THERMAL-POWER-PLANT CONDENSER-TUBE CORROSION ANALYSIS

IF 0.6 4区材料科学 Q4 MATERIALS SCIENCE, MULTIDISCIPLINARY

Materiali in tehnologije Pub Date : 2023-07-28 DOI:10.17222/mit.2023.747

J. Batelić, V. Špada, M. Kršulja, S. Martinez

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Abstract

The thermal-power-plant condenser tubes, conducting cooling seawater, experienced frequent leakages, prompting the hereby presented failure analysis. Visual inspection of the corroded/ruptured tube segments revealed that localized corrosion may be linked to seawater sediments and thick layers of corrosion products at the tube water side. Sediments were found along the tube bottom and thick corrosion products were found adjacent to the point of contact between the baffle plates and the exterior tube walls. Underdeposit corrosion, accelerated due to sulphate-reducing bacteria, was diagnosed based on the excess sulphur found at the pit bottom using EDX, the FT-IR spectrum indicating the presence of biofilm and SEM determining the featuring corrosion products based on the biofilm. It was proposed that the corrosion initiating deposits were linked to the condenser shutdown and startup periods. Results showed that pitting corrosion occurred under the influence of biofilm microorganisms tolerant to copper. The main goal of this research was achieved by defining a systematic procedure for avoiding a shutdown of the thermal power plant.

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热电厂冷凝器管腐蚀分析

火电厂的凝汽器管由于输送冷却海水，经常发生泄漏，故提出故障分析。对腐蚀/破裂管段的目视检查显示，局部腐蚀可能与海水沉积物和管道水侧厚层腐蚀产物有关。沿管底发现有沉积物，在折流板与外管壁的接触点附近发现有较厚的腐蚀产物。沉积物底部腐蚀由硫酸盐还原菌加速，根据坑底发现的过量硫，使用EDX进行诊断，FT-IR光谱表明生物膜的存在，SEM根据生物膜确定特征腐蚀产物。提出了凝汽器启停周期与腐蚀引发沉积有关。结果表明，点蚀是在耐铜生物膜微生物的作用下发生的。本研究的主要目标是通过定义一个避免火力发电厂关闭的系统程序来实现。

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

Materiali in tehnologije 工程技术-材料科学：综合

CiteScore

1.30

自引率

0.00%

发文量

审稿时长

4-8 weeks

期刊介绍： The journal MATERIALI IN TEHNOLOGIJE/MATERIALS AND TECHNOLOGY is a scientific journal, devoted to original papers and review scientific papers concerned with the areas of fundamental and applied science and technology. Topics of particular interest include metallic materials, inorganic materials, polymers, vacuum technique and lately nanomaterials.