Abstract
Chirped fiber Bragg grating (CFBG) sensors coupled to high speed interrogation systems are described as robust diagnostic approaches to monitoring shock wave and detonation front propagation tracking events for use in high energy density shock physics applications. Taking advantage of the linear distributed spatial encoding of the spectral band in single-mode CFBGs, embedded fiber systems and associated photonic interrogation methodologies are shown as an effective approach to sensing shock and detonation-driven loading processes along the CFBG length. Two approaches, one that detects spectral changes in the integrated spectrum of the CFBG and another coherent pulse interrogation approach that fully resolves its spectral response, shows that 100-MHz–1-GHz interrogation rates are possible with spatial resolution along the CFBG in the 50 m to sub-millimeter range depending on the combination of CFBG parameters (i.e., length, chirp rate, spectrum) and interrogator design specifics. Results from several dynamic tests are used to demonstrate the performance of these high speed systems for shock and detonation propagation tracking under strong and weak shock pressure loading: (1) linear detonation front tracking in the plastic bonded explosive (PBX) PBX-9501; (2) tracking of radial decaying shock with crossover to non-destructive CFBG response; (3) shock wave tracking along an aluminum cylinder wall under weak loading accompanied by dynamic strain effects in the CFBG sensor.
Highlights
Over the last five years, we have concentrated on developing and applying high-speed fiberBragg grating (FBG) sensor interrogation approaches to shock wave and high explosive detonation front tracking for experimental situations where continuous position monitoring of the propagating disturbance is monitored along the length of a chirped fiberBragg grating (FBG) (CFBG) [1,2,3,4]
Bragg grating (FBG) sensor interrogation approaches to shock wave and high explosive detonation front tracking for experimental situations where continuous position monitoring of the propagating disturbance is monitored along the length of a chirped FBG (CFBG) [1,2,3,4]
The goal of this paper is to introduce the researcher to CFBG-based shock wave and detonation front fiber sensing and to describe the current approaches, interrogation systems and sensor characteristics available for use under this purpose
Summary
Bragg grating (FBG) sensor interrogation approaches to shock wave and high explosive detonation front tracking for experimental situations where continuous position monitoring of the propagating disturbance is monitored along the length of a chirped FBG (CFBG) [1,2,3,4]. With the use of coherent pulsed ultrafast laser-based FBG interrogation systems [5,6,7], full spectral readout of uniform non-chirped FBG sensors at 100-MHz interrogation rates has been demonstrated as a valuable diagnostic for high speed strain and pressure measurement for dynamic materials under sub-microsecond loading conditions. 100 mm-long C- and L-band CFBGs on a single fiber, continuous tracking of shock or detonation wave propagation out to 200 mm in length is possible.
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