Evaluation of flow-induced vibration suppression performances of magneto-rheological damping pipe clamp using PID algorithm

Hong, Ruidong; Nie, Songlin; Ji, Hui; Nie, S.; Gong, Fei

doi:10.1177/1045389x221142087

Cited by 4 publications

(1 citation statement)

References 13 publications

(13 reference statements)

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“…Considering the influence of low-frequency vibrations on a pipeline, Hong et al adopted a PID controller to reduce the vibration of the system. Proportional-integral-derivative control has a better effect than uncontrolled or passive controls [14]. Gulbahce designed a tuner-based PID controller to control intelligent beams.…”

Section: Introductionmentioning

confidence: 99%

System Identification and Fractional-Order Proportional–Integral–Derivative Control of a Distributed Piping System

Zhang,

Xiong

et al. 2024

Fractal Fract

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The vibration of piping systems is one of the most important causes of accelerated equipment wear and reduced work efficiency and safety. In this study, an active vibration control method based on a fractional-order proportional–integral–derivative (PID) controller was proposed to suppress pipeline vibration and reduce pipeline damage. First, a mathematical model of the distributed piping system was established using the finite element analysis method, and the characteristics of the distributed piping system were studied effectively. Further, the time-frequency domain parameter identification method was used to realise the system identification of the cross-point vibration transfer function between the brake and sensor, and the particle swarm optimisation algorithm was utilised to further optimise the transfer function parameters to improve the system identification accuracy. Therefore, a fractional-order PID controller was designed using the D-decomposition method, and the optimal controller parameters were obtained. The experimental and numerical simulation results show that the improved system identification algorithm can significantly improve modelling accuracy. In addition, the designed fractional-order PID controller can effectively reduce the system’s overshoot, oscillation time, and adjustment time, thereby reducing the vibration response of piping systems.

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Section: Introductionmentioning

confidence: 99%

System Identification and Fractional-Order Proportional–Integral–Derivative Control of a Distributed Piping System

Zhang,

Xiong

et al. 2024

Fractal Fract

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Vibration control of fluid-conveying pipes: a state-of-the-art review

Ding,

2023

Appl. Math. Mech.-Engl. Ed.

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Fluid-conveying pipes are widely used to transfer bulk fluids from one point to another in many engineering applications. They are subject to various excitations from the conveying fluids, the supporting structures, and the working environment, and thus are prone to vibrations such as flow-induced vibrations and acoustic-induced vibrations. Vibrations can generate variable dynamic stress and large deformation on fluid-conveying pipes, leading to vibration-induced fatigue and damage on the pipes, or even leading to failure of the entire piping system and catastrophic accidents. Therefore, the vibration control of fluid-conveying pipes is essential to ensure the integrity and safety of pipeline systems, and has attracted considerable attention from both researchers and engineers. The present paper aims to provide an extensive review of the state-of-the-art research on the vibration control of fluid-conveying pipes. The vibration analysis of fluid-conveying pipes is briefly discussed to show some key issues involved in the vibration analysis. Then, the research progress on the vibration control of fluid-conveying pipes is reviewed from four aspects in terms of passive control, active vibration control, semi-active vibration control, and structural optimization design for vibration reduction. Furthermore, the main results of existing research on the vibration control of fluid-conveying pipes are summarized, and future promising research directions are recommended to address the current research gaps. This paper contributes to the understanding of vibration control of fluid-conveying pipes, and will help the research work on the vibration control of fluid-conveying pipes attract more attention.

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Bandgap accuracy and characteristics of fluid-filled periodic pipelines utilizing precise parameters transfer matrix method

Li,

Kong,

et al. 2024

Journal of Fluids and Structures

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Evaluation of flow-induced vibration suppression performances of magneto-rheological damping pipe clamp using PID algorithm

Cited by 4 publications

References 13 publications

System Identification and Fractional-Order Proportional–Integral–Derivative Control of a Distributed Piping System

System Identification and Fractional-Order Proportional–Integral–Derivative Control of a Distributed Piping System

Vibration control of fluid-conveying pipes: a state-of-the-art review

Bandgap accuracy and characteristics of fluid-filled periodic pipelines utilizing precise parameters transfer matrix method

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