ChemInform Abstract: The Influence of Alloying Additions and Process Parameters on the Magnetic Properties of PrFeB-Based Bonded Magnets.

The Co3Pt magnetic layer with thickness of 7~28 nm was deposited onto the Pt underlayer. The as-deposited Co3Pt/Pt double-layered films with or without a 5 nm Pt capped layer were annealed at temperatures between 275 and 375 °C in vacuum of 1 mTorr. The influences of process parameters on perpendicular magnetic properties of Co3Pt thin films were investigated. The Co3Pt film with perpendicular coercivity (Hc⊥) value of 3620 Oe and the perpendicular squareness (S⊥) of 0.7 could be achieved from the Co3Pt(18 nm)/Pt(100 nm) double-layered films by annealing at 300°C. Further added Tb30Co70 film on the Co3Pt/Pt double-layered film could greatly enhance the perpendicular magnetic properties of the film. The Hc⊥ and S⊥ of the Tb30Co70/Co3Pt/Pt film were as high as 6560 Oe and 0.88, respectively, which has significant potential to be applied in perpendicular magnetic recording media.

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Experimental Study of High Temperature Hydrozing Annealing 1J50 Alloy's Magnetic Properties

Journal of Manufacturing Science and Engineering ◽

10.1115/1.4025806 ◽

2013 ◽

Vol 135 (6) ◽

Cited By ~ 1

Author(s):

Yingtao Zhang ◽

Gang Wang ◽

Zhenguo Nie ◽

Wankai Shi ◽

Yiming Rong

Keyword(s):

Magnetic Properties ◽

High Temperature ◽

Process Parameters ◽

Quantitative Research ◽

Annealing Process ◽

National Standards ◽

Magnetic Alloy ◽

Soft Magnetic ◽

Soft Magnetic Alloy ◽

Microstructure And Magnetic Properties

The good DC magnetic properties can be achieved for 1J50 soft magnetic alloy by applying high temperature hydrogen annealing. Annealing process parameters, e.g., atmosphere, soaking temperature, and time, are critical to soft magnetic properties. Qualitative results had been done for years. However a quantitative research among process parameters, microstructure, and magnetic properties can be more comprehensive and specific. In this study, a serial of experiments for 1J50 samples under the Chinese national standards. The influence of annealing temperature and socking time on DC magnetic properties and microstructure of the samples has been investigated on DC magnetic properties and microstructure of samples. The result shows that annealing process parameters have a nonlinear effect on the development of material microstructure and magnetic properties. Furthermore, the models among magnetic property, grain size, and process parameters have been built to quantitatively describe the interrelationship in between.

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Additive Manufacturing of Bonded Nd–Fe–B—Effect of Process Parameters on Magnetic Properties

IEEE Transactions on Magnetics ◽

10.1109/tmag.2017.2715722 ◽

2017 ◽

Vol 53 (11) ◽

pp. 1-4 ◽

Cited By ~ 12

Author(s):

A. B. Baldissera ◽

P. Pavez ◽

P. A. P. Wendhausen ◽

C. H. Ahrens ◽

J. M. Mascheroni

Keyword(s):

Magnetic Properties ◽

Additive Manufacturing ◽

Process Parameters

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The influence of process parameters and alloy structure on the magnetic properties of NdDyFeBNb HD sintered magnets

Journal of Materials Processing Technology ◽

10.1016/j.jmatprotec.2003.10.022 ◽

2004 ◽

Vol 152 (1) ◽

pp. 1-8 ◽

Cited By ~ 2

Author(s):

H. Takiishi ◽

L.F.C.P. Lima ◽

I. Costa ◽

R.N. Faria

Keyword(s):

Magnetic Properties ◽

Process Parameters ◽

Alloy Structure ◽

Influence Of Process Parameters ◽

Sintered Magnets

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Integrated Process Simulation of Non-Oriented Electrical Steel

Materials ◽

10.3390/ma14216659 ◽

2021 ◽

Vol 14 (21) ◽

pp. 6659

Author(s):

Anett Stöcker ◽

Max Weiner ◽

Grzegorz Korpała ◽

Ulrich Prahl ◽

Xuefei Wei ◽

...

Keyword(s):

Grain Size ◽

Magnetic Properties ◽

Cold Rolling ◽

Process Parameters ◽

Hot Rolling ◽

Electrical Steel ◽

Sheet Thickness ◽

Electrical Steels ◽

Heterogeneous Microstructures ◽

The Impact

[d=A]A tailor-made microstructure, especially regarding grain size and texture, improves the magnetic properties of non-oriented electrical steels. One way to adjust the microstructure is to control the production and processing in great detail. Simulation and modeling approaches can help to evaluate the impact of different process parameters and finally select them appropriately. We present individual model approaches for hot rolling, cold rolling, annealing and shear cutting and aim to connect the models to account for the complex interrelationships between the process steps. A layer model combined with a microstructure model describes the grain size evolution during hot rolling. The crystal plasticity finite-element method (CPFEM) predicts the cold-rolling texture. Grain size and texture evolution during annealing is captured by the level-set method and the heat treatment model GraGLeS2D+. The impact of different grain sizes across the sheet thickness on residual stress state is evaluated by the surface model. All models take heterogeneous microstructures across the sheet thickness into account. Furthermore, a relationship is established between process and material parameters and magnetic properties. The basic mathematical principles of the models are explained and demonstrated using laboratory experiments on a non-oriented electrical steel with 3.16 wt.% Si as an example. Improving the magnetic properties of non-oriented electrical steels are of high interest. In this context, improvement by a tailor-made microstructure, especially regarding grain size and texture, is one focus. One way to adjust the microstructure is to control the production and processing in great detail. Simulation and modeling approaches, emphasizing grain size and texture development, can help to evaluate and finally set process parameters. Here, we present individual model approaches for hot rolling, cold rolling, annealing and shear cutting and aim to connect the models to account for the complex interrelationships between the process steps. Furthermore, a connection between the process parameters and the magnetic properties is drawn. Grain size, grain size distribution, texture and dislocation density are the main transfer parameters in between the models. All models take heterogeneous microstructures across the sheet thickness into account. The basic mathematical principles of the models are explained, and a case study is presented in each case using FeSi3.2wt%Si as an example material.

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Influence of Melt-Pool Stability in 3D Printing of NdFeB Magnets on Density and Magnetic Properties

Materials ◽

10.3390/ma13010139 ◽

2019 ◽

Vol 13 (1) ◽

pp. 139 ◽

Cited By ~ 3

Author(s):

Mateusz Skalon ◽

Michael Görtler ◽

Benjamin Meier ◽

Siegfried Arneitz ◽

Nikolaus Urban ◽

...

Keyword(s):

Magnetic Properties ◽

Layer Thickness ◽

Process Parameters ◽

Permanent Magnets ◽

Scanning Speed ◽

Maximum Energy ◽

Powder Layer ◽

Influence Of Process Parameters ◽

Layer Height ◽

Melt Pool

The current work presents the results of an investigation focused on the influence of process parameters on the melt-track stability and its consequence to the sample density printed out of NdFeB powder. Commercially available powder of Nd7.5Pr0.7Fe75.4Co2.5B8.8Zr2.6Ti2.5 alloy was investigated at the angle of application in selective laser melting of permanent magnets. Using single track printing the stability of the melt pool was investigated under changing process parameters. The influence of changing laser power, scanning speed, and powder layer thickness on density, porosity structure, microstructure, phase composition, and magnetic properties were investigated. The results showed that energy density coupled with powder layer thickness plays a crucial role in melt-track stability. It was possible to manufacture magnets of both high relative density and high magnetic properties. Magnetization tests showed a significant correlation between the shape of the demagnetization curve and the layer height. While small layer heights are beneficial for sufficient magnetic properties, the remaining main parameters tend to affect the magnetic properties less. A quasi-linear correlation between the layer height and the magnetic properties remanence (Jr), coercivity (HcJ) and maximum energy product ((BH)max) was found.

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Influence of Process Parameters on Grain Size and Texture Evolution of Fe-3.2 wt.-% Si Non-Oriented Electrical Steels

Materials ◽

10.3390/ma14226822 ◽

2021 ◽

Vol 14 (22) ◽

pp. 6822

Author(s):

Xuefei Wei ◽

Alexander Krämer ◽

Gerhard Hirt ◽

Anett Stöcker ◽

Rudolf Kawalla ◽

...

Keyword(s):

Grain Size ◽

Magnetic Properties ◽

Cold Rolling ◽

Process Parameters ◽

Hot Rolling ◽

Electrical Steel ◽

Texture Evolution ◽

Laboratory Scale ◽

Process Chain ◽

Final Annealing

The magnetic properties of non-oriented electrical steel, widely used in electric machines, are closely related to the grain size and texture of the material. How to control the evolution of grain size and texture through processing in order to improve the magnetic properties is the research focus of this article. Therefore, the complete process chain of a non-oriented electrical steel with 3.2 wt.-% Si was studied with regard to hot rolling, cold rolling, and final annealing on laboratory scale. Through a comprehensive analysis of the process chain, the influence of important process parameters on the grain size and texture evolution as well as the magnetic properties was determined. It was found that furnace cooling after the last hot rolling pass led to a fully recrystallized grain structure with the favorable ND-rotated-cube component, and a large portion of this component was retained in the thin strip after cold rolling, resulting in a texture with a low γ-fiber and a high ND-cube component after final annealing at moderate to high temperatures. These promising results on a laboratory scale can be regarded as an effective way to control the processing on an industrial scale, to finally tailor the magnetic properties of non-oriented electrical steel according to their final application.

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