• Title/Summary/Keyword: pack-cementation process

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Oxidation Resistant SiC Coating for carbon/carbon Composites

  • Joo, Hyeok-Jong;Lee, Nam-Joo;Oh, In-Seok
    • Carbon letters
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    • v.4 no.1
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    • pp.24-30
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    • 2003
  • In this study, densified 4D carbon/carbon composites were made from carbon fiber and coal tar pitch through the process of pressure impregnation and carbonization and then followed by carbonization and graphitization. To improve the oxidative resistance of the prepared carbon/carbon composites, the surface of carbon/carbon composites was coated on SiC by the pack cementation method. The SiC coated layer was created by depending on the constitution of pack powder, and reaction time of pack-cementation. The morpology of crystalline and texture of these SiC coated carbon/carbon composites were investigated by XRD, SEM/EDS observation. So the coating mechanism of pack-cementation process was proposed. The oxidative res istance were observed through the air oxidation test, and then the optimal condition of pack cementation was found by them. Besides, the oxidative mechanism of SiC formed was proposed through the observation of SiC coated surface, which was undergone by oxidation test.

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Mechanical Properties & Ablation Mechanism of SiC Coated Carbon/Carbon Composite by Pack-cementation Method

  • Kim, J.I.;Oh, I.S.;Joo, H.J.
    • Carbon letters
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    • v.2 no.1
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    • pp.27-36
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    • 2001
  • The pack-cementation process is the method which is formed SiC coating layer to improve weak oxidation properties of CFRCs (carbon fiber-reinforced carbons). This method develops the anti-oxidation coating layer having no dimensional changes and good wetting properties. In this study to improve the oxidative resistance of the prepared 4D CFRCs, the surface of CFRCs is coated by SiC using pack cementation method. The mechanical properties of SiC-coated 4D CFRCs are measured by the 3-point bending test, and their ablation properties are investigated by the arc torch plasma test. From the results, it is found that both mechanical and ablation properties of SiC-coated 4D CFRCs are much better than bare CFRCs.

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Oxidation Behavior of SiC Coated Carbon/carbon Composite by Pack-cementation Method (Pack-cementation 방법에 의해서 탄화규소로 도포된 탄소/탄소 복합재의 산화거동)

  • 김정일;박인서;주혁종
    • Composites Research
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    • v.13 no.2
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    • pp.22-29
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    • 2000
  • Although C/C composites have excellent mechanical properties at high temperature, the disadvantage of oxidation in air restricts their applications. Thus a lot of investments have been studied to improve this drawback. In this study, SiC used as a thermal protective coating material possesses almost the same expansion coefficient compared to that of carbon, so SiC was coated on 4D C/C composites by Pack-Cementation process. For SiC-coated C/C composites, optical microscopy observations were performed to estimate the conversion mechanism involved and air oxidation tests were also performed to evaluate the improvement of oxidation resistance. Afterwards the optimum conditions of coating process were estimated from the results of several analysis and tests.

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A Study on the Formation of Aluminide Coating on KM 1557 Alloy by Pack Cementation Process (Pack Cementation법에 의한 KM 1557 합금의 알루미나이드 코팅층 형성에 관한 연구)

  • Yoon, Jin-Kook;Yoo, Myoung Ki;Choi, Ju;Kim, Jae-Soo
    • Analytical Science and Technology
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    • v.6 no.2
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    • pp.167-180
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    • 1993
  • The effects of coating variables on the formation of aluminide coating layer with good oxidation resistance on the strongest hot-forged superalloy in the world, KM 1557 developed at KIST by pack cementation process were studied. Pack aluminizing were performed by high-activity process with pure aluminium powders and by low-activity process with codep powders. For high-activity process, Al deposition rate, growth rate of coating layer, and cross-sectional microstructures were influenced by the species and additive amounts of activators and the additive amounts of pure aluminium powders. For low-activity process, Al deposition rate, growth rate of coating layer, and the cross-sectional microstructures were not influenced by the species but additive amounts of activators. Surface structures of coating layer were influenced by the species of activators. Regardless of aluminium activity, Al deposition rate was proportional to the square root of time and parabolic rate constants were different with the species of activators. The activation energy for deposition of aluminium was different with the species of activators for high-activity process. Regardless of the species of activators, the activation energy for deposition of aluminium was 12~14 Kcal/mole for low-activity process.

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Computer simulation of aluminide coating by pack cementation (팩 세멘테이션에 의한 알루미나이드 코팅의 컴퓨터 시뮬레이션)

  • Kim, M.I.;Sohn, H.S.;Lee, I.W.
    • Journal of the Korean Society for Heat Treatment
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    • v.8 no.1
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    • pp.3-11
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    • 1995
  • A theoretical model which combines gaseous transport and solid state diffusion was used to study aluminide coating process by pack cementation. The aluminide coatings were applied in the high activity pack containing $NH_4Cl$ activator with Ni substrate under argon atmosphere. On the basis of the process conditions, the suggested model allows the surface composition, the growth rate of coating layers and the aluminium concentration profiles in coatings to be calculated. In the case of $NH_4Cl$ activator, careful consideration was required in the analysis, because activator contains nitrogen and hydrogen as well as halogen element to activate the pack. A good agreement is obtained between the theoretical predictions and the experimental results.

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Aluminizing of Incoroy 909 Alloy by Pack Cementation Method (팩 세멘테이션법에 의한 Incoloy 909 합금의 알루미나이징)

  • Ahn, Jin-Sung;Kwon, Soon-Woo;Yoon, Jae-Hong;Park, Bong-Gyu
    • Journal of the Korean institute of surface engineering
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    • v.39 no.4
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    • pp.173-178
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    • 2006
  • Incoloy alloy 909 is an Fe-Ni-Co based superalloy that is attractive for gas turbine engine applications. The absence of chromium, however, makes the alloy more susceptible to oxidation in high temperature. To improve the oxidation resistance aluminizing was performed by high activity low temperature pack cementation process. Aluminizing condition was examined with different times and temperatures. Optimum aluminizing conditions were at the temperature of $552^{\circ}C$ for 20 hrs. In the optimized condition, the thickness of the aluminized layer was about $20{\mu}m$. Also, the aluminized layer made the alloy to increase the resistance to the corrosion.

Formation of MoSi2 Layer by Hydrogen Reduction and Si-pack Cementation (수소 환원 공정과 실리콘 확산 침투 처리 공정을 통한 이규화 몰리브덴 코팅층 형성)

  • Jeon, In Mok;Byun, Jong Min;Kim, Se Hoon;Kim, Jin Woo;Kim, Young Do
    • Korean Journal of Metals and Materials
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    • v.50 no.9
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    • pp.653-657
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    • 2012
  • In this study, a molybdenum disilicide ($MoSi_2$) coating process was investigated by hydrogen reduction and Si-pack cementation. At first, the metallic Mo coating was carried out by hydrogen reduction of $MoO_3$ powder at $750^{\circ}C$ for various holding times (1, 2, 3 h) in hydrogen atmosphere. A $4.3{\mu}m$ thick metallic molybdenum thin film was formed at 3 h. $MoSi_2$ was obtained by Si-pack cementation on molybdenum thin film through hydrogen reduction processing. It was carried out using $Si:Al_2O_3:NH_4Cl=5:92:3$ (wt%) packs at $900^{\circ}C$ for various holding times (30, 60, 90 min) in Ar atmosphere. When the holding time was 90 min, a $MoSi_2$ layer was coated successfully and a $15.4{\mu}m$ thickness was observed.

Optimal Aluminizing Coating on Incoloy 909 (Incoloy 909 합금의 최적 알루미나이징 확산 코팅)

  • Kwon, S.W.;Yoon, J.H.;Joo, Y.K.;Cho, T.Y.;Ahn, J.S.;Park, B.K.
    • Journal of the Korean institute of surface engineering
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    • v.40 no.4
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    • pp.175-179
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    • 2007
  • An Fe-Ni-Co based superalloy Incoloy 909 (Incoloy 909) has been used for gas turbine engine component material. This alloy is susceptible to high temperature oxidation and corrosion because of the absence of corrosion resistant Cr. For the improvement of durability of the component of Incoloy 909 aluminizing-chromate coating by pack cementation process has been investigated at relatively low temperature of about $550^{\circ}C$ to protect the surface microstructure and properties of Incoloy 909 substrate. As a previous study to aluminizing-chromate coating by pack cementation of Incoloy 909, the optimal aluminizing process has been investigated. The size effects of source Al powder and inert filler $Al_O_3$ powder and activator selection have been studied. And the dependence of coating growth rate on aluminizing temperature and time has also been studied. The optimal aluminizing process for the coating growth rate is that the mixing ratio of source Al powder, activator $NH_4Cl$ and filler $Al_O_3$ are 80%, 1% and 19% respectively at aluminizing temperature $552^{\circ}C$ and time 20 hours.

Aluminide Coatings on IN713C by Chemical Vapor Depostion (화화증착법에 의한 알루미나이드 코팅층의 형성)

  • Sohn, H.S.;Hong, S.H.;Kim, M.I.
    • Journal of the Korean Society for Heat Treatment
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    • v.7 no.2
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    • pp.129-138
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    • 1994
  • The purpose of this study is to clarify the influence of the reaction temperature and $AlCl_3$ content on the aluminide coating formation on Ni-based superalloy IN713C in CVD process and to compare its throwing power with that of Pack Cementation process. Aluminide coating was formed by CVD in hot-wall stainless tube reactor from an $AlCl_3-H_2$ mixture in the temperature range $850{\sim}1050^{\circ}C$. At reaction temperature $850^{\circ}C$, the coating thickness and the content of aluminium at the surface were increased as $AlCl_3$ heating temperature was raised. At reaction temperature $1050^{\circ}C$, they were not influenced by the variation of $AlCl_3$ heating temperature. When $AlCl_3$ heating temperature was fixed $125^{\circ}C$, the phases of the coatings were varied from $Ni_2Al_3$ to Al-rich NiAl and to Ni-rich NiAl with the reaction temperature. Therefore, in this study the reaction temperature has been found to be a major factor in determining the phase formed in CVD process. The throwing power of CVD was superior to that of Pack Cementation.

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