Advanced search
Publication Cover
Structural Engineering International Volume 33, 2023 - Issue 4: New developments for the resilient fire design of singular buildings and engineering infrastructure
Submit an article Journal homepage
349
Views
2
CrossRef citations to date
0
Altmetric
Scientific Paper

Utilizing Advanced Modelling for Fire Damage Assessment of Reinforced Concrete Tunnel Linings

Nan Hua PhD1 Mott Macdonald, Los Angeles, USACorrespondence[email protected]
View further author information
,
Negar Elhami Khorasani PhDORCID Iconhttps://orcid.org/0000-0003-3228-0097View further author information
ORCID Icon &
Anthony Tessari PhD2 Department of Civil, Structural and Environmental Engineering, University at Buffalo, Buffalo, USAView further author information
Pages 586-595 | Published online: 22 Feb 2023

References

  • Lu F. On the prediction of concrete spalling under fire [Doctoral Thesis]. Zurich, Switzerland: ETH-Zürich; 2015.
  • Schütz D. Fire protection in tunnels: focus on road & train tunnels. Tech Newsl SCOR Glob P&C. 2014;July 2014:1–12.
  • Kusterle W, Lindbauer W, Hampejs G, Heel A, Donauer P, Zeiml M, et al. Fire resistance of fibre-reinforced, reinforced and prestressed concrete. Bundesministerium für verkher, innovation und technologie. 2004.
  • Guerrieri M, Fragomeni S, Sanabria C, Lee W, Pazmino E. Australian large scale structural fire test facility for concrete tunnel linings. 6th international workshop on concrete spalling due to fire exposure. Sheffield, United Kingdom; 2019.
  • Caner A, Böncü A. Structural fire safety of circular concrete railroad tunnel linings. J Struct Eng. 2009;135:1081–1092.
  • Yan Z, Shen Y, Zhu H, Li X, Lu Y. Experimental investigation of reinforced concrete and hybrid fibre reinforced concrete shield tunnel segments subjected to elevated temperature. Fire Saf J. 2015;71:86–99.
  • Yan Z, Zhu H, Ju JW, Ding W. Full-scale fire tests of RC metro shield TBM tunnel linings. Constr Build Mater. 2012;36:484–494.
  • Lalu O, Lennon T. Experimental investigations into the spalling of high strength concrete and the fire performance of tunnel linings. 6th international workshop on concrete spalling due to fire exposure. Sheffield, United Kingdom; 2019.
  • Pardon D, Pimienta P, Marie-Jeanne B-L, Hameury S, Pinoteau N, Moreau B et al. In situ concrete spalling risk assessment in tunnel by means of a mobile oil-fired furnace. 6th international workshop on concrete spalling due to fire exposure. Sheffield, United Kingdom; 2019.
  • Lottman BBG, Snel AJM, Kaalberg FJ, Blom CBM, Koenders EAB. Spalling mechanism: Key for structural fire resistance of tunnels. Struct Eng Int. 2021;31:233–240.
  • Rinaudo P, Paya-Zaforteza I, Calderón PA. Improving tunnel resilience against fires: A new methodology based on temperature monitoring. Tunnel Underground Space Technol. 2016;52:71–84.
  • Felicetti R. Assessment methods of fire damages in concrete tunnel linings. Fire Technol. 2013;49:509–529.
  • Hoang N-D, Nguyen Q-L, Tran X-L. Automatic detection of concrete spalling using piecewise linear stochastic gradient descent logistic regression and image texture analysis. Complexity. 2019;2019:5910625.
  • Cantero-Chinchilla S, Wilcox PD, Croxford AJ. Deep learning in automated ultrasonic NDE – developments, axioms and opportunities. NDT E Int. 2022;131:102703.
  • Concrete Society. Assessment, design and repair of fire-damaged concrete structures. Camberley, UK: Concrete Society; 2008.
  • Federal Highway Administration. Tunnel operations, maintenance, inspection, and evaluation (TOMIE) Manual. Washington, DC, USA: Federal Highway Administration; 2015.
  • Fire Safety Committee of the Concrete and Masonry Industry. Assessing the condition and repair alternatives of fire-exposed concrete and masonry members. Skokie, Illinois; 1994.
  • International Federation for Structural Concrete (fib). Fire design of concrete structures – structural behavior and assessment. Lausanne, Switzerland: fib; 2008.
  • Ni S, Gernay TJSS. A framework for probabilistic fire loss estimation in concrete building structures. Structural Safety. 2021;88:102029.
  • Bisby L, Mostafaei H, Pimienta P. White paper on fire resistance of concrete structures. US Department of Commerce, National Institute of Standards and Technology; 2014.
  • American Concrete Institute Committee 228. Report on nondestructive test methods for evaluation of concrete in structures Farmington Hills, MI 48331 U.S.A. 2013.
  • Albrektsson J, Flansbjer M, Lindqvist JE, Jansson R. Assessment of concrete structures after fire. SP Technical Research Institute of Sweden, Borås; 2011.
  • Ingham J. Forensic engineering of fire-damaged structures. Proce Inst Civil Eng Civil Eng. 2009;162:12–17.
  • ASTM International. ASTM C856M – 20 standard test method for petrographic examination of hardened concrete. West Conshohocken, PA, United States: ASTM; 2020.
  • Hua N, Tessari A, Elhami Khorasani N. The effect of geologic conditions on the fire behavior of tunnels considering soil-structure interaction. Tunnel Underground Space Technol. 2022;122:104380.
  • Ministry of Transportation and Public Works of the Netherlands. Evaluation of memorial tunnel CFD simulations Netherlands: Ministry of Transportation and Public Works of the Netherlands; 1999.
  • Franssen J-M, Gernay T. Modeling structures in fire with SAFIR®: theoretical background and capabilities. J Struct Fire Eng. 2017;8:300–323.
  • Hua N, Tessari A, Elhami Khorasani N. Characterizing damage to a concrete liner during a tunnel fire. Tunnel Underground Space Technol. 2021;109:103761.
  • Kodur VKR, Agrawal A. An approach for evaluating residual capacity of reinforced concrete beams exposed to fire. Eng Struct. 2016;110:293–306.
  • Du S, Zhang Y, Sun Q, Gong W, Geng J, Zhang K. Experimental study on color change and compression strength of concrete tunnel lining in a fire. Tunnel Underground Space Technol. 2018;71:106–114.
  • Hager I. Colour change in heated concrete. Fire Technol. 2013;49:945–958.
  • Khoury G. Effect of fire on concrete and concrete structures. Prog Struct Mat Eng. 2000;2:429–447.
  • European Committee. Eurocode 3: design of steel structures – part 1-2: general rules – structural fire design (EN 1993-1-2). Brussels, Belgium: European Committee, 2005.
  • Deshpande AA, Kumar D, Ranade R. Temperature effects on the bond behavior between deformed steel reinforcing bars and hybrid fiber-reinforced strain-hardening cementitious composite. Constr Build Mater. 2020;233:117337.
  • ACI Committee 318. Building code requirements for structural concrete (ACI 318-19). Farmington Hills, MI, USA: American Concrete Institute; 2019.
  • Hua N, Elhami Khorasani N, Tessari A, Ranade R. Experimental study of fire damage to reinforced concrete tunnel slabs. Fire Saf J. 2022;127:103504.
  • Hua N, Elhami Khorasani N, Tessari A. Numerical modeling of the fire behavior of reinforced concrete tunnel slabs during heating and cooling. Eng Struct. 2022;258:114135.
  • Hua N, Tessari A, Elhami-Khorasani N. Quantifying uncertainties in the temperature-time evolution of railway tunnel fires. Fire Technol. 2020;57:361–392.
  • European Committee. Eurocode 2: design of concrete structures – parts 1–2: general rules –structural fire design (EN 1992-1-2). Brussels, Belgium: European Committee; 2004.
  • Gernay T, Franssen JM. A formulation of the eurocode 2 concrete model at elevated temperature that includes an explicit term for transient creep. Fire Saf J. 2012;51:1–9.
  • European Committee. Eurocode 4: design of composite steel and concrete structures – part 1-2: general rules – structural fire design (EN 1994-1-2). Brussels, Belgium: European Committee; 2005.
  • ASTM International. ASTM C805-18 standard test method for rebound number of hardened concrete. West Conshohocken, PA, United States: European Committee; 2018.
  • Qureshi R, Ni S, Khorasani NE, Coile RV, Hopkin D, Gernay T. Probabilistic models for temperature-dependent strength of steel and concrete. Journal of Structural Engineering. 2020;146:04020102.
  • Shahraki M, Hua N, Elhami-Khorasani N, Tessari A, Garlock M. Residual compressive strength of concrete after exposure to high temperature: A review and probabilistic models. Fire Saf J. 2023;135:103698.
  • Jovanovic B, Elhami Khorasani N, Thienpont T, Chaudhary RK, Van Coile R. Probabilistic models for thermal properties of concrete. Proceedings of 11th international conference on structures in fire; Nov 30 – Dec 2; Queensland, Australia; 2020.

Reprints and Corporate Permissions

Please note: Selecting permissions does not provide access to the full text of the article, please see our help page How do I view content?

To request a reprint or corporate permissions for this article, please click on the relevant link below:

Order Reprints Request Corporate Permissions

Academic Permissions

Please note: Selecting permissions does not provide access to the full text of the article, please see our help page How do I view content?

Obtain permissions instantly via Rightslink by clicking on the button below:

Request Academic Permissions

If you are unable to obtain permissions via Rightslink, please complete and submit this Permissions form. For more information, please visit our Permissions help page.

Related research

People also read lists articles that other readers of this article have read.

Recommended articles lists articles that we recommend and is powered by our AI driven recommendation engine.

Cited by lists all citing articles based on Crossref citations.
Articles with the Crossref icon will open in a new tab.