Magnetic Silicone Rubbers

Petra Štefcová; Miroslav Schatz

doi:10.5254/1.3538127

Effects of Magnetic Powder Loading on Mechanical Properties and Magnetic Properties of Natural Rubber

Advances in Science and Technology ◽

10.4028/www.scientific.net/ast.45.1423 ◽

2006 ◽

Vol 45 ◽

pp. 1423-1428

Author(s):

Somsak Woramongconchai ◽

Chatchawan Lohitvisat ◽

Aree Wichainchai

Keyword(s):

Mechanical Properties ◽

Magnetic Properties ◽

Coercive Force ◽

Natural Rubber ◽

Barium Ferrite ◽

Maximum Energy ◽

Magnetic Powder ◽

Elongation At Break ◽

Maximum Energy Product ◽

Energy Product

The effect of magnetic powders and powders loading on magnetic properties and mechanical properties of magnetic rubbers were studied. The natural rubber with magnetic powders, Barium ferrite, Neodymium iron boron, were used as starting materials to prepare magnetic rubbers. Barium ferrite (BaO.6F2O3) powders had been sintered at 1285 oC for 30 hours to improve its crystal structure. The physical properties of magnetic rubbers, residual flux density (Br), coercive force (Hc), maximum energy product (BHmax), hardness and density, had a trend to increase as enhancing magnetic powders loading. However, some properties such as, intrinsic coercive force (Hci), tensile strength and elongation at break, had a trend to decrease when the magnetic powder loading was increased. Magnetic properties of the anisotropic type, sintered powders, were higher than isotropic type, non-sintered powders, except the Hci because anisotropic magnetic rubber indicated crystal orientation in the same direction.

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Influence of Milling Time on Magnetic Properties and Microstructure of Sintered Nd-Fe-B Based Permanent Magnets

Materials Science Forum ◽

10.4028/www.scientific.net/msf.930.445 ◽

2018 ◽

Vol 930 ◽

pp. 445-448

Author(s):

R.G.T. Fim ◽

M.R.M. Silva ◽

S.C. Silva ◽

Julio Cesar Serafim Casini ◽

P.A.P. Wendhausen ◽

...

Keyword(s):

Grain Size ◽

Magnetic Properties ◽

Permanent Magnets ◽

Milling Time ◽

Maximum Energy ◽

Inhomogeneous Distribution ◽

Maximum Energy Product ◽

Grain Sizes ◽

Energy Product

In this paper, the effect of the grain size on sintered Nd-Fe-B based permanent magnets was investigated. In order, the magnets were produced by different milling times at 200 rpm and then vacuum sintered at 1373 K for 60 minutes followed by cooling outside the furnace. The magnets either produced by lower and higher milling times (30 and 75 minutes) exhibited lower remanence and coercivity, due the inhomogeneous distribution of the grain sizes. The magnet produced by intermediary milling time (45 minutes) exhibited the highest properties among all samples, with remanence of 1.06 T, coercivity of 891.3 KA.m-1, maximum energy product of 211 KJ.m3and a squareness factor equal 0.92.

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Microstructural and Magnetic Properties of a Fe-Co-Ni-Al-Ti-Cu Alloy

Key Engineering Materials ◽

10.4028/www.scientific.net/kem.442.236 ◽

2010 ◽

Vol 442 ◽

pp. 236-241 ◽

Cited By ~ 5

Author(s):

S. Akbar ◽

Z. Ahmad ◽

M. Farooque

Keyword(s):

Magnetic Properties ◽

Permanent Magnets ◽

Maximum Energy ◽

X Ray Diffraction ◽

Maximum Energy Product ◽

Energy Product ◽

Cu Alloy ◽

Treatment Conditions ◽

Residual Magnetic Induction ◽

Microstructural Studies

The present work describes the development of Fe-Co-Ni-Al-Ti-Cu permanent magnets. Magnetic and microstructural studies were carried out using microscopy, magnetometery and X-ray diffraction techniques. The results indicate that both microstructural and magnetic properties are sensitive to the heat treatment conditions. Magnetic properties in the studied alloys could be improved by controlling the annealed state microstructure and by efficiently aligning and elongating the nano-structured ferromagnetic α1 particles in <001> crystallographic directions. The best magnetic properties in the alloy Fe-34.7Co-15.3Ni-8.3Al-5.4Ti-3.9Cu is obtained as coercive force (Hc) of 1528Oe, residual magnetic induction (Br) of 7105G, saturation magnetization (Bs) of 19060G and maximum energy product ((BH)max) of 3.3MGOe.

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Influence of Alloying Elements Zr, Nb and Mo on the Microstructure and Magnetic Properties of Sintered Pr-Fe-Co-B Based Permanent Magnets

Materials Science Forum ◽

10.4028/www.scientific.net/msf.930.440 ◽

2018 ◽

Vol 930 ◽

pp. 440-444

Author(s):

Melissa Rohrig Martins da Silva ◽

R.G.T. Fim ◽

S.C. Silva ◽

Julio Cesar Serafim Casini ◽

P.A.P. Wendhausen ◽

...

Keyword(s):

Magnetic Properties ◽

Permanent Magnets ◽

Maximum Energy ◽

Alloying Elements ◽

Maximum Energy Product ◽

Energy Product ◽

Cast Alloys ◽

Hydrogen Decrepitation ◽

Microstructure And Magnetic Properties

The addition of alloying elements on rare-earth permanent magnets is one of the methods used to improve the magnetic properties. This present work evaluates the influence of alloying elements such as Zr, Nb and Mo on the microstructure and magnetic properties of sintered Pr-FeCo-B based permanent magnets. The permanent magnets were produced by the conventional powder metallurgy route using powder obtained by hydrogen-decrepitation (HD) method from as cast alloys. In order to produce the magnet Pr16Fe66,9Co10,7B5,7Cu0,7 without alloying elements the mixture of alloys method was employed, mixing two compositions: Pr20Fe73B5Cu2 (33% w.t) and Pr14Fe64Co16B6 (67% w.t). With the purpose of evaluating the influence of the alloying elements, the Pr14Fe64Co16B6X0,1 (where X= Zr, Nb or Mo) (67% w.t) alloy was employed. The characterization of the alloys and the magnets was carried out using scanning electron microscopy (SEM), energy-dispersive X-ray spectroscopy (EDXS) and the magnetic properties were measured using a permeameter. The magnet without any additions presented the highest intrinsic coercivity (μ0iHc = 748 KA.m-1) while the magnet with Nb addition presented higher remanence (Br = 1,04 T). The magnet with Zr addition presented the highest maximum energy product (BHmáx = 144 KJ.m-3), and the magnet with Mo addition showed the highest squareness factor (SF = 0,73).

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EM of rapidly solidified permanent magnets

Proceedings, annual meeting, Electron Microscopy Society of America ◽

10.1017/s0424820100121399 ◽

1992 ◽

Vol 50 (1) ◽

pp. 198-199

Author(s):

Raja K. Mishra

Keyword(s):

Melt Spinning ◽

Permanent Magnets ◽

Dark Field Image ◽

Dark Field ◽

Maximum Energy ◽

Quench Rate ◽

Maximum Energy Product ◽

Energy Product ◽

Annular Dark Field ◽

Rapidly Solidified

The discovery of a new class of permanent magnets based on Nd2Fe14B phase in the last decade has led to intense research and development efforts aimed at commercial exploitation of the new alloy. The material can be prepared either by rapid solidification or by powder metallurgy techniques and the resulting microstructures are very different. This paper details the microstructure of Nd-Fe-B magnets produced by melt-spinning.In melt spinning, quench rate can be varied easily by changing the rate of rotation of the quench wheel. There is an optimum quench rate when the material shows maximum magnetic hardening. For faster or slower quench rates, both coercivity and maximum energy product of the material fall off. These results can be directly related to the changes in the microstructure of the melt-spun ribbon as a function of quench rate. Figure 1 shows the microstructure of (a) an overquenched and (b) an optimally quenched ribbon. In Fig. 1(a), the material is nearly amorphous, with small nuclei of Nd2Fe14B grains visible and in Fig. 1(b) the microstructure consists of equiaxed Nd2Fe14B grains surrounded by a thin noncrystalline Nd-rich phase. Fig. 1(c) shows an annular dark field image of the intergranular phase. Nd enrichment in this phase is shown in the EDX spectra in Fig. 2.

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Bulk Nanocrystalline Permanent Magnets by Selective Laser Melting

Practical Metallography ◽

10.1515/pm-2021-0055 ◽

2021 ◽

Vol 58 (10) ◽

pp. 630-643

Author(s):

F. Trauter ◽

J. Schanz ◽

H. Riegel ◽

T. Bernthaler ◽

D. Goll ◽

...

Keyword(s):

Additive Manufacturing ◽

Field Strength ◽

Selective Laser Melting ◽

Permanent Magnets ◽

Maximum Energy ◽

Laser Melting ◽

Maximum Energy Product ◽

Energy Product ◽

Bulk Nanocrystalline ◽

Micrometer Scale

Abstract Fe-Nd-B powders were processed by additive manufacturing using laboratory scale selective laser melting to produce bulk nanocrystalline permanent magnets. The manufacturing process was carried out in a specially developed process chamber under Ar atmosphere. This resulted in novel types of microstructures with micrometer scale clusters of nanocrystalline hard magnetic grains. Owing to this microstructure, a maximum coercive field strength (coercivity) μ0Hc of 1.16 T, a remanence Jr of 0.58 T, and a maximum energy product (BH)max of 62.3 kJ/mm3could, for example, be obtained for the composition Nd16.5-Pr1.5-Zr2.6-Ti2.5-Co2.2-Fe65.9-B8.8.

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Effect of Dysprosium Content on the Magnetic Properties of Nanocrystalline (Pr0.25Nd0.75)10-xDyxFe82Co2B6 Alloys

Materials Science Forum ◽

10.4028/www.scientific.net/msf.789.28 ◽

2014 ◽

Vol 789 ◽

pp. 28-31 ◽

Cited By ~ 2

Author(s):

He Wei Ding ◽

Chun Xiang Cui ◽

Ji Bing Sun

Keyword(s):

Magnetic Properties ◽

Melt Spinning ◽

Maximum Energy ◽

Vibrating Sample Magnetometer ◽

X Ray ◽

Maximum Energy Product ◽

Energy Product ◽

Intrinsic Coercivity ◽

Electronic Microscope ◽

Microstructure And Magnetic Properties

(Pr0.25Nd0.75)10-xDyxFe82Co2B6(x=0~0.3) ribbons were prepared by melt spinning at 25m/s and subsequent annealing. The effect of Dy content on the microstructure and magnetic properties of the ribbons has been investigated by X-ray diffractometer (XRD), scanning electronic microscope (SEM) and vibrating sample magnetometer (VSM). The magnetic properties related to the Dy content were characterized. Intrinsic coercivity of 598kA/m, remanence of 0.58T, and the maximum energy product (BH)max of 43kJ/m3 were achieved in (Pr0.25Nd0.75)9.8Dy0.2Fe82Co2B6 after annealing at 700°C for 10 minutes.

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Microstructure Of Fe-Nd-B Alloys Tailored To Approach Theoretical Coercrvtty Limits

Microscopy and Microanalysis ◽

10.1017/s1431927600013453 ◽

1999 ◽

Vol 5 (S2) ◽

pp. 26-27

Author(s):

Kannan M. Krishnan ◽

Er. Girt ◽

E. C. Nelson ◽

G. Thomas ◽

Ferdinand Hofer

Keyword(s):

Magnetic Particles ◽

Permanent Magnets ◽

Spontaneous Magnetization ◽

Particle Interaction ◽

Maximum Energy ◽

Interacting Particles ◽

Maximum Energy Product ◽

Energy Product ◽

Oriented Samples ◽

The Difference

Performance of permanent magnets for a variety of applications is often determined by the maximum energy product (BH)max. In order to obtain high (BH)max permanent magnetic materials have to have large coercivity. In theory the coercive field of ideally oriented, non-interacting, single domain, magnetic particles, assuming Kl is much bigger than K2, was shown to be He = 2K1/Ms - N Ms, where Kl and K2 are the magnetocrystalline anisotropy constants, Ms is the spontaneous magnetization and N is the demagnetization factor. For randomly oriented non-interacting particles the Stoner-Wohlfarth model predicts that the value of Hc decreases to about half. However, experimentally obtained values of the coercitive fields in permanent magnets are 3 to 10 and 2 times smaller for well oriented and randomly oriented samples, respectively. This discrepancy was attributed to inter-particle interaction and the microstructure of the permanent magnets. In order to understand the difference between the theoretically predicted and experimentally obtained results for He we prepared rapidly quenched, Nd-rich, NdxFe14B (2 < x < 150) ribbons.

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New YDy-Based R2(Fe,Co)14B Melt-Spun Magnets (R=Y+Dy+Nd)

Materials Science Forum ◽

10.4028/www.scientific.net/msf.475-479.2155 ◽

2005 ◽

Vol 475-479 ◽

pp. 2155-2160 ◽

Cited By ~ 13

Author(s):

W. Tang ◽

K.W. Dennis ◽

Matthew J. Kramer ◽

I.E. Anderson ◽

R.W. McCallum

Keyword(s):

Magnetic Properties ◽

High Temperature ◽

Temperature Coefficient ◽

Temperature Stability ◽

Maximum Energy ◽

Maximum Energy Product ◽

Energy Product ◽

Optimal Sample ◽

Melt Spun ◽

Nd Substitution

The effects of the ratio of Y to Dy as well as the effect of Nd and Co substitutions on magnetic properties in [Ndx(YDy)0.5(1-x)]2.2Fe14-yCoyB ribbons melt-spun at 22 m/s have been systematically studied. (Y1-zDyz)2.2Fe14B ribbons with a ratio z of 0.25 or 0.5 simultaneously obtains a smaller temperature coefficient of remanence (α ) and coervicity (β ) which are much smaller than those of Nd-based Nd2Fe14B ribbons. In [Ndx(YDy)0.5(1-x)]2.2Fe14-yCoyB ribbons, Nd substitution (x=0 to 0.8) can improve the maximum energy product (BH)max of annealed ribbons but degrades the temperature stability of the magnetic properties. The ribbons with x=0.4 and y=0 yield a (BH)max of 8.7 MGOe. For these ribbons, the α and β are -0.07 and -0.31 %/°C in the temperature range of 27 to 127°C, respectively. Increasing Co (x) from 0 to 3, slightly decreases coercivity Hcj from 21.5 to 16.3 kOe, but keeps the (BH)max in the range of 8.6 to 10.2 MGOe. The optimal sample with x=0.5 and y=1.5 obtains a (BH)max of 10.2 and 5.0 MGOe at 27 and 250°C, respectively. Its α and β are -0.11 and -0.30 %/°C, respectively. These results show that studied ribbons are very promising to develop into high temperature isotropic bonded magnets capable of operating at or above 180°C.

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A Comparative Study between Low and High-Energy Milling Processes for the Production of HD PrFeCoBNb Sintered Magnets

Materials Science Forum ◽

10.4028/www.scientific.net/msf.591-593.114 ◽

2008 ◽

Vol 591-593 ◽

pp. 114-119 ◽

Cited By ~ 1

Author(s):

E.A. Périgo ◽

E.P. Soares ◽

Hidetoshi Takiishi ◽

C.C. Motta ◽

Rubens Nunes de Faria Jr.

Keyword(s):

Ball Milling ◽

Permanent Magnets ◽

High Energy ◽

Maximum Energy ◽

Maximum Energy Product ◽

High Energy Milling ◽

Energy Product ◽

Energy Processing ◽

Hydrogen Decrepitation ◽

High Degree

Roller-ball milling (RBM) or planetary ball milling (PBM) have been used together with the hydrogen decrepitation (HD) process to produce sintered permanent magnets based on a mixture of Pr16Fe76B8 and Pr14.00Fe63.90Co16.00B6.00Nb0.10 magnetic alloys. Five distinct compositions have been studied comparing low- and high-energy milling. Magnets with a particular composition and prepared using these two routes exhibited similar magnetic properties. Modifications have been carried out in the procedure of the HD stage for PBM in order to guarantee a high degree of crystallographic alignment. Pr15.00Fe69.95Co8.00B7.00Nb0.05 magnets showed the best maximum energy product for both processing routes (~ 247 kJm-3). A significant reduction in the milling time (93%) has been achieved with high-energy processing, the greatest advantage over the low-energy route.

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