بررسی عددی رفتار لرزه ای قاب مهاربندی با سیستم نوین دوسطحی ترکیب میراگرهای اتصال پیچی اصطکاکی و تیر پیوند برشی افقی

نوع مقاله : پژوهشی اصیل (کامل)

نویسندگان
علی محمد روستا 1
مهرداد درج 2
1 دانشگاه یاسوج/دانشکده مهندسی/ گروه عمران
2 دانشگاه یاسوج
10.22034/21.6.11
چکیده
در این مقاله، یک پیکربندی ابتکاری برای مهاربندی قاب­های فولادی با بکارگیری استهلاک ­کننده­های انرژی ارائه شده است. قاب مهاربندی دو سطحی پیشنهادی شامل میراگرهای اتصال پیچی شکاف­­دار (SBC) با عملکرد اصطکاکی و سیستم تیر پیوند برشی افقی (H-SPS) یا قاب مهاربندی واگرا (EBF) است که تحت عنوان قاب مهاربندی واگرا با لغزش کنترل شونده (CS+EBF) نامیده شد. سیستم SBC با حرکت اصطکاکی انتهای مهاربند در سوراخ لوبیایی و سیستم H-SPS با تسلیم برشی می­توانند به ترتیب در سطوح پایین و متوسط تا شدید زلزله استهلاک انرژی کنند و مانع از کمانش عضو مهاربندی یا به تعویق انداختن آن شوند. فیوز SBC به عنوان فیوز کمکی در این سیستم دو سطحی در نظر گرفته شده است تا در زلزله­های خفیف مانع از وارد عمل شدن فیوز اصلی شود. همچنین فیوز SBC بر خلاف فیوزهای تسلیمی بعد از زلزله نیاز به تعوبض ندارد و با اعمال پیش تنیدگی مجدد درپیچ­های اتصال ترمیم می­شود که این ویژگی سبب متمایز شدن سیستم دوسطحی پیشنهادی با سایر سیستم­های مشابه شده است. جهت بررسی رفتار این سیستم، مطالعات عددی با نرم افزار کاربردیABAQUS انجام شده است. مدل­ها با مقیاس 1 به 2 و با المان­های محیط پیوسته سه بعدی (Solid) جهت دستیابی به نتایج دقیق، مدل سازی شده­اند. نتایج بدست آمده در این بررسی حاکی از این است که سیستم دو سطحی قابلیت اتلاف انرژی بیشتری نسبت به سیستم­های تک­ سطحی مشابه داشته و همچنین نشان می­دهد که با افزایش ضخامت جان تیر پیوند برشی، استهلاک انرژی و مقاومت نهایی قاب مهاربندی افزایش یافته است. اتلاف انرژی پیکربندی پیشنهادی نسبت به سیستم­های تک­ سطحیSCBF و EBF به ترتیب 88 درصد و 33 درصد بیشتر شده است و سهم اتلاف انرژی فیوز اول (SBC) و فیوز دوم (H-SPS) به ترتیب برابر با 33 درصد و 30 درصد از کل انرژی استهلاک شده توسط قاب مهاربندی CS+EBF2 می ­باشد.

کلیدواژه‌ها

موضوعات

عنوان مقاله English

Numerical investigation of seismic behavior system of braced frame with innovative two level dampers system: Friction slotted bolt connection and Horizontal Shear panel

نویسنده English

Ali mohammad Rousta 1
1 Yasouj Uni./ Faculty of Civil Eng./ Dept. of Civil Eng.
چکیده English

Structural vibration control has become a controversial topic among researchers today.In recent years passive dampers have been proposed as an effective and reliable method against these vibrations. In this paper, an innovative configuration for steel braced frames using energy dissipaters is presented. The proposed bracing system includes two-level slotted bolted connection (SBC) dampers with slipping performance and a horizontal shear panel system (H-SPS) or eccentrically braced frames (EBF) which is called CS+EBF.The proposed model consists of four structural parts, including horizontal shear link beam, beam, bracing and columns, which other structural components were designed based on the shear capacity of horizontal shear link beam. The brace provides the rigidity of the frame and remains elastic until the end of the loading, like columns and beam. The SBC fuse with frictional movement of the end of the brace in the slot hole and the H-SPS fuse with shear yield can dissipate energy at low, medium and severe earthquake levels, respectively, and prevent or delaying the bracing member from buckling. Past experience has shown that dampers designed for an earthquake energy level also start working in low level earthquakes than that level, which has hampered the ability of these dampers to dissipate energy in more severe earthquakes. Therefore, the SBC fuse is considered as an auxiliary fuse in this innovative two-level system to prevent the main fuse from operating in mild earthquakes. Also, the SBC fuse, unlike the yielding fuses after the earthquake, does not need to be replaced and is repaired by applying prestressed load to the connection screws, which distinguishes the proposed two-level system from other similar systems. The samples are modeled with 1/2 scale and solid elements to achieve accurate results.

The proposed configuration and other similar samples, in addition to push over loading, were also subjected to cyclic SAC loading protocol to compare the behavior of the proposed sample and other samples properly. The results obtained in this study indicate that in the push over analysis, in addition to maintaining the strength and stiffness of the proposed sample (CS+EBF), the ductility of this sample compared to other similar single-level systems, SCBF and EBF has increased. In addition based on cyclic loading, it was found that two-level proposed system has more ductility and energy dissipation than similar single- level systems and also shows that with increasing shear thickness of shear panel beam, energy dissipation and final strength of braced frame increases. The energy dissipation of the proposed configuration is 88% and 33% higher than that of SCBF and EBF single-level systems, respectively, and the share of energy dissipation of the first fuse (SBC) and second fuse (H-SPS) is 33% and 30% of the total energy dissipated by the CS+EBF2 braced frame respectively.

کلیدواژه‌ها English

frictional bolt connection
two-level system
horizontal shearing link beam
shear yielding
Energy Dissipation
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مهندسی عمران مدرس
دوره 21، شماره 6
آذر و دی 1400
صفحه 143-156