Distinct Advantages of Circumferential Notch Tensile (CNT) Testing in the Determination of a Threshold for Stress Corrosion Cracking (KISCC)

Stress corrosion cracking (SCC) is a vexing problem for load-bearing equipment operating in a corrosive environment in various industries, such as aerospace, chemical and mineral processing, civil structures, bioimplants, energy generation etc. For safe operation, effective maintenance and life prediction of such equipment, reliable design data on SCC (such as threshold stress intensity for SCC, i.e., K-ISCC) are invaluable. Generating reliable K-ISCC data invariably requires a large number of tests. Traditional techniques can be prohibitively expensive. This article reviews the determination of K-ISCC using the circumferential notch tensile (CNT) technique, the validation of the technique and its application to a few industrially relevant scenarios. The CNT technique is a relatively recent and considerably inexpensive approach for the determination of K-ISCC when compared to traditional techniques, viz., double-cantilever beam (DCB) and compact tension (CT) that may be fraught with prohibitive complexities. As established through this article, the CNT technique circumvents some critical limitations of the traditional techniques.

Automated summary

Stress corrosion cracking (SCC) poses a challenge for load-bearing equipment in corrosive environments across industries like aerospace, chemical and mineral processing, civil structures, bioimplants, and energy generation. Reliable K-ISCC data is crucial for safe operation and maintenance of such equipment, with traditional techniques being costly. This article highlights the use of the circumferential notch tensile (CNT) technique as a newer and more cost-effective approach to determine K-ISCC, overcoming critical limitations of traditional techniques like double-cantilever beam (DCB) and compact tension (CT).