پیش‌بینی ظرفیت باربری باقی‌مانده ستون‌های کوتاه CFST پس از قرارگیری در معرض دماهای بالا به کمک الگوریتم برنامه‌نویسی بیان ژنی

نوع مقاله : پژوهشی اصیل (کامل)

نویسندگان
حسن ثابتی فر
مهدی نعمت زاده
دانشگاه مازندران
DOI: 10.22034/22.2.18
چکیده
مقاطع لوله فولادی پرشده از بتن (CFST) گونه‌ای از مقاطع مرکب می‌باشند که بیشتر در ساختمان‌های بلندمرتبه مورد استفاده قرار می‌گیرند. رفتار مقاطع CFST در حرارت‌های بالا، به‌دلیل اندرکنش میان لوله فولادی و هسته بتنی پیچیده می‌باشد. از این رو درک صحیح رفتار و همچنین خصوصیات مصالح در ستون‌های CFST به‌منظور مقاصد طراحی و مقاوم‌سازی ضروری می‌باشد. در این پژوهش به‌کمک تکنیک برنامه‌نویسی بیان ژنی (GEP) رابطه‌ای برای پیش‌بینی ظرفیت باربری باقی‌مانده ستون‌های CFST پس از قرارگیری در معرض حرارت‌های بالا ارائه شده است. به این منظور، از نتایج آزمایشگاهی مربوط به 94 گروه نمونه ستون کوتاه CFST بهره گرفته شد. پارامتر‌های ورودی شامل مقاومت فشاری هسته بتنی ( )، مساحت هسته بتنی ( )، تنش تسلیم فولاد ( )، مساحت مقطع لوله فولادی ( )، دمای نرمال‌شده ( ) و شاخص محصورشدگی ( ) بودند. به‌منظور اطمینان از پیش‌بینی صحیح ظرفیت باربری نهایی ستون‌های کوتاه CFST توسط مدل ارائه شده، آنالیز حساسیت و مطالعات پارمتری روی مدل صورت گرفت که نشان از تطابق کامل مدل با واقعیت‌های فیزیکی داشت. عملکرد مدل ارائه شده توسط معیارهای ارزیابی آماری از جمله جذر میانگین مجذور خطا (RMSE)، میانگین خطای مطلق (MAE)، مربعات خطای نسبی (RSE) مورد بررسی قرار گرفت که این مقادیر به‌ترتیب برابر 19/114، 71/82 و 11/0 بود. بیشترین مشارکت نسبی به‌ترتیب متعلق به پارامترهای شاخص محصورشدگی ( )، مقاومت فشاری هسته بتنی ( )، مساحت سطح مقطع بتنی ( )، دمای نرمال‌شده ( )، تنش تسلیم لوله فولادی ( ) و مساحت مقطع لوله فولادی ( ) با 84/23، 41/18، 78/16، 03/16، 80/15 و 14/9 درصد بود.

کلیدواژه‌ها

موضوعات

عنوان مقاله English

Estimating of residual load-carrying capacity of CFST stub columns after exposure to elevated temperatures using gene expression programming

نویسندگان English

Hassan Sabetifar
Mahdi Nematzadeh
University if Mazandaran
چکیده English

Nowadays, the use of composite sections has become a common practice in the construction industry. Concrete is inherently a brittle material, with high stiffness and compressive strength. On the other hand, steel is a material with high tensile strength and ductility. The simultaneous use of steel and concrete in composite sections improves the performance and leads to optimum exploitation of the properties of both steel and concrete materials. Concrete-filled steel tube (CFST) is a type of section often used in high-rise buildings. In addition, the composite action of steel and concrete in CFST columns gives some advantages to these sections during fire incidents. On the one hand, the concrete core prevents the local buckling of the steel tube, and on the other, the steel tube prevents the spalling of concrete at elevated temperatures. The behavior of CFST sections at elevated temperatures is complicated due to interactions between the steel tube and concrete core. Therefore, achieving a correct understanding of the behavior and material properties in CFST columns is required for design and strengthening purposes.




In this research, with the help of the gene expression programming (GEP) technique, a formula was developed to estimate the ultimate load-carrying capacity of CFST columns after exposure to elevated temperatures. To that end, the experimental data of 94 groups of CFST stub columns were employed, of which 80% were used to train the model and the remaining 20% to validate the model. Input variables included the compressive strength of the concrete core ( ), cross-sectional area of the concrete core ( ), yielding stress of steel ( ), cross-sectional area of steel tube ( ), normalized temperature ( ), and the confinement index ( ). The validity of the developed model was assessed using a portion of the data that had not been employed in the training phase. To ensure the correct prediction of the ultimate load-carrying capacity of CFST stub columns by the developed model, a sensitivity analysis and parametric studies were conducted on the model and revealed the complete compatibility of the model with physical facts. The results of this research indicate that increasing the compressive strength of the concrete core, cross-sectional area of the steel tube, yield stress of steel tube, cross-sectional area of the concrete core and the confinement index increases the ultimate load-carrying capacity of the CFST section, while increasing the exposure temperature lowers this parameter.

کلیدواژه‌ها English

CFST stub columns
Gene Expression Programming
Sensitivity Analysis
Parametric study
Residual load-bearing capacity
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مهندسی عمران مدرس
دوره 22، شماره 2
خرداد و تیر 1401
صفحه 273-287