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IMPROVEMENTS ON AUTOMATIC ULTRASONIC TECHNIQUES APPLIED IN DETECTING NON-METALLIC INCLUSION FOR SEAMLESS PIPE MILLS

Automated ultrasonic testing is an integral validation tool utilized to detect defects in seamless pipes during the manufacturing process. The primary objective of AUT is to ensure newly manufactured seamless pipes are free of laminar imperfection such as non-metallic inclusions.
This paper describes the automatic ultrasonic testing (AUT) techniques capabilities applied to seamless pipe mills to detect non-metallic inclusions that could have an impact on the quality of the produced pipes. In addition, it covers all relevant applicable testing experiments applied to different sized seamless pipes by using different types of AUT machines. This paper discusses the capabilities of different static and dynamic calibration methodologies of detecting non-metallic inclusions. An assessment has been conducted on five (5) seamless pipes produced with non-metallic inclusions scattered along pipes lengths. The assessment revealed the recommended calibration and testing methodology capable of detecting non-metallic inclusion. Accordingly, a statistical analysis is presented to report the repeatability of different AUT techniques in detecting non-metallic inclusions in newly manufactured seamless pipes.

Product Number: MPWT19-14737
Author: Abdullah Al Qahtani
Publication Date: 2019
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Corrosion, either internal or external, along with other types of defects on pipelines eventually lead to leaks without proper treatment. This gives rise to several issues, including environmental and safety hazards, and in case of pipe leaks in a plant, a loss of the efficiency of the process or, ultimately, failure of the process. Replacing the corroded pipelines (piping) can be difficult, costly and time consuming especially for plant. A required shutdown causes major economic loss. Thus, instead of a replacement of the defected pipelines, the installation of online repair is a better option.
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Picture for Role of Non-Metallic Inclusions and the Microstructure Constituents on HIC Performance
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Role of Non-Metallic Inclusions and the Microstructure Constituents on HIC Performance

Product Number: MPWT19-14439
Author: Amro Al-Hattab1,Diaa Elsanosy2, Gaurav Tomer3, Abdullah Al-Jarbou4
Publication Date: 2019
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With increasing oil & gas demand and depletion of sweet reserves, oil & gas companies in the regional
economies are focusing towards the exploitation of sour resources. This necessitates the use of pipelines
and down-hole tubing made from special steels with significant resistance to hydrogen-induced cracking
(HIC). These steels are produced through specific technologies for enhanced chemical composition control
and microstructural engineering to incorporate the required strength, weld ability and improved HIC
resistance. It is well established that the HIC initiates at sites with microstructural heterogeneities whether
due to presence of gross nonmetallic inclusions or the micro-structural constituents. The presence of central
segregation further aggravates the conditions particularly when the final pipe sizes require the longitudinal
slitting of the coils. Presence of non-metallic inclusions in the steel makes it vulnerable to hydrogen-induced
cracking under wet H2S environment. The mechanism of HIC begins with the generation of hydrogen atoms
by corrosion reaction of H2S and Fe in the presence of free water. The hydrogen atoms then diffuse into
steel and accumulate around the inclusions. The higher number of inclusions equates to the more sites
available for hydrogen adsorption. Recombination of hydrogen atoms to H2 molecules builds up a heavy
gas pressure in the interface between matrix and inclusions. Cracking initiates because of the tensile stress
field caused by hydrogen gas pressure and crack propagates in the surrounding steel matrix. The
longitudinal slitting exposes the internal microstructural abnormalities to the skelp edges which are then
incorporated in the thermally stressed weld zone. While the post-weld heat treatment (PWHT) mostly
homogenizes the weld zone microstructure, the presence of excessive central line features cannot be
completely removed thereby making this zone more prone to HIC attack

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