Modeling and Analysis of Progressive Ice Shedding along a Transmission Line during Thermal De‐Icing

Xie, Yunyun; Huang, Linyan; Wang, Shengfei; Ding, Huaiping; Yin, Xiaochun

doi:10.1155/2019/4851235

Cited by 8 publications

(5 citation statements)

References 24 publications

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“…According to different dance mechanisms, the dance mathematical models are divided into singledegree-of-freedom models, which only consider vertical vibration, two-degree-of-freedom models, which consider vertical and horizontal, and three-degree-of-freedom models, which consider vertical, horizontal and torsion. Each of the three models corresponds to a kind of dance mechanism, and at present, the three-degree-of-freedom model is widely used because it is closer to the field description, and the three-degree-of-freedom model simplifies the ice-covered conductor into a system with vertical, horizontal and torsional vibration at the same time [24][25].…”

Section: Mathematical Modeling Of Transmission Line Dancingmentioning

confidence: 99%

Research on transmission line dance monitoring and early warning system by fusing multi inertial sensors

An,

Wei,

Tang

et al. 2023

Applied Mathematics and Nonlinear Sciences

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This paper first analyzes the mechanism of transmission line dancing and constructs the mathematical model of transmission line dancing and the parameters of transmission line dancing. Then, a transmission line dancing monitoring and warning system is designed by integrating multiple inertial sensors, and the tower monitoring main splitter and wireless inertial monitoring and warning unit are designed, respectively. Then, the transmission line dancing trajectory was denoised using the wavelet threshold method, and the two-way inequality was determined by the attitude decomposition algorithm so as to design the transmission line dancing trajectory parameter identification algorithm. Finally, the designed system is tested experimentally, and the monitoring performance of the dance monitoring trajectory system is analyzed using collected data. The results show that the angular error of the sensor’s pitch and roll attitudes is within 0.5°, the angular error of the heading angle is within 1°, and the acceleration of the smoothed signal is in the range of -0.2/g~0.2/g. The relative error of amplitude recognition is up to 2.6 cm, and the frequency recognition basically agrees with the actual movement frequency, which is 0.21 Hz, and the error of the recognized frequency is within 0.03 Hz. Hz.

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Section: Mathematical Modeling Of Transmission Line Dancingmentioning

confidence: 99%

Research on transmission line dance monitoring and early warning system by fusing multi inertial sensors

An,

Wei,

Tang

et al. 2023

Applied Mathematics and Nonlinear Sciences

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“…In a study of amplitude characteristic analysis and ice-shedding restraining measures, based on the non-linear simulation model of a 3-DOF multi-level conductor insulator system independently developed by Tsinghua University, Wang et al [20] analyzed the dynamic mechanical ice-shedding characteristics of a 1000 kV ultra-high voltage (UHV) AC double-circuit transmission line on the same tower and proposed a scheme to suppress ice-shedding vibrations with phase-to-phase spacers. Xie et al [21] proposed a two-node isoparametric truss element finite element model to simulate the dynamic process of progressive ice-shedding (PIS), which can consider the mass variation of ice and dynamic force variation on the remaining ice. And the proposed method was validated through small-scale and full-scale experimental results, which showed it is more accurate than existing methods assuming constant ice-shedding speed.…”

Section: Introductionmentioning

confidence: 99%

Multiple Factors Coupling Probability Calculation Model of Transmission Line Ice-Shedding

Pan,

Zhou,

et al. 2024

Energies

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After a transmission line is covered by ice in winter, ice-shedding and vibration occurs under special meteorological and external dynamic conditions, which leads to intense transmission line shaking. Transmission line ice-shedding and vibration often cause line flashover trips and outages. In January 2018, three 500 kV transmission lines, namely, the 500 kV Guanli line, the 500 kV Dushan line, and the 500 kV Guanqiao line, tripped and cut off due to ice-shedding and vibration in Anhui province, seriously threatening the safe operation of a large power grid. Current studies mainly focus on analyzing the influence factors and characteristics of line ice-shedding and investigating suppression measures, but they only analyze the correlation between each influencing factor and icing or shedding, and do not consider the coupling effects between multiple factors. In this paper, the key influencing factors and the probability distribution of transmission line ice-shedding were analyzed, and a multiple-factor coupling fault probability calculation model of line ice-shedding based on Copula function was proposed. The fault probability was calculated directly by considering multiple influence factors at the same time, which effectively overcame the error caused by multi-factor transformation in fuzzy membership degree and other methods. It provided an important decision-making basis for preventing and controlling transmission line ice-shedding faults.

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“…François et al (2018) proposed a multi-rotor inspection robot, which can carry a payload (5 kg) and land semiautomatically on the power line (Eisenbeiss, 2009). Chang et al (2017) designed a hybrid model inspection robot (Xie et al, 2019). Compared with other PLIRs, hybrid PLIRs integrate a walking mechanism and a flying mechanism to quickly land on and off lines and cross obstacles.…”

Section: Introductionmentioning

confidence: 99%

A novel flying–walking power line inspection robot and stability analysis hanging on the line under wind loads

et al. 2022

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Abstract. To address the problems of existing power line inspection robots (PLIRs), such as complex structural design, difficult landing on and off lines, short cruise times, and easy hitting lines, we propose a novel flying–walking power line inspection robot (FPLIR) with the ability to fly and walk. The structural design of an FPLIR is carried out, which mainly includes a flying mechanism and a walking mechanism. Compared with climbing PLIRs and unmanned aerial vehicles (UAVs), the FPLIR can quickly land on and off lines, easily cross obstacles, and have longer cruise times and steady inspection perspectives. In addition, a directing-push pressing component is designed to improve the walking stability along the line. We also investigate the walking stability of the FPLIR on the line when encountering working conditions with crossing wind. The dynamics model of the FPLIR on the power line using the Lagrangian equation is derived to analyze walking stability caused by wind loads, considering pressing force and walking speed. An optimized regression design with three factors (wind angle, walking speed, and pressing force) and five levels was adopted to reveal the effect of these factors on the walking stability of the FPLIR. The experimental results show that wind angle and pressing force significantly influence the walking stability of the FPLIR (P<0.05). The maximum swing displacement of the center of mass (COM) is 4.7 cm (when wind angle, walking speed, and pressing force are 90∘, 7.2 m min−1, and 0, respectively). The maximum swing displacement of the COM is 2.5 cm when the pressing force increasing to 39.4 N is reduced by 46.2 % (when wind angle and walking speed are 90∘ and 5.1 m min−1, respectively), which effectively reduces the influence of wind loads and improves the stability of the FPLIR. The proposed FPLIR significantly improves inspection stability, providing a theoretical basis for slipping control, collecting images of intelligence inspection robots in the future.

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Modeling and Analysis of Progressive Ice Shedding along a Transmission Line during Thermal De‐Icing

Cited by 8 publications

References 24 publications

Research on transmission line dance monitoring and early warning system by fusing multi inertial sensors

Research on transmission line dance monitoring and early warning system by fusing multi inertial sensors

Multiple Factors Coupling Probability Calculation Model of Transmission Line Ice-Shedding

A novel flying–walking power line inspection robot and stability analysis hanging on the line under wind loads

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