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In the case of underground network infrastructure it can be seen that objects functioning in the second technical condition, according to DWA-ATV 143-2, and subjected to rehabilitation with the use of close-fit trenchless technologies are capable of withstanding external loads. The main external load that is taken into account in engineering calculations in the case of conduits in the second technical condition is external groundwater pressure. In order to compare design parameters obtained with the use of various calculation methods, a comparative analysis was conducted in order to determine the values of critical pressure. The calculations were carried out using popular engineering algorithms. In addition, analyses using the Finite Element Method and Abaqus software as a computational tool were carried out for the purpose of verifying laboratory tests. This paper aims to broaden knowledge concerning the possibility of performing control numerical analyses for close-fit liners installed in pipelines that are in the second technical condition according to DWA-ATV 143-2. The analyses were carried out on ten 3D models. The models were parameterized in order to reflect the CIPP samples in the most accurate way. The computational models were built based on assumptions, which are commonly used in this type of scientific analysis, regarding material parameters and their interactions. The direct value of the performed engineering calculations and numerical analyses is the extension of knowledge in the field of strength parameters that are obtained by various material groups of close-fit liners. Comparative analysis of the results of laboratory tests and numerical analyses, and the conclusions that result from them, constitute the basis for the optimization of the design process and the individual approach to issues related to the use of liners that strengthen underground pipelines.
Słowa kluczowe
Wydawca
Czasopismo
Rocznik
Tom
Strony
307--322
Opis fizyczny
Bibliogr. 24 poz., rys., tab.
Twórcy
autor
- Wrocław University of Science and Technology, Wybrzeże Wyspiańskiego 27, 50-370 Wrocław, Poland
Bibliografia
- [1] Thepot O., International Comparison of Methods for the Design of Sewer Linings, 3R International 8-9, Vulcan-Verlag GmbH, Essen, 2004
- [2] Falter B.: Structural design of linings, Proceedings of the International Conference on Underground Infrastructure Research, Kitchener, Ontario, Balkema publisher, 2001, s. 49-58
- [3] ASTM F 1216, Standard practice for rehabilitation of existing pipelines and conduits by the inversion and curing of a resin – impregnated tube, ASTM Designation, Philadelphia, 1998.
- [4] RERAU. Project national Réhabilitation des réseaux dassainissement urbains. Reconstructuration des collecteurs visitables, Guide technique Tome 1, 2002.
- [5] WRc/WAA 4th ed. Sewerage Rehabilitation Manual (SRM), UK Water Research Centre/Water Authorities Association, Swindon, 2001.
- [6] DWA-A 143-2: Sanierung von Entwässerungssystemen außerhalb von Gebäuden Teil 2: Statische Berechnung zur Sanierung von Abwasserleitungen und -kanälen mit Lining - und Montageverfahren, Lipiec 2015
- [7] Abel T., Laboratory tests and analysis of CIPP epoxy-resin internal liners used in pipelines – part I: comparison of tests and engineering calculations, Studia Geotechnica et Mechanica, accepted for publication on 31.01.2021
- [8] Rusiński E.: The Finite Element Method, Wydawnictwo Komunikacji i Łączności. Warsaw, 1994
- [9] PN-EN ISO 178:2019-06 - Plastics — Determination of flexural properties
- [10] GWT manual, 2000. Germann Instruments, Denmark.
- [11] Timoshenko S.P., Gere J.M.: Theory of Elastic Stability. Mc Graw – Hill. New York, 1961.
- [12] Glock D.: Überkritisches Verhalten eines starr ummantelten Kreisrohres bei Wasserdruck von außen und Temperaturerhöhung, Der Stahlbau 46, 1977, s. 212-217.
- [13] Madryas C., Szot A., Structural sensitivity of circular sewer liners to geometrical imperfections, Tunnelling and Underground Space Technology 18 (2003) 421–434, Elsevier Science Ltd. 2003
- [14] Law T.C.M., Moore I. D., Numerical modeling of tight fitting flexible liner in damaged sewer under earth loads, Tunnelling and Underground Space Technology 22 (2007) 655–665, Elsevier Science Ltd. 2007
- [15] Abel. T., Changes in strength parameters of pipelines rehabilitated with close-fit Trolining liners – Numerical analysis based on laboratory tests, Archives of Civil and Mechanical Engineering 16 (2016) 30 – 40, Wrocław, 2015
- [16] Zhao W. Z., Hall D., 3D Modeling of pipe liners with thickness variations, International No-Dig Show 2004, New Orleans, 2004
- [17] Jaganathan A., Allouche E., Baumert M., Experimental and numerical evaluation of the impact of folds on the pressure rating of CIPP liners, Tunnelling and Underground Space Technology 22 (2007) 666–678, Elsevier Science Ltd. 2007
- [18] Khademi-Zahedi R., Shishesaz M., Application of a finite element method to stress distribution in buried patch repaired polyethylene gas pipes, Underground Space 4 (2019) 48–58, Elsevier Science Ltd. 2019
- [19] Shou K.J., Chen B.C., Numerical analysis of the mechanical behaviors of pressurized underground pipelines rehabilitated by cured-in-place-pipe method, Tunnelling and Underground Space Technology 71 (2018) 544–554, Elsevier Science Ltd. 2018
- [20] Shou K.J., Huang C.C., Numerical analysis of straight and curved underground pipeline performance after rehabilitation by cured-in-place method, Underground Space 5 (2020) 30–42, Elsevier B.V., 2020
- [21] Arumugam T., Karuppanan S., Ovinis M., Finite element analyses of corroded pipeline with single defect subjected to internal pressure and axial compressive stress, Marine Structures 72 (2020) 102746, Elsevier Science Ltd. 2020
- [22] Boot J.C., Elastic buckling of cylindrical pipe linings with small imperfections subject to external pressure, Trenchless Technology Research, VOL. 12, No. 1-2, pp. 3-15, Elsevier Science Ltd. 1998, England
- [23] Thépot O.: A new design method for non circular sewer linings. Trenchless Technology Research 15, 2000, s. 25-41.
- [24] Abaqus - Wrocław Center for Networking and Supercomputing (http://www.wcss.pl)
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-9c18bb32-fa95-4df3-8762-6607eabcfad9