International Journal of Engineering

International Journal of Engineering

Improving the Accuracy of Hardness Measurement using UCI Transducers for Inspecting the Heat-Affected Zone of Welded Joints in Steel Pipelines

Document Type : SPMU 2026

Authors
A. I. Shikhov 1
D. S. Gromyka 1
A. S. Umansky 1
D. V. Kopytina 1
D. R. Shakirzyanova 1
A. M. Shmakov 2
1 Empress Catherine II Saint-Petersburg Mining University, Saint-Petersburg, Russia
2 ITMO University, Saint-Petersburg, Russia
10.5829/ije.2026.39.10a.12
Abstract
Quality control of welded joints involves hardness measurements of both the weld and the heat-affected zone (HAZ). However, standardized hardness testing methods require specimen preparation, leading to pipeline downtime. Among portable devices, hardness testers implementing the Ultrasonic Contact Impedance (UCI) method are the most widely used. However, measurement results depend on the calibration curve, which accounts for the elastic properties of the specimen and assumes their uniformity across the entire inspected surface. In the HAZ of a welded joint, changes in the metal's microstructure and elastic properties occur, leading to measurement errors in UCI hardness testing. This article presents a methodology for applying a correction to the calibration by accounting for actual changes in the elastic modulus within the HAZ, measured via ultrasonic wave velocity monitoring. As a result, hardness values incorporating this correction demonstrated better correlation with reference results obtained using a Vickers microhardness tester, indicating that the proposed correction improves the accuracy of UCI transducer measurements.

Graphical Abstract

Improving the Accuracy of Hardness Measurement using UCI Transducers for Inspecting the Heat-Affected Zone of Welded Joints in Steel Pipelines
Keywords
Steel Pipes
Weld Seam
Heat-affected Zone
Ultrasonic Contact Impedance
Ultrasonic Wave
Calibration

Subjects

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International Journal of Engineering
Volume 39, Issue 10
TRANSACTIONS A: Basics
October 2026
Pages 2500-2508