Temperature measurement techniques for gas and liquid flows using thermographic phosphor tracer particles

Optical diagnostics for fluid temperature measurements continue to further our understanding of flows involving heat transfer and/or chemical reactions, which are intrinsic to key areas including energy production, the process industries, transportation, heating/cooling systems and naturally-occurring thermal convection. Besides temperature, all flows must also be described by their velocity. As these flows are often turbulent, an important capability is to measure both velocity and temperature at the same time to capture, for example, the turbulent heat flux term appearing in the energy conservation equation. This paper reviews temperature measurement techniques for fluid flows that are based on thermographic phosphors, which are materials that possess temperature-dependent luminescence properties. Phosphor particles are seeded into the fluid flow of interest. Following laser excitation, the luminescence of the particles is detected, and the temperature measurement is derived using either the spectral intensity ratio or the lifetime. The same particles can also be used for velocity measurements using well-established particle based approaches, such as laser Doppler velocimetry (LDV) or particle image velocimetry (PIV), producing instantaneously correlated vector-scalar data. First introduced over a decade ago, this concept has since evolved and is currently capable of two-dimensional measurements in the temperature range 200-900 K. At lower temperatures a single-shot spatial precision better than 4 K is possible, as is imaging at sampling rates in the multi-kHz range. The approach is flexible, allowing, for example, techniques which probe single particles for point measurements with a 200 p m spatial resolution. Besides many validation experiments, the method has been applied in internal combustion engines, a falling film absorber, a high-pressure reaction vessel and in enclosed wind tunnels to study various turbulent heat transfer and reactive flow phenomena. The objective of this article is to provide the first review of this emerging field. The focus is on 1) the method: how has the principle of phosphor thermometry been used for flow measurements, and what instrumentation and processing steps were implemented; 2) how phosphor particles were characterised, and which phosphors are best-suited to temperature measurements in flows; and 3) the applications of the technique. Throughout, and with a detailed analysis of various sources of error, the review endeavours to compare the work and identify common aspects, advantages and limitations of the studies that led to successful flow measurements, and therefore should serve as a guide for researchers using the method. The article also briefly summarises the various challenges which the authors consider are key to the future development of these diagnostics. (C) 2017 The Authors. Published by Elsevier Ltd.