• Title/Summary/Keyword: magnetic compaction

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Dynamic Compaction of Mechanochemically Alloyed Fe-Si Nano Powders by Magnetic Pulsed Pressure (기계화학적 합금화된 나노 Fe-6.5Si 분말의 자기 펄스압에 의한 동적성형)

  • Lee, G.-H.;Rhee, C.-K.;Kim, W.-W.;Yun, J.-W.;Lee, K.-S.
    • Journal of Powder Materials
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    • v.12 no.1
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    • pp.24-29
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    • 2005
  • Nano Fe-6.5wt%Si powders have been synthesized by mechano-chemical process (MCP) for an application of soft magnetic core. Owing to hard and brittle characteristics of Fe-6.5Si nano powders having large surface area, it is very difficult to reach high density more than 70% of theoretical density (~7.4 g/$cm_3$) by cold compaction. To overcome such problem a magnetic pulsed compaction (MPC), which is one of dynamic compaction techniques, was applied. The green density was achieved about 78% (~5.8 g/$cm_3$) by MPC at room temperature.

Effect of Hot-compaction Temperature on the Magnetic Properties of Anisotropic Nanocrystalline Magnets

  • Li, W.;Wang, H.J.;Lin, M.;Lai, B.;Li, D.;Pan, W.
    • Journal of Magnetics
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    • v.16 no.3
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    • pp.300-303
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    • 2011
  • The effect of the hot-compaction temperature on the microstructure and magnetic properties of anisotropic nanocrystalline magnets was investigated. The hot-compaction temperature was found to impact both the magnetic properties and the microstructure of die-upset magnets. The remanence of the isotropic precursor increases slightly with the improved hot-compaction temperature, and the grains start to grow on the flake boundary at higher hot-compaction temperatures. After hot deformation, it was found that the change in the magnetic properties was the inverse of that observed with the hot-compaction temperature. Microstructural investigation showed that die-upset magnets inherit the microstructural characteristics of their precursor. For the die-upset magnets, hot pressed at low temperature, scarcely any abnormal grain growth on the flake boundary can be seen. For those hot pressed at higher temperatures, however, layers with large equiaxed grains could be observed, which accounted for the poor alignment during the hot deformation, and thus the poor magnetic properties.

Calculations on the Reduction Rate of Ground Level Magnetic Fields due to Varying Configurations of Overhead Transmission Line (가공 송전선 형상변화에 따른 지표면 자계저감율 계산)

  • Min, Suk-Won;Kim, Eung-Sik;Park, Jun-Hyeong
    • The Transactions of The Korean Institute of Electrical Engineers
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    • v.57 no.11
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    • pp.2027-2034
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    • 2008
  • There are concerns on possible health effects from exposure to electromagnetic fields. One reflection of this concerns is the considerable controversy, delay, and cost increases involved in the construction of power lines and facilities. To cope with such challenges, in this paper we investigated magnetic fields reduction techniques such as general compaction, in' span compaction, cruciform, vertical, 3 way splits phase, and 4way splits phase. As results, we found general compaction and 4 way splits phase could reduce magnetic fields up to 90%, while cruciform, vertical, and 3 way splits phase gave lower reduction rates of 30% because these configurations were similar to a current type of low reactance arrangement. We also knew 1 spacer in span compaction was appropriate in Korea in view of effectiveness and economy.

Magnetic Pulsed Compaction and Sintering Characteristics of Al Composite Powders Reinforced with Waste Stainless Steel Short Fibers (폐 스테인레스강 단섬유로 강화한 알루미늄 복합분말의 자기펄스압 성형 및 소결 특성)

  • Hyun, Chang-Yong;Won, Chul-Hyun;Park, Jae-Soon
    • Journal of Powder Materials
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    • v.14 no.6
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    • pp.380-385
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    • 2007
  • Characteristics of Al-based composites with waste stainless steel short fiber, fabricated by magnetic pulsed compaction and sintering were investigated. The compacts prepared by magnetic pulsed compaction showed high relative density and homogeneous microstructure compared with that by conventional press compaction. The relative density of sintered composites at $430^{\circ}C$ for 1 h exhibited the same value with compacts and decreased with increase in STS short fiber content. The reaction between Al and STS phase was confirmed by the microstructural analysis using EDS. The sintered composites, prepared by magnetic pulsed compaction, showed increased hardness value with increasing STS fiber content. Maximum yield strength of 100 MPa and tensile strength of 232 MPa were registered in the AI-based composite with 30 vol% STS short fiber.

Experimental Study on Magnetic Compaction for Reducing Bughole of Free-Form Concrete Panels (비정형 콘크리트 패널 표면 공극저감을 위한 자력 다짐 실험연구)

  • Youn, Jong-Young;Kim, Ji-Hye;Kim, Hye-Kwon;Lee, Donghoon
    • Proceedings of the Korean Institute of Building Construction Conference
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    • 2023.05a
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    • pp.25-26
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    • 2023
  • Free-form buildings serve as landmarks, and interest and demand are increasing. However, in the case of free-form concrete members, different curved surfaces are required depending on the location where they are used, and the formwork is custom-made and used. Concrete is poured into the manufactured formwork to produce FCP (Free-form Concrete Panel). However, since it is an atypical building that requires precise curvature, compaction cannot be performed after concrete is poured. This leads to the occurrence of bughole, which reduce the strength and aesthetics of concrete. Therefore, in this study, we intend to conduct basic experiments to develop a magnetic compaction device that can be used for FCP. As a result of the experiment, it was confirmed that the bug hole was improved when the magnetic compaction device was applied, and there was no significant difference in compressive strength and flexural strength. This technology can be used in the field of Free-form concrete where it is difficult to perform compaction work, and it is expected to be used as a basic research related to technology for new automatic compaction.

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Fabrication and Properties of Densified Tungsten by Magnetic Pulse Compaction and Spark Plasma Sintering (자기펄스 성형 및 방전 플라즈마 소결 공정으로 제조한 텅스텐 소결체의 특성)

  • Lee, Eui Seon;Byun, Jongmin;Jeong, Young-Keun;Oh, Sung-Tag
    • Korean Journal of Materials Research
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    • v.30 no.6
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    • pp.321-325
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    • 2020
  • The present study demonstrates the effect of magnetic pulse compaction and spark plasma sintering on the microstructure and mechanical property of a sintered W body. The relative density of green specimens prepared by magnetic pulse compaction increases with increase in applied pressure, but when the applied pressure is 3.4 GPa or more, some cracks in the specimen are observed. The pressureless-sintered W shows neck growth between W particles, but there are still many pores. The sintered body fabricated by spark plasma sintering exhibits a relative density of above 90 %, and the specimen sintered at 1,600 ℃ after magnetic pulse compaction shows the highest density, with a relative density of 93.6 %. Compared to the specimen for which the W powder is directly sintered, the specimen sintered after magnetic pulse compaction shows a smaller crystal grain size, which is explained by the reduced W particle size and microstructure homogenization during the magnetic pulse compaction process. Sintering at 1,600 ℃ led to the largest Vickers hardness value, but the value is slightly lower than that of the conventional W sintered body, which is attributed mainly to the increased grain size and low sintering density.

Magnetic Properties of Fe Powder Core Fabricated by Warm Compaction (온간성형법으로 제조된 Fe 분말 코어의 자성특성)

  • Kim, Se-Hoon;Jo, Tae-Sun;Park, Min-Suh;Kim, Young-Do
    • Journal of Powder Materials
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    • v.14 no.5
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    • pp.298-302
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    • 2007
  • In recent years, a rapid increase in demands for the soft magnetic composite parts has been created and it has been tried to improve their properties by various processing methods, alloying elements and compaction parameters. Warm compaction method has been used for the reduction of residual stress, the improvement of magnetic properties and the higher densities. In this work, the effects of warm compaction and polymer binder on magnetic properties of Fe powder core were investigated. The sintering powder, Fe oxide, was ball-milled for 30n hours. And then ball-milled Fe oxide powder was reduced through hydrogen reduction process. The hydrogen reduced Fe powder and polymer binder were mixed by 3-D turbular mixer. And then the mixed powder was warm-compacted. The magnetic properties such as core loss and permeability were measured by B-H curve analyzer.

Densification of TiO2 Nano Powder by Magnetic Pulsed Compaction (자기펄스 성형법에 의한 TiO2 나노 분말의 치밀화)

  • Kim, Hyo-Seob;Lee, Jeong-Goo;Rhee, Chang-Kyu;Koo, Jar-Myung;Hong, Soon-Jik
    • Korean Journal of Materials Research
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    • v.18 no.8
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    • pp.411-416
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    • 2008
  • In this research, fine-structure TiO2 bulks were fabricated in a combined application of magnetic pulsed compaction (MPC) and subsequent sintering and their densification behavior was investigated. The obtained density of $TiO_2$ bulk prepared via the combined processes increased as the MPC pressure increased from 0.3 to 0.7 GPa. Relatively higher density (88%) in the MPCed specimen at 0.7 GPa was attributed to the decrease of the inter-particle distance of the pre-compacted component. High pressure and rapid compaction using magnetic pulsed compaction reduced the shrinkage rate (about 10% in this case) of the sintered bulks compared to general processing (about 20%). The mixing conditions of PVA, water, and $TiO_2$ nano powder for the compaction of $TiO_2$ nano powder did not affect the density and shrinkage of the sintered bulks due to the high pressure of the MPC.

Densification of Al2O3 Nanopowder by Magnetic Pulsed Compaction and Their Properties (자기펄스 가압성형법에 의한 알루미나 나노분말의 치밀화 및 특성 평가)

  • Kang, R.C.;Lee, M.K.;Kim, W.W.;Rhee, C.K.;Hong, S.J.
    • Journal of Powder Materials
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    • v.15 no.1
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    • pp.37-45
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    • 2008
  • This article presents the challenges toward the successful consolidation of $Al_2O_3$ nanopowder using magnetic pulsed compaction (MPC). In this research the ultrafine-structured $Al_2O_3$ bulks have been fabricated by the combined application of magnetic pulsed compaction (MPC) and subsequent sintering, and their properties were investigated. The obtained density of $Al_2O_3$ bulk prepared by the combined processes was increased with increasing MPC pressure from 0.5 to 1.25 GPa. Relatively higher hardness and fracture toughness in the MPCed specimen at 1.25 GPa were attributed to the retention of the nanostructure in the consolidated bulk without cracks. The higher fracture toughness could be attributed to the crack deflection by homogeneous distribution and the retention of nanostructure, regardless of the presence of porosities. In addition, the as consolidated $Al_2O_3$ bulk using magnetic pulsed compaction showed enhanced breakdown voltage.