Your search keyword '"Superconducting coils"' showing total 3,677 results

1. Indication of the measuring method for accurately determining the critical current and n value in superconducting wires and tapes used in superconducting coils.

Author

Gajda, Daniel, Zaleski, Andrzej J., Babij, Michał, and Rindfleisch, Matt A.

Subjects

*MAGNETIC field measurements, *HIGH temperature superconductors, *SUPERCONDUCTING coils, *SUPERCONDUCTORS, *SUPERCONDUCTING transitions, *SUPERCONDUCTING wire

Abstract

In our article, we show the n value determined from measurements using the magnetic field sweep method (curves of E from B/Bc) and the current sweep method (curves of E from I/Ic). The results from these two methods allowed for a scientific n value analysis. Moreover, measurements using these two methods allow for a better understanding of the behavior of superconducting wires after the transition from the superconducting state to the normal (resistive) state. Measurements were made for the NbTi wire at 4.2 K, MgB2 at the temperature range from 4.2 to 30 K, and high-temperature superconducting tape at 77 K. The magnetic field sweep method results show that the n value has a constant value independent of an increase in the magnetic field, number of filaments, type of boron, diameter of the wire, and small amount of the dopant. Moreover, research studies point out that the n value in the magnetic field sweep method depends on the type of superconductor material, a large amount of doping at high temperatures, and the low density of pinning centers. Based on the results obtained, it can be indicated that each superconducting material will have a constant n value. Measurements carried out using the current sweep method showed that the n value decreases significantly with an increase in the magnetic field. Moreover, research studies have shown that the n value depends on the number of filaments, type of boron, dopant, wire diameter, and temperature. On this basis, it can be indicated that the n value for the current sweep method depends on the morphology and structure of the superconducting wires. In addition, based on the samples measured in this research, the current sweep method allows for higher n values than the magnetic field sweep method in low magnetic fields. However, the magnetic field sweep method allows obtaining higher n values than the current sweep method in middle and high magnetic fields. [ABSTRACT FROM AUTHOR]

Published

2024

2. A phase-error immune approach for measuring transport AC loss by determination of minimum compensated voltage.

Author

Wei, Liangyu, Liu, Cong, Wang, Zeji, Zhou, Jun, and Zhang, Xingyi

Subjects

*VOLTAGE, *SUPERCONDUCTING coils, *VOLTMETERS, *EPOXY resins

Abstract

Alternating current (AC) loss measurement is crucial for the theoretical evaluation and optimization in the fabrication of superconducting AC devices. Lock-in amplifier based on the lock-in phase is commonly adopted and inevitably involves with phase error. In this work, a novel approach for measuring transport AC loss by determining the minimum compensated voltage (MCV) was developed, in which the lock-in amplifier was removed. Since it just uses the voltage signal from an AC voltmeter, it is phase-error immune. Experimental results demonstrated that when using the lock-in amplifier, there existed a system error as the initial phase difference between the sampled (reference) and real current phases, which required careful compensation. In contrast, the phase error no longer needed to be considered by the MCV method, and the AC loss results were obtained much more conveniently with the relative error between the theoretical and the experimental of less than 5%. Finally, the AC loss of a coated conductor spiral wound on an epoxy bar was obtained using the presented approach, demonstrating its low cost, ease of operation, and high accuracy. [ABSTRACT FROM AUTHOR]

Published

2024

3. The transient discharge circuit analysis of single-turn coil.

Author

Ge, Aoming, Pan, Ziying, Liu, Shaobo, Lv, Yiliang, and Peng, Tao

Subjects

*SUPERCONDUCTING coils, *ELECTROMAGNETIC coupling, *MAGNETIC fields, *ELECTRIC inductance, *ELECTRICAL conductors, *MAGNETS

Abstract

Single-turn coil (STC) is a destructive pulse magnet aiming at a 100–300 T ultra-high magnetic field. A transient discharge circuit model considering the coupling of electromagnetic diffusion and conductor deformation is proposed, and the transient coil impedance characteristics are investigated. The results show that the coil resistance first decreases and then increases due to electromagnetic diffusion and temperature rise, respectively, while the coil inductance always increases because of the conductor's outward motion. By comparison, the simulation results are consistent with the experimental data, and the correctness of the model is validated. [ABSTRACT FROM AUTHOR]

Published

2024

4. Thermal–electrical coupling analysis based on solid–liquid phase transition theory of single-turn coil.

Author

Ge, Aoming, Wang, Shuang, Pan, Ziying, and Peng, Tao

Subjects

*PHASE transitions, *ELECTRICAL conductivity transitions, *SUPERCONDUCTING coils, *ELECTRIC conductivity

Abstract

Single-turn coil (STC) is a destructive pulse magnet aiming at a 100–300 T ultra-high magnetic field. A thermal–electrical coupling model, in which the solid–liquid phase transition process is considered, is proposed. The effects of solid–liquid phase transition on pressure, temperature, and electrical conductivity are investigated. The results show that the compressed and stretched regions coexist simultaneously, and the distribution of both regions changes with time during discharging. Moreover, the region with the highest current density is inside the conductor, since the phase transition reduces the electrical conductivity of the region near the inner surface of STCs. By comparison, the simulation results are highly consistent with the measured data, and the necessity of considering the phase transition process is validated. The results obtained in this work are helpful for understanding the thermodynamic process of STCs during discharge. [ABSTRACT FROM AUTHOR]

Published

2023

5. Understanding ac losses in CORC cables of YBCO superconducting tapes by numerical simulations.

Author

Nguyen, Linh N., Shields, Nathaniel, Ashworth, Stephen, and Nguyen, Doan N.

Subjects

*SUPERCONDUCTING coils, *SUPERCONDUCTING cables, *HIGH temperature superconductors, *CABLES, *FINITE element method, *COMPUTER simulation, *ADHESIVE tape, *CURRENT distribution

Abstract

Alternating current (ac) losses in conductor-on-rounded-core (CORC) cables of YBCO high-temperature superconducting (HTS) tapes are a significant challenge in HTS power applications. This study employs two finite element analysis (FEA) models to investigate the contributions from different ac loss components and provide approaches for reducing ac losses in cables. An FEA model based on the T-A formulation treats the cross section of thin superconducting layers as 1D lines and, therefore, only can predict the ac loss generated by the perpendicular magnetic field. In contrast, the model based on H-formulation can be performed on the actual 2D rectangular cross section HTS tapes to provide the total ac losses generated by magnetic fluxes penetrating from both the edges and surfaces of HTS tapes, although this model requires more computing time and memory. The 1D and 2D simulation models were validated by cross comparing the results from both models and by comparing sub-section and full cross section models. Subsequently, two models relate cable design and operational parameters to the surface and edge losses of a two-layer CORC cable by considering the (1) relative contributions of edge and surface losses to the overall ac losses; (2) effect of the current distribution between inner and outer HTS layers on ac losses; (3) impact of the tape alignment on ac losses in each HTS layer; (4) influence of the thickness of HTS layers on ac losses; (5) effect of size and number of inter-tape gaps on ac losses; and (6) contribution frequency on the ac losses. The research results given in this paper are therefore not only valuable to suggest strategies for reducing ac loss in multi-layer cables but also for developing more accurate and effective methods to calculate ac loss in CORC HTS cables. [ABSTRACT FROM AUTHOR]

Published

2023

6. Piecewise Grading Reform Year 1: Lab Specifications.

Author

Veazey, Joshua P.

Subjects

*LEARNING curve, *SUPERCONDUCTING coils, *MATURATION (Psychology), *REFRACTIVE index, *ELECTROMAGNETIC induction, *SESSION Initiation Protocol (Computer network protocol), *HYBRID systems

Abstract

The article discusses the challenges of traditional points-based grading systems in higher education and the growing popularity of alternative grading systems. The author describes their experience transitioning to a hybrid standards and specifications-based grading system over three years, focusing on Year 1 when lab sections were assessed with specifications-based grading. The lab specifications emphasized communication and process skills over correctness, with a focus on clear standards, helpful feedback, marks indicating progress, and reassessment without penalty. Student feedback on the specifications system for labs was positive, highlighting a shift towards understanding the material rather than relying on others. [Extracted from the article]

Published

2024

7. distect: automatic sample‐position tracking for X‐ray experiments using computer vision algorithms.

Author

Berg, Michael, Furrer, Dirk, Thominet, Vincent, Wang, Xiaoqiang, Zeugin, Stefan, Grabner, Helmut, Stockinger, Kurt, and Piamonteze, Cinthia

Subjects

*COMPUTER vision, *ALGORITHMS, *SUPERCONDUCTING coils, *THERMAL shielding, *AUTOMATIC tracking

Abstract

Soft X‐ray spectroscopy is an important technique for measuring the fundamental properties of materials. However, for measurements of samples in the sub‐millimetre range, many experimental setups show limitations. Position drifts on the order of hundreds of micrometres during thermal stabilization of the system can last for hours of expensive beam time. To compensate for drifts, sample tracking and feedback systems must be used. However, in complex sample environments where sample access is very limited, many existing solutions cannot be applied. In this work, we apply a robust computer vision algorithm to automatically track and readjust the sample position in the dozens of micrometres range. Our approach is applied in a complex sample environment, where the sample is in an ultra‐high vacuum chamber, surrounded by cooled thermal shields to reach sample temperatures down to 2.5 K and in the center of a superconducting split coil. Our implementation allows sample‐position tracking and adjustment in the vertical direction since this is the dimension where drifts occur during sample temperature change in our setup. The approach can be easily extended to 2D. The algorithm enables a factor of ten improvement in the overlap of a series of X‐ray absorption spectra in a sample with a vertical size down to 70 µm. This solution can be used in a variety of experimental stations, where optical access is available and sample access by other means is reduced. [ABSTRACT FROM AUTHOR]

Published

2024

8. Use of a Scrapped Hard Disk Drive for Physics Teaching.

Author

Hu, Lian

Subjects

*FARADAY'S law, *CIRCULAR motion, *HARD disks, *FRICTION, *MAGNETIC torque, *DYNAMOMETER, *BRUSHLESS direct current electric motors, *SUPERCONDUCTING coils

Abstract

This article explores the potential use of components from a hard disk drive (HDD) for physics teaching demonstrations. Specifically, the article highlights the spindle motor and voice coil motor (VCM) within the HDD as useful tools for teaching various physics concepts. The spindle motor can be used to demonstrate electromagnetic induction, while the VCM can be used to demonstrate wireless power transfer, resonance, and interference of waves. The author provides examples of simple physics demonstrations that can be conducted using these motors, which can aid students in understanding fundamental physics principles. [Extracted from the article]

Published

2024

9. Piezoelectric Shunt Damping for a Planar Motor Application under Cryogenic Conditions.

Author

Ambaum, Niek, Mokrani, Bilal, and Vermeulen, Hans

Subjects

MOORE'S law, SUPERCONDUCTING coils, PIEZOELECTRIC transducers, TECHNOLOGICAL innovations, SEMICONDUCTOR manufacturing

Abstract

For several decades, Moore's law has driven the semiconductor industry, with computational power and production costs as the main drivers. Such drivers have enabled several technological innovations in the mechatronics and dynamics architecture of photolithography machines, used for semiconductor circuits manufacturing. Among current investigations, the use of superconductive magnets would enable higher accelerating stages and, thus, higher throughput and lower manufacturing costs. However, this involves a complex magnet structure that needs to operate at cryogenic temperatures and mechanical resonances at relatively low frequencies as a result of the thermal architecture of the system. The damping options are also limited due to the very low temperature. This paper explores the use of shunted piezoelectric transducers for damping the internal modes of the magnet mass. A classical resistive and inductive RL shunt is considered. The study was conducted both numerically and experimentally on a demonstrator of a superconductive magnet plate concept, where piezoelectric transducers are incorporated to support the superconducting coils. The study demonstrates the effectiveness of piezoelectric shunts as a damping solution at very low temperatures, with limited impact of the temperature variation on the performance. [ABSTRACT FROM AUTHOR]

Published

2024

10. Class XIII Monthly test drive.

Subjects

*MAGNETIC dipole moments, *SOLENOID magnetic fields, *ELECTROMAGNETIC induction, *MAGNETISM, *MAGNETIC fields, *SUPERCONDUCTING coils

Abstract

The document from "Physics For You" contains a monthly test for Class XII students, focusing on topics related to moving charges and magnetism. The test includes multiple-choice questions on various concepts such as magnetic fields, currents, and electromagnetic forces. It also features assertion and reason type questions, as well as numerical value and matrix match type questions. The test aims to assess students' understanding of physics concepts and their ability to apply them in different scenarios. [Extracted from the article]

Published

2024

11. Electromagnetic Induction | Alternating Current.

Subjects

*FARADAY'S law, *ELECTROMAGNETIC induction, *INDUCTION coils, *RESISTOR-inductor-capacitor circuits, *ALTERNATING current circuits, *ROTATIONAL motion, *MOTION, *SUPERCONDUCTING coils

Abstract

The given document is a practice question paper for CBSE exams on the topic of Electromagnetic Induction and Alternating Current. It contains 33 questions divided into five sections, covering concepts such as inductance, resonance, transformers, induced emf, and AC circuits. The document also provides values of physical constants that can be used in the questions. The text appears to be a set of equations and answers to physics problems, but lacks context or explanation for these calculations. [Extracted from the article]

Published

2024

12. Are you ready for Olympiads?

Subjects

*MAGNETISM, *ELECTROMAGNETIC fields, *OHM'S law, *ELECTROMAGNETIC induction, *PERMANENT magnets, *SUPERCONDUCTING coils

Abstract

The article titled "Are you ready for Olympiads?" provides a syllabus and sample questions for Olympiad exams in Physics, Chemistry, and Mathematics. The syllabus covers various topics such as Electricity and Magnetism, Optics, Modern Physics, Solutions, Electrochemistry, and Differential Equations. The exams are based on NEP (2020), NCF (2023), NCERT, and CBSE guidelines. The article aims to assist students in preparing for the Olympiad exams by providing them with relevant information and sample questions. The text includes multiple sections with different topics, each presenting a problem or scenario and asking a related question. Equations and diagrams are provided to aid in problem-solving, but solutions are not included. [Extracted from the article]

Published

2024

13. In situ detection of delamination and critical current degradation caused by the thermal stress in epoxy impregnated REBa2Cu3O7−δ coils.

Author

Yang, Zhirong, Song, Peng, Li, Yiran, Shao, Liangjun, Xiao, Mianjun, Guan, Mingzhi, and Qu, Timing

Subjects

*CRITICAL currents, *SUPERCONDUCTING coils, *TEMPERATURE distribution, *RADIAL stresses, *THERMAL expansion, *SUPERCONDUCTING magnets

Abstract

Epoxy impregnated superconducting coils have better structural integrity and thermal stability. However, for REBa 2 Cu 3 O 7 − δ (REBCO, RE=Rare earth) coils, the mismatch of thermal expansion coefficients between epoxy and REBCO tapes is a serious problem. In this work, the temperature distribution, stress evolution during the cooling process, critical current distribution, and delamination sites inside REBCO coils impregnated using Stycast 2850FT have been studied. We measured the temperature distribution and the hoop strain in the penultimate turn of impregnated coils during the cooling process and analyzed the thermal stress evolution. No damage was observed for coils with the ratio between outer and inner diameter R o / R i < 1.93. The delamination behavior occurred in coils with R o / R i > --> 2.37 , where the coils even exhibited a two-stage delamination. The delamination mechanism of REBCO coils was proposed from three aspects: the mechanical analysis, the critical current degradation, and the microscopic analysis. In this work, we found that the actual delamination behavior may appear earlier than the steady-state temperature, and temperature distribution will push the radial stress peak toward the inner radius of the coil, making the inner turn more susceptible to delamination. Multiple delamination locations were accurately predicted and confirmed. The measured compressive hoop strain first increased from − 4212 μ ε to − 4684 μ ε with the increase in R o / R i and then decreased to − 3835 μ ε obviously due to delamination. This work reveals in detail the delamination mechanism in impregnated REBCO coils, which is of great significance for the development of damage-free coils. [ABSTRACT FROM AUTHOR]

Published

2023

14. Investigation of real-time strain responses of the insulating system of superconducting magnets by using fiber Bragg grating sensors.

Author

Zhao, Wanyin, Xin, Jijun, Zhang, Hengcheng, Wang, Wei, Fang, Zhichun, Lyu, Bingkun, Wu, Longfeng, Wang, Chundong, Shen, Fuzhi, Shan, Xinran, Huang, Chuanjun, Sun, Wentao, Zhou, Yuan, and Li, Laifeng

Subjects

*FIBER Bragg gratings, *SUPERCONDUCTING magnets, *GLASS-reinforced plastics, *SUPERCONDUCTING coils, *EPOXY resins, *STRAIN sensors

Abstract

The normal operation of various superconducting magnets is greatly influenced by the thermal stress of the insulating system, commonly made of epoxy resins with vacuum pressure impregnation (VPI) technology, throughout the curing and cooling processes. In this work, we developed a Fiber Bragg Grating (FBG) strain measurement method to monitor the real-time strain responses of an epoxy resin IR-3 and its glass fiber-reinforced composite during both curing and cooling processes. Then, we also monitored the same process of a Nb–Ti superconducting magnet coil prepared by VPI technology. With the help of FBG strain sensors, the residual strains of the coil at various positions and directions were investigated. The results show that the large residual strain occurred near the end of the coil in the axial direction. In addition, the interlaminar shear stress properties were measured at both room temperature and liquid nitrogen temperature. The strain characteristics of the epoxy resin IR-3 and the insulating system can provide useful guidance for the design and construction of high-field Nb–Ti superconducting magnets. [ABSTRACT FROM AUTHOR]

Published

2023

15. A Study on the Liquid Helium Temperature Tensile Property of Fe-21Cr-15Ni-5Mn-2Mo Austenitic Stainless Steel after Solution Treatment.

Author

Zhang, Mengxing, Wang, Changjun, Ma, Dangshen, Liu, Yu, Wang, Weijun, Liang, Jianxiong, Fang, Chao, Chu, Weihan, and Huang, Chuanjun

Subjects

*HIGH strength steel, *AUSTENITIC stainless steel, *TENSILE strength, *SUPERCONDUCTING coils, *LIQUID helium

Abstract

A novel non-magnetic Fe-21Cr-15Ni-5Mn-2Mo austenitic stainless steel with high strength and plasticity has been developed. The microstructure and liquid helium temperature (4.2 K) tensile properties of the top and bottom samples of large-size forged flat steel after solution treatment at 1090 °C were investigated. The results showed that the average grain size of the bottom sample (48.0 ± 6.7 μm) was smaller than that of the top sample (58.8 ± 15.3 μm), and the MX precipitates and Z phases were distributed in the matrix of the samples. The 4.2 K strengths of the samples at the top and bottom were high, and large amounts of annealing twin boundaries played a certain role in strengthening. After cryogenic tensile testing, large amounts of deformation twins, stacking faults, and dislocations were generated inside the austenite grains of both samples, which helped the material to obtain higher plasticity and strength. The top and bottom samples possessed excellent synergies of strength and plasticity at 4.2 K, and the 4.2 K tensile properties of the top sample were as follows: ultimate tensile strength (UTS) of 1850 MPa, yield strength (YS) of 1363 MPa, and elongation (EL) of 26%. The tested steel is thus believed to meet the requirements of combined excellent strength and plasticity within a deep cryogenic environment, and it would be a promising material candidate for manufacturing superconducting coil cases to serve in new generation fusion engineering. [ABSTRACT FROM AUTHOR]

Published

2024

16. Efficient separation of large particles and giant cancer cells using an isosceles trapezoidal spiral microchannel.

Author

Park, Chanyong, Lim, Wanyoung, Song, Ryungeun, Han, Jeonghun, You, Daeun, Kim, Sangmin, Lee, Jeong Eon, van Noort, Danny, Mandenius, Carl-Fredrik, Lee, Jinkee, Hyun, Kyung-A., Jung, Hyo-Il, and Park, Sungsu

Subjects

*CANCER cells, *TRIPLE-negative breast cancer, *DRAG force, *CELL populations, *MICROFLUIDIC devices, *SUPERCONDUCTING coils

Abstract

Polyploid giant cancer cells (PGCCs) contribute to the genetic heterogeneity and evolutionary dynamics of tumors. Their size, however, complicates their isolation from mainstream tumor cell populations. Standard techniques like fluorescence-activated cell sorting (FACS) rely on fluorescent labeling, introducing potential challenges in subsequent PGCC analyses. In response, we developed the Isosceles Trapezoidal Spiral Microchannel (ITSμC), a microfluidic device optimizing the Dean drag force (FD) and exploiting uniform vortices for enhanced separation. Numerical simulations highlighted ITSμC's advantage in producing robust FD compared to rectangular and standard trapezoidal channels. Empirical results confirmed its ability to segregate larger polystyrene (PS) particles (avg. diameter: 50 μm) toward the inner wall, while directing smaller ones (avg. diameter: 23 μm) outward. Utilizing ITSμC, we efficiently isolated PGCCs from doxorubicin-resistant triple-negative breast cancer (DOXR-TNBC) and patient-derived cancer (PDC) cells, achieving outstanding purity, yield, and viability rates (all greater than 90%). This precision was accomplished without fluorescent markers, and the versatility of ITSμC suggests its potential in differentiating a wide range of heterogeneous cell populations. [ABSTRACT FROM AUTHOR]

Published

2024

17. A coupled electromagnetic-mechanical model and contact behavior of the superconducting coils.

Author

Wang, Sijian, Tang, Yunkai, Yong, Huadong, and Zhou, Youhe

Subjects

*SUPERCONDUCTING coils, *CONTINUUM mechanics, *SOLID mechanics, *ELASTIC plates & shells, *SUPERCONDUCTING magnets, *SOLID state proton conductors, *MAGNETIC flux, *BARIUM

Abstract

• A coupled electromagnetic-mechanical model is built to calculate the coupling behaviors of superconducting coils. • Mechanical deformation impacts the motion of magnetic flux and changes the critical current of superconductors. • The roles of contact conditions in the superconducting coils are derived theoretically. • A mechanical homogenization model is proposed to simplify the model containing hundreds of contact pairs. Rare-earth based barium copper oxide (REBCO) superconducting coated conductors are promising candidates for the design of high field magnets. In a high magnetic field, these conductors have to withstand huge Lorentz force, which would threaten the safety of superconducting devices. Recently, researchers have found that the electromagnetic-mechanical coupling has a significant impact on the overall response of the magnet system. It has been demonstrated that mechanical deformation can lead to the movement of magnetic flux in superconductors and changes in the critical current of superconductors. To take into account the electromagnetic-mechanical coupling effects, REBCO coated conductors are modeled as deformable conductors based on continuum mechanics of electromagnetic solids. Then, a fully coupled electromagnetic-mechanical model is developed in this paper, which is verified with the experimental results. Furthermore, during the electromagnetic-mechanical coupling simulation, contact separation occurs in REBCO pancake coils. To characterize the global mechanical performance of the REBCO pancake coils (containing hundreds of contact conditions), the concept of flexural rigidity in elastic shell theory is employed. Then, a mechanical homogeneous model is proposed to simplify the model containing hundreds of contact pairs and enable the effective simulation of large-scale HTS systems. This framework can provide theoretical support to the mechanical research of high field magnets. [ABSTRACT FROM AUTHOR]

Published

2024

18. Analysis and Optimization of the Stray Capacitance of Rogowski Coils.

Author

Wang, Jiawei, Wang, Huifu, Mao, Minyu, and Ma, Xikui

Subjects

MUTUAL inductance, STRUCTURAL optimization, MAGNETIC flux, ELECTRIC capacity, SKELETON, SUPERCONDUCTING coils

Abstract

In this work, the lumped model of Rogowski coils is briefly reviewed to illustrate that the reduction in stray capacitance expands the bandwidth and improves the high-frequency performance. Then, a network model as well as explicit formulas for the stray capacitance of Rogowski coils are established, and the influence of geometrical parameters of the skeletons on the stray capacitance is investigated. It is found that the stray capacitance of Rogowski coils is approximately proportional to the perimeter of the skeleton cross-section. Based on the above discussion, optimization of the shape of the skeleton cross-section, aiming at minimizing the perimeter without affecting the magnetic flux and mutual inductance of the coils, is carried out. The widely adopted circular and rectangular cross-sections are discussed first. Then, the cross-section of an arbitrary smooth and convex shape is optimized by solving a constrained variational problem, leading to an explicit equation for the optimal skeleton cross-section of Rogowski coils. Numerical results demonstrate that, compared with the common circular and rectangular skeleton cross-sections, the proposed optimal cross-section exhibits the shortest perimeter and thus the highest upper cutoff frequency under fixed magnetic flux. The optimization method developed by this work can provide a theoretical basis and guidance for the design of Rogowski coils. [ABSTRACT FROM AUTHOR]

Published

2024

19. Experimental Measurement of Working Parameters of Conical Electromagnetic Levitation Coils.

Author

Silamikelis, V., Snikeris, J., Apsitis, A., and Pumpurs, A.

Subjects

*LEVITATION, *WORK measurement, *MAGNETIC field measurements, *LIFT (Aerodynamics), *SUPERCONDUCTING coils

Abstract

Electromagnetic levitation (EML) is a promising technique allowing to melt various materials, including refractive metals, while avoiding physical contact between the molten material and components of the melting system, thus avoiding contamination of the molten material. EML coils act both as a container and a heating source for a conductive sample placed within it. EML systems are difficult to optimize for specific tasks and computational simulations are often used to aid the process. Development of simulations of EML processes is an ongoing field of research. Obtaining precise experimental measurement data of EML processes is important for development and verification of computational simulations. This study aims to provide experimental data of simultaneous measurements for magnetic field, Joule heating and lift force in different conical EML coils with a counterturn. [ABSTRACT FROM AUTHOR]

Published

2024

20. Calibration techniques for Thomson scattering diagnostics on large fusion experiments.

Author

Fuchert, G., Wagner, J., Henschke, L. V., Pasch, E., Beurskens, M. N. A., Bozhenkov, S. A., Brunner, K. J., Chen, S., Frank, J. M., Hirsch, M., Knauer, J., and Wolf, R. C.

Subjects

*SUPERCONDUCTING coils, *THOMSON scattering, *RAYLEIGH scattering, *LASER beams, *TORUS

Abstract

Larger fusion experiments require long beam paths for laser diagnostics, which requires mechanical stability and measures to deal with remaining alignment variations. At the same time, due to technical and organizational boundary conditions, calibrations become challenging. The current mid-sized experiments face the same issues, yet on a smaller scale, which makes them ideal testing environments for novel calibration methods, since a comparison with the established best practices is still possible. At the stellarator Wendelstein 7-X, the calibration and operation of the Thomson scattering diagnostic is hampered by beam displacements, coating of windows during operation, and access restrictions while the superconducting coils are active. New calibration techniques were developed to improve the profile quality and reduce calibration time. While positional variations of the laser beam have to be minimized, the remaining displacements can be accounted for during the absolute calibration. An in situ spectral calibration has been developed based on Rayleigh scattering, which calibrates the whole diagnostic, including observation windows. In addition, a less accurate but faster method has been developed, which utilizes stray-light of a tunable OPO to perform spectral calibration within minutes and does not require torus hall access. Finally, a workflow has been established to consider finite linewidths of the calibration source in the spectral calibration. While these methods will be used at W7-X to complement existing calibration techniques, they may also solve some of the aforementioned issues expected for even larger and nuclear experiments, where access restrictions are stringent and calibration becomes even more demanding. [ABSTRACT FROM AUTHOR]

Published

2024

21. Optimization Design of DC Electromagnet Coil Considering the Power Consumption and Cost.

Author

Song, Yanhe, Yang, Liu, Chen, Xin, Zhou, Wentao, Qiu, Tiechao, Hao, Yueyue, Ai, Chao, and Kong, Xiangdong

Subjects

*ELECTROMAGNETS, *ELECTRICITY pricing, *SUPERCONDUCTING coils, *COPPER wire, *VALUE engineering, *ELECTRICAL engineers

Abstract

Electromagnet coil is mainly composed of enameled wire which wound on the coil skeleton, and the function is to convert the electrical signal into a magnetic signal, which is a very important electric‐magnetic conversion element. When designing the electromagnet coil, usually only the total winding turns and winding inner diameter can be calculated, and the specific design parameters such as the diameter of copper wire, paint layer thickness, and winding turns of each layer can only be selected through experience, indicating that the design method should be improved. In addition, the unreasonable design parameters will seriously affect the power consumption and cost of coil, so it is highly necessary to improve the optimization design method. In order to solve the above problems, an optimization design method for DC electromagnet coil is proposed in this paper. This method simultaneously takes into account both power consumption and manufacturing cost, and can achieve the optimal matching of design parameters. In this paper, the structure of electromagnet coil is introduced, and the theoretical calculation model of resistance is improved first. Then, according to the expected requirements of electromagnet coil for steady current, the optimization design method is proposed and the optimal design parameters are obtained. Finally, the effectiveness of the proposed optimization design method is verified by the test platform of electromagnet coil. The results show that the electromagnet coil designed by the optimization design method fully meets the expected requirements. The relevant research results can provide reference for the optimization design of electromagnet coil, which has a certain engineering practical value. © 2024 Institute of Electrical Engineers of Japan and Wiley Periodicals LLC. [ABSTRACT FROM AUTHOR]

Published

2024

22. A loosely coupled transformer structure with anti-offset capability based on uniform magnetic field.

Author

Zhou, Yufei, Yan, Yu, Li, Dongdong, and Luo, Yang

Subjects

*MAGNETIC fields, *WIRELESS power transmission, *SOLENOIDS, *ELECTRIC charge, *SUPERCONDUCTING coils, *AIRPORTS

Abstract

Inductively coupled power transfer (ICPT) technology is widely used in wireless charging systems because of its safety, convenience, and reliability. However, the loosely coupled transformer, the most significant part of an ICPT system, has misalignment conditions in practical applications, which have a negative effect on the efficiency of the ICPT system. This paper proposes a new loosely coupled transformer structure, where the primary side is composed of two hybrid winding D coils and a solenoid coil, and the secondary side consists of a D coil and a solenoid coil, which is referred to as a "double-D solenoid coil–D solenoid coil" (DDS–DS). The hybrid winding D coils, which are composed of multiple layers of windings, can construct a uniform magnetic field at the operational air gap. The S coil is added to the primary and secondary sides of the transformer to build a mutually perpendicular energy channel with the D coils, which compensates the coupling valley without introducing cross-coupling. Therefore, the DDS–DS structure can construct a wide uniform magnetic field and effectively improve the anti-offset capability of the system. Finally, an experimental prototype is established, and the effective charging width reaches 78% of the transmitting coil's width with a 50 mm operational air gap, which verifies that the structure has good anti-offset capability. [ABSTRACT FROM AUTHOR]

Published

2024

23. Cold-Formed Cross-Sectional Folds with Optimal Signature Curve.

Author

Ahmadi, Babak, Razi, Shayan, Saghand, Mohammad P., Changizi, Navid, Fallah, Arash S., and Tootkaboni, Mazdak

Subjects

*METAHEURISTIC algorithms, *FINITE strip method, *RESIDUAL stresses, *SUPERCONDUCTING coils, *PERFORMANCE standards, *COLD-formed steel

Abstract

A novel figure of merit based on the concept of signature curve for cold formed steel (CFS) cross sections is used to improve the structural member's overall behavior regardless of length and boundary conditions. The objective is defined as the area under the signature curve, plus a penalty function that ensures improved performance over standard sections at specified lengths. Charged system search (CSS), a meta-heuristic optimization algorithm, is used to search the design space. End-use and other geometrical constraints suggested by previous studies are considered to arrive at practical cross sections. This includes limiting the fold angles to minimize sharp corners in the optimized cross sections, which might result in residual stresses that diminish axial capacity. Such nonlinear constraints are also taken into account using penalty functions to facilitate integration with the heuristic optimization process. The proposed strategy is examined through a couple of illustrative examples and is shown to yield higher axial capacity at all points when combined with the proper penalization. The optimized cross sections are also analyzed in simple-simple and clamped-clamped boundary conditions showing improved axial capacity compared to the standard lipped-channel sections with the same coil width. [ABSTRACT FROM AUTHOR]

Published

2024

24. Dual receiver series topology for bipolar segmented DWPT system.

Author

Zou, Yaqiang, Xu, Tian, Li, Zhong, and Qiang, Hao

Subjects

*WIRELESS power transmission, *MAGNETIC fields, *ELECTRIC vehicles, *DIODES, *TOPOLOGY, *SUPERCONDUCTING coils

Abstract

For a segmented dynamic wireless power transfer (DWPT) system, when electric vehicles (EVs) move over two adjacent transmitting coils, the received power fluctuates greatly and has some loss. Arming at this problem, this paper proposes a dual receiver segmented DWPT topology to reduce the received power fluctuation of the receiving coil passing through the rail junction during the moving process of the EV. Through magnetic field analysis in this paper, tuning the current phase difference between two adjacent transmitting coils to 180° can enhance the magnetic field. In this paper, a dual receiver series topology (DRST) is designed to pick up power, which consists of four fully controlled components and four diodes. According to EVs' real-time position, the segment DWPT system has three working modes and six working states under the control of DRST. Finally, experiments are carried out. Compared to the single-receiving-coil system, DRST is effective in improving the average output power from 2.007 to 5.657 W and significantly reducing the power fluctuation. [ABSTRACT FROM AUTHOR]

Published

2024

25. Impact of the cloud zenith angle of the pickup coil upon the sensitivity of a flexible rosette eddy current sensor.

Author

Chen, Guolong, Lu, Cang, Fan, Le, Wei, Ji, Wan, Hao, Zhang, Gang, Zhang, Yanlong, and Zhang, Guanyao

Subjects

*ZENITH distance, *EDDY current testing, *SUPERCONDUCTING coils, *FATIGUE cracks, *STRUCTURAL health monitoring, *RIVETED joints, *STRESS concentration, *VEHICLE routing problem

Abstract

Bolt links and riveted joints, although widely used in aerospace and other mechanical systems, are susceptible to stress concentrations and fatigue cracks, which are undesirable. The flexible rosette eddy current sensor is typically used for the structural monitoring of bolt connections and riveted joints. This study proposes a method to improve the sensitivity of a flexible rosette eddy current sensor by reducing the cloud zenith angle of the pickup coil. First, the effect of the cloud zenith angle upon the sensitivity of the flexible rosette eddy current sensor is analyzed theoretically; the results show that a larger cloud zenith angle corresponds to a larger background signal. This diminishes the relative rate of change of the crack signal when the sensitivity of the sensor is evaluated based upon the maximum rate of change of the output. Therefore, the sensitivity is optimized by reducing the cloud zenith angle. Subsequently, through simulation and experimental methods, the relationship between sensor sensitivity and cloud zenith angle was studied. The results indicate that the cloud zenith angle significantly affects the sensitivity and that reducing the cloud zenith angle effectively reduces the background and improves the sensitivity. [ABSTRACT FROM AUTHOR]

Published

2024

26. Designing gradient coils with the shape derivative and the closed B-spline curves.

Author

Takahashi, Toru

Subjects

*CARTESIAN coordinates, *MAGNETIC resonance imaging, *DERIVATIVES (Mathematics), *SUPERCONDUCTING coils, *MAGNETIC fields

Abstract

This study proposes a versatile and efficient optimisation method for discrete coils that induce a magnetic field by their steady currents. The prime target is gradient coils for MRI (Magnetic Resonance Imaging). The derivative (gradient) of the z -component the magnetic field, which is calculated by the Biot–Savart's law, with respect to the z -coordinate in the Cartesian xyz coordinate system is considered as the objective function. Then, the derivative of the objective function with respect to a change of coils in shape is formulated according to the concept of shape optimisation. The resulting shape derivative (as well as the Biot–Savart's law) is smoothly discretised with the closed B-spline curves. In this case, the control points (CPs) of the curves are naturally selected as the design variables. As a consequence, the shape derivative is discretised to the sensitivities of the objective function with respect to the CPs. Those sensitivities are available to solve the present shape-optimisation problem with a certain gradient-based nonlinear-programming solver. The numerical examples exhibit the mathematical reliability, computational efficiency, and engineering applicability of the proposed methodology based on the shape derivative/sensitivities and the closed B-spline curves. [ABSTRACT FROM AUTHOR]

Published

2024

27. Accelerated multi-b-value multi-shot diffusion-weighted imaging based on EPI with keyhole and a low-rank tensor constraint.

Author

Tang, Xin, Gao, Juan, Aburas, Ahmed, Wu, Dan, Chen, Zhuo, Chen, Hao, and Hu, Chenxi

Subjects

*DIFFUSION magnetic resonance imaging, *ECHO-planar imaging, *DIFFUSION tensor imaging, *SUPERCONDUCTING coils, *IN vivo studies

Abstract

Multi-Shot (MS) Echo-Planar Imaging (EPI) may improve the in-plane resolution of multi-b-value DWI, yet it also considerably increases the scan time. Here we explored the combination of EPI with Keyhole (EPIK) and a calibrationless reconstruction algorithm for acceleration of multi-b-value MS-DWI. We firstly analyzed the impact of nonuniform phase accrual in EPIK on the reconstructed image. Based on insights gained from the analysis, we developed a calibrationless reconstruction algorithm based on a Space-Contrast-Coil Locally Low-Rank Tensor (SCC-LLRT) constraint for reconstruction of EPIK-acquired data. We compared the algorithm with a modified SPatial-Angular Locally Low-Rank (SPA-LLR) algorithm through simulations, phantoms, and in vivo study. We then compared EPIK with uniformly undersampled EPI for accelerating multi-b-value DWI in 6 healthy subjects. Through theoretical derivations, we found that the reconstruction of EPIK with a SENSE-encoding-based algorithm, such as SPA-LLR, may cause additional aliasing artifacts due to the frequency-dependent distortion of the coil sensitivity. Results from simulations, phantoms, and in vivo study verified the theoretical finding by showing that the calibrationless SCC-LLRT algorithm reduced aliasing artifacts compared with SPA-LLR. Finally, EPIK with SCC-LLRT substantially reduced the ghosting artifacts compared with uniform undersampled multi-b-value DWI, decreasing the fitting errors in ADC (0.05 ± 0.01 vs 0.10 ± 0.01, P < 0.001) and IVIM mapping (0.026 ± 0.004 vs 0.06 ± 0.006, P < 0.001). The SCC-LLRT algorithm reduced the aliasing artifacts of EPIK by using a calibrationless modeling of the multi-coil data. The dense sampling of k-space center offers EPIK a potential to improve image quality for acceleration of multi-b-value MS-DWI. [ABSTRACT FROM AUTHOR]

Published

2024

28. Multi-mode switching and charging area division of multi-transmitter IPT system.

Author

Li, Da, Sun, Pan, Ji, Kai, Liang, Yan, Liu, Yilin, and Wu, Xusheng

Subjects

*PASSIVE components, *ELECTRIC charge, *SUPERCONDUCTING coils, *POWER resources

Abstract

How to improve the efficiency of IPT systems in the case of transceiver coil misalignment is a core problem that needs to be solved urgently. Compared with single-transmitter IPT systems, multi-transmitter ones exhibit greater power supply flexibility, which ensures stable operation despite misalignment. A topology of a multi-transmitter IPT system is proposed in this study. A grouping and switching control strategy of 3 × 3 multi-transmitter coils is designed on the basis of reconfigurable inverter. A method for charging area division is also put forward to improve the efficiency of the IPT system under the condition of power priority. Compared with the traditional multi-transmitter IPT system, the new multi-transmitter topology proposed in this study can realize the independent operation of each transmitter coil with the minimum number of passive devices. [ABSTRACT FROM AUTHOR]

Published

2024

29. Design and simulation of a superconducting machine excitation system taking into account the three-dimensional magnetic leakage.

Author

Chen, Chen and Zhang, Wenfeng

Subjects

*MAGNETIC flux leakage, *SUPERCONDUCTING coils, *HIGH temperature superconductors, *SUPERCONDUCTING magnets, *ELECTROMAGNETIC fields, *MAGNETIC fields

Abstract

The optimized design of a new high-temperature superconducting rotating pole machine is presented. Its main structural feature is the use of a double stator core which separates the synchronous machine pole shoe from the pole body to rotate separately as the machine rotor, allowing the superconducting coil to operate in a stationary state. The inner stator core, the stationary dewar and the rotor core together form the excitation system of the machine. The excitation coil windings adopt a rectangular cross-section, with flux divertor strategically placed between the high-temperature superconducting coils. This configuration aims to modulate the background magnetic field, specifically reducing the perpendicular magnetic field component. This mitigation minimizes the impact of ambient magnetic fields on the superconducting coil's current carrying capacity, ensuring an optimized magnetic field environment for its operation. Through the integration of these modifications, the technical and economic parameters of the enhanced high-temperature superconducting machine have been significantly improved. The optimization of design, coupled with detailed calculations of the 3D electromagnetic field, was achieved utilizing the commercial software Ansys EM module. [ABSTRACT FROM AUTHOR]

Published

2024

30. Simulation Study of Magnetic Microcalorimeters for Rare Event Search Experiments.

Author

Lee, D. Y., Chung, J. S., Jeon, J. A., Kim, H. B., Kim, H. J., Kim, Y. H., Kim, Y. M., Kwon, D. H., Lee, Y. C., Lim, H. S., Park, H. K., and Woo, K. R.

Subjects

*CALORIMETERS, *FINITE element method, *MAGNETIC fields, *MAGNETIC properties, *SUPERCONDUCTING coils, *ELECTRIC inductance

Abstract

We present advancements in a finite element method for computing the physical properties of magnetic microcalorimeters (MMCs). Utilizing the COMSOL package, we conducted 3D simulations of a meander-shaped Nb coil with a realistic geometry. The resulting magnetic field distribution showed good agreement with a previous 2D simulation and revealed non-negligible differences at the side edge of the sensor material. Employing the simulation results, we calculated the MMC properties and compared them with previous measurements. Our calculated values closely align with the measured values for the sensor magnetization, the pulse heights from alpha detection, and the coil inductance. [ABSTRACT FROM AUTHOR]

Published

2024

31. Flexible Electromagnetic Tactile Sensor Based on Double‐Layer High‐Density MEMS Coils and Tilted Magnetic Column Array.

Author

Liu, Jianjun, Hou, Xiaojuan, Liu, Juan, Bi, Xiaoxue, Wu, Hui, Zhang, Jie, Niu, Lixin, Chen, Wei, He, Jian, and Chou, Xiujian

Subjects

*TACTILE sensors, *ELECTROMAGNETS, *MORSE code, *MAGNETIC flux, *DETECTION limit, *MAGNETIC fields, *SUPERCONDUCTING coils

Abstract

With the rapid development of wearable devices, tactile sensors have received extensive attention as supplements to vision and hearing. However, it remains challenging for a single tactile sensor to generate distinguishable electrical signals when receiving mechanical stimuli in different directions. Herein, a novel flexible electromagnetic tactile sensor (FETS) prepared by combining flexible double‐layer coils and a flexible tilted magnetic column array (TMCA) is presented. Flexible double‐layer high‐density coils are fabricated using the micro‐electromechanical system (MEMS) technology. The turns of the coil (1 × 1 cm) are 100, while both the line width and spacing of turns are 40 µm. TMCA is prepared using a template and magnetized along the axis direction. When a pulling force or pressure is applied to the TMCA, the magnetic flux decreases or increases correspondingly, allowing the FETS to accurately distinguish stimuli and produce different signals (−/+ or +/−). The FETS presents a sensitivity of up to 21.7 µV kPa−1 (0.05–10 kPa), a minimal magnetic field detection limit of 10 mT, a low‐pressure detection limit of 5 g, and good repeatability (5000 cycles). Additionally, the FETS is applied in robotic tactile testing, Morse code, and noncontact magnetic field recognition. It has potential applications in the Internet of Things (IoT) and information communication. [ABSTRACT FROM AUTHOR]

Published

2024

32. Study on the Selection of Coil Energization Directions in Multistage Synchronous Induction Coil Launcher.

Author

Kang, Jiayu, Guan, Yuan, and Wan, Xiaobo

Subjects

INDUCTION coils, FINITE element method, SUPERCONDUCTING coils, ELECTROMAGNETIC coupling, ARMATURES, ENERGY conversion

Abstract

In order to enhance the initial velocity and energy conversion efficiency of multi-stage synchronous induction coil launchers, the direction of coil energization for the drive coils is studied. There are typically two energization methods for multi-stage launching devices: (1) PP (Positive-Positive), where positive current is applied to all drive coils, and (2) PN (Positive-Negative), where currents in opposite directions are alternately applied to the drive coils. A finite element model of a four-stage coil launcher is established in ANSYS2022R2, and the acceleration effects of the armature under different inter-stage distances are analyzed for two energization methods. The study reveals that the PN configuration does not always result in higher armature velocities compared to the PP configuration under different inter-stage distances. The theoretical explanation is provided for the variations in the forces exerted by the previous and next drive coils on the armature during the acceleration process. It is found that the magnitude of the induced current in the previous and next drive coils during the launch process is influenced by the inter-stage distance, which in turn affects the electromagnetic thrust coupled with the armature. Thus, the method of determining the direction of current in the launching device coil is obtained. [ABSTRACT FROM AUTHOR]

Published

2024

33. A Novel CAD Structure with Bakelite Material-Inspired MRI Coils for Current Trends in an IMoT-Based MRI Diagnosis System.

Author

Sakthisudhan, K., Saranraj, N., Vinothini, V. R., Sekaran, R. Chandra, and Saravanan, V.

Subjects

BODY area networks, MAGNETIC resonance imaging, ORGANS (Anatomy), COPLANAR waveguides, IMAGING phantoms, DIELECTRIC strength, SUPERCONDUCTING coils

Abstract

The research work proposed for the X-band microstrip line-based magnetic resonance imaging (MRI) coils has been accomplished with coplanar waveguide feeding and ha highlighted the design parameters to be employed in the internet of medical things (IoMT) features. The proposed research has focused on the wireless body area networks (WBAN) phenomenon in simulated human organs. It has been employed to study the electro-magnetic (EM) parameters of the simulated human organ and the functioning of wearable MRI coils on the human body. Therefore, these coils have been configured in triangle-shaped hierarchical structures, and each layer has been printed on both sides of the conductive strips. These proposed coils utilize a Bakelite substrate with a 1.6-mm thickness and an equivalent dielectric strength of 1.2. It has 69.9 × 85.2 × 1.6 mm3 dimensions and was fabricated using microwave integrated circuits (MIC). These coils have been generated at 8 GHz and this spectrum has been justified with the microwave X band (8–12 GHz) using the standard measured results. Hence, these coils have demonstrated 45.81-dB signal attenuation with a 1-dB standing wave ratio (SWR). Therefore, this research has extended to the different kinds of virtual simulation scenarios in diagnosis applications. Additionally, the research delves into the electromagnetic characteristics, encompassing electric and magnetic fields, the specific absorption ratio (SAR), and temperature. These characteristics are thoroughly analyzed using MRI phantom models within virtual environments. As a result of this comprehensive analysis, the suitability and efficacy of these MRI coils have met rigorous standards. These coils are highly demanded by complicated systems functioning in these bands for IoMT and MRI diagnosis applications. [ABSTRACT FROM AUTHOR]

Published

2024

34. Measuring the Magnetic Field of a Solenoid Using a Reed Relay.

Author

Kladivová, Mária and Duranka, Peter

Subjects

*SOLENOID magnetic fields, *HALL effect transducers, *MAGNETISM, *ELECTRIC currents, *MAGNETIC fields, *SUPERCONDUCTING coils

Abstract

The article discusses an experiment using a reed relay to map the magnetic field of a solenoid coil. The setup involves measuring the electrical currents at which the relay turns on and off, calculating relay constants, and plotting experimental and theoretical magnetic field dependences. The experiment is suitable for high school and undergraduate students and can be adapted to measure the magnetic field of a permanent magnet. The study was supported by the Scientific Grant Agency of the Ministry for Education of the Slovak Republic and conducted by Mária Kladivová and Peter Duranka, experts in physics and engineering. [Extracted from the article]

Published

2024

35. Physics in FOCUS.

Subjects

*FARADAY'S law, *ELECTROMAGNETIC induction, *ELECTROMOTIVE force, *ELECTRIC currents, *MAGNETIC flux, *SUPERCONDUCTING coils

Abstract

This article from Physics For You provides a detailed explanation of electromagnetic induction, covering topics such as Faraday's Laws of Electromagnetic Induction, magnetic flux, Lenz's Law, motional electromotive force, eddy currents, self-inductance, mutual inductance, and the combination of inductances. It also discusses the working principle of an AC generator. The information is presented clearly and concisely, with high-definition images to aid understanding. The document also discusses Kirchhoff's loop law and its application to an LR circuit, providing equations for calculating current and time constant. It explains the decay of current in an LR circuit with a step-by-step example. The information is presented in a technical manner and would be useful for library patrons researching electrical circuits. [Extracted from the article]

Published

2024

36. ITER and World Fusion Work Advance With New Record at WEST Device.

Author

Vereycken, Karel

Subjects

NUCLEAR energy, PLASMA physics, SUPERCONDUCTING coils, FUSION reactors, LASER fusion

Abstract

The article provides an overview of the advancements in fusion power research at the WEST device, a part of the ITER project. The WEST device, formerly known as Tore SUPRA, has been upgraded with a tungsten divertor to improve heat conduction and plasma confinement. The article highlights the collaboration between various countries in building the largest fusion reactor in history. The recent achievements of the WEST device, including record plasma confinement duration and doubled plasma density, contribute to the research and development of fusion technology for the ITER project. The text emphasizes the cooperative nature of the scientific community involved in ITER and mentions the challenges that still need to be addressed. It concludes by mentioning a forthcoming strategic document from the International Atomic Energy Agency that will provide an overview of fusion energy development. [Extracted from the article]

Published

2024

37. Fast evaluation of the critical current of high-temperature superconducting coils based on the integral method.

Author

Zhong, Junlin, Zou, Shengnan, Lai, Lingfeng, Chen, Pengrong, and Deng, Shutong

Subjects

*CRITICAL currents, *SUPERCONDUCTING magnets, *SUPERCONDUCTING coils, *HIGH temperature superconductors, *SUPERCONDUCTORS, *FINITE element method, *DENSITY of states

Abstract

The need for energy is growing as civilization develops. Superconductors have various benefits over regular conductors, including a high current-carrying density and nearly no resistance. Therefore, the objective that scientists continue to seek is the use of superconductors to replace traditional conductors in order to satisfy the demand for energy. As a key part of the superconducting electrical system, the critical current is one of the key properties of high-temperature superconducting (HTS) coils. Scholars have created a variety of numerical simulation models to estimate the performance of HTS coils. However, the extremely nonlinear E–J power law relationship that characterizes the voltage–current relationship in superconducting materials necessitates numerous iterative refinements during the coil design stage, which is time-consuming from the perspective of computing efficiency. Consequently, it is essential to increase computational efficiency. In this study, the critical current of HTS coils was calculated using the J model (integral method with the current density J as the state solution variable), and it was proved to be an efficient research method. The accuracy of the method is verified by comparing with the H model and the experimental measurement results of the critical current of the HTS coil. Moreover, compared with the reference finite element simulation model, this model has a speed advantage of at least four times, which is a good choice, especially, for HTS circular coils with large turns. [ABSTRACT FROM AUTHOR]

Published

2022

38. Magnetic field detection utilizing soft magnetic ribbons and a rectangular solenoid.

Author

Bao, Jinfeng, Mu, Yimin, Ding, LiDong, Zhu, Wenjun, Zhang, Mengyi, and Yi, Yang

Subjects

*MAGNETIC fields, *SOLENOIDS, *GIANT magnetoresistance, *MAGNETIC sensors, *CENTROID, *COPPER wire, *MAGNETIC cores, *SUPERCONDUCTING coils

Abstract

An effective approach to high-sensitivity magnetic field detection under low-frequency excitation by soft magnetic ribbons and a rectangular solenoid is proposed and certificated. The solenoid wound by nonmagnetic copper wire is located at the geometric center region of the soft magnetic ribbons that act as the magnetic core. The proposed magnetic sensor utilizes the nonlinear magnetization of soft magnetic ribbons and the magneto-inductive effect and proximity effect of the solenoid, exhibiting significant impedance variation at a relatively low frequency. The impedance ratio and impedance sensitivity of the prototype reaches the maximum value of 5630% and 570% Oe−1 at 500 kHz, which is far superior to the conventional giant magneto-impedance (GMI) magnetic sensor and planar coil laminated GMI magnetic sensor. The investigation indicates the fabricated magnetic sensor with optimal dimension parameters can provide a sensitivity of 3329 mV Oe−1 at 500 kHz. More importantly, the proposed prototype is particularly suitable for micromachining, providing the possibility for manufacturing high-sensitivity micro-magnetic sensors. [ABSTRACT FROM AUTHOR]

Published

2024

39. Numerical investigation on a dual-nozzle ejector with spiral guide blades for hydrogen recirculation system.

Author

Li, Zekai, Yin, Bifeng, Xu, Sheng, Qin, Wenshan, and Dong, Fei

Subjects

*SUPERCONDUCTING coils, *NOZZLES, *GAS flow, *KINETIC energy, *HYDROGEN, *COMPUTATIONAL fluid dynamics, *RADIAL flow, *FUEL cells

Abstract

Hydrogen ejectors effectively utilize excess unreacted hydrogen. However, traditional ejectors have limited operational ranges and are only suitable for specific power ranges. This paper presents a dual-nozzle ejector aimed at broadening its operational range through different working modes. A simulation model, validated by experiments, is employed based on the working principles of ejectors. Spiral blades are installed at drive end to improve the recirculation efficiency. Flow characteristics, including streamwise and spanwise vortices at high power, are also investigated in different modes. Results indicate that optimal operating range for Ring-nozzle(RN) mode is between 31.1 and 124.4A. When output current exceeds 124.4A, it is necessary to switch to Central-nozzle (CN) or Double-nozzles (DNs) mode. Analysis of streamlines and velocity vectors reveals that installing spiral blades can modify directions of primary flow. Blades with appropriate distortion should be selected. In CN mode, when stack reaches 60% of rated power, installing 20° spiral blades has a minimal impact on stability of radial flow. Installing 30° or 40° spiral blades is suitable for full-load condition. In DNs mode, installing 30° spiral blades enhances acceleration of gas flow with lower influence from radial influx. This ejector provides assurance for upgrade of fuel cell stacks by incorporating recirculation technology. • A dual-nozzle ejector with spiral guide blades is designed, verified and evaluated. • Installed spiral blades change direction and gather kinetic energy of primary flow. • Advantageous working conditions of different modes with blades are discussed. • Flow mechanism of different blades under high power in two modes is analyzed. • Flow acceleration and losses should be balanced by changing the twist of blades. [ABSTRACT FROM AUTHOR]

Published

2024

40. Assemblies of Coaxial Pick-Up Coils as Generic Inductive Sensors of Magnetic Flux: Mathematical Modeling of Zero, First and Second Derivative Configurations.

Author

Moraitis, Petros and Stamopoulos, Dimosthenis

Subjects

*INDUCTIVE sensors, *MAGNETIC flux, *MAGNETIC sensors, *MAGNETIC declination, *MAGNETIC fields, *GEOPHYSICS, *SUPERCONDUCTING coils

Abstract

Coils are one of the basic elements employed in devices. They are versatile, in terms of both design and manufacturing, according to the desired inductive specifications. An important characteristic of coils is their bidirectional action; they can both produce and sense magnetic fields. Referring to sensing, coils have the unique property to inductively translate the temporal variation of magnetic flux into an AC voltage signal. Due to this property, they are massively used in many areas of science and engineering; among other disciplines, coils are employed in physics/materials science, geophysics, industry, aerospace and healthcare. Here, we present detailed and exact mathematical modeling of the sensing ability of the three most basic scalar assemblies of coaxial pick-up coils (PUCs): in the so-called zero derivative configuration (ZDC), having a single PUC; the first derivative configuration (FDC), having two PUCs; and second derivative configuration (SDC), having four PUCs. These three basic assemblies are mathematically modeled for a reference case of physics; we tackle the AC voltage signal, VAC (t), induced at the output of the PUCs by the temporal variation of the magnetic flux, Φ(t), originating from the time-varying moment, m(t), of an ideal magnetic dipole. Detailed and exact mathematical modeling, with only minor assumptions/approximations, enabled us to obtain the so-called sensing function, FSF, for all three cases: ZDC, FDC and SDC. By definition, the sensing function, F S F , quantifies the ability of an assembly of PUCs to translate the time-varying moment, m(t), into an AC signal, VAC (t). Importantly, the F S F is obtained in a closed-form expression for all three cases, ZDC, FDC and SDC, that depends on the realistic, macroscopic characteristics of each PUC (i.e., number of turns, length, inner and outer radius) and of the entire assembly in general (i.e., relative position of PUCs). The mathematical methodology presented here is complete and flexible so that it can be easily utilized in many disciplines of science and engineering. [ABSTRACT FROM AUTHOR]

Published

2024

41. MPI System with Bore Sizes of 75 mm and 100 mm Using Permanent Magnets and FMMD Technique.

Author

Jeong, Jae Chan, Kim, Tae Yi, Cho, Hyeon Sung, Seo, Beom Su, Krause, Hans Joachim, and Hong, Hyo Bong

Subjects

*MAGNETIC particle imaging, *MECHANICAL movements, *IMAGE reconstruction, *SUPERCONDUCTING coils, *FERRIC oxide, *ENERGY consumption

Abstract

We present two magnetic particle imaging (MPI) systems with bore sizes of 75 mm and 100 mm, respectively, using three-dimensionally arranged permanent magnets for excitation and frequency mixing magnetic detection (FMMD) coils for detection. A rotational and a translational stage were combined to move the field free line (FFL) and acquire the MPI signal, thereby enabling simultaneous overall translation and rotational movement. With this concept, the complex coil system used in many MPI systems, with its high energy consumption to generate the drive field, can be replaced. The characteristic signal of superparamagnetic iron oxide (SPIO) nanoparticles was generated via movement of the FFL and acquired using the FMMD coil. The positions of the stages and the occurrence of the f1 + 2f2 harmonics were mapped to reconstruct the spatial location of the SPIO. Image reconstruction was performed using Radon and inverse Radon transformations. As a result, the presented method based on mechanical movement of permanent magnets can be used to measure the MPI, even for samples as large as 100 mm. Our research could pave the way for further technological developments to make the equipment human size, which is one of the ultimate goals of MPI. [ABSTRACT FROM AUTHOR]

Published

2024

42. Evaluation of Two Digital Wound Area Measurement Methods Using a Non-Randomized, Single-Center, Controlled Clinical Trial.

Author

Casanova-Lozano, Lorena, Reifs-Jiménez, David, Martí-Ejarque, Maria del Mar, Reig-Bolaño, Ramon, and Grau-Carrión, Sergi

Subjects

MACHINE learning, CLINICAL trials, SKIN imaging, UNITS of measurement, AUGMENTED reality, SUPERCONDUCTING coils

Abstract

A prospective, single-center, non-randomized, pre-marketing clinical investigation was conducted with a single group of subjects to collect skin lesion images. These images were subsequently utilized to compare the results obtained from a traditional method of wound size measurement with two novel methods developed using Machine Learning (ML) approaches. Both proposed methods automatically calculate the wound area from an image. One method employs a two-dimensional system with the assistance of an external calibrator, while the other utilizes an Augmented Reality (AR) system, eliminating the need for a physical calibration object. To validate the correlation between these methods, a gold standard measurement with digital planimetry was employed. A total of 67 wound images were obtained from 41 patients between 22 November 2022 and 10 February 2023. The conducted pre-marketing clinical investigation demonstrated that the ML algorithms are safe for both the intended user and the intended target population. They exhibit a high correlation with the gold standard method and are more accurate than traditional methods. Additionally, they meet the manufacturer's expected use. The study validated the performance, safety, and usability of the implemented methods as a valuable tool in the measurement of skin lesions. [ABSTRACT FROM AUTHOR]

Published

2024

43. NUMERICAL COMPLEXITY OF HELIX UNRAVELING ALGORITHM FOR CHARGED PARTICLE TRACKING.

Author

TOPOLNICKI, KACPER and BOLD, TOMASZ

Subjects

*NUCLEAR track detectors, *MONTE Carlo method, *ALGORITHMS, *SUPERCONDUCTING coils, *MAGNETIC fields

Abstract

This paper describes a procedure for estimating the number of iterations in the main loop of a recently proposed algorithm designed to detect helical charged particle tracks in detectors submerged in a magnetic field. The calculations are based on a Monte Carlo simulation of the ATLAS inner detector. The resulting estimates of numerical complexity suggest that using the new procedure for online triggering is not feasible. There are however some areas, such as triggering for particles in a specific sub-domain of the phase space, where using this procedure might be beneficial. [ABSTRACT FROM AUTHOR]

Published

2024

44. Application and analysis of superconducting magnetic eddy current heater used in wind thermal power generation system.

Author

Zhang, Wenfeng, Chen, Chen, Liu, Zeyuan, Wang, Youhua, and Liu, Chengcheng

Subjects

*WIND power, *HEAT storage devices, *SUPERCONDUCTORS, *SUPERCONDUCTING coils, *HEATING, *WIND forecasting

Abstract

In order to cope with the grid fluctuation caused by large‐scale wind power connected to the grid, the wind thermal power generation system has been proposed and extensively studied. The wind thermal power generation system uses a wind turbine to drive a heat generation device to heat the heat storage medium, which is further exchanged to drive a turbine to generate electricity. A superconducting magnetic eddy current heater (SMH) is proposed for the characteristics of wind thermal power generation system, which uses non‐resistive, large current‐carrying superconducting coils for excitation, and has high output efficiency and power density. The working principle of magnetic eddy current heating is analysed, and the structure of SMH with no ferromagnetic material and two heating screens inside and outside is proposed according to the characteristics of SMH. An analytical model of the SMH is established, and the influence of the structure and materials of the SMH on the magnetic field distribution is analysed. Based on this, a 22‐pole SMH was designed and analysed for output power at 10–20 rpm. A three‐dimensional magnetism‐stress combined analysis model of SMH is established, and the strain and stress characteristics of SMH are simulated under the condition of maximum output power, which verifies the feasibility of the mechanical properties of existing superconducting materials for application in SMH. [ABSTRACT FROM AUTHOR]

Published

2024

45. Effect of local and global screening current on the current decay in closed-loop HTS coils.

Author

Zhou, Pengbo, Zhang, Shuai, Wang, Ruichen, Li, Songlin, Grilli, Francesco, and Ma, Guangtong

Subjects

*SUPERCONDUCTING coils, *HIGH temperature superconductors, *ELECTRIC circuits, *FINITE element method, *ELECTROMAGNETS, *POWER resources

Abstract

High-temperature superconducting (HTS) coils are generally operated in a closed-loop persistent current mode, which is crucial for ensuring long-term stability and minimizing heat generation in various applications. However, factors such as joint resistance, flux creep, and losses due to external fields can lead to accelerated decay of the coil's current, making it challenging to achieve an effective persistent current mode. To gain insight into the current decay characteristics of HTS coils, we built a finite element method based model coupled with a lumped parameter electric circuit model. The model is initially verified against the experiment of an inductive magnetized HTS coil subject to a magnetic field perpendicular to the tape surface. The results indicate that the proposed model is highly effective in predicting the current decay behavior of this magnetized HTS coil and is able to provide high accuracy. With the help of this model, we have experimentally and numerically studied the behavior of a current-carrying closed-loop HTS coil subject to external alternating fields. The HTS coil is charged by a DC power supply and then shorted using a thermally-controlled persistent current switch. The current decay behavior of the HTS coil is examined under various scenarios. The simulation results show excellent agreement with experimental data, further validating the effectiveness and versatility of the modeling strategy. The influence of both local and global screening currents on the current decay performance of the closed-loop HTS coils has been investigated. For every case examined, rapid demagnetization occurred in the initial cycle of the applied alternating field. Furthermore, the current decay rate demonstrated a slight dependence on the frequency of the applied fields. Additionally, the resulting resistance has been thoroughly characterized. These insights contribute to the knowledge of the behavior and performance of closed-loop HTS coils, facilitating their practical application. [ABSTRACT FROM AUTHOR]

Published

2024

46. Reconstruction of the Ferromagnetic Hysteresis in the Rayleigh Regime by Means of Impedance Analysis of the Excitation Coil.

Author

Thieltges, Sascha, Youssef, Sargon, and Hartmann, Uwe

Subjects

*SUPERCONDUCTING coils, *HYSTERESIS, *MEASUREMENT

Abstract

Ferromagnetic hysteresis measurements can be used to determine both magnetic and mechanical state variables that correlate with each other. Therefore, hysteresis measurements are suitable for mechanical material characterization. The application of standardized hysteresis measurement methods is complex and can only be used to a limited extent in an industrial environment. In this work, a BH (ferromagnetic hysteresis) curve is to be reconstructed on 22NiMoCr3-7 samples that are in different mechanically deformed states (different histories). The reconstruction of the hysteresis is performed by an impedance analysis of the H-field generating coil. The applied method demonstrates that the ferromagnetic hysteresis can be reconstructed by means of an impedance analysis and is sensitive to different states of plastical deformation. [ABSTRACT FROM AUTHOR]

Published

2024

47. On the influence of an energy harvesting device on a dynamical system.

Author

Amer, TS, Arab, A, and Galal, AA

Subjects

*DYNAMICAL systems, *ENERGY harvesting, *LAGRANGE equations, *FORCE & energy, *EQUATIONS of motion, *MOTION, *SUPERCONDUCTING coils

Abstract

This article studies the motion of a three degrees-of-freedom (DOF) dynamical system, which consists of two parts, a dynamic part, and an electromagnetic harvesting device. The composition of the system depends on the magnet oscillating in the coil of this device. An electric potential is exerted because of the electromotive force to obtain energy harvesting (EH). Lagrange's equations (LE) are used to derive the system's equations of motion (EOM), which are solved analytically up to a third-order of approximation using the multiple-scales method (MSM). These solutions are considered novel, in which the mentioned method is applied to a novel dynamical system. The gained are confirmed through comparison with the numerical solutions of the EOM to reveal a high degree of consistency. To establish the system's solvable conditions and modulation equations (ME), three scenarios of primary external resonance are investigated simultaneously. Certain diagrams of time histories for the amplitudes and phases of the examined dynamical system are plotted to show their behaviors at any given instance of time. The Routh–Hurwitz criteria (RHC) are used to establish the stability and instability regions in light of the graphs of resonance response curves. The presence of an energy harvester in dynamic devices helps us to convert vibrational motion into electrical energy that can be exploited in several applications in a variety of daily tasks, including structural and environmental monitoring, military applications, space exploration, and remote medical sensing. [ABSTRACT FROM AUTHOR]

Published

2024

48. Effect of nozzle contamination on microwave discharge cathode performance.

Author

Morishita, Takato, Tsukizaki, Ryudo, and Nishiyama, Kazutaka

Subjects

*HIGH-frequency discharges, *CATHODES, *NOZZLES, *ELECTRON emission, *CURRENT-voltage characteristics, *POLYTEF, *SUPERCONDUCTING coils

Abstract

An understanding of the degradation mechanism of a microwave discharge cathode is the key to extending the lifetime of microwave ion thruster systems. This study investigates the effect of nozzle contamination by sputtered Ag-polytetrafluoroethylene (PTFE) on microwave discharge cathode performance. The current–voltage characteristics were measured for nominal and contaminated (by PTFE spray with 0.2 µm thick or tape with 0.15 mm thick) cathodes. The contamination thickness and area on the nozzle were varied to investigate the characteristic differences. It was confirmed that the anode voltage increased by 20 V or more in the case of the contaminated cathode. The anode voltage was measured for the sputter-contaminated cathode to evaluate the effect of contamination under more realistic conditions. After 630 h of sputter-contamination operation, it is estimated that sputtered particles were deposited to a thickness of 77 µm at most, and the anode voltage increased by 8 V. The results show that the downstream surface of the nozzle is critical for maintaining cathode performance. The insulating coating formed by the sputtered PTFE may interfere with ion absorption and degrade electron emission capability. A theoretical model based on the extended Brophy model supports these results. This study provides important information for the use of PTFE-based materials around ion thrusters. [ABSTRACT FROM AUTHOR]

Published

2024

49. Impact of Combined Modulation of Two Potassium Ion Currents on Spiral Waves and Turbulent States in the Heart.

Author

Bai, Jing, Zhang, Chunfu, Liang, Yanchun, Tavares, Adriano, and Wang, Lidong

Subjects

*POTASSIUM ions, *MYOCARDIAL depressants, *CARDIAC research, *DRUG target, *POTASSIUM antagonists, *SUPERCONDUCTING coils

Abstract

In the realm of cardiac research, the control of spiral waves and turbulent states has been a persistent focus for scholars. Among various avenues of investigation, the modulation of ion currents represents a crucial direction. It has been proved that the methods involving combined control of currents are superior to singular approaches. While previous studies have proposed some combination strategies, further reinforcement and supplementation are required, particularly in the context of controlling arrhythmias through the combined regulation of two potassium ion currents. This study employs the Luo–Rudy phase I cardiac model, modulating the maximum conductance of the time-dependent potassium current and the time-independent potassium current, to investigate the effects of this combined modulation on spiral waves and turbulent states. Numerical simulation results indicate that, compared to modulating a single current, combining reductions in the conductance of two potassium ion currents can rapidly control spiral waves and turbulent states in a short duration. This implies that employing blockers for both potassium ion currents concurrently represents a more efficient control strategy. The control outcomes of this study represent a novel and effective combination for antiarrhythmic interventions, offering potential avenues for new antiarrhythmic drug targets. [ABSTRACT FROM AUTHOR]

Published

2024

50. Graph-Based Modeling and Optimization of WPT Systems for EVs.

Author

Hansen, Matthew J., Droge, Greg, and Kamineni, Abhilash

Subjects

WIRELESS power transmission, ELECTRICAL load, MATHEMATICAL optimization, ENERGY transfer, SUPERCONDUCTING coils

Abstract

A model of a system of wireless power transfer (WPT) pads is developed, where each WPT pad is modeled as a node and the coupling between pads is modeled as graph edges. This modeling approach is generalized to admit primary, secondary, and booster coils, where power can flow among the pads and a pad can fill multiple roles. An excitation in one pad induces voltage and current in all neighboring pads, causing each pad to act as both a booster coil and either a transmitter or a receiver. Power flow through the entire system can be modeled with the graph structure; the power flow can then be optimized by alternating the phases of the WPT excitations to maximize power transfer. An example is shown where exploiting the graph-based WPT system modeling increases total energy transfer by 25% compared to another method. This increase occurs without altering the geometry of the pads or the magnitude of the pad excitations. [ABSTRACT FROM AUTHOR]

Published

2024