NON-DESTRUCTIVE TESTING OF CIPP DEFECTS USING A MACHINE LEARNING APPROACH

Richard Dvořák; Lubos Pazdera; Libor Topolář; Lubos Jakubka; Jan Puchýř

doi:10.17222/mit.2023.1000

Richard Dvořák Brno University of Technology, Veveří 331/95, Brno 602 00, Czech Republic
Lubos Pazdera Brno University of Technology, Veveří 331/95, Brno 602 00, Czech Republic https://orcid.org/0000-0002-9416-5644
Libor Topolář Brno University of Technology, Veveří 331/95, Brno 602 00, Czech Republic https://orcid.org/0000-0001-9437-473X
Lubos Jakubka Brno University of Technology, Veveří 331/95, Brno 602 00, Czech Republic https://orcid.org/0009-0001-9358-103X
Jan Puchýř Brno University of Technology, Veveří 331/95, Brno 602 00, Czech Republic https://orcid.org/0000-0001-8303-4748

DOI: https://doi.org/10.17222/mit.2023.1000

Keywords: retrofitting, cured-in-place pipes, non-destructive testing, impact-echo method, pipe defects, acoustic parameters, machine learning, classification

Abstract

In civil engineering, retrofitting actions involving repairs to pipes inside buildings and in extravehicular locations present complex and challenging tasks. Traditional repair procedures typically involve disassembling the surrounding structure, leading to technological pauses and potential work environment disruptions. An alternative approach to these procedures uses the cured-in-place-pipe (CIPP) technology for repairs. Unlike standard repairs, CIPP repairs do not require a disassembly of the surrounding structures; only the access points at the beginning and end of the pipe need to be accessible. However, this method introduces the possibility of different types of defects.¹ This research aims to observe the defects between the host and newly cured pipes. The presence of holes, cracks, or obstacles prevents achieving a desired close-fit state, ultimately reducing the life expectancy of the retrofitting. This paper focuses on the non-destructive observation of these defects using the non-destructive testing (NDT) impact-echo (IE) method. The study explicitly applies this method to the composite segments inside concrete host pipes, forming a testing polygon. Previous results have indicated that the mechanical behaviour of cured composite pipes can vary in stiffness depending on factors such as the curing procedure and environmental conditions.² The change in acoustic parameters such as resonance frequency, attenuation and other features of typical IE signals can describe the stiffness evolution. This study compares different sensors used for the proposed IE testing, namely piezoceramic and microphone sensors. It evaluates their ability to distinguish between the defects present in the body of a CIPP via a machine-learning approach using random tree classifiers.

This research aims to observe defects between the host and newly cured pipes. However, the presence of holes, cracks, or obstacles prevents attaining this desired close-fit state, ultimately reducing the life expectancy of the retrofitting action. This paper focuses on the non-destructive observation of these defects using the NDT Impact-Echo (IE) method. The study explicitly applies this method to CIPP composite pipe segments inside concrete host pipes, forming a testing polygon. Previous results have indicated that the mechanical behaviour of cured CIPP composite pipes can vary in stiffness depending on factors such as the curing procedure and environmental conditions. The change of acoustic parameters such as resonance frequency, attenuation and other features of typical IE signals can describe the stiffness evolution.

This paper compares different sensors used for IE proposed testing, namely piezoceramic and microphone sensors. It evaluates their ability to distinguish between defects present in the body of the CIPP via a machine-learning approach using random tree classifiers.

References

KULICZKOWSKA, Emilia a Agata ZWIERZCHOWSKA. A qualitative analysis of early defects present in PVC-U sewers but not observed in rigid pipes. Tunnelling and Underground Space Technology [online]. 2016, 56, 202-210 [cit. 2023-08-25]. ISSN 08867798. DOI:10.1016/j.tust.2016.03.013
HODUL, Jakub, Jana MAJEROVÁ, Rostislav DROCHYTKA, Richard DVOŘÁK, Libor TOPOLÁŘ a Luboš PAZDERA. Effect of Chemical Aggressive Media on the Flexural Properties of Cured-In-Place Pipes Supported by Microstructure Observation and Acoustic Emission. Materials [online]. 2020, 13(14) [cit. 2023-08-25]. ISSN 1996-1944. DOI:10.3390/ma13143051
CARINO, Nicholas J. The Impact-Echo Method: An Overview. Structures 2001. Reston, VA: American Society of Civil Engineers, 2001, 1-18. ISBN 978-0-7844-0558-1. DOI: 10.1061/40558(2001)15
METODA KAWO. In: Wombat s.r.o. [online]. 2022 [cit. 2022-09-01]. URL: https://www.wombat.cz/metoda-kawo-bezvykopova-inverzni-technologie-pro-sanaci-kanalizacnich-sberacu/
ARTS, Lukas P. A. a Egon. L. VAN DEN BROEK. The fast continuous wavelet transformation (fCWT) for real-time, high-quality, noise-resistant time–frequency analysis. Nature Computational Science [online]. 2022, 2(1), 47-58 [cit. 2023-08-25]. ISSN 2662-8457. DOI: doi:10.1038/s43588-021-00183-z
BREIMAN, Leo. Random forest. Machine Learning [online]. 45(1), 5-32 [cit. 2023-08-25]. ISSN 08856125. DOI:10.1023/A:1010933404324