• 한국재료학회지
• /
• 제10권7호
• /
• pp.489-492
• /
• 2000

0.5%C-25.0%Cr-1.0%Si(합금1), 0.5%C-5.0%Cr-1.0%Si(합금2) 및 2.0%C-5.0%Cr-1.0%Si(합금3)의 3종류 크롬백주철에 있어서 기지조직 및 탄화물에 분푀도는 Cr 및 Si의 거동을 연구하였다. 15kg 용량의 고주파 유도용해로에 선철, 고철, Fe-Cr, Fe-Si 등을 장입시켜 용해시킨후 슬래그를 제거시키고 $1550^{\circ}C$에서 펩 주형에 주입시킨후 실온까지 냉각시켜 SEM으로 응고조직을 관찰하였으며 EPMA분석을 통하여 Cr 및 Si 의 분포거동을 관찰하였다. 합금1의 경우 초정으로 $\delta$페라이트가 정출후 $\delta$페라이트와 용액의 입계에서 $\delta$페라이트와 $M_7C_3$탄화물이 공정으로 정출하였으며 합금2의 경우 용액에서 초정으로 거의 $\delta$페라이트가 정출된 수 극히 일부분만이 $\delta$페라이트와 $M_7C_3$탄화물의 공정으로 정출하였다. 반면 합금 3의 경우 오스테나이트가 초정으로 정출된 후 오스테나이트와 $M_3C$탄화물이 공정으로 정출하였다. Cr은 주로 $M_7C_3$ 및 $M_3C$탄화물에 , 그리고 Si는 기지조직에 선택적으로 분배되었으며 Cr의 기지조직에 대한 분배계수는 0.56-0.68, 그리고 Si는 1.12-1.28의 범위에 걸쳐있었다. 또한 Cr의 기지조직에 대한 분배계수는 C 함량이 2.0%일때가 0.5%의 경우보다 낮았으며 $M_7C_3$탄화물내의 Cr 함량은 Cr함량이 25.0% 일때가 5.0%의 경우보다 높은값을 나타내었다. 나타내었다.

• 한국재료학회지
• /
• 제17권5호
• /
• pp.256-262
• /
• 2007

Effects of interlayer and the combination of different coating methods on the mechanical and corrosion behaviors of TiN and CrN coated on 420 stainless steel have been studied. STS 420 specimen were tempered at $300^{\circ}C$ for 1 hr in vacuum furnace. The TiN and CrN thin film with 2 ${\mu}m$ thickness were coated by arc ion plating and DC magnetron sputtering following the formation of interlayer for pure titanium and chromium with 0.2 ${\mu}m$ thickness. The microstructure and surface analysis of the specimen were conducted by using SEM, XRD and roughness tester. Mechanical properties such as hardness and adhesion also were examined. XRD patterns of TiN thin films showed that preferred TiN (111) orientation was observed. The peaks of CrN (111) and $Cr_2N$ (300) were only observed in CrN thin films deposited by arc ion plating. Both TiN and CrN deposited by arc ion plating had the higher adhesion and hardness compared to those formed by magnetron sputtering. The specimen of TiN and CrN on which interlayer deposited by magnetron sputtering and thin film deposited by arc ion plating had the highest adhesion with 22.2 N and 19.2 N. respectively. TiN and CrN samples shown the most noble corrosion potentials when the interlayers were deposited by using magnetron sputtering and the metal nitrides were deposited by using arc ion plating. The most noble corrosion potentials of TiN and CrN were found to be approximately -170 and -70 mV， respectively.

• 대한금속재료학회지
• /
• 제47권3호
• /
• pp.147-154
• /
• 2009

The effect of carbon addition on the microstructures and mechanical properties of $Ni_3Al$ and TiAl intermetallic alloys have been characterized. It is shown that carbon is not only an efficient solid solution strengthener in $Ni_3Al$ and TiAl, it is also an efficient precipitation strengthener by fine dispersion of carbide. Transmission electron microscope investigation has been performed on the particle-dislocation interactions in $Ni_3Al$ and TiAl intermetallics containing various types of fine precipitates. In an $L1_2$-ordered $Ni_3Al$ alloy with 4 mol.% of chromium and 0.2~3.0 mol.% of carbon, fine octahedral precipitates of $M_{23}C_6$ type carbide, which has the cube-cube orientation relationship with the matrix, appear during aging. Typical Orowan loops are formed in $Ni_3Al$ containing fine dispersions of $M_{23}C_6$ particles. In the L10-ordered TiAl containing 0.1~2.0 mol.% carbon, TEM observations revealed that needle-like precipitates, which lie only in one direction parallel to the [001] axis of the $L1_0$ matrix, appear in the matrix and preferentially at dislocations. Selected area electron diffraction (SAED) patterns analyses have shown that the needle-shaped precipitate is $Ti_3AlC$ of perovskite type. The orientation relationship between the $Ti_3AlC$ and the $L1_0$ matrix is found to be $(001)_{Ti3AlC}//(001)_{L10\;matrix}$ and $[010]_{Ti3AlC}//[010]_{L10\;matrix}$. By aging at higher temperatures or for longer period at 1073 K, plate-like precipitates of $Ti_2AlC$ with a hexagonal structure are formed on the {111} planes of the $L1_0$ matrix. The orientation relationship between the $(0001)_{Ti2AlC}//(111)_{L10\;matrix}$ is and $[1120]_{Ti2AlC}//[101]_{L10\;matrix}$. High temperature strength of TiAl increases appreciably by the precipitation of fine carbide. Dislocations bypass the carbide needles at further higher temperatures.