. The MEEP program is a Phase 1 International Space Station Risk Mitigation Experiment. The payload was attached by EVA to the exterior of the Mir docking module during the Space Shuttle mission STS-76. It was removed during STS-86 after exposure to the Mir space station environment for 18 months. POSA-I consists of nearly 400 samples of thermal control paints, chemical conversion coatings, mirrors, optics, and baseline materials for International Space Station. POSA-I also flew state-of-the-art materials and passive instruments for monitoring the atomic oxygen and UV radiation dose to the experiment. Pre- and post-flight characterization of candidate spacecraft materials is discussed. Contamination was detected on the POSA-I experiment. On the side facing space, visible contamination was observed. The contamination was uniform as would occur from a slow photodeposition process. A very definite film was deposited on the optical samples. The deposition appears to have directionality with definite shadowing effects. On the side facing the main Mir core, no visible contamination was noted.
36th AIAA/ASME/SAE/ASEE Joint Propulsion Conference and Exhibit | 2000
Jason A. Vaughn; Rachel R. Kamenetzky; Miria M. Finckenor; Peter Schuler
Two polymeric coatings have been developed for the Propulsive Small Expendable Deployer System (ProSEDS) mission. ProSEDS is designed to provide an on-orbit demonstration of the electrodynamic propulsion capabilities of tethers in space. The ProSEDS experiment will be a secondary payload on a Delta II unmanned expendable booster scheduled for launch in August 2000. A 5-km conductive tether is attached to the Delta 11 second stage and collects current from the low Earth orbit (LEO) plasma to facilitate de-orbit of the spent stage. The conductive tether is attached to a 10-km non-conductive tether, the other end of which is attached to an endmass containing several scientific instruments. A bare metal tether would have the best conductivity but thermal concerns preclude this design. A conductive polymer developed by Triton Systems has been optimized for conductivity and thermo-optical properties. The current design for the ProSEDS conductive tether is seven strands of 28 AWG aluminum wire individually coated with 8.7 micrometers (0.35 mil) of an atomic oxygen-resistant conductive polymer composed of a mixture of 87% Clear Oxygen-Resistant polymer (COR) and 13% polyanaline (PANi), wrapped around a braided Kevlar (TM) 49 core. Extensive testing has been performed at the Marshall Space Flight Center (MSFC) to qualify this material for flight on ProSEDS. Atomic oxygen exposure was performed, with solar absorptance and infrared emittance measured before and after exposure. Conductivity was measured before and after atomic oxygen exposure. High voltage tests, up to 1500 V, of the current collecting ability of the COR/PANi have been completed. Approximately 160 meters of the conductive tether closest to the Delta 11 second stage is insulated to prevent any electron reconnection to the tether from the plasma contactor. The insulation is composed of polyimide overcoated with TOR-BP, another polymeric coating developed by Triton for this mission. TOR-BP acts as both insulator and a protective coating against atomic oxygen erosion. The insulation has been tested to withstand 5000 V.
38th Aerospace Sciences Meeting and Exhibit | 2000
Rachel R. Kamenetzky; Miria M. Finckenor
A common component of multi-layer insulation blankets is beta cloth, a woven fiberglass cloth impregnated with Teflon. It is planned for extensive use on the International Space Station (ISS). The Environmental Effects Group of the Marshall Space Flight Center Materials, Processing and Manufacturing Department has investigated the impact of atomic oxygen (AO) and ultraviolet (UV) radiation on the optical properties of plain and aluminized beta cloth, both in the laboratory and as part of long-duration flight experiments. These investigations indicate that beta cloth was susceptible to darkening in the presence of UV radiation, dependent on the additives used. The presence of AO countered some, if not all, of the UV degradation.
30th Aerospace Sciences Meeting and Exhibit | 1992
Ann F. Whitaker; Miria M. Finckenor; Rachel R. Kamenetzky
Property changes that occurred in four groups of polymer-based materials in the Long Duration Exposure Facility (LDEF) due to exposure to the outer space environment for 5.8 yrs are examined. Evaluations of contamination and mass loss are presented along with optical, thermal, and electrical analyses and mechanical property evaluations for TFE Teflon, the fluorinated material Halar, the silicone-based material RTV 511, and PEEK resin. 5 refs.
37th Aerospace Sciences Meeting and Exhibit | 1999
M. Ralph Carruth; Donald R. Wilkes; James M. Zwiener; Stanislav Naumov; Rachel R. Kamenetzky
Degradation of thermal control surface properties results from the synergistic effects of the space environments interaction with materials. This includes the natural space environment and the contamination environment produced by the spacecraft itself. Past flight experiments have utilized small witness samples which were recovered for post flight analysis on the ground. However, reintroduction into an oxygen atmosphere can, in itself, cause a change in the properties of the material being studied. Space based measurements using video cameras were not quantifiable. Very limited experiments have previously measured material properties in-situ on a spacecraft but only using small prepared witness samples with minimal exposure to space. The only way to really determine the properties of actual spacecraft surfaces after an extended exposure to the space environment is to measure them directly, in space. The SPSR provides this capability to measure the most important thermal property which can change in the space environment, the solar absorptivity. The Mir space station provides an excellent opportunity for such experiments due to the long exposure that some of the modules have experienced. Measurements from different modules would have provided an opportunity to determine the effect of various exposure time in orbit and under different contamination environments. Due to other pressing issues only one site was measured using the SPSR.
Archive | 1998
John R. Christensen; Steve D. Underwood; Rachel R. Kamenetzky; Jason A. Vaughn
Space Programs and Technologies Conference | 1996
Jason A. Vaughn; Rachel R. Kamenetzky; Miria M. Finckenor; Dave Edwards; Jim Zwiener
Archive | 1992
Ann F. Whitaker; Rachel R. Kamenetzky; Miria M. Finckenor; Joseph K. Norwood
39th Aerospace Sciences Meeting and Exhibit | 2001
Miria M. Finckenor; Rachel R. Kamenetzky; Jason A. Vaughn; Richard Mell; M. S. Deshpande
37th Aerospace Sciences Meeting and Exhibit | 1999
James M. Zwiener; Rachel R. Kamenetzky; Jason A. Vaughn; Miria M. Finckenor