Modeling and Analysis of Pipe External Surface Grinding Force using Cup-shaped Wire Brush

2023 IEEE International Conference on Robotics and Biomimetics (ROBIO) Pub Date : 2023-12-04 DOI:10.1109/ROBIO58561.2023.10354945

Dongying Shao, Mingyuan Wang, Liang Du, Sheng Bao, Zhengtao Hu, Longchuan Li, Jianjun Yuan

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Abstract

Grinding the pipe external surface using cup-shaped wire brushes is a widely adopted approach in pipeline maintenance. To achieve automated grinding of the external pipe, it is crucial to establish a grinding force model and explore the grinding mechanism accordingly. In this study, based on the characteristics of cup-shaped wire brushes, a controllable and efficient approach for grinding the pipe external surface is proposed. An experimental platform is constructed to simulate the grinding process and measure real-time pipeline grinding forces using a six-axis force sensor. The influence of different grinding parameters on the grinding forces on the curved surface of the pipe is investigated via parameter study. Furthermore, based on a single abrasive grain grinding force model, a predictive model for investigating grinding forces on the pipe external surface using is developed, where the fitted grinding force model obtained from the experimental data is taken into account.

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使用杯形钢丝刷的管道外表面磨削力建模与分析

使用杯状钢丝刷打磨管道外表面是管道维护中广泛采用的一种方法。要实现管道外表面的自动化打磨，建立打磨力模型并探索相应的打磨机理至关重要。本研究根据杯形丝刷的特性，提出了一种可控、高效的管道外表面打磨方法。构建了一个实验平台来模拟磨削过程，并使用六轴力传感器实时测量管道磨削力。通过参数研究，探讨了不同磨削参数对管道曲面磨削力的影响。此外，在单磨粒磨削力模型的基础上，开发了一个用于研究管道外表面磨削力的预测模型，其中考虑了从实验数据中获得的拟合磨削力模型。

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来源期刊

2023 IEEE International Conference on Robotics and Biomimetics (ROBIO)

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