Study and Investigation of Microbial Influenced Corrosion Effect for Performance Analysis of Vortex Tube on Stainless Steel with and without Coating

Ganta Suresh Ph.D Scholar, A. P. Kumar, Eriki Ananda Kumar Professor
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Abstract

Alloy material testing for stable the properties of Vortex tube and corrosion resistance, this research for specially for fabrication of Vortex tube and also in future may supplier will ask the properties and testing evidence we are going to provide week wise testing schedule. Microbial Influenced Corrosion (MIC) is a type of corrosion that happened on a metal's surface under the seawater. MIC occurs due to the colonization of microorganism on the surface, these microorganisms may be fungus, bacteria or algae. In this paper the E. Coli bacteria are used to investigate the MIC on metal sample of vortex chamber. A metal sample of vortex tube which is stainless steel is coated with different coating such as alocit, rubber, epoxy, and graphene. The samples for vortex tube with different coating are tested to find out the best one which can resist MIC better than the others. There are different tests carried out; wet and dry test, atmospheric test. To find the corrosion progress the weight loss and corrosion rate is found in the sample material to apply vortex tube. The hardness of the coating is done to find the best one. The optical microscope is used to understand the corrosion progress in the metal surfaces and for the hardness test. The result analyzed shows that graphene is the best coating because of its excellent properties in resisting and preventing MIC corrosion of vortex tube is a non-conventional cooling device, having no moving parts which will produce cold air and hot air from the source of compressed air without effecting the environment when a high-pressure air is tangentially injected into the vortex chamber, a strong vortex flow will be created which will be split into two air streams. Beyond that, the improvement in energy separation is minor, and Vortex Tube performance begins to deteriorate as shock waves form outside the nozzle. Without any moving parts or chemical reactions, a vortex tube (VT) can generate hot and cold streams from a single pressurised room temperature fluid.
微生物腐蚀对不锈钢涡流管性能分析的影响研究
合金材料的稳定性能和耐腐蚀性测试,这项研究是专门为涡流管的制造和未来可能的供应商将询问性能和测试证据,我们将提供每周的测试计划。微生物腐蚀(MIC)是发生在海水下金属表面的一种腐蚀。MIC是由于微生物在表面定植而发生的,这些微生物可能是真菌、细菌或藻类。本文利用大肠杆菌对涡流室金属样品的MIC进行了研究。以不锈钢涡旋管为金属样品,涂上不同的涂层,如alocit、橡胶、环氧树脂和石墨烯。对不同涂层的涡流管样品进行了测试,找出了抗MIC性能最好的涂层。进行了不同的测试;干湿试验,大气试验。为了了解腐蚀过程,研究了涡流管对样品材料的腐蚀失重和腐蚀速率的影响。对涂层的硬度进行测定,以找出最佳的硬度。光学显微镜用于了解金属表面的腐蚀过程和硬度测试。结果分析表明,石墨烯具有优异的抗MIC腐蚀性能,是最佳的涂层。涡流管是一种非传统的冷却装置,没有运动部件,在不影响环境的情况下从压缩空气源产生冷空气和热空气,当高压空气切向涡流室时,将产生强烈的涡流,并将其分裂成两股气流。除此之外,能量分离的改善很小,当激波在喷嘴外形成时,涡流管的性能开始恶化。在没有任何移动部件或化学反应的情况下,涡流管(VT)可以从单一的室温加压流体中产生冷热流。
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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