Abstract
This paper presents the refined technique of dynamic calculations for suspension earthquake-resistant building. The improved design schemes of suspension buildings and structures have been demonstrated. Two versions of suspension buildings have been analysed. For the system with the building as a point mass suspension on the fixed bearing frame thread, a system of Lagrange differential equations of the second kind has been derived. For the building presented as a rigid rod with the length equal to its height, also suspended on the supporting frame, the solution is performed using principles of dynamic calculations and methods of theoretical mechanics. It has been demonstrated, that the horizontal force in the suspension building is ten times less than the force in a traditional cantilever building, and that for the real horizontal stiffness of the supporting frame the dynamic strains are far from resonant values. The possibility of adjusting dynamic forces by regulating the stiffness of the supporting frame, length of the thread of suspension and other parameters. The proposed calculation schemes are useful for the preliminary calculations, and the finite design of the suspension building can be performed in modern software packages (e.g., Ansys, Abacus, etc.).
Highlights
The most dangerous component of the acting forces during an earthquake is the horizontal component
An analysis of the proposed suspension buildings has been conducted in this paper
The benefits of suspension buildings have been demonstrated in comparison to the traditional cantilever buildings
Summary
The most dangerous component of the acting forces during an earthquake is the horizontal component. Horizontal seismic forces on each floor are known to be equal to the product of the mass and acceleration of the ground vibration. Due to the unusual suspension of the building, its design features, as well as the approach to calculation of strength and deformability, must be subjected to careful examination and justification. Advantages of such a construction are obvious, but the technique for the calculation of dynamic strains requires improvement. The purpose of this paper is to improve the dynamic design scheme of suspension building in order to refine the calculated dynamic strains
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