产教融合背景下腻子智能喷涂实验教学平台设计OA
Design of an intelligent putty spraying experimental teaching platform for industry-education integration
大尺寸复杂曲面工件人工喷涂腻子面临效率低、质量一致性差、材料浪费等问题,自动化喷涂亟需突破高精度三维感知、智能决策与精准执行等关键技术.该文构建了以多传感器阵列与七轴机器人为基础的腻子智能喷涂实验教学平台,感知层采用 NDT-ICP 混合点云配准算法,将大尺度点云的平均配准误差降至0.08 mm,分析层提出基于曲率特征增强的点云模板匹配方法,对亚毫米级缺陷的识别准确率超过 96%,决策层设计了融合生物激励神经网络(BINN)与非均匀有理 B 样条(NURBS)优化的动态路径规划算法,有效避免了重复的路径规划.实验表明,系统喷涂效率为人工作业的 9 倍,材料成本降低 17%.基于此算法体系设计的层次化教学项目,可培养学生解决智能制造领域复杂工程问题的能力.
[Objective]The existing putty spraying process continues to rely heavily on manual operation,resulting in challenges such as surface flatness inconsistencies,low construction efficiency,and considerable material waste.These issues have become impediments to industrial upgrading.The transition to automated solutions necessitates fundamental breakthroughs in key enabling technologies,including high-precision three-dimensional(3D)perception,intelligent decision-making,and precise motion control.To address these technical challenges and concurrently support the talent development objectives of emerging engineering education in intelligent manufacturing,this research presents an industrial robot-based intelligent putty spraying system that leverages core algorithm innovations to advance automated spraying technology.[Methods]The developed system is built on a robust hardware platform integrating a multisensor array for 3D laser reconstruction and a seven-axis industrial robot for execution.The core methodology is structured in a multilayered architectural approach.In the perception layer,a high-speed point cloud stitching process is employed to create a holistic digital twin of the workpiece.An improved normal distribution transform-iterative closest point(NDT-ICP)hybrid point cloud registration algorithm was proposed,specifically engineered to enhance alignment accuracy for large-scale scans,successfully reducing the average registration error to 0.08 mm.In the analysis layer,a novel point cloud template matching method was developed,augmented by curvature feature enhancement.This algorithm demonstrates strong capability in identifying subtle geometric variations,achieving a recognition accuracy exceeding 96%for submillimeter-level defects,including dents and bulges.This process is further refined through improved guided point cloud filtering and adaptive contour matching processing to precisely isolate defective regions.In the decision and execution layer,a dynamic path planning algorithm was designed.This algorithm strategically fuses a bio-inspired neural network(BINN)for real-time obstacle and coverage mapping with non-uniform rational B-spline(NURBS)optimization for trajectory smoothing.This synergy enables the real-time generation of efficient,collision-free,and fully covered spraying paths tailored for complex free-form surfaces,effectively minimizing redundant motions and path repetition.[Results]Experimental validation confirmed the superior performance of the proposed system and its constituent algorithms.The enhanced NDT-ICP registration algorithm exhibited higher precision and robustness compared with conventional curvature-based region-growing segmentation methods.All defect identification errors were confined below the 0.05 mm threshold,with the most notable improvement observed in bulge defect recognition,where accuracy increased by up to 70%.The BINN+NURBS dynamic path planning algorithm consistently generated the most efficient paths,achieving the lowest recorded metrics in path repetition rate and overall redundancy among all benchmarked algorithms.This optimal pathing directly translates to reduced cycle times and mitigates material waste caused by overspraying.In a practical application scenario involving the coating of an aluminum alloy sidewall panel,the system demonstrated a nine-fold increase in spraying efficiency compared with skilled manual labor,alongside a 17%reduction in material consumption.The final coating quality consistently met the stringent requirements of the Q/CR546.1 industry standard,validating the system's practical reliability and effectiveness.[Conclusions]The intelligent putty spraying system developed in this project represents a significant advancement in automating a traditionally manual-dependent process,providing a reliable technical solution for industrial applications requiring sophisticated path planning and intelligent decision-making capabilities.As a representative case of intelligent manufacturing,the project has been incorporated into the experimental teaching curriculum,effectively strengthening students'innovative and practical abilities in addressing complex engineering challenges.
习爽;张远兰;刘英;周海燕
南京林业大学 机械电子工程学院,江苏 南京 210037南京林业大学 南方现代林业协同创新中心,江苏 南京 210037南京林业大学 机械电子工程学院,江苏 南京 210037南京林业大学 机械电子工程学院,江苏 南京 210037
信息技术与安全科学
工业机器人腻子喷涂智能制造机器学习轨迹规划
industrial robotputty sprayingintelligent manufacturingmachine learningtrajectory planning
《实验技术与管理》 2026 (3)
156-161,6
江苏省高等教育教改研究课题(2021JSJG082)南京林业大学教学质量提升工程改革项目(2021-YLRC-002)
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