Emirati Journal of Civil Engineering and Applications

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مجلد 1 عدد 1 (2023): Emirati Journal of Civil Engineering and Applications

Simple Visual Aids for Predicting Fire Response of RC Columns: Nomograms via Machine Learning

  • M.Z Naser
  • Arash Teymori Gharah Tapeh
  • Haley Hostetter
  • Mohammad Khaled al-Bashiti
  • William Qin
مقدم
November 10, 2023
منشور
2023-11-10

الملخص

Assessing the ability of reinforced concrete (RC) columns to withstand the effects of fire is a multifaceted and intricate problem due to the various factors that influence their fire response. As such, engineers may find it challenging to precisely predict such fire resistance. While some codal provisions exist and fire testing/advanced modeling can be adopted, the same methods may suffer from poor predictivity and can be costly and/or complex. In this paper, we shift focus toward machine learning techniques (by means of Nomograms) that can produce simple visual aids to assess the fire resistance of RC columns. Our analysis shows that Nomograms can be accurate, account for a series of factors currently absent from our domain knowledge and provisions, and outperform existing methods adopted in building codes. Our analysis also infers that such Nomograms could be possible candidates for adoption in standardized settings, given their simplicity, ease of use, and lack of multi-stepped procedures. 

المراجع

  1. Kodur V (2014) Properties of Concrete at Elevated Temperatures. ISRN Civil Engineering 2014:1–15. https://doi.org/10.1155/2014/468510
  2. Khan MA, Khan AA, Usmani AS, Huang X (2022) Can fire cause the collapse of Plasco Building: A numerical investigation. Fire Mater 46:560–575. https://doi.org/10.1002/FAM.3003
  3. Kodur V, Naser M (2020) Structural Fire Engineering, 1st ed. McGraw Hill Professional
  4. (1988) Fire Resistance of Concrete Construction. Fire Technol 24:374–375. https://doi.org/10.1007/BF01040054/METRICS
  5. Banerji S, Solhmirzaei R, Kodur VKR (2019) Fire Response of Ultra High Performance Concrete Beams. In: International Interactive Symposium on Ultra-High Performance Concrete
  6. Dwaikat MB (2009) Flexural response of reinforced concrete beams exposed to fire. Michigan State University
  7. Dwaikat MB, Kodur VKR (2010) Fire induced spalling in high strength concrete beams. Fire Technol 46:251–274
  8. Bolina FL, Gil AM, Fernandes B, et al (2020) Influence of design durability on concrete columns fire performance. Journal of Materials Research and Technology 9:4968–4977
  9. Kodur VKR, Phan L (2007) Critical factors governing the fire performance of high strength concrete systems. Fire Saf J 42:482–488
  10. Wu B, Li YH, Chen SL (2010) Effect of heating and cooling on axially restrained rc columns with specialshaped cross section. Fire Technol 46:231–249. https://doi.org/10.1007/S10694-009-0091-Y/TABLES/3
  11. Martins AMB, Rodrigues JPC (2010) Fire resistance of reinforced concrete columns with elastically restrained thermal elongation. Journal of Engineering Structures 32:3330–3337
  12. Rodrigues JPC, Calmeiro dos Santos C, Pires TAC (2012) Fire resistance tests on concrete columns. In: 15th International Conference on Experimental Mechanics (ICEM15)
  13. Bikhiet MM, El-Shafey NF, El-Hashimy HM (2014) Behavior of reinforced concrete short columns exposed to fire. Alexandria Engineering Journal 53:643–653
  14. Ali F, Nadjai A, Choi S (2010) Numerical and experimental investigation of the behavior of high strength concrete columns in fire. Eng Struct 32:1236–1243
  15. Yang D, Liu F, Huang S, Yang H (2021) Fire performance of eccentrically loaded square and rectangular tube-reinforced-concrete columns. Structures 33:1053–1076
  16. Buch SH, Sharma UK (2019) Fire Resistance of Eccentrically Loaded Reinforced Concrete Columns. Fire Technol 55:1517–1552. https://doi.org/10.1007/S10694- 019-00823-X/FIGURES/19
  17. Yang D, Liu F, Huang S-S (2021) Structural behavior and design of end-restrained square tubedreinforced concrete columns exposed to fire. Journal of Constructional Steel Research2
  18. Huang X, Wu X, Usmani A, et al (2022) Perspectives of Using Artificial Intelligence in Building Fire Safety. Handbook of Cognitive and Autonomous Systems for Fire Resilient Infrastructures 139–159. https://doi.org/10.1007/978-3-030-98685-8_6
  19. Behaviour of Concrete Walls in Fire | First National Structural Engineering Conference 1987: Preprints of Papers. Accessed 21 Mar 2023
  20. How much fire resistance is really needed? - NRC Publications Archive - Canada.ca. https://nrcpublications.canada.ca/eng/view/object/?id=d5bfbc50-17ab4691-9e96-358aed14f1f2. Accessed 21 Mar 2023
  21. Naser MZ, Kodur VKR (2022) Explainable machine learning using real, synthetic and augmented fire tests to predict fire resistance and spalling of RC columns. Eng Struct 253:
  22. Naser MZ, Ciftcioglu AO (2023) Causal discovery and inference for evaluating fire resistance of structural members through causal learning and domain knowledge. Structural Concrete
  23. Ahmad A, Ostrowski KA, Maslak M, et al (2021) Comparative study of supervised machine learning algorithms for predicting the compressive strength of concrete at high temperature. Materials 14:
  24. Tanyildizi H, Sengur A, Akbulut Y, Sahin M (2020) Deep learning model for estimating the mechanical properties of concrete containing silica fume exposed to high temperatures. Frontiers of Structural and Civil Engineering 14:1316–1330
  25. He J, Huang X, Ning X, et al (2022) Modelling fire smoke dynamics in a stairwell of high-rise building: Effect of ambient pressure. Case Studies in Thermal Engineering 32:. https://doi.org/10.1016/J.CSITE.2022.101907
  26. Zhang T, Wang Z, Huang X, Xiao F (2021) Realtime flashover prediction in compartment fire via computer vision and AI. In: 12th Asia-Oceania Symposium on Fire Science and Technology (AOSFST 2021). University of Queensland Library
  27. Zeng Y, Zhang X, Su L, et al (2022) Artificial Intelligence tool for fire safety design (IFETool): Demonstration in large open spaces. Case Studies in Thermal Engineering 40:102483. https://doi.org/10.1016/j.csite.2022.102483
  28. Jiang L, Orabi MA, Jiang J, Usmani A (2021) Modelling concrete slabs subjected to fires using nonlinear layered shell elements and concrete damage-plasticity material. Eng Struct 234:. https://doi.org/10.1016/J.ENGSTRUCT.2021.111977
  29. Qiu J, Jiang L, Anwar Orabi M, et al (2022) A computational approach for modelling composite slabs in fire within OpenSees framework. Eng Struct 255:. https://doi.org/10.1016/J.ENGSTRUCT.2022.113909
  30. Panev Y, Kotsovinos P, Deeny S, Flint G (2021) The Use of Machine Learning for the Prediction of fire Resistance of Composite Shallow Floor Systems. Fire Technol 57:3079–3100. https://doi.org/10.1007/S10694- 021 01108-Y/FIGURES/19
  31. Chen C, Jiang L, Qiu J, et al (2022) OpenSees development for modelling timber structural members subjected to realistic fire impact. Fire Mater. https://doi.org/10.1002/FAM.3115
  32. Cai X, Jiang L, Qiu J, et al (2022) Dual-3D hybrid fire simulation for modelling steel structures in fire with column failure. J Constr Steel Res 197:. https://doi.org/10.1016/J.JCSR.2022.107511
  33. Khan MA, Jiang L, Cashell KA, Usmani A (2018) Analysis of restrained composite beams exposed to fire using a hybrid simulation approach. Eng Struct 172:956– 966. https://doi.org/10.1016/J.ENGSTRUCT.2018.06.048
  34. Naser MZ, Kodur V, Thai H-T, et al (2021) StructuresNet and FireNet: Benchmarking databases and machine learning algorithms in structural and fire engineering domains. Journal of Building Engineering 44:102977. https://doi.org/10.1016/j.jobe.2021.102977
  35. Naser MZ (2021) Observational Analysis of FireInduced Spalling of Concrete through Ensemble Machine Learning and Surrogate Modeling, J. Mater Civ Eng 33:. https://doi.org/10.1061/(ASCE)MT.1943-5533.0003525
  36. Smeden M van, Moons KG, Groot JA de, et al (2018) Sample size for binary logistic prediction models: Beyond events per variable criteria: https://doi.org/101177/0962280218784726 28:2455–2474. https://doi.org/10.1177/0962280218784726
  37. Riley RD, Snell KIE, Ensor J, et al (2019) Minimum sample size for developing a multivariable prediction model: PART II - binary and time-to-event outcomes. Stat Med. https://doi.org/10.1002/sim.7992
  38. Frank I, Todeschini R (1994) The data analysis handbook
  39. Altair Company (2023) RapidMiner Studio, Version 10.1 . https://academy.rapidminer.com/. Accessed 21 Mar 2023
  40. Cox DR (1959) The Regression Analysis of Binary Sequences, J. R. Stat. Soc. Ser. B
  41. Nelder JA, Wedderburn RWM (1972) Generalized Linear Models. J R Stat Soc Ser A 135:370. https://doi.org/10.2307/2344614
  42. LeCun Y, Bengio Y, Hinton G (2015) Deep learning.Nature 521:436–444. https://doi.org/10.1038/nature14539
  43. Freund Y, Schapire RE (1997) A DecisionTheoretic Generalization of On-Line Learning and an Application to Boosting. J Comput Syst Sci. https://doi.org/10.1006/jcss.1997.1504
  44. Çevik A, KURTOĞLU AE, Bilgehan M, et al (2015) Support vector machines in structural engineering: A review. Journal of Civil Engineering and Management 21:261–281. https://doi.org/10.3846/13923730.2015.1005021
  45. Naser MZ, Alavi AH (2021) Error Metrics and Performance Fitness Indicators for Artificial Intelligence and Machine Learning in Engineering and Sciences. Architecture, Structures and Construction 1:3. https://doi.org/10.1007/s44150-021-00015-8
  46. Tapeh ATG, Naser MZ (2022) Discovering Graphical Heuristics on Fire-Induced Spalling of Concrete Through Explainable Artificial Intelligence. Fire Technol 58:2871–2898. https://doi.org/10.1007/s10694-022-01290-7
  47. Arash Teymori Gharah Tapeh, Mohammad Khaled al-Bashiti, Alireza Ghasemi, et al (2022) A NOMOGRAM FOR PREDICTING FIRE-INDUCED SPALLING. SIF, Hong Kong

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