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Comparison between deep learning and fully connected neural network in performance prediction of power cycles: Taking supercritical CO <sub>2</sub> Brayton cycle as an example

Chenghao Diao, Tianye Liu, Zhen Yang, Yuanyuan Duan

2021International Journal of Intelligent Systems13 citationsDOI

Abstract

AI is becoming increasingly important in promoting the energy revolution of carbon-neutral to achieve sustainable development. Induced by the large implementation of renewable energy, the more complexities and uncertainties in the future carbon-neutral energy systems make their designs hard accessible to the conventional methods, so machine learning (ML) especially the neural network becomes under focus. Here, we design a deep learning architecture based on convolutional neural networks (DL-CNN) known for its powerful predicting ability, and first utilize it in a case study of performance prediction of supercritical CO2 Brayton cycle. The design paradigm of DL-CNN architecture for performance prediction of power cycle is proposed. We also summarize the commonly used fully connected neural network (FC-NN) in related studies of power cycle design. Through systematically comparing the prediction performance of DL-CNN and FC-NN, their respective advantages and application scenarios in energy system design are discussed. In addition, a multiobjective design approach based on DL-CNN combined with random search is proposed and proved to be feasible by comparing with genetic algorithm. The results show that our proposed DL-CNN model is much more competitive than FC-NN model when the training data is sufficient and the prediction condition is complex, in which the prediction accuracy can achieve 99.6%. In the future, our deep learning model may help solve the complex design problems of hybrid carbon-neutral energy systems.

Topics & Concepts

Brayton cycleComputer scienceDeep learningArtificial neural networkArtificial intelligenceConvolutional neural networkMachine learningEnergy (signal processing)Power (physics)MathematicsStatisticsQuantum mechanicsPhysicsThermodynamic and Exergetic Analyses of Power and Cooling SystemsAdvanced Thermodynamics and Statistical MechanicsSolar Thermal and Photovoltaic Systems