The effect of nitrite on pitting and stress corrosion cracking of corrosion resistant alloys (CRA) under oil field conditions

Okeremi, Akinyemi

January 2011

The need to inject treated seawater to enhance reservoir pressure and secondary oil recovery is increasing in the oil field, so also is the reservoir souring potential caused by the activities of Sulphate Reducing Bacteria (SRB) generating H2S in the reservoir. The total cost of SRB mediated corrosion in the United States alone is estimated to be 1-2 billion US dollars per year. In the last few years, a number of potential souring mitigation and prevention tools have been studied. These include: sulphate-reduction using membranes, biocide injection and nitrate injection. Out of all the various methods used for the mitigation and prevention of reservoir souring, the use of nitrate injection in conjunction with waterflood projects is becoming more popular because of its economic benefits and least environmental impact. However, nitrate injection is still widely considered as an emergent technology because there are still many unknowns. One of the major unknowns, of great concern is the susceptibility of subsea hardware components to nitrite, which is a by-product of nitrate anti-souring treatment. Any detrimental effect can compromise the technical integrity of subsea installations. The objective of this research is to study the corrosion susceptibility of CRA (13Cr- Martensitic, 22Cr, and 25Cr super duplex stainless steel) to pitting and stress corrosion cracking in the presence of nitrite. Research hitherto, has investigated corrosion susceptibility of carbon steel to nitrite and found out that nitrite causes pitting in carbon steel. This research work built on previous studies and extensively investigated the effect of nitrite on CRA materials in terms of pitting and stress corrosion cracking. Using electrochemistry techniques in conjunction with C-ring test and slow strain rate test, with variables such as temperature, and nitrite concentration all under anaerobic conditions. Metallographic examination and further evaluation using scanning electron microscopy confirmed pitting and intergranular stress corrosion cracking of 13Cr-L80 and 25Cr due to presence of nitrite.Test data confirmed that sodium nitrite is an anodic inhibitor; it shifts the corrosion potentials to more noble potential and also shifts the anodic curve to lower current, given a net reduction in corrosion rate. A critical concentration of 400ppm is required for inhibition to be effective on 13Cr-L80 and 25Cr. However, below the critical concentration, nitrite significantly increases the corrosion rate. The experimental data generated from this research work provides very valuable information that will tremendously assist the materials selection process for subsea and subsurface hardware components and also serve as a guide in the corrosion management process in existing systems.

669

Study of the Effect of Laser Shock Peening on Corrosion Behavior of Aluminum Alloy 7075

Aravamudhan, Boopa Nandhini

30 October 2018

No description available.

Materials Science

Laser Shock Peening

Stress corrosion cracking

Al 7075

Aluminum

corrosion

surface treatment

Evaluating the Potential for Atmospheric Corrosion of 304 Stainless Steel Used for Dry Storage of Spent Nuclear Fuel

Weirich, Timothy Douglas

24 October 2019

No description available.

Materials Science

marine corrosion

pitting or pits

chloride

damage morphology

stress corrosion cracking

surface finish

[pt] AVALIAÇÃO DA JUNTA SOLDADA DE AÇO API EM MEIO CORROSIVO / [en] EVALUATION OF API STEEL WELDED JOINTS IN A CORROSIVE MEDIUM

FRANCISCO DE ARAUJO MARTINS

20 December 2005

[pt] As tubulações de aços utilizadas pela indústria do petróleo estão constantemente expostas à ação do ácido sulfídrico (H2S) que é o veículo para a difusão do hidrogênio no aço, provocando o surgimento de trincas induzidas pela fragilização por hidrogênio e/ou trincas de corrosão sob tensão. A junta soldada, que é considerada a região crítica dos dutos, foi o objeto de avaliação neste trabalho mediante ensaios de tração sob baixa taxa de deformação (BTD) e através da norma NACE TM0177/96 - Método A (Standard Tensile Test), verificando o seu comportamento quanto à fragilização por hidrogênio e à corrosão sob tensão em aços da classe API grau X70 e X80. Uma solução de tiossulfato de sódio foi utilizada no ensaio BTD para avaliação da fragilização por hidrogênio e corrosão sob tensão, reduzindo custos e atendendo aos ítens de segurança. Os resultados mostraram que os aços API 5L X70 e X80 são susceptíveis à fragilização por hidrogênio e à corrosão sob tensão. / [en] The steel tubes used in the Oil Industry are constantly exposed to hydrogen sulphide (H2S) which leads to the diffusion of hydrogen into the steel, provoking hydrogen induced embrittlement cracks and/or stress corrosion cracking. Welded joints, generally considered to be the critical region in pipelines, were evaluated in this study, using slow strain rate tensile testing (SSRT) and NACE TMO177/96 - Method A (standard tensile test) norm, verifying the behaviour of joints in API X-70 and X-80 grade steels, with regard to hydrogen embrittlement and stress corrosion cracking. Sodium thiosulphate was used in the slow strain rate tests permit the evaluation of hydrogen embrittlement and stress corrosion cracking while reducing testing costs and maintaining safety standards. The results show that the API X-70 and X-80 grade steels are susceptible to hydrogen embrittlement and stress corrosion cracking.

[pt] SOLDAGEM

[pt] CORROSAO SOB TENSAO

[pt] FRAGILIZACAO PELO HIDROGENIO

[en] WELDING

[en] STRESS CORROSION CRACKING

[en] HYDROGEN EMBRITTLEMENT

Study of the corrosion and cracking susceptibility of low carbon steels under cathodic protection with AC Interference

Sanchez Camacho, Lizeth johana

24 July 2022

No description available.

Chemical Engineering

Engineering

Incorporation of Corrosion Mechanisms into a State-dependent Probabilistic Risk Assessment

Lewandowski, Radoslaw

24 July 2013

No description available.

Nuclear Engineering

Probabilistic Risk Assessment

Stress Corrosion Cracking

Flow-accelerated Corrosion

Passive Components

Implementation and Optimization of Time Reversal for Use in Nondestructive Evaluation of Stress Corrosion Cracking

Young, Sarah Marie

01 August 2018

The time reversal (TR) process manipulates a system's impulse response in order to focus a peak of acoustic energy at a specific location in space and time. This technique has been implemented in both fluid and solid media for purposes ranging from communications to source localization. This thesis will examine both the implementation and processing of TR for nondestructive evaluation in steel, specializing in nonlinear detection methods. A series of steel samples are inspected for stress corrosion cracking (SCC) using TR focusing to excite nonlinearities inherent in cracks. It is determined that SCC exists in the expected regions of the steel samples and that an induced increase in SCC corresponds to an increase in detected nonlinearity. In addition to this, a study is shown wherein TR signal processing is optimized for the detection of cracks. The TR impulse response is modified in a number of ways with the primary goal of increasing the amplitude of the TR focus. Each of these modifications is experimentally scrutinized for characteristics necessary for application to nondestructive evaluation, and ultimately one is chosen that amplifies TR focusing without increasing system nonlinearity. The optimized technique, decay compensation TR, is employed in the detection of SCC and is found to be as or perhaps even more successful than typical TR nondestructive evaluation methods.

time reversal

nondestructive evaluation

stress corrosion cracking

Physical Sciences and Mathematics

Physics

Experimental Characterization and Computer Vision-Assisted Detection of Pitting Corrosion on Stainless Steel Structural Members

Muehler, Riley J

01 June 2023

Pitting corrosion is a prevalent form of corrosive damage that can weaken, damage, and initiate failure in corrosion-resistant metallic materials. For instance, 304 stainless steel is commonly utilized in various structures (e.g., miter gates, heat exchangers, and storage tanks), but is prone to failure through pitting corrosion and stress corrosion cracking under mechanical loading, regardless of its high corrosion resistance. In this study, to better understand the pitting corrosion damage development, controlled corrosion experiments were conducted to generate pits on 304 stainless steel specimens with and without mechanical loading. The pit development over time was characterized using a high-resolution laser scanner. In addition, to achieve scalable and automatic assessment of pitting corrosion conditions, two convolutional neural network-based computer vision algorithms were adopted and implemented to evaluate the efficacy of networks to identify existence of pitting damage. One was a newly trained convolutional neural network (CNN) using MATLAB software, while the other one was a retrained version of GoogLeNet. Overall, the experimental results showed that time is the dependent variable in predicting pit depth. Meanwhile, loading conditions significantly influence pit morphology. Under compression loading, pits form with larger surface opening areas, while under tension loading, pits have smaller surface opening areas. Deep pits of smaller areas are dangerous for structural members, as they can lead to high stress concentrations and early stress corrosion cracking (SCC). Furthermore, while the training library was limited and consisted of low-resolution images, the retrained GoogLeNet CNN showed promising potential for identifying pitting corrosion based on the evaluation of its performance parameters, including the accuracy, loss, recall, precision, and F1-measure.

Pitting Corrosion

Computer Vision

Image Processing

Damage Assessment

Stress Corrosion Cracking

Structural Engineering

Structural Materials

A Study of the Effects of Mechanical Surface Treatments on Residual Stresses, Microstructure and Stress Corrosion Cracking Behavior of Alloy 600

Telang, Abhishek

January 2015

No description available.

Materials Science

Stress Corrosion Cracking

Microstructure

Laser Shock Peening

Microstructure

Grain boundary

Residual Stress

Chloride-Induced Stress Corrosion Cracking in Used Nuclear Fuel Welded Stainless Steel Canisters

Xie, Yi

28 December 2016

No description available.

Nuclear Engineering