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Corrosion Detection Methods for Stainless Steel Pipes and Tubes

Written by Thermaxx Jackets | Jun 26, 2018 7:58:00 PM

Stainless steel is resistant, but certainly not immune, to corrosion.  In a previous article, we examined the need for inspecting stainless steel pipes further, including a discussion of conditions which encourage corrosion.  When corrosion does occur in stainless steel, the corrosion often manifests in a very localized manner rather than uniform (or “general”) corrosion. Two forms of corrosion particularly troublesome to stainless steel are pitting and stress corrosion cracking, and both can cause very bad problems. Thus, for stainless steel piping systems, corrosion is an issue worthy of the attention of plant managers.

In this article, we overview some of the common methods used to detect corrosion in stainless steel pipes and tubes. Technological developments have produced a dizzying array of non-destructive testing (NDT) used for detecting corrosion, each with its own advantages and limitations. Accurately detecting corrosion in stainless steel in a cost effective and practical manner is an incredibly complex problem. Choosing the most appropriate method(s) for your needs requires consideration of the particulars of the situation and may warrant the assistance of experts in corrosion detection. For simplicity sake, we will focus mostly on austenitic stainless steel (or 300 series), which is susceptible to problematic forms of corrosion and accounts for the majority of stainless steel in use.

Detection Considerations for Stainless Steel

To provide some assistance in understanding the underlying principles of corrosion detection in stainless steel, we begin by identifying three things that make inspection of stainless steel tubing different from corrosion detection in other materials.

1. Stainless Steel Magnetic Properties

First, most (but not all) stainless steel does not have the magnetic properties that ferromagnetic materials like typical carbon steel and many other iron alloys have. Austenitic stainless steel (or 300 series) makes up the majority of stainless steel production and is not ferromagnetic.  Corrosion detection methods relying upon magnetic interaction with the piping need not apply with non-ferromagnetic materials. For example, magnetic particle testing such as the Magnetic Flux Leakage Technique (MFL) will not work on non-ferromagnetic materials like austenitic stainless steel.

According to experts1, the following detection methods have applications for stainless steel: Acoustic Emission, conventional Eddy Current Testing, Infra-red Thermography, Laser Optics, Penetrate Dye Testing, Radiographic Testing (X-ray), Visual Inspection, and Ultrasonic Testing.

2. Detecting Pitting and Cracking

Second, many corrosion detection methods do not detect pitting and stress corrosion cracking. Both of these problems are difficult to detect and could potentially cause catastrophic failure. The unfortunate Silver Bridge collapse was caused by stress corrosion cracking, for example. Thus, if there is a high cost of failure or there is likelihood of pitting or cracking, appropriate detection methods must be employed. According to experts1, methods that will detect cracking and pitting in stainless steel include: penetrant dye testing, acoustic emission, ultrasonic testing, and eddy current testing.

3. Insulation Removal

Third, many corrosion detection methods require direct contact with the metal. Therefore, if there is insulation, the insulation must be at least partially removed. However, when pieces of insulation are removed moisture has an opening to get under the insulation, thereby actually increasing the likelihood for corrosion under insulation. Furthermore, we’ve seen firsthand countless times that plugs cut into the insulation are frequently not properly replaced and are one of the top contributors to energy inefficiency in piping systems.

This creates a notable dilemma, as there are few instances where you can accurately and thoroughly check for corrosion under insulation(CUI) without cutting into the insulation.

Popular Detection Methods

Having identified unique aspects of detecting corrosion in stainless steel, we will briefly overview some of the more popular detection techniques.

Visual Inspection

Visually inspecting for corrosion with your own eyes is the simplest method of all. If you have only a small amount of pipes or tubes, it may be the cost-effective approach as well. However, for the large systems home to most stainless steel tubes and pipes, visual inspection becomes the least cost-effective approach due to the enormous amount of labor required. In addition, you can’t visually inspect what your eyes can’t see, so if there is insulation, you can’t inspect anything that you do not cut off, making it extremely difficult to detect non-uniform corrosion such as cracking. Furthermore, the human eye has proved notoriously inept at detecting stress corrosion cracks, which can start out incredibly small. Relying solely on visual inspection is almost always not recommended.

X-Ray

X ray (radiography) can be used for corrosion detection without requiring insulation removal. One disadvantage is that X-rays produce radiation, and the precautions that need to be put in place when conducting X-ray testing may be impractical in many environments. Another disadvantage is that X-ray does not detect cracking and pitting; however it can be very useful for detecting other kinds of defects.

Eddy Current Technique

The Eddy Current Technique (ECT) has likely become the most frequently recommended corrosion detection method for stainless steel. This technique uses electromagnetic induction to apply alternating “Eddy” currents to the pipe or tube. As the electromagnetic field interacts with the material, the impedance of the coil in the testing probe changes; the impedance paints the picture of the defect in the tube.

Conventional Eddy Current: There are now a few variations of Eddy Current methods, but Conventional Eddy Current remains what is most commonly used on stainless steel. The advantages of conventional Eddy Current are that it is versatile, fast, and cost-effective. The main downside of conventional ECT is that the material being tested must be accessible to the probe; thus, if there is insulation on the pipe or tube, at least some must be removed.

Pulsed Eddy Current: Pulsed Eddy Current testing is a specialized Eddy Current method that has the fantastic advantage of the probe not needing to be in direct contact with the material being tested. Thus, no insulation needs removed. Pulsed Eddy Current has therefore become a popular method for detecting corrosion under insulation. However, it has the drawback of not being known as reliable in detect ultra-localized corrosion like pitting.

Conclusion:

That was just the tip of the iceberg when it comes to corrosion detection methods. There truly is a tremendous variety of techniques and none of them seem to come out as a clear winner for detecting CUI in stainless steel piping in a full range of scenarios. However, techniques can be combined to better meet inspection needs.

Due to severity of problems that can be caused by CUI and the difficulty detecting CUI – especially in stainless steel pipes – it is all the more important to factor in corrosion and detection methods before piping and insulation is installed. Consider how corrosion-prone your conditions are and how costly failure would be due to corrosion; then draft a detection plan before the system is complete. Consider your insulation system based on your corrosion detection andprevention needs. For example, removable insulation can be the superior choice when frequent inspection and maintenance is required. It is also recommended to enlist in the advice of corrosion detection experts when choosing detection methods and making detection plans.

For more information on corrosion detection in stainless steel pipes and tubes, we recommend the following expert resources:

  1. Khatak, et al. Corrosion of Austenitic Stainless Steel: Mechanism, Mitigation and Monitoring (2002). Alpha Science International Ltd.
  2. Raj, et al. Practical Non-Destructive Testing (2001). Woodhead Publishing
  3. www.ndt.net
  4. www.asnt.org - The American Society for Nondestructive Testing (NDT)