Robert Salko scite author profile

The critical heat flux (CHF) corresponding to the departure from nucleate boiling (DNB) crisis is essential to the design and safety of a two-phase flow boiling system. Despite the abundance of predictive tools available to the thermal engineering community, the path for an accurate, robust CHF model remains elusive due to lack of consensus on the DNB triggering mechanism. This work aims to apply a physics-informed, machine learning (ML)-aided hybrid framework to achieve superior predictive capabilities. Such a hybrid approach takes advantage of existing understanding in the field of interest (i.e., domain knowledge) and uses ML to capture undiscovered information from the mismatch between the actual and domain knowledge-predicted target. A detailed case study is carried out with an extensive DNB-specific CHF database to demonstrate (1) the improved performance of the hybrid approach as compared to traditional domain knowledge-based models, and (2) the hybrid model's superior generalization capabilities over standalone ML methods across a wide range of flow conditions. The hybrid framework could also readily extend its applicability domain and complexity on the fly, showing an elevated level of flexibility and robustness. Based on the case study conclusions, the window-type extrapolation mapping methodology is further proposed to better inform high-cost experimental work. Keywords: critical heat flux, departure from nucleate boiling, hybrid framework, machine learning, domain knowledge. API application programming interface CHF critical heat flux DK domain knowledge DNB departure from nucleate boiling EPRI Electric Power Research Institute LUT look-up table MAE mean absolute error ML machine learning MSE mean squared error NN (feed-forward) neural network PWR pressurized water reactor ReLU rectified linear unit RF random forest rRMSE relative root-mean-square error

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Coupling of CTF and TRANSFORM using the Functional Mockup Interface

Gurecky

Wet

Greenwood

et al. 2020

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CTF 4.0 Theory Manual

Salko¹,

Avramova

Wysocki³

et al. 2019

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Coolant-Boiling in Rod Arrays-Two Fluids (COBRA-TF) is a thermal/hydraulic (T/H) simulation code designed for light water reactor (LWR) vessel analysis. It uses a two-fluid, three-field (i.e. fluid film, fluid drops, and vapor) modeling approach. Both sub-channel and 3D Cartesian forms of 9 conservation equations are available for LWR modeling. The code was originally developed by Pacific Northwest Laboratory in 1980 and had been used and modified by several institutions over the last few decades.COBRA-TF also found use at the Pennsylvania State University (PSU) by the Reactor Dynamics and Fuel Modeling Group (RDFMG) and has been improved, updated, and subsequently re-branded as CTF. As part of the improvement process, it was necessary to generate su cient documentation for the open-source code which had lacked such material upon being adopted by RDFMG. This document serves mainly as a theory manual for CTF, detailing the many two-phase heat transfer, drag, and important accident scenario models contained in the code as well as the numerical solution process utilized. Coding of the models is also discussed, all with consideration for updates that have been made when transitioning from COBRA-TF to CTF. Further documentation outside of this manual is also available at RDFMG which focus on code input deck generation and source code global variable and module listings.

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Robert Salko

VERA Core Simulator Methodology for Pressurized Water Reactor Cycle Depletion

CTF Validation and Verification Manual

On the prediction of critical heat flux using a physics-informed machine learning-aided framework

Coupling of CTF and TRANSFORM using the Functional Mockup Interface

CTF 4.0 Theory Manual

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