Movement and binding control strategy based on a new type of rebar-binding robot

Dong Huan Shen, Shuai Guo, Hao Duan, Kehao Ji, Haili Jiang
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Abstract

Purpose

The paper focuses on the issue of manual rebar-binding tasks in the construction industry, which are marked by high labor intensity, high costs and inefficient operations. The rebar-binding robots that are currently available are not fully mature. Most of them can only bind one or two nodes in one position, which leads to significant time wastage in movement. Based on a new type of rebar-binding robot, this paper aims to propose a new movement and binding control that reduces manpower and enhances efficiency.

Design/methodology/approach

The robot is combined with photoelectric sensors, travel switches and other sensors. It is supposed to move accurately and run in a limited area on the rebar mesh through logical judgment, speed control and position control. Machine vision is used by the robot to locate the rebar nodes and then adjusts the binding-gun position to ensure that multiple rebar nodes are bound sequentially.

Findings

By moving on the rebar mesh with accuracy, the robot meets the positioning accuracy requirements of the binding module, with experimental testing accuracy within 5 mm. Furthermore, its ability to bind four rebar nodes in one place results in a high efficiency and a binding effect that meets building standards.

Originality/value

The innovative design of the robot can adapt itself to the rebar mesh, move accurately to the target position and bind four nodes at that position, which reduces the number of movements on the mesh. Repetitive and heavy rebar-binding tasks can be efficiently completed by the robot, which saves human resources, reduces worker labor intensity and reduces construction overhead. It provides a more feasible and practical solution for using robots to bind rebar nodes.

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基于新型钢筋绑扎机器人的运动和绑扎控制策略
目的 本文重点讨论建筑行业中人工绑扎钢筋的问题,这些工作的特点是劳动强度大、成本高、操作效率低。目前市面上的钢筋绑扎机器人尚未完全成熟。它们大多只能在一个位置上绑扎一个或两个节点,导致在移动过程中浪费大量时间。本文以一种新型钢筋绑扎机器人为基础,旨在提出一种新的移动和绑扎控制方法,以减少人力并提高效率。通过逻辑判断、速度控制和位置控制,机器人可在钢筋网的有限区域内准确移动和运行。机器人利用机器视觉定位钢筋节点,然后调整绑扎枪的位置,以确保多个钢筋节点按顺序绑扎。通过在钢筋网上的精确移动,机器人满足了绑扎模块的定位精度要求,实验测试精度在 5 毫米以内。原创性/价值创新设计的机器人能够适应钢筋网,准确移动到目标位置,并在该位置绑定四个节点,从而减少了在钢筋网上的移动次数。重复而繁重的钢筋绑扎任务可由机器人高效完成,节省了人力资源,降低了工人的劳动强度,减少了施工开销。它为使用机器人绑扎钢筋节点提供了一个更加可行和实用的解决方案。
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