선박 프로펠러의 케비테이션 침식 저항 향상을 위한 Ni-P 무전해 도금층 형성 및 열처리를 통한 미세조직 제어

김영재; 손인준; 이승훈; Young-jae Kim; In-Jun Son; Seonghoon Yi

Korean Journal of Materials Research, Vol.27, No.8, 409-415, August, 2017

DOI10.3740/MRSK.2017.27.8.409 Export Citation

선박 프로펠러의 케비테이션 침식 저항 향상을 위한 Ni-P 무전해 도금층 형성 및 열처리를 통한 미세조직 제어

Electroless Ni-P Plating and Heat Treatments of the Coating Layer for Enhancement of the Cavitation Erosion Resistance of Vessel Propellers

김영재, 손인준, 이승훈^†

경북대학교 금속신소재공학과

Young-jae Kim, In-Jun Son, and Seonghoon Yi^†

Department of Materials Science and Metallurgical Engineering, Kyungpook National University, Daegu 41566, Republic of Korea

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For enhanced cavitation erosion resistance of vessel propellers, an electroless Ni-P plating method was introduced to form a coating layer with high hardness on the surface of Cu alloy (CAC703C) used as vessel propeller material. An electroless Ni-P plating reaction generated by Fe atoms in the Cu alloy occurred, forming a uniform amorphous layer with P content of ~10 wt%. The amorphous layer transformed to (Ni3P+Ni) two phase structure after heat treatment. Cavitation erosion tests following the ASTM G-32 standard were carried out to relate the microstructural changes by heat treatment and the cavitation erosion resistance in distilled water and 3.5 wt% NaCl solutions. It was possible to obtain excellent cavitation erosion resistance through careful microstructural control of the coating layer, demonstrating that this electroless Ni-P plating process is a viable coating process for the enhancement of the cavitation erosion resistance of vessel propellers.

Keywords:nanostructured material;electroless plating;erosion;cavitation

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[1] Kim SJ, J. Korean Inst. Surf. Eng., 44, 105 (2011)

[2] Kim SJ, Lee SJ, Corros. Sci. Tech., 10, 101 (2011)

[3] Kim JS, Kim HS, J. Korean Inst. Surf. Eng., 39, 26 (2006)

[4] Kear G, Barker BD, Stokes KR, Walsh FC, Corrosion Sci., 47, 1694 (2005)

[5] Lee SO, Yong KH, J. Korean Inst. Surf. Eng., 4, 23 (1990)

[6] Kim JK, SYA, Korean Inst. Met. Mater., 9, 36 (1998)

[7] Lin CJ, Chen KC, Wear, 261, 1390 (2006)

[8] Yamasaki T, lzumi H, Sunada H, Scripta Met., 15, 177 (1981)

[9] Parker K, Plating, 61, 834 (1974)

[10] Annual Book of ASTM Standards G-32, ASTM 115 (1992).

[11] Yu KZ, Hammitt FG, Wear, 86, 299 (1983)

[12] Munsterer S, Kohlhof K, Surf. Coat. Technol., 74-75, 642 (1995)

[13] Huang WH, Cheng KC, He JL, Wear, 252, 459 (2002)