Time in DNB experimental study on Cr coated zircaloy cladding

•Detailed temperature measurements for several times in DNB.•Post-CHF/rewetting details were captured with novel optical fiber data.•Critical heat flux at prototypic reactor conditions on Cr coated zircaloy.•Cr coated zircaloy withstand temperatures above 800 °C during DNB.•Minimum film boiling temp...

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Bibliographic Details
Published in:Applied thermal engineering 2024-07, Vol.248, p.123266, Article 123266
Main Authors: Moreira, Tiago A., Murray, Keegan D., Conner, Michael E., Sung, Yixing, Walters, Jorie, Maier, Benjamin R., Wood, Carrie, Broach, Kirkland D., Karoutas, Zeses, Anderson, Mark H.
Format: Article
Language:English
Subjects:
ATF materials
Critical Heat Flux
Minimum Film Boiling Temperature
PWR conditions
Rewet
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Summary:•Detailed temperature measurements for several times in DNB.•Post-CHF/rewetting details were captured with novel optical fiber data.•Critical heat flux at prototypic reactor conditions on Cr coated zircaloy.•Cr coated zircaloy withstand temperatures above 800 °C during DNB.•Minimum film boiling temperature data obtained during rewet. Since the Fukushima-Daiichi accident effort has been put in by the nuclear community to develop Accident Tolerant Fuel (ATF) cladding materials to reduce the risk of clad oxidation and, consequently, hydrogen generation and potential major accidents. Among designed materials, the use of a chromium coating on top of zirconium-alloy cladding showed reasonable results in preliminary tests, being a favorable cladding solution for Pressurized Water Reactors. This paper provides highly detailed temperature data obtained during time in departure from nucleate boiling (DNB) experiments under prototypical reactor conditions of temperature, pressure, mass flux, and heat flux profile on a Cr-coated zirconium-alloy cladded heater rod simulating the fuel pin. Data were obtained at mass fluxes from 1300 to 1700 kg/m2s, pressure of 16 MPa, and inlet temperature of 333 °C (subcooling degree of 14.4 °C). The change in dry time was obtained by increasing the spike in wall temperature necessary to shut down the power. These tests showed that increasing the spike in temperature to characterize the critical heat flux from 50 °C to 400 °C resulted in variations of the departure from nucleate boiling measured value within the uncertainty range of their measurements, hence, validating the use of a spike of 50 °C, a commonly used value in this kind of study, as an indicator of the critical heat flux. Within the dry region, the temperature was found to increase along the direction of the flow for a very short length, reaching a peak, from which it reduces linearly until the surface reaches a temperature that is no longer able to sustain a dry patch. It was noticed that the dry region can grow against the flow direction due to the cosine profile of the heat flux, and that small dryout events can occur without leading to departure from nucleate boiling, i.e., being fully suppressed. However, two consecutive events may sum up and cause the critical heat flux. Rewet time was found to increase with peak cladding temperature and decrease with mass flux. A maximum peak cladding temperature of 844 °C was found, with the surface remaining dry for approximately
ISSN:1359-4311
DOI:10.1016/j.applthermaleng.2024.123266