Development of Electroless Ni-P-Cu Composite Coating: A Characterisation, Corrosion and Thermal Study on AISI-1040 Used in Heat Exchangers

IF 2.1 4区 材料科学 Q3 MATERIALS SCIENCE, MULTIDISCIPLINARY JOM Pub Date : 2024-09-06 DOI:10.1007/s11837-024-06817-7
Suparna Bhattacharyya, Prashant Kumar, Deepak Choudhary, Surjya K. Pal, Sudipto Chakraborty
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Abstract

Electroless coating is such an area that has recently taken the research spotlight. Heat exchangers are the most used industrial equipment by chemical and mechanical firms. Of various other materials like copper, iron and carbon steel, it is considered that the structural units of these heat exchangers should be mild steel because the other metals are more porous in nature, encouraging corrosion, scaling and fouling. Mild steel is a revolutionary material that has a varied range of uses, from tiny needles to giant machinery. Easy market availability, material durability, great thermal efficiency and reasonable prices are the core reasons for this. However, the material has a few crucial disadvantages like corrosion, wear, fouling, pitting, etc. Electroless coating can be a good alternative to overcome these issues. These coatings can create novel nickel-based composite materials, of which Ni-P-Cu is the most common when the application demands the property of heat conduction. These coatings also provide great corrosion resistance. As our objective is the application of these composite coatings on heat exchangers, both corrosion and heat transfer properties have been demonstrated respectively in this study. The analysis has chosen electroless ENPC-coated mild steel at various concentrations of copper ranging from 0.2 g/l to 1.2 g/l. The surface morphology and elemental analysis have been explained using FESEM and EDX analysis. The material phase transformation has been observed using an XRD plot. The microhardness of the sample before and after the heat transfer study has been analysed and compared. The Tafel curve of the heated sample showed the increase of corrosion resistivity within the temperature range of 100°C to 400°C for an optimised coated sample ENPC-1, (i.e., electroless nickel phosphorous copper coating with copper concentration 1 g/l). A spray cooling setup built in house has been used to analyse the heat transfer mechanism. The cooling rate obtained for the ENPC-1 sample is around 25.2% more than in the previous studies on uncoated samples using base fluid (water).

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开发化学镍-铜复合涂层:用于热交换器的 AISI-1040 的特性、腐蚀和热研究
非电解涂层就是最近备受瞩目的研究领域。热交换器是化工和机械公司使用最多的工业设备。在铜、铁和碳钢等其他各种材料中,人们认为这些热交换器的结构单元应该是低碳钢,因为其他金属的多孔性更强,更容易腐蚀、结垢和结垢。低碳钢是一种革命性的材料,用途广泛,小到针头,大到机械。市场供应方便、材料耐用、热效率高和价格合理是其核心原因。然而,这种材料也有一些关键的缺点,如腐蚀、磨损、结垢、点蚀等。要克服这些问题,非电解涂层是一个不错的选择。当应用需要热传导特性时,这些涂层可以创造出新型镍基复合材料,其中 Ni-P-Cu 是最常见的一种。这些涂层还具有很强的耐腐蚀性。由于我们的目标是在热交换器上应用这些复合涂层,因此本研究分别对腐蚀和传热性能进行了论证。分析选择了不同铜浓度(0.2 克/升至 1.2 克/升)的无电解 ENPC 涂层低碳钢。使用 FESEM 和 EDX 分析方法解释了表面形貌和元素分析。通过 XRD 图观察了材料的相变。对传热研究前后样品的显微硬度进行了分析和比较。加热样品的塔菲尔曲线显示,对于优化涂层样品 ENPC-1(即铜浓度为 1 克/升的无电解镍磷铜涂层),在 100°C 至 400°C 的温度范围内,腐蚀电阻率有所增加。为了分析传热机制,我们使用了自制的喷雾冷却装置。ENPC-1 样品的冷却率比之前使用基液(水)对未涂层样品进行的研究高出约 25.2%。
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来源期刊
JOM
JOM 工程技术-材料科学:综合
CiteScore
4.50
自引率
3.80%
发文量
540
审稿时长
2.8 months
期刊介绍: JOM is a technical journal devoted to exploring the many aspects of materials science and engineering. JOM reports scholarly work that explores the state-of-the-art processing, fabrication, design, and application of metals, ceramics, plastics, composites, and other materials. In pursuing this goal, JOM strives to balance the interests of the laboratory and the marketplace by reporting academic, industrial, and government-sponsored work from around the world.
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