Contactless measurement of electric current using magnetic sensors

Ripka, Pavel

doi:10.1515/teme-2019-0032

Cited by 22 publications

(9 citation statements)

References 99 publications

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“…Research has been done on various current sensing techniques for a wide range of applications [23,[285][286][287]. Many of these techniques can be used for IBSs in EVs.…”

Section: Currentmentioning

confidence: 99%

Critical Review of Intelligent Battery Systems: Challenges, Implementation, and Potential for Electric Vehicles

et al. 2021

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This review provides an overview of new strategies to address the current challenges of automotive battery systems: Intelligent Battery Systems. They have the potential to make battery systems more performant and future-proof for coming generations of electric vehicles. The essential features of Intelligent Battery Systems are the accurate and robust determination of cell individual states and the ability to control the current of each cell by reconfiguration. They enable high-level functions like fault diagnostics, multi-objective balancing strategies, multilevel inverters, and hybrid energy storage systems. State of the art and recent advances in these topics are compiled and critically discussed in this article. A comprising, critical discussion of the implementation aspects of Intelligent Battery Systems complements the review. We touch on sensing, battery topologies and management, switching elements, communication architecture, and impact on the single-cell. This review contributes to transferring the best technologies from research to product development.

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“…Research has been done on various current sensing techniques for a wide range of applications [23,[285][286][287]. Many of these techniques can be used for IBSs in EVs.…”

Section: Currentmentioning

confidence: 99%

Critical Review of Intelligent Battery Systems: Challenges, Implementation, and Potential for Electric Vehicles

et al. 2021

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“…(7,8) They have poor anti-interference with the external magnetic field owing to the small cross-sectional area of the adopted core. (9) The loop core of a high-permeability ferromagnetic material can focus the magnetic field produced by the measured current. Hence, the flux in the test will not depend on the location of the conductor that is tested.…”

Section: Introductionmentioning

confidence: 99%

“…However, compared with a fully closed core loop, sensors with gaps have a stronger temperature dependence. (9) A gradiometer or an array of current sensors is an alternative for current measurement where space and power limitations preclude the use of a magnetic yoke. (20) Such devices perform magnetic field measurements in accordance with the ampere loop rule.…”

Section: Introductionmentioning

confidence: 99%

Flexible-substrate Fluxgate Current Sensor Based on MEMS Technology

Yang¹,

Fan²

2020

Sensors and Materials

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A method of preparing a flexible-substrate fluxgate based on MEMS technology was proposed, and the prepared flexible-substrate fluxgate was applied as a current sensor for online measurement. On the basis of MEMS technology, we combined the high precision and high stability of the fluxgate with the flexible and extension characteristics of the substrate to prepare a fluxgate current sensor. This flexible-substrate fluxgate current sensor not only has high precision, but also has the advantage of convenient online measurement of a Rogowski coil.

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“…Contactless transducers for the electric current usually have a magnetic core or yoke around the current conductor. The purpose of the yoke is to concentrate the magnetic flux inside this yoke because of its small reluctance [2]. Magnetic yoke has significant advantages—the measurement does not depend on the position of the current conductor inside the yoke, and the yoke shields against the external magnetic fields, including high gradient fields from other currents in the vicinity of the transducer.…”

Section: Introductionmentioning

confidence: 99%

Rectangular Array Electric Current Transducer with Integrated Fluxgate Sensors

Ripka

Mlejnek

Hejda

et al. 2019

Sensors

Self Cite

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Novel rectangular yokeless current transducer with the range 400 A using 16 microfluxgate sensors around the busbar conductor is presented in this paper. Compared to yokeless transducers utilizing the differential pair of magnetic sensors, our solution has much better suppression of the external currents (lower crosstalk). Compared to industrial transducers with yoke, the new transducer has 15-times lower noise, 7-times better temperature stability, and same crosstalk. Sensor design and design of current monitoring system is presented together with the results of long-term field tests. Crosstalk error is examined in dependence on the number of the operating sensors and external current position.

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Contactless measurement of electric current using magnetic sensors

Cited by 22 publications

References 99 publications

Critical Review of Intelligent Battery Systems: Challenges, Implementation, and Potential for Electric Vehicles

Critical Review of Intelligent Battery Systems: Challenges, Implementation, and Potential for Electric Vehicles

Flexible-substrate Fluxgate Current Sensor Based on MEMS Technology

Rectangular Array Electric Current Transducer with Integrated Fluxgate Sensors

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