Intelligence modeling of the flow boiling heat transfer of nanorefrigerant for integrated energy system

Songyuan Zhang; Songyuan Zhang; Yuexiwei Li; Yuexiwei Li; Zheng Xu; Zheng Xu; Lei Ma; Lei Ma; Yongjia Li; Yongjia Li

doi:10.3389/fenrg.2024.1412538

Frontiers in Energy Research (Apr 2024)

Intelligence modeling of the flow boiling heat transfer of nanorefrigerant for integrated energy system

Songyuan Zhang,
Songyuan Zhang,
Yuexiwei Li,
Yuexiwei Li,
Zheng Xu,
Zheng Xu,
Lei Ma,
Lei Ma,
Yongjia Li,
Yongjia Li

Affiliations

Songyuan Zhang: Yunnan International Joint Research and Development Center of Green Energy Storage Material Industrial Chain Coupled with Digital Twin Technology, Kunming Metallurgy College, Kunming, China
Songyuan Zhang: Faculty of Metallurgical and Mining, Kunming Metallurgy College, Kunming, China
Yuexiwei Li: Yunnan International Joint Research and Development Center of Green Energy Storage Material Industrial Chain Coupled with Digital Twin Technology, Kunming Metallurgy College, Kunming, China
Yuexiwei Li: Faculty of Metallurgical and Mining, Kunming Metallurgy College, Kunming, China
Zheng Xu: Yunnan International Joint Research and Development Center of Green Energy Storage Material Industrial Chain Coupled with Digital Twin Technology, Kunming Metallurgy College, Kunming, China
Zheng Xu: Faculty of Metallurgical and Mining, Kunming Metallurgy College, Kunming, China
Lei Ma: Yunnan International Joint Research and Development Center of Green Energy Storage Material Industrial Chain Coupled with Digital Twin Technology, Kunming Metallurgy College, Kunming, China
Lei Ma: Faculty of Metallurgical and Mining, Kunming Metallurgy College, Kunming, China
Yongjia Li: Yunnan International Joint Research and Development Center of Green Energy Storage Material Industrial Chain Coupled with Digital Twin Technology, Kunming Metallurgy College, Kunming, China
Yongjia Li: Faculty of Metallurgical and Mining, Kunming Metallurgy College, Kunming, China

DOI: https://doi.org/10.3389/fenrg.2024.1412538
Journal volume & issue: Vol. 12

Abstract

Read online

To promote the application of nanorefrigerant in Organic Rankine Cycle and Integrated Energy System a reliable model with simple structure and favorable accuracy for predicting the flow boiling heat transfer coefficient (HTC) of nanorefrigerant is essential. In this work, four intelligence models—the radial basis function (RBF), multilayer perceptron (MLP), least squares support vector machine (LSSVM), and adaptive neuro fuzzy inference system (ANFIS)—were developed to predict the flow boiling heat transfer coefficient using nanorefrigerants, based on 765 experimental samples. The performances of these artificial intelligence models were comprehensively evaluated through accuracy analysis, variation trend analysis, and sensitivity analysis. Results indicated that the comprehensive performance of the RBF model was superior than those of other intelligence models and the existing empirical models. The RBF model accurately captured the variation trend of the output as the input variables were varied. Meanwhile, the impact degrees of all input variables in decreasing order were nanoparticle concentration (φ), mass flux (G), thermal conductivity of nanoparticle (kp), and vapor quality (x).

Published in Frontiers in Energy Research

ISSN: 2296-598X (Online)
Publisher: Frontiers Media S.A.
Country of publisher: Switzerland
LCC subjects: General Works
Website: https://www.frontiersin.org/journals/energy-research

About the journal

Abstract

Keywords