FEM-Based Power Transformer Model for Superconducting and Conventional Power Transformer Optimization

Orosz, Tamás

doi:10.3390/en15176177

Cited by 10 publications

(7 citation statements)

References 50 publications

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“…Because of this, the loss due to circulating currents between the parallel coil paths was considered negligible, as was the case in the work of Widmer et al [83]. The eddy current loss can be more precisely approximated by the axial (B ax ) and radial (B rad ) components of magnetic induction when using the FEM-based magnetic field calculations that were presented in [84,85]. The axial and radial components of the eddy current loss for rectangular-shaped conductors are shown in Equations ( 19) and (20).…”

Section: The Rewinding Process Of the Electric Machinementioning

confidence: 99%

Remanufacturing a Synchronous Reluctance Machine with Aluminum Winding: An Open Benchmark Problem for FEM Analysis

Katona,

Bányai,

Németh

et al. 2024

Electronics

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The European Union’s increasing focus on sustainable and eco-friendly product design has resulted in significant pressure on original equipment manufacturers to adopt more environmentally conscious practices. As a result, the remanufacturing of end-of-life electric machines is expected to become a promising industrial segment. Identifying the missing parameters of these types of machines will play an essential role in creating feasible and reliable redesigns and remanufacturing processes. A few case studies related to this problem have been published in the literature; however, some novel, openly accessible benchmark problems can facilitate the research and function as a basis for comparing and validating novel numerical methods. This paper presents the identification process of an experimental synchronous machine. It outlines methodologies for identifying material properties, winding schemes, and other critical parameters for the finite element analysis and modelling of electric machines with incomplete information. The machine in question is intended for remanufacturing, with the plan to replace its faulty winding with an aluminium-based alternative. It also serves as an open benchmark problem for researchers, designers, and practitioners.

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Section: The Rewinding Process Of the Electric Machinementioning

confidence: 99%

Remanufacturing a Synchronous Reluctance Machine with Aluminum Winding: An Open Benchmark Problem for FEM Analysis

Katona,

Bányai,

Németh

et al. 2024

Electronics

Self Cite

View full text Add to dashboard Cite

show abstract

“…AC loss depends on several factors, including conductor dimensions, frequency, and amplitude of the magnetic field [146,147]. For a more precise estimation of the eddy current loss, FEM-based magnetic field calculations are used, which consider both the axial (B ax ) and radial (B rad ) components of magnetic induction [148,149]. The axial and radial components of the eddy current loss for rectangular-shaped conductors can be found in Equations ( 3) and ( 4).…”

Section: Ecological Aspects Of Aluminium and Copper Windingsmentioning

confidence: 99%

Circular Economy Aspects of Permanent Magnet Synchronous Reluctance Machine Design for Electric Vehicle Applications: A Review

Katona,

Orosz

2024

Energies

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Innovative technological solutions have become increasingly critical in addressing the transportation sector’s environmental impact. Passenger vehicles present an opportunity to introduce novel drivetrain solutions that can quickly penetrate the electric vehicle market due to their shorter development time and lifetime compared to commercial vehicles. As environmental policy pressure increases and customers demand more sustainable products, shifting from a linear business approach to a circular economy model is in prospect. The new generation of economically competitive machines must be designed with a restorative intention, considering future reuse, refurbishment, remanufacture, and recycling possibilities. This review investigates the market penetration possibilities of permanent magnet-assisted synchronous reluctance machines for mini and small-segment electric vehicles, considering the urban environment and sustainability aspects of the circular economy model. When making changes to the materials used in an electric machine, it is crucial to evaluate their potential impact on efficiency while keeping the environmental impact of those materials in mind. The indirect ecological effect of the vehicle’s use phase may outweigh the reduction in manufacturing and recycling at its end-of-life. Therefore, thoroughly analysing the materials used in the design process is necessary to ensure maximum efficiency while minimising the environmental impact.

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“…Finite element method (FEM) is a robust method for solving electromagnetic problems [7], [8] including highly superior numerical accuracy in complex phenomena and electromagnetic field distribution analysis [9], [10]. In addition, FEM can directly obtain the result while avoiding complex modeling processes [11].…”

Section: Introductionmentioning

confidence: 99%

Analysis of Transformer No-Load Loss Using Finite Element Method Validated by Experimental Tests

Hashemi,

Taheri,

Jozi

2024

Preprint

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Transformers are one of the most critical components of electricity networks, with no-load loss as an essential technical characteristic, which plays a major role in its performance indicators. Transformer no-load loss must be determined precisely before being manufactured. They allow the development of computer programs and the faster and more accurate solution of electromagnetic problems with complex structures and boundary conditions without requiring prototyping. The Finite Element Method (FEM) is among the most popular and robust numerical methods used to solve electromagnetic field problems. This paper aimed to evaluate no-load loss in 1000 and 1600 kVA transformers while considering nonlinear magnetic characteristics by FEM and Ansys Maxwell software. Core magnetic characteristics were obtained directly from experimental tests. The results were verified by the no-load loss test in the studied transformers in a high-voltage laboratory. A comparison between simulation results with high-voltage laboratory results indicated that the simulation error in calculating no-load loss in 1000 and 1600 kVA transformers was less than 1%.

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FEM-Based Power Transformer Model for Superconducting and Conventional Power Transformer Optimization

Cited by 10 publications

References 50 publications

Remanufacturing a Synchronous Reluctance Machine with Aluminum Winding: An Open Benchmark Problem for FEM Analysis

Remanufacturing a Synchronous Reluctance Machine with Aluminum Winding: An Open Benchmark Problem for FEM Analysis

Circular Economy Aspects of Permanent Magnet Synchronous Reluctance Machine Design for Electric Vehicle Applications: A Review

Analysis of Transformer No-Load Loss Using Finite Element Method Validated by Experimental Tests

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