Abstract
A steel-batten ribbed cable dome structural system is proposed. By replacing the upper flexible cables with semi-rigid steel battens, rigid roofing materials were conveniently installed overhead via non-bracket or less-bracket technology. Additionally, an 8 m diameter test model was designed, and a ‘ω’ shaped less-bracket consequent hoist-dragging system was adopted. Finally, the test model was tested under symmetric and asymmetric uniform loading arrangements, while a finite element model was established to verify the test values. The results indicate that the measured values are basically consistent with the finite element values. In the early steps of hoisting and dragging, the structure establishes a prestress, accumulates stiffness, and found its internal force balance, while the entire structure keeps a “ω” shape to guarantee stability. As the internal forces of the components increase, the structure turns from “ω” to “m” and finally reached its designed shape. With increasing symmetric uniform load, the internal forces of the cables decrease, the bending stresses of the steel battens increase, and the steel battens remain in the elastic stage. Under an asymmetric uniform load, the high loaded area is displaced downward, and the low loaded area behaves upward, twisting the overall structure.
Highlights
Due to their excellent spanning ability and low weight, and clear transmission path, cable domes [1] have been extensively studied and used in various engineering projects, such as stadiums [2,3], airports, and exhibition centers [4]
The internal forces of the components obtained by the test and finite element simulation under a symmetric uniform load are illustrated in Figure 22, the average stresses of the steel battens are presented in Figure 23, and the displacement results are shown in
The sandbags were removed from the steel battens, while the forces of cables and struts were modulated afterwards until the entire structure basically recovers the initial prestress state before the symmetric uniform loading test
Summary
Due to their excellent spanning ability and low weight, and clear transmission path, cable domes [1] have been extensively studied and used in various engineering projects, such as stadiums [2,3], airports, and exhibition centers [4]. Relatively clearer force transmission path makes ribbed cable dome more popular. Roofing materials of large-span structures mainly contains two types: flexible materials and rigid materials. To make the appearance light and concise, the distance between adjacent ridge cables of a cable dome is always designed to be large, which is a large challenge to the spanning ability of roofing plates. The current domestic climate and environmental conditions impose higher durability and self-cleaning requirements on membrane materials, which make the construction and maintenance costs
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