Abstract
Aiming at the problem of nonlinear vibration of current-carrying iced conductors, the aerodynamic forces are introduced into the previous vibration equation of current-carrying conductors that only considered Ampere’s forces. At the same time, on this basis, a forced excitation load is further introduced to study the influence of dynamic wind on the nonlinear vibration characteristics of current-carrying iced conductors, and a new current-carrying iced conductors system under the combined action of Ampere’s forces, forced excitation, and aerodynamic forces has been established, and the improved theoretical modeling of current-carrying iced transmission lines made the model more in line with practical engineering. Firstly, the model of current-carrying iced conductors was established, and then the vibration equation of the model was derived. And the vibration equation was transformed into a finite dimensional ordinary differential equation by using the Galerkin method. The amplitude-frequency response functions of the nonlinear forced primary resonances and super-harmonic and subharmonic resonances of the system are derived by using the multiscale method. Through numerical calculation, the influence of current-carrying, spacing, wind velocity, tension, and excitation amplitude on the response amplitude when the primary resonance of the system appears is analyzed, and the difference between the two working conditions (considering the aerodynamic forces and without considering aerodynamic forces) is compared. The influence of the variation of current-carrying i on the response amplitude of super-harmonic and subharmonic resonances and the stability of the steady-state solution of forced primary resonance was analyzed. The results show that the response amplitude and the nonlinearilty of system under the action of aerodynamic forces are smaller and weaker than without the action of aerodynamic forces; the variation of line parameters has a certain influence on the response amplitude of conductor and the nonlinearity of system; the response amplitudes of the primary resonance, super-harmonic resonance, and subharmonic resonance increase with the increase in the excitation amplitudes, and the resonance peak is offset towards the negative value of the tuning parameter σ, showing the characteristics of soft spring, and the response amplitudes are accompanied by complex nonlinear dynamic behaviors such as the multivalue and jump phenomenon. The change of current-carrying i has an obvious effect on the nonlinearity of the system. The nonlinear and response amplitudes of the system are also enhanced with the increase in wind velocity. The stability of the system is judged when the primary resonance occurs, and it is found that the response amplitude shows synchronization and the out-of-step phenomenon with the change of tuning parameters. The research results obtained in this paper would help to further improve the theoretical modeling about current-carrying iced lines, and the research of line parameters can give a certain reference value to practical engineering, and it will have a positive effect on the safe operation of high-voltage transmission lines.
Highlights
High-voltage transmission lines are an important part of power facilities; its destruction will lead to great economic losses
With the increasing development of nonlinear dynamics, scholars have noticed that the transmission lines belong to the flexible cable structure because the span length of the transmission lines is much larger than the diameter of the transmission lines, and they would show obvious nonlinear behavior when they are affected by gravity and external forces [10]
A new current-carrying iced conductor system under the combined action of Ampere’s forces, forced excitation, and aerodynamic forces has been formulated, in which forced excitation was introduced to study the influence of dynamic wind on the nonlinear vibration characteristics of currentcarrying iced conductors. us, the theoretical model is improved, and a new self-excited Ampere’s force-forced system has been proposed. e theoretical solution is solved by the multiscale method and compared with the numerical solution
Summary
High-voltage transmission lines are an important part of power facilities; its destruction will lead to great economic losses. Erefore, on the basis of the above research results, this paper considers that in the actual wind field, when one current-carrying conductor in the bundle conductors is located in the electromagnetic field provided by two adjacent current-carrying conductors, it is modeled into a model composed of two long straight parallel conductors and the current-carrying conductor in the middle, and the influence of dynamic wind and Ampere’s force caused by current changes on the nonlinear vibration of the conductor is considered, forming a new mathematical model of currentcarrying iced conductors under the combined action of aerodynamic force-Ampere’s force-forced excitation, and the nonlinear vibration control equation is obtained, and the effects of several key parameters on the vibration characteristics of current-carrying conductors are analyzed by numerical examples, some valuable conclusions have been drawn, and it plays an active role in the safe operation of current-carrying conductors.
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