Combinatory Finite Element and Artificial Neural Network Model for Predicting Performance of Thermoelectric Generator

Kishore, Ravi Anant; Mahajan, Roop L.; Priya, Shashank

doi:10.3390/en11092216

Cited by 35 publications

(21 citation statements)

References 52 publications

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“…In addition to that, having a deep network structure (i.e., many hidden layers) does not necessarily require any laborious feature selection and can work with raw data [29]. FE-based ANN models have been utilized for predicting stress distribution in a 3D printing process [30], bend angles in laser-guided bending [31], and performance of a thermoelectric generator [32], for example.…”

Section: Data-driven Surrogate Modelsmentioning

confidence: 99%

Surrogate Modeling of Electrical Machine Torque Using Artificial Neural Networks

et al. 2020

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Section: Data-driven Surrogate Modelsmentioning

confidence: 99%

Surrogate Modeling of Electrical Machine Torque Using Artificial Neural Networks

et al. 2020

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“…• "Comparison of different solar-assisted air conditioning systems for Australian office buildings" with 11 citations [77]. • "Combinatory finite element and artificial neural network model for predicting performance of thermoelectric generator" with three citations [78].…”

Section: Conversion Of Thermal/electrical Energy Communitymentioning

confidence: 99%

“…The main drawback is that the heat-to-electricity conversion efficiency of thermoelectric generators (TEG) is up to 11% in laboratory environments; it is much lower in practice. In [78] they propose a model based on artificial neural networks that can predict the performance of an TEG on demand. The model evaluated predicts the performance of an EEG at 26.4 ms per data point compared to the 6.0 min required in traditional simulations.…”

Section: Conversion Of Thermal/electrical Energy Communitymentioning

confidence: 99%

Energies and Its Worldwide Research

et al. 2020

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Energy efficiency and management is certainly one of the key drivers of human progress. Thus, the trends in the energy research are a topic of interest for the scientific community. The aim of this study is to highlight global research trends in this field through the analysis of a scientific journal indexed exclusively in the energy and fuels category. For this purpose, a journal has been selected that is in the center of the category considering its impact factor, which is only indexed in this category and of open access, Energies of the publisher MDPI. Therefore, a bibliometric analysis of all the contents of the journal between 2008 and 2020, 13,740 documents published, has been carried out. Analyzing the articles that are linked to each other by their citations, 14 clusters or research topics have been detected: smart grids; climate change–electric energy community; energy storage; bioenergy sources; prediction algorithms applied to power; optimization of the grid link for renewable energy; wind power; sustainability of power systems; hydrocarbon improvements; conversion of thermal/electrical energy; electric motor advancements; marine renewable energy; hydropower and energy storage; and preventive techniques in power transformers. The main keywords found were electric vehicle, renewable energy, microgrid, smart grid, and energy efficiency. In short, energy research remains necessary to meet the future challenge of sustainable energy with high efficiency and the exploration of new renewable resources, all for increasingly sustainable cities.

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“…Their results show that the employment of an appropriate ANN would be a time-effective operating method of a photovoltaic thermal hybrid system without any complex analysis and calculations; however, the scope of their study deviated from the application of ANNs to TEGs operating under various exhaust heat conditions. Kishore et al [14] suggested a finite element-ANN combined model for predicting the performance of a TEG with a high degree of accuracy. They investigated the accuracy of the ANN while varying the design parameters of a single TEM, including the length of the nand p-type thermoelectric legs, cross-sectional area of the legs, and external load resistance.…”

Section: Introductionmentioning

confidence: 99%

Prediction of System-Level Energy Harvesting Characteristics of a Thermoelectric Generator Operating in a Diesel Engine Using Artificial Neural Networks

Kim

2021

Energies

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This study evaluated the potential of artificial neural networks (ANNs) to predict the system-level performance of a thermoelectric generator (TEG), whose performance depends on various variables including engine load, engine rotation speed, and external load resistance. Therefore, a Python code was developed to determine an optimal ANN structure by tracking the training/prediction errors of the ANN as a function of the number of hidden layers and nodes of hidden layers. The optimal ANN was trained using 484 output current (I)–load resistance (R) datasets obtained under three different engine rotation speeds and five different engine loads. The prediction accuracy of the ANN was validated by comparing 88 I–R datasets reproduced by the ANN using experimental data that were not used for training. In the validation procedure, differences of only 3.49% and 2.59% were observed in the experimental and ANN-predicted output power obtained for the 1000 rpm–0.8 MPa brake mean effective pressure (BMEP) and 1500 rpm–0.4 MPa BMEP scenarios, respectively. The exhaust gas flow characteristics were used for training and validation to predict the pumping loss caused by the installation of the TEG in the middle of the exhaust tailpipe with high accuracy. The results demonstrated that the ANN effectively reproduced datasets to fill the gaps between the discretized experimental results for all the experimental scenarios without any noticeable overfitting and underfitting. The net power gain obtained by the ANN exhibited a clear peak point for the engine rotation speed of 2000 rpm, which is difficult to obtain using experimental data.

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Combinatory Finite Element and Artificial Neural Network Model for Predicting Performance of Thermoelectric Generator

Cited by 35 publications

References 52 publications

Surrogate Modeling of Electrical Machine Torque Using Artificial Neural Networks

Surrogate Modeling of Electrical Machine Torque Using Artificial Neural Networks

Energies and Its Worldwide Research

Prediction of System-Level Energy Harvesting Characteristics of a Thermoelectric Generator Operating in a Diesel Engine Using Artificial Neural Networks

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