Constant Magnetic Permeability Research Articles

Achieving constant magnetic permeability in Fe-based nanocrystalline alloys by Ni alloying and magnetic-field annealing for high DC bias capability and low coercivity

Achieving constant magnetic permeability in Fe-based nanocrystalline alloys by Ni alloying and magnetic-field annealing for high DC bias capability and low coercivity

Heat transfer analysis of MHD viscous nanofluid flow over a nonlinearly stretching sheet with heat source/sink: A numerical study

The present study analyses the magnetohydrodynamics (MHD) viscous nanofluid flow past a nonlinearly stretching sheet embedded in a porous medium under the influence of heat generation and thermal radiation. Further, variable magnetic field as well as variable permeability is used instead of constant magnetic field and permeability due to many therapeutic applications, which makes them distinctive and practically helpful. The MHD viscous flow and heat transfer equations have been generated as coupled second-order nonlinear partial differential equations using a mathematical model that resembles the physical flow problem. The partial differential equations governing the flow problems are reduced to ordinary differential equations via similarity variables. The reduced equations are then solved by Runge–Kutta–Fehlberg’s scheme with shooting method by the help of MATLAB software. The result obtained reveals that enhancing the heat generation parameter, porosity parameter, and radiation parameter upsurges the temperature of the nanofluid, whereas the magnetic parameter shows the reverse effect in the case of velocity distribution. Nusselt number decreases at the rate of 2.6147% for copper–water nanofluid when increased from 0 to 0.05. Silver nanoparticles have the highest heat transfer as compared to other nanoparticles. Because of this, silver nanoparticles are the most effective thermal conductors for increasing the effectiveness of heat storage in phase transition materials.

Homogenization of MHD flows in porous media

The paper is concerned with the homogenization of a nonlinear differential system describing the flow of an electrically conducting, incompressible and viscous Newtonian fluid through a periodic porous medium, in the presence of a magnetic field. We introduce a variational formulation of the differential system equipped with boundary conditions. We show the existence of a solution of the variational problem, and derive uniform estimates of the solutions depending on the characteristic parameters of the flow. Using the two-scale convergence method, we rigorously derive a two-scale equation for the two-scale current density, and a two-pressure Stokes system. We derive, in the case of constant magnetic permeability, an explicit relation expressing the macroscopic velocity as a function of the macroscopic Lorentz force, the pressure gradient, the external body force, and the macroscopic current density, via two permeability filtration tensors. When the magnetic field is absent, this relation reduces to the Darcy law.

On the Maxwell-wave equation coupling problem and its explicit finite-element solution

It is well known that in the case of constant dielectric permittivity and magnetic permeability, the electric field solving the Maxwell’s equations is also a solution to the wave equation. The converse is also true under certain conditions. Here we study an intermediate situation in which the magnetic permeability is constant and a region with variable dielectric permittivity is surrounded by a region with a constant one, in which the unknown field satisfies the wave equation. In this case, such a field will be the solution of Maxwell’s equation in the whole domain, as long as proper conditions are prescribed on its boundary. We show that an explicit finite-element scheme can be used to solve the resulting Maxwell-wave equation coupling problem in an inexpensive and reliable way. Optimal convergence in natural norms under reasonable assumptions holds for such a scheme, which is certified by numerical exemplification.

Effects of phosphorus substitution on amorphous formation, crystallization behavior and magnetic properties of FeSiBCuNb alloys

Fe-Si-B-Cu-Nb nanocrystalline alloys exhibit excellent soft magnetic properties and have been increasingly applied in high frequencies ranging from several kHz to several hundred kHz, but the magnetic permeability needs further to design to meet the magnetic components under different frequencies. In the present work, the influences of phosphorus substitution on amorphous forming, crystallization behavior and soft magnetic properties of silicon-rich Fe-Si-B-Cu-Nb alloys were systematically investigated. It was found that the suitable addition of 1 at.% of P in Fe-Si-B-Cu-Nb alloy can significantly improve the amorphous forming ability, reduce the coercivity (Hc) of the annealed alloys and elevate the effective magnetic permeability (μe) at frequencies ranging from 1 to 30 kHz in spite of having fractional detriment to the alloy's thermal stability but still remaining a relatively broad annealing temperature region. Besides, the μe in high P-containing alloys becomes insensitive to frequencies at high frequencies region, which can attain frequencies-dependent constant magnetic permeability induced by composition design.

К расчету поля конечного магнитного цилиндра с внутренним соосным цилиндрическим дефектом

Using the grid method, a numerical solution of the direct problem of magnetostatics for calculating the field of a finite cylinder with a constant magnetic permeability containing an internal inclusion in the form of a coaxial cylinder with a different magnetic permeability is carried out. The algorithm is created for an arbitrary external field. In order to assess the reliability and accuracy of the solution method, the results were tested using precisely solved problems. A comparison is also made with the results of the previously solved problem of a finite defect-free cylinder. The coordinate dependences of the components of the resulting field are constructed for different source data. The program adds to the library of magnetic control problems and can be used for high-quality verification with the results of model experiments, as well as for evaluating the geometric characteristics of an internal defect.

Homogenization of Nonstationary Maxwell System with Constant Magnetic Permeability

Homogenization of Nonstationary Maxwell System with Constant Magnetic Permeability

Homogenization of nonstationary Maxwell system with constant magnetic permeability

Изучается нестационарная система Максвелла в $\mathbb{R}^3$ с диэлектрической проницаемостью $\eta(\varepsilon^{-1}{\mathbf x})$ и магнитной проницаемостью $\mu$. Здесь $\eta(\mathbf{x})$ - положительно определенная и ограниченная симметричная матрица-функция размера $3\times 3$, периодическая относительно некоторой решетки, а $\mu$ - постоянная положительная $(3 \times 3)$-матрица. Получены аппроксимации решений по норме в $L_2(\mathbb{R}^3;\mathbb{C}^3)$ при фиксированном времени с оценками погрешностей операторного типа.

Calculation of the performance of the electromagnetic magnetic fluid separator non-magnetic materials

Magnetic fluid separation is a promising area in the field of disposal and recycling of non-magnetic materials. Performance and separation accuracy are important features of any separator. The methods for calculating the productivity offered at this moment have a number of assumptions that can significantly affect the result (constant magnetic permeability of the magnetic fluid, linear change in tension along the height of the gap, etc.), and are applicable only to specific models of separators. The aim of the study is to develop a methodology for calculating the performance of an electromagnetic magnetic fluid separator of non-magnetic materials, taking into account the distribution of the magnetic field in the gap and the influence of the hydrodynamic properties of the magnetic fluid on the movement of particles in the separation zone. The proposed approach allows us to calculate the mass and volumetric capacities of the magnetic fluid separator, the dependences of the capacities for each fraction separately, and the total on various parameters of the separator (for example, on the angle of inclination of the pole pieces). The obtained results can be used to assess the optimality of the adopted parameters when designing a magnetic fluid separator. Also, the results obtained will help optimize the installations already in operation.

Effect of Ni substitution to Fe on amorphous nanocrystalline soft magnetic alloy

Improve the Finemet alloy properties by adding Ni elements, and through change the Ni content to control the composition of the alloy system, the alloy has resistance to DC bias characteristics and excellent soft magnetic properties. In the Fe79.5-XSi6B12Cu1Nb1.5NiX (X = 0, 1, 3, 5, 7, 10) alloy, increasing the content of Ni improves the amorphous forming ability of the alloy, and increased thermal stability, the soft magnetic performance has also been improved. with X is about 10 at.% the nanocrystalline core of alloy ribbon annealed show μ is about 3.4 k, and Hc is about 17.51 A/m. The addition of Ni is beneficial to improve the linearity of the hysteresis loop, when the amount of Ni content increases, the linearity is significantly improved, Ni10at.% alloy shows good DC bias resistance in the magnetic field. And tensile stress has also been improved linearity of the hysteresis loop, make the alloy shows good DC bias resistance in the magnetic field of 0–600 A/m. So it has constant magnetic permeability in this magnetic field, the alloys to be a kind of promising material for current transformer with direct current tolerance.

Calculation of the performance of electromagnetic magnetic liquid separator of non-magnetic materials

Magnetic-liquid separation is a promising area in the field of disposal and recycling of non-magnetic materi-als. The performance and separation accuracy are important features of any separator. The methods for performance calculation offered at the present moment have a number of assumptions that can significantly affect the result (constant magnetic permeability of the magnetic fluid, linear change in tension along the height of the gap, etc.), and are applicable only to specific models of separators. The aim of this study is to develop a methodology for calculating the performance of an electromagnetic magnetic liquid separator of non-magnetic materials taking into account the distribution of the magnetic field in the gap and the influence of the hydrodynamic properties of the magnetic fluid on the movement of particles in the separation zone. Numerical methods are used to solve systems of equations of motion which are obtained on the basis of Newton's fundamental laws and the developed programs for calculating particle trajectories in the separation zone of a magnetic liquid separator are applied. To simplify the calculation, the particles are assumed to be spherical and, when they move, vortices in the magnetic fluid are not created. The system is solved iteratively: at each step, the change in values is calculated and is summed up with the result of the previous iteration. A technique has been developed for calculating the performance of an electromagnetic magnetic liquid separator of non-magnetic materials considering the distribution of the magnetic field in the gap and the influence of the hydrodynamic properties of the magnetic fluid on the particle movement in the separation zone. Particle trajectories in the separation zone are obtained, which allows one to analyze the separation process of the separator under development. The proposed approach allows calculating the mass and volumetric capacities of the magnetic liquid separator, the dependences of the capacities for each fraction separately and the total on various parameters of the separator (for example, on the angle of inclination of the pole pieces). The obtained results can be used to assess the optimality of the adopted parameters when designing a magnetic liquid separator. Also, the results obtained will help optimize the installations already in operation.

To the Calculation of the Field of a Finite Magnetic Cylinder

An algorithm has been developed for numerical solution of the direct linear problem of magnetostatics on calculating the field of a finite cylinder with constant magnetic permeability μ. Sampling parameters for the system of equations have been established in numerical experiments. The solution has been checked for compliance with the results of problems with exact solutions. The limits of applicability of the infinite cylinder model have been indicated. Prospects for further use of the numerical algorithm and computer program have been outlined.

Design and Analysis of a Novel LHM Structure Realized in Low-Frequency Band

The left-handed material (LHM) composed of a combination of magnetic and electrical resonator is an important method for designing the structure of the LHM. In this paper, a novel structure of LHM is designed and analyzed based on the traditional LHM structure. The parameter extraction method is applied to calculate the effective dielectric constant and effective magnetic permeability. The simulation results indicate that the effective dielectric constant and effective magnetic permeability can achieve negative value in a specific frequency band with about 200 MHz. It will provide important theoretical and practical guiding for designing the novel LHM structure with low-frequency band.

Regression models for magnetic flux density using DoE techniques and geometric optimization of MR valve

Magnetorheological (MR) fluids have found wide application in engineering devices, especially, in MR dampers. Calculation of magnetic flux density in the MR valve plays a critical role in the performance analysis of MR dampers. In the present study, regression models have been fitted for magnetic flux densities in the active and core regions of the MR valve for a commercially available MR fluid. The fitted model is presented as a function of the MR valve’s geometric parameters and applied current. For fitting the regression model, simulation experiments have been performed in ANSYS-APDL software using different design of experiment (DoE) techniques. For each technique, the model is improved upon by p-value test and the best model among different DoE techniques is selected by analyzing the coefficients of determination. The best-improved models are then used for geometric optimization of MR valve in the MATLAB® environment and the optimal results are compared to the one obtained from the approximated magnetic circuit with constant relative magnetic permeability.

Comparison of methods for calculating the magnetic moment of the cores of electromagnets of spacecraft control systems

The relevance of determining the magnetic moment of the core of a DC electromagnet of spacecraft control systems is shown. The review of methods for calculating the magnetic moment of a cylindrical core by demagnetizing factors and integral equations is made. Methods based on the use of demagnetizing factors are considered in more detail, their comparative analysis is made, and the field of application is investigated depending on the level of the external magnetic field and the relative length of the core. It has been established that the field of application of experimentally determined demagnetizing factors is limited by the range (60–100) of the relative length of the core and the upper limit of the level of an external magnetic field of strength 10000 A/m, and for other variants of relative lengths and levels, additional experiments are necessary. The determination of the demagnetizing factors under the assumption of the uniformity of magnetization is possible if the relative length of the core and the level of an external magnetic field exceed, respectively, the values of 100 and 40000 A/m. The use of demagnetizing factors under the assumption of constant magnetic permeability for cores of relative length not less than 60 with the level of an external magnetic field whose strength does not exceed 10000 A/m is not sufficiently substantiated, since its values may differ by an order of magnitude at different points of the core. The drawbacks of the method of demagnetization factors are noted and the necessity of using the method of integral equations is justified.

Microwave Characterization of Metal-Decorated Carbon Nanopowders Using a Single Transmission Line

This paper presents a novel approach for the characterization of microwave properties of carbon-based nanopowders, decorated or not with magnetic nanoparticles. Their microwave parameters, dielectric constant, electrical conductivity, and complex magnetic permeability are extracted from measurements performed using a single transmission line acting as a test cell. Two geometries of transmission line were tested, and successful results were obtained with each one of them. The measurement results are assessed by a phenomenological model enabling to fit the measurement of the dielectric constant and conductivity, providing an insight on the compacity quality of the powder sample. Also, the extraction of the permeability is validated by the detection of a ferromagnetic resonance showing a linear dependence on external DC magnetic field.

Homogenization of a stationary periodic Maxwell system in a bounded domain in the case of constant magnetic permeability

In a bounded domain $\mathcal{O}\subset\mathbb{R}^3$ of class $C^{1,1}$, we consider a stationary Maxwell system with the boundary conditions of perfect conductivity. It is assumed that the magnetic permeability is given by a constant positive $(3\times 3)$-matrix $\mu_0$ and the dielectric permittivity is of the form $\eta({\mathbf x}/ \varepsilon)$, where $\eta({\mathbf x})$ is a $(3 \times 3)$-matrix-valued function with real entries, periodic with respect to some lattice, bounded and positive definite. Here $\varepsilon >0$ is the small parameter. Suppose that the equation involving the curl of the magnetic field intensity is homogeneous, and the right-hand side $\mathbf r$ of the second equation is a divergence-free vector-valued function of class $L_2$. It is known that, as $\varepsilon \to 0$, the solutions of the Maxwell system, namely, the electric field intensity ${\mathbf u}_\varepsilon$, the electric displacement vector ${\mathbf w}_\varepsilon$, the magnetic field intensity ${\mathbf v}_\varepsilon$, and the magnetic displacement vector ${\mathbf z}_\varepsilon$ weakly converge in $L_2$ to the corresponding homogenized fields ${\mathbf u}_0$, ${\mathbf w}_0$, ${\mathbf v}_0$, ${\mathbf z}_0$ (the solutions of the homogenized Maxwell system with effective coefficients). We improve the classical results. It is shown that ${\mathbf v}_\varepsilon$ and ${\mathbf z}_\varepsilon$ converge to ${\mathbf v}_0$ and ${\mathbf z}_0$, respectively, in the $L_2$-norm, the error terms do not exceed $C \varepsilon \| {\mathbf r}\|_{L_2}$. We also find approximations for ${\mathbf v}_\varepsilon$ and ${\mathbf z}_\varepsilon$ in the energy norm with error $C\sqrt{\varepsilon} \|{\mathbf r}\|_{L_2}$. For ${\mathbf u}_\varepsilon$ and ${\mathbf w}_\varepsilon$ we obtain approximations in the $L_2$-norm with error $C\sqrt{\varepsilon} \| {\mathbf r}\|_{L_2}$.

Levitation of non-magnetizable droplet inside ferrofluid

The central theme of this work is that a stable levitation of a denser non-magnetizable liquid droplet, against gravity, inside a relatively lighter ferrofluid – a system barely considered in ferrohydrodynamics – is possible, and exhibits unique interfacial features; the stability of the levitation trajectory, however, is subject to an appropriate magnetic field modulation. We explore the shapes and the temporal dynamics of a plane non-magnetizable droplet levitating inside a ferrofluid against gravity due to a spatially complex, but systematically generated, magnetic field in two dimensions. The coupled set of Maxwell’s magnetostatic equations and the flow dynamic equations is integrated computationally, utilizing a conservative finite-volume-based second-order pressure projection algorithm combined with the front-tracking algorithm for the advection of the interface of the droplet. The dynamics of the droplet is studied under both the constant ferrofluid magnetic permeability assumption as well as for more realistic field-dependent permeability described by Langevin’s nonlinear magnetization model. Due to the non-homogeneous nature of the magnetic field, unique shapes of the droplet during its levitation, and at its steady state, are realized. The complete spatio-temporal response of the droplet is a function of the Laplace number $La$ , the magnetic Laplace number $La_{m}$ and the Galilei number $Ga$ ; through detailed simulations we separate out the individual roles played by these non-dimensional parameters. The effect of the viscosity ratio, the stability of the levitation path and the possibility of existence of multiple stable equilibrium states is investigated. We find, for certain conditions on the viscosity ratio, that there can be developments of cusps and singularities at the droplet surface; we also observe this phenomenon experimentally and compare with the simulations. Our simulations closely replicate the singular projection on the surface of the levitating droplet. Finally, we present a dynamical model for the vertical trajectory of the droplet. This model reveals a condition for the onset of levitation and the relation for the equilibrium levitation height. The linearization of the model around the steady state captures that the nature of the equilibrium point goes under a transition from being a spiral to a node depending upon the control parameters, which essentially means that the temporal route to the equilibrium can be either monotonic or undulating. The analytical model for the droplet trajectory is in close agreement with the detailed simulations.

Two-Dimensional Exact Subdomain Technique of Switched Reluctance Machines with Sinusoidal Current Excitation

This paper presents a two-dimensional (2D) exact subdomain technique in polar coordinates considering the iron relative permeability in 6/4 switched reluctance machines (SRM) supplied by sinusoidal waveform of current (aka, variable flux reluctance machines). In non-periodic regions (e.g., rotor and/or stator slots/teeth), magnetostatic Maxwell’s equations are solved considering non-homogeneous Neumann boundary conditions (BCs). The general solutions of magnetic vector potential in all subdomains are obtained by applying the interface conditions (ICs) in both directions (i.e., r- and θ-edges ICs). The global saturation effect is taken into account, with a constant magnetic permeability corresponding to the linear zone of the nonlinear B(H) curve. In this investigation, the magnetic flux density distribution inside the electrical machine, the static/dynamic electromagnetic torques, the magnetic flux linkage, the self-/mutual inductances, the magnetic pressures, and the unbalanced magnetic forces (UMFs) have been calculated for 6/4 SRM with two various non-overlapping (or concentrated) windings. One of the case studies is a M1 with a non-overlapping all teeth wound winding (double-layer winding with left and right layer) and the other is a M2 with a non-overlapping alternate teeth wound winding (single-layer winding). It is important to note that the developed semi-analytical model based on the 2D exact subdomain technique is also valid for any number of slot/pole combinations and for non-overlapping teeth wound windings with a single/double layer. Finally, the semi-analytical results have been performed for different values of iron core relative permeability (viz., 100 and 800), and compared with those obtained by the 2D finite-element method (FEM). The comparisons with FEM show good results for the proposed approach.

Stray field of a wedge placed in an external inhomogeneous magnetic field

The problem of determining the stray field of an OZ-axis–infinite wedge with a constant magnetic permeability μ placed in a constant inhomogeneous magnetic field is considered. The problem statement is given, the properties of the solution are examined, and some examples are provided.