اثر تغییرات مکانی جنبش شدید زمین و نوع ساختگاه بر عملکرد لرزه‌ای پل‌های بتنی با ارتفاع پایه متغیر

نوع مقاله : پژوهشی اصیل (کامل)

نویسندگان
داریوش درویش پور
غلامرضا نوری
دانشکده فنی و مهندسی، دانشگاه خوارزمی
چکیده
در نظر گرفتن تغییرات مکانی حرکات زمین در طراحی سازه‌ها و پل‌های طویل بسیار حائز اهمیت است. در این مقاله اثر تغییرات مکانی جنبش شدید زمین و تغییر شرایط ساختگاهی بر پاسخ لرزه‌ای پل‌های بتنی با ارتفاع پایه متغیر مطالعه شده است. برای تولید شتابنگاشت‌های غیریکنواخت حرکت زمین از الگوریتم شبیه‌سازی‌شده مبتنی بر طیف طرح با توابع فرآیند تصادفی چند متغیره ناایستا و ماتریس چگالی طیفی استفاده شده است. تولید شتابنگاشت‌ها با تابع همدوسی شامل اثر انتشار موج و مدت زمان زمین‌لرزه که سازگار با طیف پاسخ منتخب باشد، انجام شد. پاسخ‌های لرزه‌ای پل 5 دهانه به طول 5/242 متر تحت اثر تحریک یکنواخت و غیریکنواخت با تحلیل دینامیکی تاریخچه زمانی غیرخطی در برنامه OpenSess مورد بررسی قرار‌گرفت. اثر تغییر شرایط ساختگاهی با فرض تغییر نوع خاک و سرعت ظاهری موج در زیر پایه‌های مختلف پل لحاظ گردید. تغییرات نیروی محوری، نیروی برشی و لنگر خمشی در پایه‌های پل در حالت‌های مختلف به عنوان معیار مقایسه مطالعه شد. نتایج نشان داد، همزمانی تغییرات مکانی و تغییر شرایط ساختگاهی باعث افزایش قابل توجه در پاسخ‌های پل می‌شود، بطوریکه در این حالت حداکثر لنگر خمشی پایه پل تا حدود 2.5 برابر نیز می‌تواند افزایش یابد. همچنین مقایسه نتایج در دو حالت تحریک یکنواخت و غیریکنواخت بیانگر این است که حتی در شرایط ساختگاهی یکسان، خصوصیات تغییرات مکانی حرکات زمین‌لرزه می‌تواند به‌شدت پاسخ پل را تغییر دهد.

کلیدواژه‌ها

موضوعات

عنوان مقاله English

Seismic Response of non-uniform Column Heights Bridge under Spatial Variation of Ground Motion and Local Soil Condition

نویسندگان English

Darush Darvishpour
Gholamreza Nouri
Faculty of Engineering, Kharazmi University
چکیده English

It is vital to consider the spatial variations of ground motions in the design of extended structures and long bridges. In this paper, the effect of spatial variations of ground motions and local site conditions on the response of non-uniform column heights bridge is studied. To generate non-uniform accelerometers of ground motion, a simulated algorithm based on the spectrum design with unstable multivariate random process functions and a spectral density matrix is used. Accelerometers were generated with a coherence function including the effect of wave propagation and the duration of the earthquake that is consistent with the selected response spectrum. In addition, the simulation is performed in 800 time intervals with a time step of 0.025 seconds. The maximum ground acceleration is assumed 0.35 g. The response of the bridge with a length of about 242 m with 5 spans under the effect of uniform and non-uniform accelerometers was investigated by nonlinear time history analysis in OpenSees program. The local site effect was assumed by changing soil type (soil under the two piers is softer than the other piers) and apparent wave velocity under different bridge piers. The apparent velocity of the wave propagation of the soft soil assumed 1000 m/s and for the hard soil 2000 m/s. To verify the acceleration of the generated accelerograms, the generated spectrum is compared with the Eurocode design spectrum, and to validate the analysis performed on the bridge, the ratio of M/ calculated and compared with ratio that calculated by Shinozaka and Deodatis. In this paper variations of axial force, shear force and bending moments in bridge piers in different positions were studied as comparison criteria. The results showed that the simultaneity of spatial variations of ground motions and changes in the soil conditions causes a significant increase in the bridge response. Comparison of the results in the two input cases of uniform and non-uniform spatial variations of ground motions shows that the properties of spatial variations of earthquake motions can affect the response of the bridge. The results are compared based on the ratio of the maximum stress created at the base in the non-uniform excitation state to the maximum created in the uniform excitation state or the ratio of the maximum stress created at the base in the variable soil to the same soil. Based on the presented results, it was observed that the maximum bending moments in variable soil conditions can be increased to about 2.5 times to the maximum created in the same soil condition in the piers and also the maximum axial force created in the two shorter piers in the non-uniform excitation state is up to 2 times larger than in the uniform excitation state, and if the effect of different soils is applied to the two middle piers, the axial force in the middle two piers can be increased up to 3 times. Based on the obtained results, it is observed that the maximum shear force created in the direction of the transverse axis in the two middle piers occurred in a situation where non-uniform excitation coincides with the change of soil conditions under the piers and the bending moment in the direction of the transverse axis in the piers in this case has increased up to 120%.

کلیدواژه‌ها English

long bridge
spatial variations
site effect
spectral based simulation
uniform and non-uniform simulation
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مهندسی عمران مدرس
دوره 21، شماره 5
مهر و آبان 1400
صفحه 119-131