MODERN CONSTRUCTION SOLUTIONS FOR PRESTRESSED CABLE DOMES AND WAYS TO IMPROVE THEM
DOI:
https://doi.org/10.31650/2707-3068-2021-25-56-64Abstract
To create fundamentally new innovative large-span structures of buildings and
structures coverings, modern design solutions of prestressed cable domes of the Tensegrity type are
considered. The service life of the first built Tensigrity domes is only 35 years. These are fairly new,
effective structures that require careful study and use of modern scientific approaches for their design
using software systems, since their work under load and the construction process are quite complex.
The design analysis and erection of self-stressed structures is based on the invention of an equilibrium
structure, the so-called tensegrity form. The search for the shape is multidimensional and consists of
the stage of computational analysis of a self-stressed dome for the equilibrium position of elements
and their nodes, selection of the most stable and rigid structure, as well as taking into account possible
unfavorable loads during operation and the initial load in the elements from the application of
prestressing. To determine the shape of cable domes, a nonlinear programming problem with given
axial forces is formulated, which can be considered as the problem of minimizing the difference in
the total strain energy between the elements of the cables and struts under constraints on the
compatibility conditions. The first step in calculating the prestressing of a cable dome is to assess the
feasibility of its geometry. The possibility of forming a cable dome of negative Gaussian curvature is
considered and a method for calculating the prestressing for this new shape is investigated. The
proposed method is effective and accurate in determining the allowable prestressing for a cable dome
with negative Gaussian curvature and can be used for other types of prestressed structures. The new
directions for the development of effective constructive solutions for large-span coatings are
presented, including a suspended-dome structure, which combines the advantages of a mesh shell and
a cable dome. Special attention should be paid to experimental studies on models of tensegrity domes,
the results of which demonstrate the positive and negative aspects of the behavior of structures under
load, the process of their erection, as well as the possibility of control and restoration during operation.




