Erosion–Corrosion of Novel Electroless Ni-P-NiTi Composite Coating

Corrosion and Materials Degradation Pub Date : 2023-02-08 DOI:10.3390/cmd4010008

Rielle Jensen, Z. Farhat, Md. Aminul Islam, G. Jarjoura

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引用次数: 1

Abstract

The lifespan of low-carbon steel petroleum pipelines can often be shortened by the erosion–corrosion damage caused by their service conditions. Applying electroless Ni-P coating is a promising option to protect the steel from the environment due to its high hardness and corrosion resistance. However, electroless Ni-P has a low toughness but can be increased by the addition of NiTi ductile particles. This work produced electroless Ni-P and Ni-P-NiTi coatings of different thicknesses on AISI 1018 substrates and compared their erosion, corrosion, and erosion–corrosion behaviors. The methodology involved conducting slurry pot erosion–corrosion tests on AISI 1018 steel substrate, the monolithic Ni-P coatings, and the composite Ni-P-NiTi coatings. Erosion resistance was highly influenced by coating thickness, presumably because of the relationship between the erosion-induced compressive stresses and the coating’s as-plated internal stresses. The NiTi nanoparticle addition was highly effective at improving the erosion–corrosion resistance of the coating. Pitting corrosion and cracking were present after erosion–corrosion on the monolithic Ni-P coatings. However, the Ni-P-NiTi composite coating had a relatively uniform material loss. Overall, the AISI 1018 steel substrate had the worst erosion–corrosion resistance and 25 μm thick Ni-P-NiTi coating had the best.

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新型化学镀Ni-P-NiTi复合镀层的冲刷腐蚀

低碳钢石油管道的使用条件往往会造成冲蚀损伤，从而缩短管道的使用寿命。由于其高硬度和耐腐蚀性，化学镀Ni-P涂层是一种很有前途的选择，可以保护钢免受环境的影响。然而，化学镀Ni-P的韧性较低，但可以通过添加NiTi延展性颗粒来提高。本研究在AISI 1018基体上制备了不同厚度的Ni-P和Ni-P- niti化学涂层，并比较了它们的侵蚀、腐蚀和侵蚀-腐蚀行为。该方法包括对AISI 1018钢基体、整体Ni-P涂层和复合Ni-P- niti涂层进行浆液罐侵蚀-腐蚀试验。涂层厚度对抗冲蚀性能有很大影响，这可能是由于腐蚀引起的压应力与涂层的镀态内应力之间的关系。纳米镍钛颗粒的加入对提高涂层的抗冲蚀性能非常有效。整体Ni-P涂层在冲蚀后出现点蚀和开裂现象。而Ni-P-NiTi复合涂层的材料损失相对均匀。总体而言，AISI 1018钢基体抗冲蚀性能最差，25 μm厚的Ni-P-NiTi涂层性能最好。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Corrosion and Materials Degradation

CiteScore

4.50

自引率

0.00%

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