Dynamic Stiffness and Damping of Rigid Retaining Wall under Seismic Loading
الشريط الجانبي للمقالة
محتوى المقالة الرئيسي
الملخص
Dynamic stiffness and damping of the soil under the base of the foundation of the retaining wall and the backfill soil behind it play the main role in estimating vibrating displacement during seismic loading. The purpose of the present study is to investigate the effect of dimensionless frequency (ao) on the horizontal, vertical, and rocking dynamic stiffness and dynamic damping of rigid retaining walls. On the other hand, the effect of (ao) and height of the retaining wall on the stiffness and damping for backfill soil behind the rigid retaining wall was also investigated in the cases of active and passive dynamic sliding and dynamic rocking. The study demonstrated that the dynamic stiffness and damping of the soil under the base of the rigid retaining wall increased with the soil shear modulus. While the dynamic stiffness and damping of the backfill soil behind the retaining wall increased with the wall height. The percentage of increment generally varied between (42.1 – 113.2)% when the height of the retaining wall rose from (4 to 6) m. The maximum horizontal, rocking, and vertical dynamic stiffness of the soil under the base of the foundation of the retaining wall occurred at high, low, and intermediate values of (ao), respectively, i.e., at high, low, and intermediate values of angular frequencies (ω) for constant values of soil properties and retaining wall height. It can be also noted that the values of dynamic sliding damping and dynamic rocking damping of the backfill soil decreased and increased with increasing the (ao) or (ω), respectively. The percentages of decrement and increment were (37.5)% and (183.3)% when (ao) increased from (0.19 to 1.35), respectively.
المقاييس
تفاصيل المقالة
هذا العمل مرخص بموجب Creative Commons Attribution 4.0 International License.
THIS IS AN OPEN ACCESS ARTICLE UNDER THE CC BY LICENSE http://creativecommons.org/licenses/by/4.0/
##plugins.generic.plaudit.displayName##
المراجع
Xiaoyu G, Gopal SP. Numerical Modelling of Structures Adjacent Retaining Walls Subjected to Earthquake Loading. Geosciences 2020; 10(12):486.
Rafnsson EA, Prakash S. Stiffness and Damping Parameters for Dynamic Analysis of Retaining Wall. Second International Conference, St. Louis, Missouri, 1991 Mar 11-15; 1943-1951.
Yadav P, Singh DK, Dahale PP, Padade AH. Analysis of Retaining Wall in Static and Seismic Condition with Inclusion of Geofoam Using Plaxis 2D. Indian Geotechnical Conference, Bengaluru, India, 2018 Dec 13-15; 1-8.
Chowdhury I, Dasgupta SP. Earthquake Analysis and Design of Industrial Structures and Infra-structures. Cham, Switzerland: Springer; 2019.
Gazetas G. Formulas and Charts for Impedances of Surface and Embedded Foundation. Journal of Geotechnical Engineering 1991; 117(9):1363-1381.
Mita A, Luco JE. Impedance Functions and Input Motions for Embedded Square Foundations. Journal of Geotechnical Engineering 1989; 115(4):491-503.
Bertha O, Jose MJ, Guillermo M. Radiation Damping for Rigid Foundations: Approximate Expressions. Vibro Engineering Procedia 2019; 27:103-108.
Veletsos A. Lateral and Rocking Vibration of Footings. Journal of the Soil Mechanics and Foundations Division 1971; 97(9):1227-1248.
Veletsos A. Vibration of Viscoelastic Foundations. Earthquake Engineering and Structural Dynamics 1973; 2(1):87-102.
Dobry R, Gazetas G. Dynamic Response of Arbitrarily Shaped Foundation: Experimental Verification. Journal of Geotechnical Engineering 1986; 112(2):109-135.
Bowles JE. Foundation Analysis and Design. 5th ed. New York: McGraw-Hill Companies; 2001.
Gazetas G, Tassoulas JL. Horizontal Stiffness of Arbitrarily Shaped Embedded Foundation. Journal of Geotechnical Engineering 1987; 113(5): 440-457.
Gazetas G, Tassoulas JL. Horizontal Damping of Arbitrarily-Shaped Embedded Foundations. Journal of Geotechnical Engineering 1987; 113(5): 458-475.
Das BM, Ramana GV. Principles of Soil Dynamics. 3rd ed. USA: Engineering Publisher; 2017.
Nandakumaran P. Behavior of Retaining Wall Under Dynamic Loads. Ph.D. Thesis. Roorkee, India: Indian Institute of Technology Roorkee; 1973.
Burt GL. Handbook of Geotechnical Investigation and Design Tables and Franci. 2nd ed. London, UK: CRC Press; 2017.