Improvement in Efficiency of Converter Transformer by The Reduction of Stray Losses

Kothavade, Jayesh; Kundu, Prasanta

doi:10.24840/2183-6493_009-003_001600

Cited by 2 publications

(1 citation statement)

References 18 publications

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“…The impedance matching circuit developed is in the form of an air core transformer. The value of the coupling coefficient possessed by the air core transformer can be known by using equations ( 8) and ( 9) with the secondary coil radius (a) which is 0.021 m, the primary coil radius (b) which is 0.031 m, and the distance between the center of the first winding of the primary coil and the distance between the center of the first winding of the secondary coil (d) is 0.05 m. The coupling coefficient of the air core transformer is shown in equation ( 8) [18].…”

Section: Figure 1 Class E Amplifier Topologymentioning

confidence: 99%

Development of RF plasma generator based on Class E Power Amplifier

Putro,

Dwiyanto,

Anggraeni

et al. 2024

J. Phys.: Conf. Ser.

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The plasma produced at 2 MHz radio frequency has substantial energy release stability and can be used to modify a material’s surface. The objective of this research is to create a plasma generator operating at a radio frequency of 2 MHz and examine how voltage affects the plasma spectrum that is generated. An AD9833 frequency generator, a class E amplifier, and impedance matching are used in the design of a 2 MHz radio frequency plasma generator as power amplifiers to create plasma. Variations in voltage, gas, and gas flow have been used. The input voltage variations used were 10V and 15V from the power supply. Two different media, free air (atmospheric gas) and argon gas flow, are used for plasma generation. In free air, the plasma formed is Nitrogen plasma with a wavelength of 300 to 380 nm. Argon gas flow is given a variation of Argon gas rate of 2 LPM, and 3 LPM. The plasma formed is Argon plasma with a wavelength of 700 to 850 nm.

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Section: Figure 1 Class E Amplifier Topologymentioning

confidence: 99%

Development of RF plasma generator based on Class E Power Amplifier

Putro,

Dwiyanto,

Anggraeni

et al. 2024

J. Phys.: Conf. Ser.

View full text Add to dashboard Cite

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Determining the Positions and Dimensions of Horizontal Magnetic Shunts in Transformer Tank Walls Using Parametric Analyses Based on the Finite Element Method

Çeçen,

Gümüş,

Hazar

2024

Applied Sciences

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Magnetic shunts efficiently mitigate losses caused by leakage currents in the tank walls of power transformers. Transformer manufacturers frequently utilize vertical magnetic shunts positioned on the inside surfaces of the transformer tank walls. This study investigated the optimum use of horizontal shunts in a power transformer. A 50 MVA power transformer, manufactured on a commercial scale and featuring optimized vertical magnetic shunts integrated into the wall structure, was analyzed using the 3D finite element method for 100 ms at full load. Simulations for analyses were performed using a commercial ANSYS Electronics Desktop 2021 R1 FEM software program. The model’s validity was demonstrated by verifying the analysis results with experimental tank loss values. Tank loss samples were obtained by analyzing the transformer tank for two milliseconds with vertical magnetic shunts only on the long front wall and the short side wall. Using these loss samples as a reference, parametric analyses were performed for two milliseconds with horizontal magnetic shunts only on the short side wall and only on the long front wall of the tank. A tank model with horizontal magnetic shunts of an appropriate location and size was obtained via the parametric analyses. This model was analyzed for 100 milliseconds at full load and compared with the experimental results of the transformer manufacturer’s vertical magnetic shunt transformer. According to the results, a saving of 25.83% was achieved in the horizontal magnetic shunt volume compared with the vertical magnetic shunt volume. The maximum magnetic flux density was lower in the horizontal magnetic shunts, and the maximum current density was lower in the transformer tank with horizontal magnetic shunts.

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Improvement in Efficiency of Converter Transformer by The Reduction of Stray Losses

Cited by 2 publications

References 18 publications

Development of RF plasma generator based on Class E Power Amplifier

Development of RF plasma generator based on Class E Power Amplifier

Determining the Positions and Dimensions of Horizontal Magnetic Shunts in Transformer Tank Walls Using Parametric Analyses Based on the Finite Element Method

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