Magnetic core

About: Magnetic core is a research topic. Over the lifetime, 30011 publications have been published within this topic receiving 155247 citations.

Effects of coatings on the soft magnetic properties of an iron-based amorphous alloy

Abstract: Measurements of core loss and de magnetic properties are reported on insulated and uninsulated smooth, high pack-factor iron-based amorphous metal ribbon. Higher losses measured on uninsulated ribbons, wound with winding tensions of 5 N and above, are found to be associated with macroscopic interlaminar eddy currents due to numerous shorts between laminations.

Temperature rise analytical method for predicting temperature of permanent magnet in permanent magnet synchronous motor

Abstract: The invention relates to a temperature rise analytical method for predicting temperature of a permanent magnet in a permanent magnet synchronous motor (PMSM), belonging to the application electrical engineering design field; the method is characterized in that: distributed heat source of a motor is analyzed by a filed-circuit compact coupling method, comprising eddy current loss in the permanent magnet, iron loss in an iron core and copper loss in armature; on the consideration of precision requirements, the coupling analysis of a magnetic field and a temperature filed can be realized by single-way coupling mode A thermal model of the permanent magnet synchronous motor is built based on a mixing method of a novel equivalent heat network and a finite element, heat parameters are rationally selected by adopting a combining mode of experimental measurement and empirical formula, the heat transferring coefficient and cooling condition of the motor are described completely, a stator and a rotor can be systematically combined by adopting air gap joints in the heat network, the stator and rotor unified temperature rise model is formed, the difficulty of measuring air gap temperature is avoided, material parameters are adopted at the practical working temperature, so as to lead the analysis to be rational; the accurate and optical method for predicting the temperature of the permanent magnet is realized by special correction processing in experimental links; in addition, the design method is used to give suggestions for model selection of the permanent magnet material in the motor

Vibration Reduction of Inductors Under Magnetostrictive and Maxwell Forces Excitation

Abstract: This paper analyzes the phenomenon of vibrations in U-shaped (two-limb) inductors with distributed air gaps due to both Maxwell and magnetostriction forces. A weak 2-D magnetomechanical finite-element model (FEM), including magnetostrictive tensor, is developed under the GetDP open-source simulation environment. A simple analytical model of the reactor core vibration under magnetic forces is established and validated using the FEM model. The resonance effect of magnetostriction and Maxwell forces on the inductor structure is analyzed, and a sensitivity analysis is run on some of the inductor geometrical parameters. An example of inductor is presented, and a methodology to reduce vertical vibrations under magnetic force excitation is proposed by opposing the magnetostrictive and Maxwell forces. This technique is validated using both the analytical and the FEM models.

Extraction of 3D field maps of magnetic multipoles from 2D surface measurements with applications to the optics calculations of the large-acceptance superconducting fragment separator BigRIPS

Abstract: The fringing fields of magnets with large apertures and short lengths greatly affect ion-optical calculations. In particular, for a high magnetic field where the iron core becomes saturated, the effective lengths and shapes of the field distribution must be considered because they change with the excitation current. Precise measurement of the three-dimensional magnetic fields and the correct application of parameters in the ion-optical calculations are necessary. First we present a practical numerical method of extracting full 3D magnetic field maps of magnetic multipoles from 2D field measurements of the surface of a cylinder. Using this novel method, we extracted the distributions along the beam axis for the coefficient of the first-order quadrupole component, which is the leading term of the quadrupole components in the multipole expansion of magnetic fields and proportional to the distance from the axis. Higher order components of the 3D magnetic field can be extracted from the leading term via recursion relations. The measurements were done for many excitation current values for the large-aperture superconducting triplet quadrupole magnets (STQs) in the BigRIPS fragment separator at the RIKEN Nishina Center RI Beam Factory. These distributions were parameterized using the Enge functions to fit the fringe field shapes at all excitation current values, so that unmeasured values are interpolated. The extracted distributions depend only on the position along the beam axis, and thus the measured three-dimensional field can easily be parameterized for ion-optical calculations. We implemented these parameters in the ion-optical calculation code COSY INFINITY and realized a first-order calculation that incorporates the effect of large and varying fringe fields more accurately. We applied the calculation to determine the excitation current settings of the STQs to realize various optics modes of BigRIPS and the effectiveness of this approach has been demonstrated.

Microfabrication and characteristics of low-power high-performance magnetic thin-film transformers

Abstract: We investigated low-power (1.5-W), solenoid-type magnetic thin-film transformers with a Ni/sub 81/Fe/sub 19/ core for a 5-MHz drive dc-dc converter application. We used 2-/spl mu/m-thick Ni/sub 81/Fe/sub 19/ films covered by 20-/spl mu/m-thick copper coils as the core materials. The transformers fabricated in this study range in size from 3.08 mm /spl times/ 25.5 mm to 6.15 mm /spl times/ 12.75 mm. The design of the transformers was optimized by utilizing the conventional equations, a Maxwell three-dimensional field simulator, and parameters obtained from the magnetic properties of NiFe magnetic core materials. The 6.15 mm /spl times/ 12.75 mm transformers exhibit inductance (L) of 0.83 /spl mu/H, dc resistance of 2.3 /spl Omega/, coupling factor of 0.91, and gain of -1 dB at 5 MHz. These results are comparable to those reported in recent literature for various types of transformers sandwiched by more complex magnetic core materials. The calculated data obtained by using the well-known equation of L and the equivalent circuit agreed well with the high-frequency data for L and gain of the transformers.