Research on the corrosion behavior of floating bead low-density cement stone/P110 steel system under different CO2 pressure

Corrosion Engineering, Science and Technology: The International Journal of Corrosion Processes and Corrosion Control Pub Date : 2024-02-13 DOI:10.1177/1478422x241233074

Shuliang Wang, Zidan Wen, Shuai Zhang, M. Yao, Wanneng Lei, Ming-hua Wu, Yongbing Liu, Xiaoyan Zhang, Xianguang Zeng, Shidong Wang

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Abstract

This study investigates the corrosion state of the floating bead low-density cement stone/P110 steel system in simulated CO2-saturated formation water under high and atmospheric CO2 pressure. Results show that the resistance of the cement stone reaches a maximum value at 28 days and then decreases. The corrosion rate of P110 steel under high pressure is greater than that under atmospheric pressure. There is a certain gap and accumulation of corrosion products between the cement stone and the steel. Additionally, the maximum gap size and corrosion product thickness reach 27.5 and 67.69 μm, respectively. The composition of the corrosion products on the steel surface is mainly FeCO3, and the presence of the iron oxides are caused by oxidation. The corrosion products of the cement are also confirmed to be CaCO3 and a small amount of SiO2.

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不同二氧化碳压力下浮珠低密度水泥石/P110 钢系统的腐蚀行为研究

本研究调查了浮珠低密度水泥石/P110 钢系统在模拟二氧化碳饱和地层水中的腐蚀状态。结果表明，水泥石的抗腐蚀性在 28 天时达到最大值，然后开始下降。高压下 P110 钢的腐蚀速率大于常压下的腐蚀速率。水泥石和钢之间存在一定的间隙，腐蚀产物在水泥石和钢之间积聚。此外，最大间隙尺寸和腐蚀产物厚度分别达到 27.5 和 67.69 μm。钢表面腐蚀产物的成分主要是 FeCO3，铁氧化物的存在是由氧化引起的。水泥的腐蚀产物也被证实为 CaCO3 和少量 SiO2。

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Corrosion Engineering, Science and Technology: The International Journal of Corrosion Processes and Corrosion Control

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