Abstract
As a new type of composite bridge, the dynamic structural characteristics of a tensioned string bridge need to be deeply studied. In this paper, based on the structural characteristics of a tensioned string bridge, the Rayleigh method is used to derive formulas for calculating the frequencies of vertical, antisymmetric and lateral bending vibrations. The characteristics of the vertical and lateral bending vibration frequencies are summarized. The fundamental frequencies of the antisymmetric vertical bending and lateral bending of the tensioned string bridge are the same as that of the single-span beam under the corresponding constraint conditions. The shape and physical characteristics of the main cable have no effect on the frequency. The vertical bending symmetrical vibration frequency of the tensioned string bridge is greater than the corresponding symmetrical vibration frequency of the simply supported beam. The shape and physical characteristics of the main cable have a greater impact on the vertical bending symmetrical vibration frequency than the lateral bending frequency, and the vertical bending symmetrical vibration frequency increases with an increasing rise-to-span ratio. The tension force of the main cable has no influence on the frequency of tensioned string bridges. The first-order frequency of the tensioned string bridge is generally the vertical bending symmetrical vibration frequency. By adopting a tensioned string bridge structure, the fundamental frequency of a structure can be greatly increased, thereby increasing the overall rigidity of the structure. Finally, an engineering example is applied with the finite element parameter analysis method to study the vibration frequency characteristics of the tensioned string bridge, which verifies the correctness of the formula derived in this paper. The finite element analysis results show that the errors between the derived formula in this paper and the finite element calculation results are less than 2%, indicating that the formula derived in this paper has high calculation accuracy and can meet the calculation accuracy requirements of engineering applications.
Highlights
As a newly developed beam and cable combination structure system, beam string structures have been investigated during the past 20 years
Jiang [29] established a nonlinear dynamic finite element model of a long-span string beam structure based on engineering examples, analyzed the natural vibration characteristics of the string beam structure and discussed the distribution laws of various frequencies and corresponding modes
Based on the finite element parameter analysis of an engineering example, the analysis results show that the main cable force has no influence on the vibration frequency
Summary
As a newly developed beam and cable combination structure system, beam string structures have been investigated during the past 20 years. Based on the parameter analysis method, Wang Xiuli et al [26] determined the natural vibration law and the influence of the rise-span ratio, vertical-span ratio, number of struts and other parameters on the natural vibration characteristics of a string beam structure He Yongjun et al [27] analyzed the order of appearance of the first-order vibration modes and the corresponding natural vibration period of a tensioned giant grid structure. Jiang [29] established a nonlinear dynamic finite element model of a long-span string beam structure based on engineering examples, analyzed the natural vibration characteristics of the string beam structure and discussed the distribution laws of various frequencies and corresponding modes. Based on parameter analysis methods, Shi [30] investigated the influence of prestress, number of struts, cable cross-sectional area and restraint conditions on the natural vibration characteristics of long-span string truss structures. In this paper, based on the existing literature [31], the Rayleigh method is applied to study the simplified calculation formula of the fundamental frequency of a tensioned string bridge, and the corresponding frequency characteristics are analyzed to provide a preliminary design calculation basis for the dynamic calculation of a tensioned string bridge
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