• Title/Summary/Keyword: Graphite powder

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Electrochemical Properties of Graphite-based Electrodes for Redox Flow Batteries

  • Kim, Hyung-Sun
    • Bulletin of the Korean Chemical Society
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    • v.32 no.2
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    • pp.571-575
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    • 2011
  • Graphite-based electrodes were prepared using synthetic graphite (MCMB 1028) or natural graphite (NG) powder using a dimensionally stable anode (DSA) as a substrate. Their electrochemical properties were investigated in vanadiumbased electrolytes to determine how to increase the durability and improve the energy efficiency of redox flow batteries. Cyclic voltammetry (CV) was performed in the voltage range of -0.7 V to 1.6 V vs. SCE at various scan rates to analyze the vanadium redox reaction. The graphite-based electrodes showed a fast redox reaction and good reversibility in a highly concentrated acidic electrolyte. The increased electrochemical activity of the NG-based electrode for the $V^{4+}/V^{5+}$ redox reaction can be attributed to the increased surface concentration of functional groups from the addition of conductive material that served as a catalyst. Therefore, it is expected that this electrode can be used to increase the power density and energy density of redox flow batteries.

Fabrication of Porous Materials having an Anisotropic Thermal Conductivity through the Alignment of Plate-shaped Pores (배향된 판상 기공구조를 통해 열전도도 이방성을 갖는 다공질 재료의 제조)

  • Yun, Jung-Yeol;Song, In-Hyeok;Kim, Hae-Du
    • 연구논문집
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    • s.33
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    • pp.147-155
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    • 2003
  • In order to fabricate porous materials having an anisotropic thermal conductivity by aligning plate-shaped pores structure, alumina powder (AM-21, mean particle size $4\mum$) and flake crystalline graphite was used. The aligned pore structure was realized using multi-pressing process. Degree of pore orientation increased with the number of pressing and thermal conductivity, parallel to the pressing direction, decreased with the number of pressing. Thermal conductivity decreased significantly to the addition of 30vol% crystalline graphite, however, in the case of 60vol%, thermal conductivity did not decrease significantly due to the breakage of crystalline graphite. An anisotropy of the thermal conductivity increased with the content of crystalline graphite up to 30vol%. Graded pore structure was fabricated by controlling the content and size of crystalline graphite, which provides, possibly, the enhancement in mechanical strength and thermal insulation properties of the insulating bricks.

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Synthesis of β-SiC Powder using a Recycled Graphite Block as a Source (그라파이트 블록을 원료로써 재활용한 β-SiC 분말 합성)

  • Nguyen, Minh Dat;Bang, Jung Won;Kim, Soo-Ryoung;Kim, Younghee;Jung, Eunjin;Hwang, Kyu Hong;Kwon, Woo-Teck
    • Resources Recycling
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    • v.26 no.1
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    • pp.16-21
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    • 2017
  • This paper relates to the synthesis of a source powder for SiC crystal growth. ${\beta}-SiC$ powders are synthesized at high temperatures (>$1400^{\circ}C$) by a reaction between silicon powder and carbon powder. The reaction is carried out in a graphite crucible operating in a vacuum ambient (or Ar gas) over a period of time sufficient to cause the Si+C mixture to react and form poly-crystalline SiC powder. End-product characterizations are pursued with X-ray diffraction analysis, SEM/EDS, particle size analyzer and ICP-OES. The purity of the end-product was analyzed with the Korean Standard KS L 1612.

Fabrication of isotropic bulk graphite using artificial graphite scrap

  • Lee, Sang-Min;Kang, Dong-Su;Kim, Woo-Seok;Roh, Jea-Seung
    • Carbon letters
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    • v.15 no.2
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    • pp.142-145
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    • 2014
  • Isotropic synthetic graphite scrap and phenolic resin were mixed, and the mixed powder was formed at 300 MPa to produce a green body. New bulk graphite was produced by carbonizing the green body at $700^{\circ}C$, and the bulk graphite thus produced was impregnated with resin and re-carbonized at $700^{\circ}C$. The bulk density of the bulk graphite was $1.29g/cm^3$, and the porosity of the open pores was 29.8%. After one impregnation, the density increased to $1.44g/cm^3$ while the porosity decreased to 25.2%. Differences in the pore distribution before and after impregnation were easily confirmed by observing the microstructure. In addition, by using an X-ray diffractometer, the degrees-of-alignment (Da) were obtained for one side perpendicular to the direction of compression molding of the bulk graphite (the "top-face"), and one side parallel to the direction of compression molding (the "side-face"). The anisotropy ratio calculated from the Da-values obtained was 1.13, which indicates comparatively good isotropy.

Manufacturing and Damping Properties of Al-Si/Gr. Composite using extruded Al/Gr. Composite (Al/흑연 압출재를 이용한 Al-Si/흑연 복합재료 제조와 감쇠능)

  • Park, Hun-Berm;Kwon, Hyuk-Moo
    • Journal of Korea Foundry Society
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    • v.21 no.2
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    • pp.119-126
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    • 2001
  • Al/15%Gr. composite have been manufactured by mixing, compacting, and extruding aluminium powder and graphite powder. Then, Al-6%Si/x%Gr., Al-12%Si/x%Gr., and Al-18%Si/x%Gr.(x: 0, 2, 4, 6, 8) composites have been manufactured by remelting the extruded materials(Al/15%Gr.), Al-33.3%Si alloy, and Al ingot, etc. We conducted experiments to chracterize the microstructure, and damping properties and hardness. The result of microstructure experiment on Al-x%Si/y%Gr. composites reveals the good dispersion of graphite. As to Al-Si/y%Gr. composites, the more the graphite contents, the less the tensile strength. And the tensile strength varied according to contents of Si: with its highest value in Al-18%Si/y%Gr. composites and lowest in Al-6%Si/y%Gr. composites. As to Al-x%Si/y%Gr. composites, the more the contents of graphite, the more the vibration damping properties. And we can get the highest vibration damping rate in Al-12%Si/y%Gr. composites which matrix structure is an eutectic component.

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Effect of Carbon-coated Silicon/Graphite Composite Anode on the Electrochemical Properties

  • Kim, Hyung-Sun;Chung, Kyung-Yoon;Cho, Byung-Won
    • Bulletin of the Korean Chemical Society
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    • v.29 no.10
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    • pp.1965-1968
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    • 2008
  • The effects of carbon-coated silicon/graphite (Si/Gr.) composite anode on the electrochemical properties were investigated. The nanosized silicon particle shows a good cycling performance with a reasonable value of the first reversible capacity as compared with microsized silicon particle. The carbon-coated silicon/graphite composite powders have been prepared by pyrolysis method under argon/10 wt% propylene gas flow at $700{^{\circ}C}$ for 7 h. Transmission electron microscopy (TEM) analysis indicates that the carbon layer thickness of 5 nm was coated uniformly onto the surface silicon powder. It is confirmed that the insertion of lithium ions change the crystalline silicon phase into the amorphous phase by X-ray diffraction (XRD) analysis. The carbon-coated composite silicon/graphite anode shows excellent cycling performance with a reversible value of 700 mAh/g. The superior electrochemical characteristics are attributed to the enhanced electronic conductivity and low volume change of silicon powder during cycling by carbon coating.

Environmental Influences on Gas pressure Sintering of $Si_3N_4$ (질화규소의 가스압 소결에 미치는 환경 영향)

  • 김인섭;이경희;이병하
    • Journal of the Korean Ceramic Society
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    • v.30 no.4
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    • pp.309-315
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    • 1993
  • Gas pressure sintering is a promising process in various densification methods of high strength Si3N4 ceramics. Environmental influences on gas pressure sintering of Si3N4 was investigated with the variationof packing powder, specimen container and N2 gas pressure. The specimens had higher density, larger weight loss and inhomogeneous color in graphite specimen container than in SN26 crucible. The variations of sintering densities in various packing powders (Si3N4, SN26, AlN, BN) were very small but SiC powder was synthesised in graphite crucible with Si3N4 packing powder, aluminium oxynitride compounds were synthesised in SN26 crucible with AlN packing power. Also N2 gas pressure over 20kg/$\textrm{cm}^2$ reduced the densification of Si3N4 in one step-gas pressure sintering. As the result of two step-gas pressure sintering at 700kg/$\textrm{cm}^2$ for 15min., relative density of 99.9% and 3-point bending strength of 1090MPa and dense microstructure of 3~4${\mu}{\textrm}{m}$ grain size were obtained.

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Effect of Co and Ni Catalyst on the Preparation of Porous Graphite Using Magadiite Template (Magadiite 주형을 이용한 다공성 흑연제조에 미치는 Co와 Ni 촉매 효과)

  • Choi, Seok-Hyon;Kwon, Oh-Yun
    • Korean Journal of Materials Research
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    • v.28 no.3
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    • pp.189-194
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    • 2018
  • Porous graphites were synthesized by removing the template in HF after cabothermal conversion for 3 h at $900^{\circ}C$, accompanied by intercalations of pyrolyzed fuel oil (PFO) in the interlayer of Co or Ni loaded magadiite. The X-ray powder diffraction pattern of the porous graphites exhibited 00l reflections corresponding to a basal spacing of 0.7 nm. The particle morphology of the porous graphites was composed of carbon plates intergrown to form spherical nodules resembling rosettes like a magadiite template. TEM shows that the cross section of the porous graphites is composed of layers with very regular spaces. In particular, crystallization of the porous graphite was dependent on the content of Co or Ni loaded in the interlayer. The porous graphite had a surface area of $328-477m^2/g$. This indicates that metals such as Co and Ni act as catalysts that accelerate graphite formation.

Fabrication of TiC powder by carburization of TiH2 powder (타이타늄 하이드라이드 분말의 침탄에 의한 타이타늄 카바이드 분말 제조)

  • Lee, Hun-Seok;Seo, Hyang-Im;Lee, Young-Seon;Lee, Dong-Jun;Wang, Jei-Pil;Lee, Dong-Won
    • Journal of Powder Materials
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    • v.24 no.1
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    • pp.29-33
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    • 2017
  • Titanium carbide (TiC) powders are successfully synthesized by carburization of titanium hydride ($TiH_2$) powders. The $TiH_2$ powders with size lower than $45{\mu}m$ (-325 Mesh) are optimally produced by the hydrogenation process, and are mixed with graphite powder by ball milling. The mixtures are then heat-treated in an Ar atmosphere at $800-1200^{\circ}C$ for carburization to occur. It has been experimentally and thermodynamically determined that the de-hydrogenation, "$TiH_2=Ti+H_2$", and carburization, "Ti + C = TiC", occur simultaneously over the reaction temperature range. The unreacted graphite content (free carbon) in each product is precisely measured by acid dissolution and by the filtering method, and it is possible to conclude that the maximal carbon stoichiometry of $TiC_{0.94}$ is accomplished at $1200^{\circ}C$.