Your search keyword '"SOLENOIDS"' showing total 1,887 results

1. A Fast Actuation Mechanism and Energy-Effective Driving Method for Pulse-Closers.

Author

Yoon, Joanne, Jung, Raehun, Kim, Young-il, Ye, Sung-Joon, and Bang, Young-bong

Subjects

*ELECTRIC power distribution, *MAGNETIC actuators, *ELECTRIC currents, *ELECTRIC lines, *FAULT currents

Abstract

When a recloser detects fault currents in electric power distribution lines, it breaks the line and then restores the line after several fault tests. To check whether fault remains, the recloser performs CO operations (opening the contacts after reclosing them for a while). In this operation, the fault currents flow into the line, potentially causing damage to equipment connected to the line. Therefore, reducing the current-carrying time during the fault test is desirable, but this reduction is difficult because of the slow actuation mechanism of reclosers. In this article, a novel actuation mechanism combining a permanent magnetic actuator (PMA) and a solenoid actuator (SA) is proposed. During the CO operations for the fault tests, the proposed mechanism can rapidly break the closed contacts by hitting the moving contact with the SA. To increase the energy efficiency of the actuation mechanism, a distinctive PMA driving method is also proposed; it weakens the strong holding force of the PMA using assistive magneto-motive force (MMF). The structure and configuration of the proposed mechanism are explained. The performance of the mechanism and the effectiveness of the driving method are studied through cosimulations. Finally, a prototype is developed, and its practicality is verified through experiments. [ABSTRACT FROM AUTHOR]

Published

2023

2. A 2.5m Long-Range IPT System Based on Domino Cylindrical Solenoid Coupler Compensated Respectively in Layers.

Author

Gu, Peng, Liu, Zhimin, Guan, Honglu, Wang, Yijie, Mai, Jianwei, Zhou, Yuhao, Liu, Jianxing, and Xu, Dianguo

Subjects

*SOLENOIDS, *SMART power grids, *MAGNETIC insulators, *MAGNETIC structure, *POLITICAL succession, *INTELLIGENT sensors, *MEASURING instruments

Abstract

In this article, a 2.5m five-stage inductive power transfer (IPT) system based on domino cylindrical solenoid coupler (CSC) compensated, respectively, in layers is proposed. The system is considered to be used as 220 kV post insulators application, transferring power for sensors and measuring instruments of smart grids. The distributed series compensation method is applied to double-layer CSC. Compared with the two types of parallel schemes, this method can significantly reduce the current of the main circuit. Compared with the concentrated series compensation method, this method can effectively reduce the resistance caused by the stray capacitance. The interaction between the post insulator and the magnetic coupling structure is analyzed. The circuit model of the system with constant voltage output characteristics is analyzed. A prototype with a maximum efficiency of 66.7% is built. When the power is transferred to a larger value of 77.8W, the efficiency can still reach 62%. Comparing with previous works, the wireless distance is extended while the efficiency is improved. [ABSTRACT FROM AUTHOR]

Published

2023

3. Sensor Fusion of Self-Sensed Measurements for Position Control of a Constant Air-Gap Solenoid.

Author

Reinholz, Bradley A. and Seethaler, Rudolf J.

Abstract

This article presents a novel constant air-gap solenoid (CAS) actuator design that can perform accurate and wide-bandwidth closed-loop position control with two fused self-sensed plunger measurements. The recently patented CAS actuator is experimentally validated to be the first electromagnetic actuator with the ability to simultaneously produce two plunger position measurements with complementary bandwidth characteristics. First, a variable reluctance differential solenoid transducer (VRDST) is converted into a stacked CAS actuator through minor geometry modifications. Next, two complementary self-sensing methods that are based on inductance and back electromotive force (BEMF) are selected. Then, a complementary filter design is proposed to fuse the inductance- and BEMF-based self-sensing methods. Afterward, the design and fabrication of the prototype CAS actuator and the experimental setup are discussed. The experimental setup is then used to characterize the prototype CAS actuator and observe the performance of the individual self-sensing methods. Finally, the fused measurement is used for feedback in closed-loop position control. The closed-loop position control experiments show that the self-sensed feedback performs comparably with a dedicated high-end laser vibrometer. Furthermore, the results show that the sensor fusion output performs better than the individual self-sensing methods. [ABSTRACT FROM AUTHOR]

Published

2022

4. Venc Design and Velocity Estimation for Phase Contrast MRI.

Author

Zhao, Shen, Ahmad, Rizwan, and Potter, Lee C.

Subjects

*PHASE contrast magnetic resonance imaging, *PHASE velocity, *STANDARD deviations, *DISTRIBUTION (Probability theory), *SOLENOIDS, *MAXIMUM likelihood statistics

Abstract

In phase-contrast magnetic resonance imaging (PC-MRI), spin velocity contributes to the phase measured at each voxel. Therefore, estimating velocity from potentially wrapped phase measurements is the task of solving a system of noisy congruence equations. We propose Phase Recovery from Multiple Wrapped Measurements (PRoM) as a fast, approximate maximum likelihood estimator of velocity from multi-coil data with possible amplitude attenuation due to dephasing. The estimator can recover the fullest possible extent of unambiguous velocities, which can greatly exceed twice the highest venc. The estimator uses all pairwise phase differences and the inherent correlations among them to minimize the estimation error. Correlations are directly estimated from multi-coil data without requiring knowledge of coil sensitivity maps, dephasing factors, or the actual per-voxel signal-to-noise ratio. Derivation of the estimator yields explicit probabilities of unwrapping errors and the probability distribution for the velocity estimate; this, in turn, allows for optimized design of the phase-encoded acquisition. These probabilities are also incorporated into spatial post-processing to further mitigate wrapping errors. Simulation, phantom, and in vivo results for three-point PC-MRI acquisitions validate the benefits of reduced estimation error, increased recovered velocity range, optimized acquisition, and fast computation. A phantom study at 1.5T demonstrates 48.5% decrease in root mean squared error using PRoM with post-processing versus a conventional “dual-venc” technique. Simulation and 3T in vivo results likewise demonstrate the proposed benefits. [ABSTRACT FROM AUTHOR]

Published

2022

5. A Multi-Segment Compensation Method for Improving Power Density of Long-Distance IPT System.

Author

Mai, Jianwei, Wang, Yijie, Zeng, Xianrui, Yao, Yousu, Wu, Kang, and Xu, Dianguo

Subjects

*WIRELESS power transmission, *INDUCTIVE power transmission, *QUALITY factor, *MEDICAL electronics, *POWER (Social sciences)

Abstract

Inductive power transmission has been applied in industries, such as electric vehicles, consumer electronics and biomedical fields. However, there is a long-term key problem in this field that has not been solved. This is the adverse effect of the parasitic capacitance of the coil, which will cause the change of the coil inductance, the reduction of the quality factor and the reduction of efficiency. Especially in the field of long-distance wireless power transmission. The existing technologies all adopt the scheme of sacrificing volume in exchange for the quality factor of the coil. As a result, the volume of the system is very large, and the quality factor of the coil is still not high enough because the influence of parasitic capacitance has not been completely eliminated. Here, we found the solution. Connect compensation capacitors in series to the coil sections to short-circuit the parasitic capacitance and reduce its loss. The designed system has a diameter of 502 mm and a thickness of 22 mm, which can transmit 115.2 W of power within a distance of two meters with an efficiency of 29%. [ABSTRACT FROM AUTHOR]

Published

2022

6. Analytical Winding Loss and Inductance Models for Gapped Inductors With Litz or Solid Wires.

Author

Ewald, Thomas and Biela, Jurgen

Subjects

*EDDY current losses, *ELECTRIC inductance, *AIR gap (Engineering), *PERMANENT magnets, *AIRPORTS, *SOLENOIDS

Abstract

In gapped inductors, the fringing field of the air gaps causes additional eddy current losses in the windings and an increase of the inductance. Since this impact of the fringing field is very significant, calculating the additional eddy current losses and the inductance increase is important in the design of inductors. This article proposes analytical formulas to accurately calculate the inductance and the additional eddy current losses in gapped inductors with solid round wire and Litz wire windings. The analytical formulas are verified by measurements, showing that the proposed models are accurate over a wide-frequency range. [ABSTRACT FROM AUTHOR]

Published

2022

7. Dynamics of Single Domain Wall Propagating in Bistable Microwire in Rapidly Changing Magnetic Field.

Author

Onufer, J., Ziman, J., Duranka, P., Samuhel, S., Horniakova, J., and Kladivova, M.

Subjects

*MAGNETIC fields, *INERTIAL mass, *MAGNETIC field measurements, *MAGNETIC domain

Abstract

The presented experimental method enables the study of the dynamics of a domain wall (DW) moving in bistable microwire in a region of rapidly changing magnetic field. DW velocity versus DW position dependence is obtained in this experiment. Measurements were carried out on Fe77.5Si15B7.5 microwire with strong unidirectional effect in DW propagation. The propagating DW is forced to change its parameters in a very short time, which results in the velocity increasing above its equilibrium value after the DW passes the region of rapid increase in magnetic field. In order to interpret the observed experimental behavior, a simple theoretical model was proposed. Comparison of experimental and model dependences produced a high value of DW inertial mass, indicating that the DW area was much larger than the cross-sectional area of the microwire. Another interesting conclusion was that a DW with stronger damping (shorter wall) does not have a lower value of inertial mass. [ABSTRACT FROM AUTHOR]

Published

2022

8. A Free-Rotation Asymmetric Magnetic Coupling Structure of UAV Wireless Charging Platform With Conformal Pickup.

Author

Bie, Zhi, Zhang, Jiantao, Song, Kai, Wang, Deaan, and Zhu, Chunbo

Subjects

*MAGNETIC structure, *WIRELESS power transmission, *MAGNETIC fields, *MAGNETIC materials, *MUTUAL inductance, *ROTATIONAL motion

Abstract

This article proposes an asymmetric magnetic coupler using the horizontal magnetic field to realize the conformal and lightweight unmanned aerial vehicle (UAV) side pickup mechanism and solve the problems of rotation misalignment and horizontal offset of UAVs. The novel structure uses multiple groups of series circular coils as the transmitting coil to construct a uniform near harness horizontal magnetic field. The solenoid structure covered with flexible magnetic material is used as the receiver, which is attached to the UAV landing gear. A 200-W prototype is produced to validate the proposed structure. The system can maintain smooth mutual inductance with a dc–dc efficiency of 90% under a ±20 mm offset and free-rotation. [ABSTRACT FROM AUTHOR]

Published

2022

9. Diagnosing Disk-Space Variation in Transformer Windings Using High-Frequency Inductance Measurement.

Author

Mukherjee, Pritam and Panda, Sanjib Kumar

Subjects

*ELECTRIC inductance, *WIND damage, *ELECTRIC utilities, *WIND power, *POWER transformers, *SOLENOIDS

Abstract

Leakage and magnetizing inductances of transformer windings are routinely measured by power utilities during scheduled maintenance. They are often used to confirm the diagnosis of mechanical damages in windings after Swept Frequency Response Analysis shows a mismatch. Inductance measurements performed at power frequency can possibly reveal the presence of damages that have substantially progressed but cannot detect them at their nascent stages since inductances at power frequency remain almost unaltered. This paper investigates the possibility of using high-frequency inductance to this end considering a frequently encountered mechanical damage, viz., disk-space variation in a disk winding. Effect of disk-space variation is investigated in this article using FEM at first and inductances at different frequencies are considered: magnetizing and leakage inductances at 50 Hz, and inductance at a higher frequency region corresponding to winding resonances, say, 500 kHz. The inductance at high frequencies not only exhibited increased sensitivity compared to that at power frequency, but also captured the extent of damage. Simulations performed using Ansys Maxwell and experimental results on an actual 1- $\phi$ transformer are reported. Results show that the high-frequency inductance not only offers a considerably increased sensitivity to disk-space variation in windings compared to the power frequency inductances, but also provides insight regarding the extent of movement which is not apparent from the frequency response. [ABSTRACT FROM AUTHOR]

Published

2022

10. Frequency-Dependent Inductance and Winding Loss Model for Gapped Foil Inductors.

Author

Ewald, Thomas and Biela, Jurgen

Subjects

*ELECTRIC inductance, *EDDY current losses, *SOLENOIDS, *MAGNETIC fields

Abstract

For comprehensively optimizing high-frequency foil inductors, calculating the increased inductance and the additional eddy current losses due to a two-dimensional magnetic fringing field caused by air gaps in the center leg is mandatory. This article proposes an analytical model that accurately calculates the inductance and the additional eddy current losses in gapped inductors with foil windings. The analytical field expressions are combined into closed-form winding loss and inductance formulas and verified by measurements. Furthermore, the frequency dependency of the inductance due to the shielding effect of the foil conductors is being discussed. [ABSTRACT FROM AUTHOR]

Published

2022

11. Design and Optimization of Wireless Charging Drawer Coil for Smart Garments.

Author

Chang, Chin-Wei, Riehl, Patrick, and Lin, Jenshan

Abstract

In this letter, wireless charging chests suitable for smart garments are analyzed and optimized. The coil structure is optimized to generate a uniform magnetic field in a variety of drawer sizes. With the hybrid Helmholtz–solenoid coil structure, the variation of coupling factor is reduced from 78.2% to 26.4% as compared with solenoidal coil. Two design approaches for multidrawer chest are examined. In the first approach, the coils are optimized for individual drawers. In the second approach, the coils are optimized by considering the entire drawer chest. The measurement results show that the second approach further reduces the variation of charging current of receiver coils placed at different locations. [ABSTRACT FROM AUTHOR]

Published

2022

12. 100-MW-Level Experiments of a Gyromagnetic Nonlinear Transmission Line System.

Author

Cui, Yancheng, Meng, Jin, Huang, Liyang, and Zhu, Danni

Subjects

*ELECTRIC lines, *VACUUM tubes, *MAGNETIC fields, *DELAY lines, *ELECTRON beams, *PERPENDICULAR magnetic anisotropy

Abstract

The wideband high-power microwave systems have the advantages of wide energy spectrum, electron beam independence, compactness, and low cost. The gyromagnetic nonlinear transmission line (GNLTL) has drawn much attention for its potential as a novel solid-state, frequency-agile, and compact wideband source. The working mechanism of GNLTL is different from that of the traditional electric vacuum tubes, and the strong dispersion and nonlinear characteristics make it difficult to be accurately theoretically calculated and simulated. In this article, a 100-MW-level GNLTL system based on a Tesla-type driver was designed and constructed. A series of test experiments were then carried out to investigate the effects of different configurations, including delay line length, ferrite cores’ assembly orientation, transmission line length, bias magnetic field magnitude, and excitation voltage. The changing laws of the key parameters of the output microwaves including the peak power, modulation depth, center frequency, and percentage band are summarized and the underlying physical mechanisms are analyzed. The results may be instructive for the predesign of GNLTLs, especially for the devices operating at high power. In addition, a multiple center frequency points’ phenomenon was discovered in the output signal, which may bring new application possibilities for GNLTL. [ABSTRACT FROM AUTHOR]

Published

2022

13. Embedded Magnetic Solenoid Inductor Into Organic Packaging Substrate Using Lithographic Via Technology for Power Supply Module Integration.

Author

Zhang, Weihao, Zhou, Guoyun, Gao, Qi, Jia, Wei, Chen, Xianming, Huang, Benxia, Feng, Lei, He, Wei, Wang, Chong, and Zhu, Yongkang

Subjects

*POWER resources, *SOLENOIDS, *MAGNETIC cores, *SOFT magnetic materials, *ELECTRIC inductance, *BUILDING-integrated photovoltaic systems

Abstract

In this article, an embedded magnetic solenoid inductor into an organic packaging substrate is implemented based on lithographically defined vias with a semiadditive process flow. In this solenoid inductor, the solid vertical interconnects and magnetic composite core are simultaneously utilized, both significantly reducing dc resistance and boosting inductance per unit area. A small-signal electrical test of the microinductor shows greatly improved performance including a flat dc inductance of 41.9 nH, low dc resistance of 60 $\text{m}\Omega $ , a peak quality of 42.7 at 92.8 MHz, and a high 10% saturation current of 3.81 A with a footprint area of 5.7 mm2. Consequently, the microinductor fabricated achieves a high inductance to resistance ratio of 0.7 nH/ $\text{m}\Omega $. Therefore, the proposed inductor achieves a superior ${Q}$ -factor of 42.7 that is the highest reported value for a solenoid magnetic power inductor with this prior art. The calculated peak effective inductor efficiency is 98.11% for 3.6- to 1-V, 100-MHz dc–dc conversion. [ABSTRACT FROM AUTHOR]

Published

2022

14. Theoretical and Experimental Study of Gyro-TWT Solenoids With Displacement and Tilt.

Author

Guan, Bo, Yao, Yelei, Jiang, Wei, Liu, Guo, Li, Hao, Wang, Jianxun, and Luo, Yong

Subjects

*SOLENOIDS, *GYROTRONS, *GLOBAL optimization, *MAGNETIC field measurements, *NUMERICAL calculations, *MATHEMATICAL optimization

Abstract

Axis coincidence consideration is necessary in the design of gyrotron solenoids; besides, radial field component strongly affects the performance of gyrodevices owing to the transverse particle–wave interaction mechanism in it, especially for high-frequency operation. In this article, the theory of multiple eccentric coils is derived. It is capable of calculating the off-axis field inside the solenoid with specified displacement and tilt. Numerical calculations are validated by 3-D electromagnetic simulation methods. Based on the measured magnet field, the displacement and tilt of a three-coil magnet system are successfully predicted with a global optimization algorithm, and then, the magnet system is well calibrated using a pair of flanges. [ABSTRACT FROM AUTHOR]

Published

2022

15. Experimental Assessment of the Thermal Strain Distribution in Nb 3 Sn React & Wind Conductor Prototype for European DEMO.

Author

Frittitta, C. and Sedlak, K.

Subjects

*THERMAL strain, *TOROIDAL magnetic circuits, *ELECTRIC conduits, *FUSION reactors, *CYCLIC loads, *TIN, *SOLENOIDS, *THERMOCYCLING

Abstract

In a typical Nb3Sn cable for fusion applications, the knowledge of the strain state of Nb3Sn filaments is important to predict and interpret the conductor performance in operation. Amongst the relevant strain sources, the predominant is the thermal strain that arises during the cool-down of the conductor to operating temperature, due to the different expansion of Nb3Sn and copper in the cable and the stainless steel conduit. This work addresses the characterization of Nb3Sn thermal strain in the React & Wind prototype (RW2) developed by EPFL-SPC for the toroidal field coil and the central solenoid of the EUROfusion DEMO fusion reactor. AC susceptibility measurements were performed on the RW2 prototype to assess the thermal strain distribution in the cable cross-section, before and after undergoing electromagnetic and thermal cyclic loading. The results of the analysis have shown that RW2 exhibits a significantly lower absolute mean strain value (about −0.3%), compared to many Wind & React ITER conductor samples investigated with the same method. In addition, the analysis highlighted that the assessed thermal strain distribution does not vary significantly before and after the electromagnetic and thermal cycles, confirming the small performance degradation in the RW2 conductor that has been recently reported. [ABSTRACT FROM AUTHOR]

Published

2022

16. Numerical Model Development for CFETR CSMC Quench Detection System.

Author

Wang, Teng, Hu, Yanlan, Wang, Zhongli, and Ni, Qicai

Subjects

*ELECTRIC potential measurement, *POWER resources, *MAGNETIC fields, *ELECTRIC inductance, *ALTERNATING currents, *SUPERCONDUCTING coils, *SOLENOIDS

Abstract

The Center Solenoid Model Coil (CSMC) is a pre-research project of CFETR, and its task is to design and manufacture the CS superconducting model coil to gain wider experience in solving the related technical problems existing in design and construction of CFETR CS coils. The expected achievement is to charge the CSMC up to the operation current of 47.65 kA and the maximum magnetic field to 12 T with a swift rump rate of 1.5 T/s without quench. Quench detection by voltage measurements is likely to be the fastest available technical solution to avoid coil's damage caused by quench, but the voltage detection is a real challenge due to large noise induced by the power supply in alternating current operation. The pick-up sensors, comprising the co-wound wire (CWW) and the co-wound tape (CWT), are used in the CSMC quench detection system for noise compensation and suppression. To accurately compensate all related induced voltage in the multi-pulse coil system, the foremost task is to estimate the static inductance matrix between the CSMC and its pick-up sensors. In this paper, a numerical model is developed for inductance calculation and analysis. Moreover, several numerical simulations with this design model to evaluate the maximum inductive noises and quench detection signals by CWW and CWT have been conducted for the case of the worst test scenarios. [ABSTRACT FROM AUTHOR]

Published

2022

17. Conceptual Design Studies of an HTS Insert for the DTT Central Solenoid.

Author

Giannini, L., Muzzi, L., Celentano, G., De Marzi, G., Romanelli, G., Zoboli, L., Turtu, S., Zenobio, A. Di, Califano, F., and della Corte, A.

Subjects

*HIGH temperature superconductors, *CONCEPTUAL design, *SOLENOIDS, *MAGNETIC flux density, *MAGNETIC flux

Abstract

The “Divertor Tokamak Test” (DTT) facility is an experimental fusion reactor being built in Frascati (IT) in the framework of the European Fusion Roadmap. The DTT Central Solenoid comprises six independently energized modules, wound from Nb3Sn Cable-In-Conduit Conductors (CICC). The future addition of a High Temperature Superconductor (HTS) insert would enhance the CS performance, in terms of magnetic flux density and magnetic field produced in the machine and would represent a fundamental technology demonstration toward high-field fusion. Along with the LTS cables, the Central Solenoid complex aims to reach 18 Wb at the pre-magnetization phase, being 16.54 Wb with the LTS CS only. Each LTS module is internally divided into three sub-modules: High Field (HF), Medium Field (MF) and Low Field (LF), each with a dedicated CICC cable optimized for the intense electromagnetic loads during the plasma scenarios. The LTS cables adopt a 316LN steel jacket and a fiberglass-reinforced resin insulation layer. The conceptual design presented here concerns an HTS insert, to be possibly placed inside the CS bore in the machine, employing a Round-In-Square (RIS) configuration of the conductor with either aluminum alloy or steel jackets. The study carried out for the design of the HTS insert and its pre-compression structure, the main electromagnetic and structural analyses and the design solution are presented in this work. [ABSTRACT FROM AUTHOR]

Published

2022

18. Numerical and Experimental Investigations of HTS Coils Inductance.

Author

Fawaz, S., Menana, H., and Douine, B.

Subjects

*ELECTRIC inductance, *HIGH temperature superconductors, *CURRENT distribution, *PANCAKES, waffles, etc., *SOLENOIDS

Abstract

In this article, the inductance variation with the current in high-temperature superconducting (HTS) pancake coils is investigated numerically and experimentally. Both dc and ac modeling approaches are developed. The results show that the dc modeling approach, even though it considers the non-uniformity of the current density distribution using a power minimization criterion, is not sufficient to characterize the inductance variation, which is affected by the dynamic behavior of HTS coils. The ac modeling approach reproduces a variation of the inductance similar to the experimental results. [ABSTRACT FROM AUTHOR]

Published

2022

19. Optimization of Coil Element Configurations Based on Matrix Gradient Coil.

Author

He, Hongyan, Wei, Shufeng, Wang, Huixian, and Yang, Wenhui

Subjects

*MAGNETIC resonance imaging, *POWER amplifiers, *MAGNETIC fields, *COST control, *SOLENOIDS

Abstract

Matrix gradient coils (also named multi-coils or arrays) have been introduced for magnetic resonance imaging (MRI) and shimming with amount of coil elements. However, equipping each coil element with a power amplifier is not always convenient because of expensive cost and complex control system. This study aims to analyze the effect of coil elements on generating magnetic fields and reduce the number of amplifiers, which is fewer than the number of coil elements for similar system performance, low cost, and simple control of matrix gradient coil system. A matrix gradient coil with 48-channels is created to generate the $X$ , $Y$ , and $Z$ gradient magnetic fields, respectively. The metric role of coil element is implemented, and the relationship between the distribution of coil elements and the target fields is analyzed. Eliminating the coil elements that have no effect on the target field and connecting the coil elements that have the same amplitude of current in series, the coil element configurations are obtained. Different configurations have different groups and coil elements in the same group are driven via an amplifier. Three power amplifiers are sufficient to generate the $X$ , $Y$ , and $Z$ gradient fields, respectively, in this study. Comparing the results of using full 48 amplifiers and using three amplifiers, the performances of the coil system for producing the magnetic fields are similar. Experiments for generating all linear gradient fields demonstrate that using fewer amplifiers to drive coil elements can also achieve acceptable results. The optimization method for configurating the coil elements is simple and time-saving to reduce the number of amplifiers to drive the matrix gradient coil. [ABSTRACT FROM AUTHOR]

Published

2022

20. Three-Dimensional Particle-in-Cell Analysis of Mechanical Design Tolerances of the Scorpius Injector With Warp.

Author

Clark, S. Eric, Stem, W. D., Melton, C. N., Pogue, N., and Ellsworth, J.

Subjects

*INJECTORS, *ELECTRON beams, *LINEAR accelerators, *NUCLEAR physics, *PLASMA beam injection heating, *MAGNETIC fields, *PARTICLE accelerators

Abstract

This article examines the mechanical design tolerances for the Scorpius injector using a 3-D particle-in-cell (PIC) code. In order to meet its objective as a high-fidelity, multipulse flash X-ray source, the accelerator has requirements for the electron beam in order to minimize the spot size of the beam focused onto a foil target to create high fluence X-rays at energies greater than 10 MeV. The requirements for alignment of the cathode, anode beam pipe, focusing solenoids, and transport solenoids specified using Trak and AMBER are independently verified using a 3-D electrostatic/magnetostatic model of the Scorpius injector, including transverse magnetic field errors that arise from mechanical alignment errors. It is predicted that the injector will meet the performance requirements for radiographic operation and has a design margin to correct for potentially unforeseen operating conditions. [ABSTRACT FROM AUTHOR]

Published

2022

21. Operation and Qualification of Coaxial Plasma Gun Modes With a Gas Puff Inlet.

Author

Chesny, David L., Moffett, Mark B., Hatfield, Kaleb W., Cole, Jake M., Landers, Kevin, Shokrollahi, Yasin, and Ege, Faraz

Subjects

*PLASMA torch, *PLASMA instabilities, *SPACE flight propulsion systems, *FAST ions, *PLASMA sheaths

Abstract

We describe the design, operation, and qualification of a coaxial plasma gun (CPG) in a low-pressure environment with a gas puff inlet. This infrastructure enables a CPG to operate in the deflagration mode followed by snowplow plasma sheath formation. These modes inject radially expanding and axially propagating plasma sheaths into a low-pressure residual background. This manuscript details the pulse power delivery circuit, including automatic logic control of subcircuits. High-speed camera images (12800 frames/s) of the formed plasma elucidate the ionization of an axially propagating plasma. Long-exposure images (1.3 s) capture the full propagation distance of the plasmoid. Rogowski coil current diagnostics elucidate the timing of a self-crowbar discharge that delineates between deflagration and snowplow modes. An empirically determined 50-ms gas puff duration resulted in a maximum plasma propagation distance of $\approx 23$ cm. Shorter durations did not ionize a sufficient amount of gas for elongated axial propagation, whereas longer durations suppressed axial plasma sheath expansion. This type of gas injection CPG device is now qualified for use in CPG experiments that require the snowplow mode and maximum mean free path of fast ions resulting from various plasma heating mechanisms. These include CPG operation within external magnetic fields in which significant plasma propagation distance is required, including solar physics experiments and space propulsion development. [ABSTRACT FROM AUTHOR]

Published

2022

22. Precision Motion Control of an Independent Metering Hydraulic System With Nonlinear Flow Modeling and Compensation.

Author

Li, Chen, Lyu, Litong, Helian, Bobo, Chen, Zheng, and Yao, Bin

Subjects

*NONLINEAR systems, *ROBUST control, *ADAPTIVE control systems, *PRESSURE drop (Fluid dynamics), *INVERSE functions, *VIDEO compression

Abstract

The independent metering system decouples the meter-in and meter-out flows of the chamber, giving extra control flexibility and can reducing energy consumption while keeping motion control accuracy. The control performance of the independent metering system is significantly determined by the valve characteristics.Valve nonlinearities, such as deadband, nonlinear flow gain, and leakage, may restrict the control accuracy. To address the issue and improve the system control precision, the nonlinearities of the valve need to be further modeled. In this article, a nonlinear valve flow model is proposed to accurately depict the relationships between the flow rate, pressure drop, and input voltage. The valve deadband is compensated by the static inverse function, while a certain polynomial projection function is used to mimic the nonlinear flow curve outside the deadband. To deal with uncertainties and nonlinearities in the independent metering system, an adaptive robust control approach is synthesized. The least-squares estimation law is adopted to online adapt the valve parameter and other system parameters. Comparative experiments were carried out to illustrate the effectiveness of the proposed approach. The results show that the valve flow nonlinearities are further captured by the proposed model, and the independent metering system performed a higher level control precision. [ABSTRACT FROM AUTHOR]

Published

2022

23. A Parametric Integral Formulation to Approximate the Magneto Quasi-Static Fields of 3-D Cylindrical Solenoids With Helical Winding.

Subjects

*SOLENOIDS, *MAGNETO, *MAGNETIC flux density, *ELLIPTIC integrals, *NUMERICAL integration

Abstract

The solenoid has been used extensively in a wide range of electrical applications. In the present work, an analytical model is presented for estimating the 3-D magneto quasi-static (MQS) fields of the cylindrical solenoid with helix-shaped (helical) wire winding. The proposed integral formulation is based on the Schur (Hadamard) vector product of the current vector $\vec {I}$ and the helical tangent vector $\vec {T}$ , to express the magnetic vector potential $\vec {A}$. The model is used to estimate the magnetic flux density vector $\vec {B}$ and the flux linkage $\Psi $ anywhere in 3-D space, excluding the (source) regions of conducting wire. A constant scaling coefficient, based on the measured terminal inductance, is proposed for calibration of the model’s magnetic field. Error analysis is presented on numerical integration, based on truncated series expansion of complete elliptic integrals in terms of Chebychev polynomials. The model may be used to estimate all three cylindrical components of MQS fields of solenoids as a function of core diameter, wire radius, the number of wire turns per winding layer, the number of winding layers, and complex permeability of frequency-dependent linear material. Several numerical examples are provided to validate the helical model against the superposition of circular loops and an idealized circuit model. [ABSTRACT FROM AUTHOR]

Published

2022

24. Cortical Bone Vibrations Induced by Electromagnetic Field Pulse.

Author

Royer, Robert, Harders, Walter, Moore, Lee R., Androjna, Caroline, Midura, Meredith, Kligman, Boris, Midura, Ronald J., Zhang, Nianli, Waldorff, Erik I., Ryaby, James T., and Zborowski, Maciej

Subjects

*ELECTROMAGNETIC fields, *ELECTROMAGNETIC pulses, *COMPACT bone, *VIBRATION (Mechanics), *MAGNETIC fields, *ELECTROMECHANICAL effects, *BONE shafts

Abstract

The purpose of our study was to test the hypothesis that the electromagnetic pulse (EMP) is capable of inducing mechanical vibrations in bone ex vivo. A thin segment of human femur diaphysis (from a tissue repository) suspended on a tensioned line (range $T =$ 2.2–123 N) was exposed to EMP (mean $B =0.64$ T, dB/dt = 5877 T/s, and the mean $B$ -field gradient of 127 T/m) from a solenoid with axis orthogonal to tensioning line, forming a harmonic oscillator whose mechanical vibrations were measured using laser Doppler vibrometry (LDV, noise floor 1 $\mu \text{m}$ /s). Calculated mean Maxwell stress and Lorentz forces acting on a weakly conducting, diamagnetic bone slice point away from the solenoid for maximum sensitivity of LDV measurement. The electromechanical origin of the LDV signal was confirmed by the order-of-magnitude agreement between calculated (range from 12 to 50 $\mu \text{m}$ /s) and measured initial bone velocity amplitudes (e.g., $35.5~\mu \text{m}$ /s ± $7.5~\mu \text{m}$ /s at $T =22.2$ N and $17.7~\mu \text{m}$ /s ± $2.5~\mu \text{m}$ /s at $T =58.2$ N) and the increasing frequency (25–180 Hz) of decaying oscillations with the square root of $T$ over the range of line tensions ($r^{2} =0.978$ , $p < 10^{-4}$ , and $n =17$). Theory and experiment show that magnetic field impulses are capable of exerting measurable mechanical forces on bone ex vivo. The results raise an interesting question if the electromechanical effect could be sufficiently large to contribute to bone remodeling, reportedly sensitive to vibration amplitudes as small as 1 nm, and considering long duration of orthopedic therapy using repetitive EMP (months). [ABSTRACT FROM AUTHOR]

Published

2022

25. Birdcage Transmitter for Wireless Power Transfer.

Author

Rajendran, Meena, Yang, Justin Eng Hee, Kaibin, Jocelyn Loh, Ping, Lim Chui, and Huang, Shao Ying

Abstract

With the proliferation of Internet of Things (IoT) technology, the number of devices and gadgets used per person is ever-increasing. There is an indispensable need for the extension of wireless power transfer (WPT) to charge multiple devices simultaneously without compromising the charging efficiency. To accommodate multiple units (tens) of wireless devices, planar transmitter coils are constrained by space and their efficiency is sensitive to the variation in receiver position and orientation. Hence in this letter, we adapt the concept of volume birdcage coil from magnetic resonance imaging (MRI) and design a cylindrical transmitter coil for WPT with a diameter of 500 mm and a length of 300 mm, called birdcage WPT charging bin, to efficiently charge multiple wireless devices in the bin at various positions and orientations. The designed birdcage WPT charging bin supplies a homogeneous and circularly polarized magnetic field which leads to a stable efficiency for the receivers at different locations and orientations around the bin axis in the bin. The bin was built and measurement was conducted for validating the performance. [ABSTRACT FROM AUTHOR]

Published

2022

26. Design and Quench Analysis of Superconducting Solenoids for the Lepton Future Circular Collider.

Author

Deelen, N., Dudarev, A., Cure, B., and Mentink, M.

Subjects

*SOLENOIDS, *PARTICLE detectors, *SUPERCONDUCTING magnets, *ELECTRON-positron interactions, *PARTICLE physics, *ELECTROWEAK interactions

Abstract

As part of the European Strategy for Particle Physics there is an ongoing development towards a Future Circular Collider (FCC-ee) where electron-positron collisions could be used to study the entire electro-weak sector in a low background environment. Particle detectors are used to study these collisions and a strong magnetic field is required to measure the particles’ momenta. Currently, two detector concepts are being studied: the Innovative Detector for Electron-positron Accelerators (IDEA) and the CLIC-Like Detector (CLD). Both these detectors include a superconducting solenoid magnet with a central field of $2 \,\mathrm{T}$ of which the designs are presented here. The IDEA magnet has an stored magnetic energy density of 14 kJ/kg and in CLD this is 12 kJ/kg. Taking into account their respective free-bore diameters of $4.2 \,\mathrm{m}$ for IDEA and $7.2 \,\mathrm{m}$ for CLD this results in very challenging designs for which the mechanical and quench studies are presented. Their results are promising, but extensive R&D on these magnets would be needed in the future to reach the goals set out in the Conceptual Design Report (CDR). [ABSTRACT FROM AUTHOR]

Published

2022

27. Examination and Characterization of Physical and Mechanical Properties of the ITER Central Solenoid Module Coils.

Author

Sgobba, Stefano, Aviles Santillana, Ignacio, Lourenco, Sandra, Guinchard, Michael, De Frutos, Oscar, Jong, Cornelis, Libeyre, Paul, Schild, Thierry, Gaxiola, Enrique, Bennet, Jose, Mayri, Christophe, Smith, John, Everitt, David, and Freudenberg, Kevin

Subjects

*SOLENOIDS, *X-ray computed microtomography, *SUPERCONDUCTING magnets, *WIND pressure, *THERMOCYCLING

Abstract

The ITER Central Solenoid (CS) consists of a stack of six independent coil packs called modules. It features a total height of 18 m and a diameter of over 4 m. The modules are in an advanced stage of fabrication and testing by the US ITER Project Office (USIPO) and its subcontractor General Atomics (GA). A qualification module mockup at one to one scale but of reduced height was wound and Vacuum Pressure Impregnated (VPI) by GA to validate final manufacturing, using tooling and processes fully representative of a series module. The module was submitted to a thermal cycle down to the temperature of 4.5 K at which the coils will be cooled by supercritical helium. During plasma operation, the CS modules are subjected to a complex combination of static and dynamic forces. The understanding of the mechanical behaviour of the CS module coils is of paramount importance to analyse and predict the overall response of the CS stack. To this purpose, an extensive programme of investigation of the module mockup has been defined and applied. This allowed assessing, through examination and testing of a large number of VPI conductor array samples extracted from the mockup, the soundness of the coil through advanced non-destructive examination techniques including X-ray microtomography, dimensional metrology measurements and micro-optical observations. Moreover, additional testing of physical and mechanical properties carried out at room and cryogenic temperature allowed the behaviour of the conductor stacks to be assessed. The paper summarises the results of these investigations and their interpretation through mechanical analyses based on the individual properties of the coil constituents. [ABSTRACT FROM AUTHOR]

Published

2022

28. Magnet Design of the Electron Cooling System for HIAF.

Author

Zhao, Lixia, Yao, Qinggao, Lv, Mingbang, Zhang, Xiang, Tang, Meitang, Chen, Yuquan, Sha, Xiaoping, Lu, Haijiao, and Ma, Lizhen

Subjects

*ION beams, *COOLING systems, *ELECTRON beams, *MAGNETIC fields, *MAGNETS, *ELECTRONS

Abstract

The electron cooling technology is applied in the spectrometer ring (SRing) to improve the luminosity of ion beam for the High Intensity heavy-ion Accelerator Facility (HIAF). The electron cooler consists of a gun section, two 90-degree toroids, a cooling section and a collector section. There are four kinds of main coils used to provide longitudinal magnetic fields along the path of the electron beam. In this paper, we present the modeling and analyzing of the electron cooler magnets by three-dimension software. The optimizing of the magnetic field of cooling section is completed to achieve the required effective cooling length. The magnetic fields along the electron beam path and ion beam path are calculated and the beam trajectory of typical ion is also simulated to offer data for correcting the orbit. [ABSTRACT FROM AUTHOR]

Published

2022

29. Characteristics of an Annular Electron Flow Formed by an Electron Gun With a Field Emitter.

Author

Taradaev, E. and Sominskii, G.

Subjects

*ELECTRON gun, *ELECTRON beams, *ELECTRON distribution, *FLOW velocity, *MAGNETIC resonance imaging

Abstract

Characteristics of annular electron flow formed in electron gun with a multitip field emitter were determined experimentally and by numerical simulations, and the possibility to achieve electron beam current up to 75 mA was demonstrated. The gun performance was stable in technical vacuum conditions—at the pressure of ~10−7 torr. Electron velocity distributions in a flow on transverse and longitudinal components were determined. It was shown that the relative root-mean-square transverse velocity spread varied with radial coordinate within the annular beam wall from ca. 6% to 30%, while the total spread in the electron flow was about 60%. [ABSTRACT FROM AUTHOR]

Published

2022

30. Measurement of Holding Force and Transportation Force Acting on Tabular Object in Near-Field Acoustic Levitation.

Author

Aono, Kohei and Aoyagi, Manabu

Subjects

*LEVITATION, *ACOUSTIC radiation, *MAGNETISM, *GRAVIMETERS (Geophysical instruments), *ELECTRIC currents, *MAGNETIC levitation vehicles, *AIR gap (Engineering)

Abstract

The holding force acting on a levitated object during near-field acoustic levitation has not been statically and directly measured so far. In this study, it was considered to realize such a measurement when a levitated object has a large displacement from the vibration source. In previous studies, under restricted conditions, the holding force has been calculated indirectly by image processing or measured from the balance with gravity by tilting the apparatus. In this article, the force was measured based on the magnetic force (MF) compensation principle. This is the first attempt to measure the force directly and statically under arbitrary conditions. One side of a rectangular rotor, which was placed above the acoustic radiation surface, received the holding force. The other side of the rotor received the MF generated by a solenoid. The holding force was estimated from the electric current flowing in the solenoid when the holding force and the MF were balanced. The holding force acting on the rotor surfaces was affected by the deviation between the rotor and the radiation surface. The holding force increased with increasing vibration amplitude or decreasing air gap between the rotor and the radiation surface. When the vibration sources were opposed, the holding force was affected by their vibration phase difference. The holding force was maximum at the opposite vibration phase and decreased with decreasing vibration phase difference. When the vibration sources were arranged in the transportation direction, the transportation force occurred and increased with increasing vibration amplitude of the destination vibration source. These measurement results agree well with the analysis results. [ABSTRACT FROM AUTHOR]

Published

2022

31. High-Misalignment-Tolerant IPT Systems With Solenoid and Double D Pads.

Author

Mai, Jianwei, Wang, Yijie, Yao, Yousu, Sun, Mengzhou, and Xu, Dianguo

Subjects

*SOLENOIDS, *MUTUAL inductance, *MAGNETIC flux, *MAGNETIC fields

Abstract

The capability of misalignment tolerance is vital for an inductive power transfer (IPT) system. In this article, a new loosely coupled transformer (LCT) structure with series solenoid and DD pads (SDDP) is proposed to improve the misalignment tolerance of the IPT system. The designed LCT not only has strong misalignment-tolerant capability in the X-direction but also has strong misalignment-tolerant capability in the Y-direction. The fluctuation of mutual inductance is 3.15% within 67.0% misalignment distance of the largest size of the SDDP in the X-direction and 44% misalignment distance of the largest size of the SDDP in the Y-direction. Finally, an LCC/S compensated IPT system with 300 W power is built as an example to demonstrate the performance of the proposed LCT. The output voltage fluctuates with the rated load, which is less than 3.2%, and the efficiency is 90.2–91.3%. [ABSTRACT FROM AUTHOR]

Published

2022

32. The Influence of the Copper Stabilizer On the Current Carrying Capacity of REBCO Tapes and Stacks With Various Joints at High Ramp Rates.

Author

Kovalev, Ivan A., Kruglov, Sergey S., Polyakov, Alexey V., and Shutova, Darya I.

Subjects

*SUPERCONDUCTING cables, *ADHESIVE tape, *ARTIFICIAL joints, *HIGH temperature superconductors, *COPPER, *LIQUID helium, *MAGNETIC fields

Abstract

In this work, we experimentally investigate the current carrying capacity of single REBCO tapes and stacks made 5 12 mm REBCO tapes with a 25 μm copper stabilizer in liquid helium in comparison with those made of bare tapes with no stabilizer at current ramp rates up to 55 kA/s. The motivation for the research was checking the usability of REBCO stacks as basic sub-elements for high current superconducting cables operating in fast cycling modes at 4.2 K. An original experimental technique was employed to induce the extremely high ramp rates. During the tests, one or 5-folded stacks curled into rings 95 mm dia with different types of joints were charged in the external magnetic field generated by an outer solenoid at ramp rates up to 1.6 T/s. The curled REBCO stacks were either soft-soldered over their entire length or contained local joints only. The maximum screening current induced in the samples during the outer solenoid charging Imax was registered. Our experiments showed that the current carrying capacity of the REBCO tapes and stacks was strongly affected by the absence or presence of the copper stabilizer as well as the type of the joint. The reasons for the Imax limitation for the copper stabilized and bare samples are also briefly discussed. [ABSTRACT FROM AUTHOR]

Published

2022

33. Magnetoelectric Design of Simulation System for Strong Magnetic Field Environment.

Author

Wu, Xiaokang, Sun, Zhaolong, Liu, Qi, and Zhou, Guohua

Subjects

*MAGNETIC fields, *SIMULATION methods & models, *RELIABILITY in engineering, *ELECTRONIC equipment, *MAGNETOELECTRIC effect

Abstract

How to design an impact platform that can provide a strong electromagnetic environment for all kinds of precision electronic equipment and experimental reference for strong electromagnetic protection is of great significance. In this article, an electromagnetic coil system that generated a strong magnetic field environment was designed and studied. First, the coil parameters and coil structure were designed. Then, the Comsol finite element software was used to simulate and design the three-component coil. The coil distance and turns were adjusted to make the coil center produce a uniform magnetic field area and meet the strong magnetic field index. Finally, the coil system was built to verify the magnetic field generated by the coil through experiments. This system will be used to simulate the strong magnetic field environment that produces different high precision and may occur in the operating environment of the equipment. It will also be used to provide strong magnetic field impact test support conditions for aerospace, naval vessels, and various types of equipment, so as to find and solve the problem of antistrong magnetic reliability of equipment in the design stage. [ABSTRACT FROM AUTHOR]

Published

2022

34. Undulators Consisting of Magnetized Helices.

Author

Magory, Eyal, Balal, Nezah, and Bratman, Vladimir L.

Subjects

*FREE electron lasers, *MAGNETIC suspension, *MAGNETIZATION, *MAGNETIC separation

Abstract

A ferromagnetic helix magnetized axially or radially is apparently the simplest helical undulator. Four helices with alternating magnetization can provide a stronger helical field than a pair of conventional planar Halbach arrays. Such undulators and microundulators seem promising for various powerful high frequency sources. The fields of infinite helices uniformly magnetized in the longitudinal and radial directions are found analytically by integration of contributions from elementary dipoles. The analytical values of the field magnitudes are close to the numerically calculated ones for a helix with a relatively small number of periods five–ten. According to simulation, a magnitude of about 1 T can be obtained on the axis of a system of helices with small inner radii. [ABSTRACT FROM AUTHOR]

Published

2022

35. A Three-Stage-Five-Coil IPT System Based on Cylindrical Solenoid Coupler Applied to State Detection Equipment of HV Device.

Author

Gu, Peng, Wang, Yijie, Mai, Jianwei, Yao, Yousu, Gao, Shenghan, Huang, Shengxin, and Xu, Dianguo

Subjects

*SOLENOIDS, *MUTUAL inductance, *ELECTRIC fields, *WIRELESS power transmission, *MAGNETIC cores, *DIRECTIONAL couplers, *MATHEMATICAL models

Abstract

A three-stage-five-coil inductive power transfer (IPT) system which is based on cylindrical solenoid coupler (CSC) is proposed in this article. The shape and parameters of the CSC are optimized. The five litz coils compensated by series capacitors are considered to form an IPT system based on equivalent CLC/S/CLC compensation topology with constant voltage characteristics. The mutual inductance between compensation auxiliary coil (CAC) and power transfer coil could be changed by moving the position of CAC, and the freedom of parameter design is enhanced. Mathematical model and loss model of the system are established, and power transfer characteristics of the system are analyzed. The system is considered to be used as a power source for state detection equipment of high-voltage (HV) device to achieve long-distance IPT, the effect of the coupler on the HV electric field is verified. Finally, a prototype with a length of 1.54 m was built. Based on the platform, output voltage and dc–dc power transfer efficiency curves with changed input voltage and load are obtained. The maximum efficiency of the dc–dc system can reach about 60%. [ABSTRACT FROM AUTHOR]

Published

2022

36. Efficient ULF Transmission Utilizing Stacked Magnetic Pendulum Array.

Author

Fereidoony, Foad, Nagaraja, Srinivas Prasad M., Santos, Jean Paul Dytioco, and Wang, Yuanxun Ethan

Subjects

*FREQUENCY shift keying, *PENDULUMS, *MAGNETIC flux, *QUALITY factor, *MAGNETIC fields, *MAGNETIC resonance, *ELECTRIC inductance

Abstract

A novel stacked magnetic pendulum array (MPA) is proposed as an antenna for efficient transmission in ultralow frequencies (ULF). The MPA structure consists of an array of ${m\times n}$ magnets stacked in $n$ rows (m magnets of the same magnetization per row) and a solenoid that encompasses the array. The magnetic flux generated by the solenoid couples to the magnets through a mechanical motion and creates a strong time variant magnetic field at the resonance frequency of the array. The proposed MPA is developed utilizing bearings with extremely small damping which hold the magnets, enable efficient oscillation, and guarantees a high-quality factor ($Q$ -factor). A comprehensive analysis to study the performance of the MPA and a conventional solenoid will be provided and accordingly, characteristics of an arbitrary ${m\times n}$ array in terms of field strength, resonance frequency, transmission efficiency and inductance are studied. Furthermore, a figure of merit (FOM) is introduced as the ratio of efficiency to the maximum linear dimension of the antenna. The experimental results for a fabricated $5 \times 11$ array show a resonance frequency of 715 Hz and a Q-factor of 94 while the maximum linear dimension of the antenna is just 9 cm. Moreover, measurement results show 24.9 dB improvement in the transmission efficiency of the MPA compared to the efficiency of a single solenoid of the same dimensions. The MPA has the FOM of ${1.26\times 1}{0}^{{4}}$ which is noticeably higher than that of proposed antennas in the literature. To demonstrate broadband transmission with the MPA, a binary frequency shift keying (BFSK) signal is transmitted through the use of direct antenna modulation (DAM) at a rate of 18 bps. [ABSTRACT FROM AUTHOR]

Published

2022

37. On-Chip Coupled Solenoid Inductors for Integrated Power Conversion.

Author

He, Yuhan, Wu, Rongxiang, Zhong, Zhiyong, Zhang, Huaiwu, and Bai, Feiming

Subjects

*DC-to-DC converters, *PERPENDICULAR magnetic anisotropy, *SOLENOIDS, *MAGNETIC cores

Abstract

Magnetic core inductors with a sufficiently high coupling factor ${k}$ are critical for interleaved dc–dc converters. In current work, solenoid coupled inductors with a joint magnetic core were designed and fabricated to boost ${k}$ while preserving the hard-axis excited characteristic. Devices were optimized based on a closed-loop magnetic reluctance model. Test results evidence a high coupling coefficient of 0.42. Meanwhile, a large ${L}/{R}_{dc}$ ratio of 295 nH/ $\Omega $ and a high saturation current of 1.87 A have been achieved. The performance of the coupled inductor has been calculated for a standard 1.8–0.9-V interleaved converter and a high efficiency ~96% can be obtained across a wide range of phase currents between 0.3 and 1.6 A. [ABSTRACT FROM AUTHOR]

Published

2021

38. A Pre-Concentration System Design for Electronic Nose via Finite Element Method.

Author

Qian, Junhui, Zhang, Ailing, Tian, Fengchun, and Zhang, Yisha

Abstract

Volatile organic compounds (VOCs), which is measured by electronic nose (e-nose), have utilities as biomarkers for classification and detection. However, the concentration of biomarker in VOCs is usually lower than the detection limit of gas sensors of e-nose, which results in systematic failure. The VOCs enrichment technology can be used to break through the limitations via enriching the low concentration of VOCs with adsorption tubes. In this brief, a pre-concentration system is designed based on the finite element method. Through the finite element analysis, the pre-concentration system can efficiently determine parameters to control the temperature field. In addition, with the expanded adsorption range of VOCs C3-C30, the lower bound of adsorption is analytically proved by C3H8O (including n-propanol and isopropanol). Moreover, the conformal technique is exploited to improve the enrichment efficiency. Also, the upper bound of adsorbable VOCs can be further improved via the double adsorption tubes structure design. Finally, gas chromatography-mass spectrometry (GC-MS) and e-nose are used to detect the concentration of the different sample gas before and after the pre-concentration device, and the results show the effectiveness of the design. [ABSTRACT FROM AUTHOR]

Published

2021

39. Bayesian Convolutional Neural Networks for Remaining Useful Life Prognostics of Solenoid Valves With Uncertainty Estimations.

Author

Mazaev, Tamir, Crevecoeur, Guillaume, and Hoecke, Sofie Van

Abstract

Solenoid valves (SV) are essential components of industrial systems and therefore widely used. As they suffer from high failure rates in the field, fault prognosis of these assets plays a major role for improving their maintenance and reliability. In this work, Bayesian convolutional neural networks are used to predict the remaining useful life (RUL) of SV, by training them on the valve's current signatures. Predictive performance is further improved upon by using salient physical features obtained from an electromechanical model as the network's training input. Results show that our designed network architecture produces well-calibrated uncertainty estimations of the RUL predictive distributions, which is an important concern in prognostic decision-making. [ABSTRACT FROM AUTHOR]

Published

2021

40. Development of a Bi-2212 Solenoid Insert Coil in a 12 T Superconducting Magnet.

Author

Chen, Huang, Liu, Hua-jun, Shi, Yi, and Qin, Jing-gang

Subjects

*SUPERCONDUCTING magnets, *SUPERCONDUCTORS, *ELECTROMAGNETIC fields, *SOLENOIDS, *HEAT treatment, *SUPERCONDUCTING coils

Abstract

Bi-2212 is one of the most hopeful superconducting material by virtue of its excellent irreversible field and isotropic electromagnetic characteristic. We developed Bi-2212 insert coil for the sake of testing the uniform performance of the round wire (RW). Some important explorations were made including the preliminary test of coil insulation, sealing and heat treatment. In the end, the insert coil achieved a critical performance of 130 A at 12 T and 4.2 K. The experiment results indicated that Bi-2212 RW had met the future application. [ABSTRACT FROM AUTHOR]

Published

2021

41. Electron-Beam Corkscrew Motion in an Advanced Linear Induction Accelerator.

Subjects

*BETATRONS, *LINEAR accelerators, *MAGNETIC fields, *PARTICLE beams, *RADIOGRAPHY, *SKYRMIONS, *ELECTRON beams

Abstract

Scorpius is a multipulse linear induction accelerator (LIA) under development for flash radiography. Because it has substantially more cells than present LIAs, higher magnetic focusing fields are needed to suppress beam breakup (BBU). Therefore, it is more susceptible to corkscrew motion of the beam, which also depends on beam energy spread and focusing magnet misalignments. For energy spread and alignment tolerances expected for Scorpius, a magnetic tune designed to suppress BBU is shown to produce corkscrew motion within the range that can be controlled through the use of steering dipoles on existing LIAs. A gap-voltage modulation scheme is shown to almost completely eliminate chromatic effects such as corkscrew. [ABSTRACT FROM AUTHOR]

Published

2021

42. Optimal Transmit Coil Design for Wirelessly Powered Biomedical Implants Considering Magnetic Field Safety Constraints.

Author

Andersen, Erik, Casados, Curtis, Truong, Binh Duc, and Roundy, Shad

Subjects

*MAGNETIC fields, *WIRELESS power transmission, *MAGNETIC flux density, *ELECTRIC currents, *ELECTRIC power

Abstract

This article presents an investigation on the optimal design of a transmit coil for a wireless power transfer system (WPTS) for biomedical implants with the goal of maximizing the magnetic flux density (B-field) at the location of the implant while not violating magnetic field exposure limits. Maximizing the B-field correlates to higher transferable electric power for certain WPTSs, such as those that use magnetoelectric receivers. While previous works have optimized the thermal efficiency, or system efficiency, to our knowledge no one yet has developed the procedure to optimize the transmitter to maximize the B-field subject to an imposed safety limit constraint for magnetic field exposure. In addition to this safety constraint, the optimal design of the transmitter is considered when the system geometry or the input current is constrained. Equations for determining the design parameters of an optimal solenoid transmitter are derived subject to constraints on either transmitter size or electric current. If a certain magnetic field strength is required, solutions to the size and current of the transmitter are presented, which allow the desired fields without violating the safety constraint. The mathematical model is experimentally validated, and a case study is described that illustrates the optimal design rules. [ABSTRACT FROM AUTHOR]

Published

2021

43. An Axial Output Relativistic Magnetron Fed by a Split Cathode and Magnetically Insulated by a Low-Power Solenoid.

Author

Leopold, J. G., Krasik, Ya. E., Hadas, Y., and Schamiloglu, E.

Subjects

*MAGNETRONS, *SOLENOID magnetic fields, *SOLENOIDS, *CATHODES, *MAGNETIC fields

Abstract

One of the main difficulties in designing a relativistic magnetron producing high-power microwaves (HPMs) to be compact, is the power source required to feed the solenoid producing the axial magnetic field, which magnetically insulates the electron beam. This is because the diffusion of the magnetic field through the walls of the system is on the millisecond timescale. The latter requires high-power supplies and restricts the magnetron from operating repetitively. Using permanent magnets instead does not make the system sufficiently compact, because of the size and weight of the magnets and does not allow varying the magnetic field. We suggest a simple solution to this problem by cutting longitudinal slits through the entire magnetron anode system. With such slits, the magnetic field penetration is not restricted by the diffusion rate. Thus, one can apply a microsecond-timescale magnetic field produced by a solenoid powered by a considerably smaller power supply. We test this idea by using particle-in-cell (PIC) simulations of a magnetron for the axial output design suggested by Xu et al. (2018) fed by a split cathode (Leopold et al., 2020). With a split cathode, the second major problem with relativistic magnetrons is alleviated—pulse shortening is avoided. [ABSTRACT FROM AUTHOR]

Published

2021

44. Duality-Derived Models of High-Speed Electromagnetic Valves.

Author

Zhao, Jianhui, Zirka, Sergey E., and Moroz, Yuriy I.

Subjects

*COMPUTATIONAL electromagnetics, *MAGNETIC cores, *ARMATURES, *HYSTERESIS, *SOLENOIDS, *TRANSIENT analysis

Abstract

The article analyzes a high-speed solenoid valve (HSV) whose core and moving armature are massive elements characterized by strong eddy currents, hysteresis, and saturation. The feedback control employed in obtaining a predetermined nonsinusoidal current in the core coil necessitates the use of a high-frequency pulsewidth modulation (PWM)-like voltage with parameters varying in a manner unknown in advance during the uninterrupted transient. In view of the known difficulties in using finite-element solvers, physical Cauer circuits are found to be a reliable engineering alternative. The use of the duality transformation is proposed to obtain a pure electric model of the core and armature. As a preliminary result, it is found that a threefold reduction in eddy-current loss is achieved by using the slotted core. The results obtained with the model are in a reasonable agreement with the experimental magnetizing current and the armature movement during successive valve operations. [ABSTRACT FROM AUTHOR]

Published

2021

45. Optimum Separation for Performance Improvement of RFID Solenoid Coil Antenna in Metallic Environments.

Author

Zhu, Jixuan, Li, Yuan, Jin, Cheng, Liu, Xin, and Liu, Huan

Abstract

A metal pipe is a key factor affecting the performance of the oil well downhole radio frequency identification (RFID) system. This letter investigates the optimum separation for coping with the impact of metal pipe on the solenoid coil antenna so as to improve the performance of the downhole RFID system. Through the equivalent circuit model of RFID communication, a new objective of maximizing the reader antenna inductance is introduced from the perspective of demodulating the tag data easily. Then, a small optimum separation with a large antenna diameter is given out by the electromagnetic simulation of solenoid antenna in the metal pipe, which could not only ensure the trafficability of tag ball and decrease the tag speed in the antenna area but also reduce the minimum magnetic field required for the reader to read the tag. Finally, the calculation of optimum separation is compared with that of the experimental test and shows good agreement. [ABSTRACT FROM AUTHOR]

Published

2021

46. A Bridge-Type Inductance Sensor With a Two-Stage Filter Circuit for High-Precision Detection of Metal Debris in the Oil.

Author

Xie, Yucai, Shi, Haotian, Zhang, Hongpeng, Yu, Shuang, Llerioluwa, Lebile, Zheng, Yiwen, Li, Guobin, Sun, Yuqing, and Chen, Haiquan

Abstract

A bridge-type inductance sensor with a two-stage filter circuit for high-precision detection of metal debris in the oil is proposed. The sensor mainly consists of a bridge-structure sensing unit and a two-stage filter circuit. The sensing unit consists of two double-wire solenoid coils (as the detection unit and the reference unit, respectively) and a Wheatstone bridge -structure. This structure enhances the response of the detection unit to the magnetic field disturbance generated by the wear debris and can improve the detection accuracy of the sensor. Furthermore, a circuit with rectification, amplitude modulation, and amplification functions is introduced to eliminate the noise interference from the environment and the system, and to accurately extract the weak abrasive signals that are submerged in the noise. Meanwhile, by adjusting the passband gain of the two-stage filter circuit, the measurement range of the sensor voltage value is improved. Experimental results show that adding a two-stage filter circuit can improve the resolution of the sensor, and can effectively detect $45~\mu \text{m}$ iron particles. The sensor provides technical support for the modularity and portability of the testing instrument, which is essential for fault diagnosis and prevention of the hydraulic systems. [ABSTRACT FROM AUTHOR]

Published

2021

47. Prototype Data Acquisition and Slow Control Systems for the Mu2e Experiment.

Author

Gioiosa, A., Bonventre, R., Donati, S., Flumerfelt, E., Horton-Smith, G., Morescalchi, L., O'Dell, V., Pedreschi, E., Pezzullo, G., Spinella, F., Uplegger, L., and Rivera, R. A.

Subjects

*ACQUISITION of data, *DATA acquisition systems, *PCI bus (Computer bus), *WEB browsers, *FLAVOR, *INDUSTRIAL controls manufacturing

Abstract

The Mu2e experiment at the Fermilab Muon Campus will search for the coherent neutrinoless conversion of a muon into an electron in the field of an aluminum nucleus with a sensitivity improvement by a factor of 10 000 over existing limits. Such a charged lepton flavor-violating reaction probes new physics at a scale unavailable with direct searches at either present or planned high-energy colliders. The Mu2e Trigger and Data Acquisition (TDAQ) system exploits otsdaq as its online Data Acquisition System (DAQ) solution. Developed at Fermilab, otsdaq integrates both the artdaq DAQ and the art analysis frameworks for event transfer, filtering, and processing. otsdaq is an online DAQ software suite with a focus on flexibility and scalability and provides a multi-user, web-based, interface accessible through a web browser. The read out controllers (ROCs) stream out zero-suppressed data continuously from the detector subsystems to the data transfer controllers (DTCs). The data stream is then read over the peripheral component interconnect express (PCIe) bus to a software filter algorithm that selects events which are combined with the data flux coming from a cosmic-ray veto (CRV) system. The detector control system (DCS) has been developed using the experimental physics and industrial control system (EPICS) open source platform for monitoring, controlling, alarming, and archiving. The DCS has been integrated into otsdaq. A prototype of the TDAQ system and the DCS has been built at Fermilab’s Feynman Computing Center. In this article, we report on the progress of the integration of this prototype in the online otsdaq software. [ABSTRACT FROM AUTHOR]

Published

2021

48. Mutual Inductance Modeling of Two Coaxial Solenoid Antennas With Large Ferrite Core for Underground RFID Applications.

Author

Zhu, Jixuan, Jin, Cheng, and Liu, Huan

Subjects

*MUTUAL inductance, *RADIO frequency identification systems, *RADIO antennas, *ANTENNAS (Electronics), *COAXIAL cables, *FERRITES, *FINITE element method, *SUBSTRATE integrated waveguides

Abstract

Mutual inductance is a crucial parameter in the design and optimization of coupled antennas in underground radio frequency identification (RFID) systems. In this article, a simple and accurate modeling method for determining the mutual inductance between two coaxial solenoid antennas with a large ferrite core is proposed. This proposed model is verified by comparing the results obtained from the commonly used method for small ferrite core antennas, high-precision filament method, and finite element method (FEM). An experimental setup has also been built to validate the proposed method. This new method for predicting mutual inductance has greater adaptability and higher accuracy, and is much better suitable to optimize the performance of RFID antennas with a large ferrite core. [ABSTRACT FROM AUTHOR]

Published

2021

49. Ferrofluidic Manipulator: Automatic Manipulation of Nonmagnetic Microparticles at the Air–Ferrofluid Interface.

Author

Cenev, Zoran, Harischandra, P. A. Diluka, Nurmi, Seppo, Latikka, Mika, Hynninen, Ville, Ras, Robin, Timonen, Jaakko, and Zhou, Quan

Abstract

Manipulation of small-scale matter is a fundamental topic in micro and nanorobotics. Numerous magnetic robotic systems have been developed for the manipulation of microparticles in an ambient environment, liquid, as well as on the air–liquid interface. These systems move intrinsically magnetic or magnetically tagged objects by inducing a magnetic torque or force. However, most of the materials found in nature are nonmagnetic. Here, we report a ferrofluidic manipulator for automatic 2-D manipulation of nonmagnetic objects floating on top of a ferrofluid. The manipulation system employs 8-cm-scale solenoids, which can move nonmagnetic particles by deforming the air–ferrofluid interface. Using linear programming, we can control the motion of the nonmagnetic particles with a predefined trajectory of a line, square, and circle with a precision of 25.1 ± 19.5, 34.4 ± 28.4, and 33.4 ± 26.6 μm, respectively. The ferrofluidic manipulator is versatile with the materials and the shapes of the objects under manipulation. We have successfully manipulated particles made of polyethylene, polystyrene, a silicon chip, and poppy and sesame seeds. This article shows a promising venue for the manipulation of living and nonliving matter at the air–liquid interface. [ABSTRACT FROM AUTHOR]

Published

2021

50. A Universal Calibration Method for Electronic Nose Based on Projection on to Convex Sets.

Author

Zhang, Shuya, Tian, Fengchun, Covington, James A., Li, Hantao, Zhao, Leilei, Liu, Ran, Qian, Junhui, and Liu, Bei

Subjects

*ELECTRONIC noses, *CONVEX sets, *NOSE, *CALIBRATION, *MACHINE learning, *ACETONE, *GAS detectors, *DICAMBA

Abstract

The drift of electronic nose (e-nose) sensors is the most challenging problem. An effective calibration method for e-nose is proposed in this article, which is based on projection on to convex sets (POCS) and extreme learning machine (ELM) method, including an automatic sampling platform and an e-nose sensor calibration model. It realizes a unified and universal calibration for both recognition and regression application to solve the electronic nose drift problem under long-term working conditions. Isopropanol and acetone gases that respond to most sensors were chosen as training gases for the model. Experiments show the effectiveness of the proposed e-nose calibration method. [ABSTRACT FROM AUTHOR]

Published

2021