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Energie

Direct and Simultaneous Measurement of Wall-Heat Flux and Temperature in a Shock Tube by Atomic Layer Thermopiles

Autoren

Claudia Hofmann
C.Hofmann@haw-landshut.de
Simon Kaneider
Simon.Kaneider@haw-landshut.de
Prof. Dr.-Ing. Tim Rödiger
Tim.Roediger@haw-landshut.de
Prof. Dr.-Ing. Ralf Brederlow
Jan-Erik Brune
Lukas Jakobs
Tobias Sander
Christian Mundt

Veröffentlichungsjahr

2025

Veröffentlichungsart

Beiträge in Monografien, Sammelwerken und Schriftenreihen

DOI

https://doi.org/10.2514/6.2025-1629

Zitierung

Hofmann, Claudia; Kaneider, Simon; Roediger, Tim; Brederlow, Ralf; Brune, Jan-Erik; Jakobs, Lukas; Sander, Tobias; Mundt, Christian (2025): Direct and Simultaneous Measurement of Wall-Heat Flux and Temperature in a Shock Tube by Atomic Layer Thermopiles. DOI: 10.2514/6.2025-1629

Energie

Direct and Simultaneous Measurement of Wall-Heat Flux and Temperature in a Shock Tube by Atomic Layer Thermopiles

Abstract

This study focuses on the static and dynamic analysis and calibration experiments of Atomic Layer Thermopile (ALTP) sensors exposed to a traveling shock wave at the side and end wall of a shock tube. A newly developed methodology allows direct and simultaneous measurement of heat-flux density and temperature in ALTPs. The heat flux at the end wall of the shock tube is directly measured by an ALTP-sensor and is compared with analytical end-wall solutions. The analytical heat-flux progression is derived from estimations for post-reflected shock conditions based on the pressure data and 1-D computations. The experimental data compare well with the time-invariant analytically-determined heat-flux progression for lowand high-pressure conditions. In addition, the dynamic response of heat flux as well as of temperature is investigated: ALTP-sensor response on the side wall compares well with optical dynamic calibration results. The response of the end-wall sensor significantly underestimates the optically predicted response times. For the first time, the dynamic response of ALTP temperature data could be investigated in short-duration shock tube experiments and compared with coaxial thermocouple readings.