SEISMIC RESPONSE OF FRAME BUILDINGS WITH COMBINED EARTHQUAKE PROTECTION SYSTEM

• Main Authors: Abakar J. Abakarov, Khadzhimurad M. Omarov
• Format: Article
• Language: Russian
• Published: Daghestan State Technical University 2017-07-01
• Series: Vestnik Dagestanskogo Gosudarstvennogo Tehničeskogo Universiteta: Tehničeskie Nauki
• Subjects: seismic actions; frame buildings; rubber-metallic seismic insulating supports; elements of dry friction; shutdown elements; horizontal shearing seismic forces; maximum mass movements; maximum movements of rubber-metallic seismic insulating supports
• Online Access: https://vestnik.dgtu.ru/jour/article/view/373
• ISSN: 2073-6185; 2542-095X

Abstract. Objectives The aim of the study is to search for methods to improve the efficiency of the earthquake protection systems with rubber-metallic seismic insulating supports by combining them with dry friction and brittle uncoupling elements. Method The research is based on dynamic modelling methods. Results The computational dynamic model of the combined earthquake protection system and the system of differential equations of the seismic motion of a five-story frame building were compiled and an algorithm for estimating the efficiency and selection of the optimum parameters of the earthquake protection system was developed. Horizontal shifting seismic forces, maximum mass movements and maximum movements of rubber-metallic seismic insulating supports at different intensities and prevailing periods of seismic soil oscillations were determined. It is shown that, by using a combined earthquake protection system, seismic loads on frame buildings can be reduced by a factor of 1.5-2 and maximum mass movements – by 4-5 times. In addition, the area of rational application of seismic isolation systems with rubber-metallic supports in relation to the prevailing periods of seismic ground oscillations is expanding substantially. Conclusion The combined earthquake protection system allows the area of effective use of rubber-metallic supports to be expanded by increasing the range of possible prevailing periods of seismic soil vibrations at which the maximum movement of the top of the rubber-metallic supports does not exceed the maximum allowable value. The maximum residual movements of rubber-metallic supports can be reduced by using a lead core.