Ultrasonic measurement of temperature distributions in extreme environments: Electrical power plants testing in utility-scale steam generators

Mason John; Kenneth Walton; Daniel Kinder; Michael A Dayton; Mikhail Skliar

doi:10.1016/j.ultras.2023.107205

Ultrasonic measurement of temperature distributions in extreme environments: Electrical power plants testing in utility-scale steam generators

Ultrasonics. 2024 Mar:138:107205. doi: 10.1016/j.ultras.2023.107205. Epub 2023 Nov 22.

Authors

Mason John¹, Kenneth Walton¹, Daniel Kinder², Michael A Dayton³, Mikhail Skliar⁴

Affiliations

¹ Department of Chemical Engineering, University of Utah, 50 S Central Campus Dr., Salt Lake City, UT, USA.
² Rocky Mountain Power, 1407 W North Temple, Salt Lake City, UT, USA.
³ Rocky Mountain Power, 1407 W North Temple, Salt Lake City, UT, USA; Currently with Seminole Electric Cooperative, 16313 N Dale Mabry Highway, Tampa, FL, USA.
⁴ Department of Chemical Engineering, University of Utah, 50 S Central Campus Dr., Salt Lake City, UT, USA. Electronic address: misha@chemeng.utah.edu.

PMID: 38000096
DOI: 10.1016/j.ultras.2023.107205

Abstract

Thermal heterogeneities within energy conversion and storage, material processing, nuclear processes, aerospace, and military applications are often inaccessible to characterization by insertion sensors. When sensor deployment is possible, conventional pointwise temperature probes quickly degrade when inserted into harsh environments typical of such processes. We developed spatially-resolved ultrasonic thermometry to noninvasively measure the spatial distributions of thermal properties in such applications, even when sizable thermal gradients are present. Our method divides the path of ultrasonic propagation into segments bound by echogenic features, which create echoes in pulse-echo mode, encoding the information about interior temperature distributions. We use the acquired ultrasonic responses to estimate the internal temperature distributions by solving an inverse problem or concatenating segmental estimates. This work describes the implementation and industrial testing of the developed method at a coal-fired electrical power generation plant. We inserted an echogenically segmented Inconel 625 waveguide into the combustion zone of the utility-scale boiler and continuously acquired ultrasonic data while keeping sensitive components away from the damaging combustion environment. The accuracy of the time-dependent temperature distributions reconstructed from the ultrasonic measurements was comparable to that of thermocouples. The resiliency of ultrasonic thermometry to harsh combustion conditions was far superior to conventional insertion sensors. The measurements obtained during plant operation captured daily steam generation cycles in response to changing customer demand and intermittent contributions of renewable power sources to the power grid. These measurements have revealed new insights into the relationship between the dynamic power generation load and the conditions inside the steam generator. The successful industrial testing of spatially-resolved ultrasonic thermometry in solids indicates that the developed technology has matured to become an attractive alternative to conventional sensing in solving challenging problems of long-term thermal characterizations in extreme environments.

Keywords: Extreme environments; Industrial testing; Ultrasonic thermometry; Utility boilers.