Thickness optimization of semi-structural CIPP pressure pipe liners: A mathematical modeling approach

Ferran Gras-Travesset; Antoni Andreu-Torras; Marco A. Pérez

doi:10.1016/j.tust.2024.105876

Thickness optimization of semi-structural CIPP pressure pipe liners: A mathematical modeling approach

Ferran Gras-Travesset, Antoni Andreu-Torras, Marco A. Pérez

Research output: Indexed journal article › Article › peer-review

Abstract

This paper introduces a novel mathematical model to optimize the thickness of semi-structural liners in Cured-In-Place-Pipe (CIPP) rehabilitation based on the host pipe holes criterion defined in current standards. The model considers the residual structural mechanical properties of the damaged host pipe, and holes are defined considering the direction, the area, and the perimeter of the host pipe hole, providing a more accurate estimation of the liner behavior. Results indicate potential thickness reductions of 20%–40% for circular holes, while non-circular holes offer even greater optimization possibilities ranging from 40 to 80%. Moreover, a full-scale test was conducted on a reinforced concrete host pipe of DN 400, damaged with three holes 150 mm in diameter. The full-scale test results were used to refine the numerical model employed in developing the mathematical model, ensuring its accuracy and reliability.

Original language	English
Article number	105876
Number of pages	14
Journal	Tunnelling and Underground Space Technology
Volume	152
DOIs	https://doi.org/10.1016/j.tust.2024.105876
Publication status	Published - Oct 2024

Keywords

ASTM F1216
CIPP
Composite liner
Full-scale test
Holes criterion
Pipe Rehabilitation
UNE 53929

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10.1016/j.tust.2024.105876

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title = "Thickness optimization of semi-structural CIPP pressure pipe liners: A mathematical modeling approach",

abstract = "This paper introduces a novel mathematical model to optimize the thickness of semi-structural liners in Cured-In-Place-Pipe (CIPP) rehabilitation based on the host pipe holes criterion defined in current standards. The model considers the residual structural mechanical properties of the damaged host pipe, and holes are defined considering the direction, the area, and the perimeter of the host pipe hole, providing a more accurate estimation of the liner behavior. Results indicate potential thickness reductions of 20%–40% for circular holes, while non-circular holes offer even greater optimization possibilities ranging from 40 to 80%. Moreover, a full-scale test was conducted on a reinforced concrete host pipe of DN 400, damaged with three holes 150 mm in diameter. The full-scale test results were used to refine the numerical model employed in developing the mathematical model, ensuring its accuracy and reliability.",

keywords = "ASTM F1216, CIPP, Composite liner, Full-scale test, Holes criterion, Pipe Rehabilitation, UNE 53929",

author = "Ferran Gras-Travesset and Antoni Andreu-Torras and P{\'e}rez, {Marco A.}",

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doi = "10.1016/j.tust.2024.105876",

language = "English",

volume = "152",

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T2 - A mathematical modeling approach

AU - Gras-Travesset, Ferran

AU - Andreu-Torras, Antoni

AU - Pérez, Marco A.

PY - 2024/10

Y1 - 2024/10

N2 - This paper introduces a novel mathematical model to optimize the thickness of semi-structural liners in Cured-In-Place-Pipe (CIPP) rehabilitation based on the host pipe holes criterion defined in current standards. The model considers the residual structural mechanical properties of the damaged host pipe, and holes are defined considering the direction, the area, and the perimeter of the host pipe hole, providing a more accurate estimation of the liner behavior. Results indicate potential thickness reductions of 20%–40% for circular holes, while non-circular holes offer even greater optimization possibilities ranging from 40 to 80%. Moreover, a full-scale test was conducted on a reinforced concrete host pipe of DN 400, damaged with three holes 150 mm in diameter. The full-scale test results were used to refine the numerical model employed in developing the mathematical model, ensuring its accuracy and reliability.

AB - This paper introduces a novel mathematical model to optimize the thickness of semi-structural liners in Cured-In-Place-Pipe (CIPP) rehabilitation based on the host pipe holes criterion defined in current standards. The model considers the residual structural mechanical properties of the damaged host pipe, and holes are defined considering the direction, the area, and the perimeter of the host pipe hole, providing a more accurate estimation of the liner behavior. Results indicate potential thickness reductions of 20%–40% for circular holes, while non-circular holes offer even greater optimization possibilities ranging from 40 to 80%. Moreover, a full-scale test was conducted on a reinforced concrete host pipe of DN 400, damaged with three holes 150 mm in diameter. The full-scale test results were used to refine the numerical model employed in developing the mathematical model, ensuring its accuracy and reliability.

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KW - CIPP

KW - Composite liner

KW - Full-scale test

KW - Holes criterion

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JO - Tunnelling and Underground Space Technology

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ER -

Thickness optimization of semi-structural CIPP pressure pipe liners: A mathematical modeling approach

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Keywords

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