论文信息 - SHOCK LAYER OPTICAL ATTENUATION AND EMISSION SPECTROSCOPY MEASUREMENTS DURING ARC JET TESTING WITH ABLATING MODELS

SHOCK LAYER OPTICAL ATTENUATION AND EMISSION SPECTROSCOPY MEASUREMENTS DURING ARC JET TESTING WITH ABLATING MODELS

Measurements of optical attenuation and emission spectra for the radiating bow shock region upstream of several ablating arc jet test models are reported. Attenuation measurements were intended to assess light transmission parallel to the model face at k633 nm by the shock layer formed over the ablating surface; the attenuation is attributed to the presence of particles. As the models ablated, the surface receded, effectively translating the detection line of sight upstream from the model surface. Substantial loss of transmission correlated with the macroscopic ablation and surface heating rates, and persisted upstream of the shock front. Simultaneously, optical emission spectra were measured in the same plane as the attenuation laser. These measurements were intended to determine the extent to which ablation products (particles or vapor) influence the bow shock radiation. The spectra were measured rapidly using miniature fixed-grating spectrometers with fiber optic input. With a field of view of 2 mm and acquisition time less than 100 ms, spatial resolution was retained and time dependent intensity trends were observed. Several components of dissociated air can be identified based on their spectral signatures; the radiative contribution by ablation products appears minor, however.

David M. Driver | D. Driver | George A. Raiche | G. Raiche

[1] Douglas G. Fletcher,et al. Spectroscopic measurements of shock-layer flows in an arcjet facility , 1999 .

[2] S. Langhoff,et al. Spectroscopic Measurement of the Flows in an Arc-Jet Facility , 1998 .

[3] Karen J. Olsen,et al. NIST Atomic Spectra Database (version 2.0) , 1999 .

[4] Chul Park. Interaction of Spalled Particles with Shock Layer Flow , 1999 .

[5] David M. Driver,et al. Radiation of Spalled Particles in Shock Layers , 2004 .

[6] Daniel J. Rasky,et al. Phenolic Impregnated Carbon Ablators (PICA) as Thermal Protection Systems for Discovery Missions , 1997 .

[7] A. G. Gaydon,et al. The identification of molecular spectra , 1950 .

[8] Douglas G. Fletcher,et al. Arcjet flow properties determined from laser-induced fluorescence of atomic nitrogen , 1999 .

[9] J. Jeffries,et al. Optical diagnostics for temperature measurement in a DC arcjet reactor used for diamond deposition , 1997 .

[10] Charles H. Kruger,et al. Arrays of radiative transition probabilities for the N2 first and second positive, no beta and gamma, N+2 first negative, and O2 Schumann-Runge band systems , 1992 .

[11] D. Driver,et al. Comparison of Enthalpy Determination Methods for an Arc-Jet Facility , 2004 .

[12] Aliza Balter-Peterson,et al. Arc jet testing in NASA Ames Research Center thermophysics facilities , 1992 .