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机器视觉感知理论与技术在煤炭工业领域应用进展综述

巩师鑫 赵国瑞 王飞

巩师鑫,赵国瑞,王飞. 机器视觉感知理论与技术在煤炭工业领域应用进展综述[J]. 工矿自动化,2023,49(5):7-21.  doi: 10.13272/j.issn.1671-251x.2022100087
引用本文: 巩师鑫,赵国瑞,王飞. 机器视觉感知理论与技术在煤炭工业领域应用进展综述[J]. 工矿自动化,2023,49(5):7-21.  doi: 10.13272/j.issn.1671-251x.2022100087
GONG Shixin, ZHAO Guorui, WANG Fei. Review on the application of machine vision perception theory and technology in coal industry[J]. Journal of Mine Automation,2023,49(5):7-21.  doi: 10.13272/j.issn.1671-251x.2022100087
Citation: GONG Shixin, ZHAO Guorui, WANG Fei. Review on the application of machine vision perception theory and technology in coal industry[J]. Journal of Mine Automation,2023,49(5):7-21.  doi: 10.13272/j.issn.1671-251x.2022100087

机器视觉感知理论与技术在煤炭工业领域应用进展综述

doi: 10.13272/j.issn.1671-251x.2022100087
基金项目: 国家自然科学基金资助项目(52104161,52274208);天地科技股份有限公司开采设计事业部科技创新基金资助项目(KJ-2021-KCZD-01)。
详细信息
    作者简介:

    巩师鑫(1990—),男,辽宁大连人,助理研究员,博士,研究方向为智能化开采与数据融合分析挖掘,E-mail:gongshixin1990@163.com

  • 中图分类号: TD67

Review on the application of machine vision perception theory and technology in coal industry

  • 摘要: 机器视觉技术对改善煤矿安全监测手段、提高装备自动化水平具有积极意义。详细阐述了当前煤矿智能化建设过程中基于机器视觉的不同场景和系统下的设备信息状态感知原理,综述了机器视觉感知技术在煤矿安全监测、拣选识别、煤岩识别、定位导航、运输检测、位姿检测和信息测量等方面的实践应用;分析指出未来煤矿机器视觉感知技术应深入挖掘采掘工作面机器视觉场景理解需求,构建生产全视场监视检测体系,提升多时空多维度多变量集成监测效果,改善视频自主监视告警能力,增强视觉引导能力,并形成地面生产管理运行系统的视觉资料统一化管理方式等,重点研究综采装备(群)姿态同时空测量、采掘环境动态变化感知、生产全视场监测与自主告警、煤矿机器人视觉引导控制等技术;指出煤矿机器视觉感知技术在防爆或本安型智能视觉传感器研发、高效视觉测量与分析、检测识别测量精度提升、图像高质量标注方面仍存在挑战,通过开发具有边缘计算能力的视觉传感器,构建井上下视觉分布式测量方案,实现各类复杂环境下开采信息准确识别与测量,可有效提高机器视觉感知技术在煤炭行业的更深层次融合和应用。

     

  • 图  1  机器视觉感知系统

    Figure  1.  Machine vision perception system

    图  2  机器视觉感知系统硬件资源

    Figure  2.  Hardware resources of machine vision perception system

    图  3  卷积神经网络

    Figure  3.  Convolutional neural network

    图  4  机器视觉感知技术在煤炭工业领域应用场景

    Figure  4.  Application scenes of machine vision perception technology in coal industry field

    图  5  融合迁移学习与结构优化的煤矸识别模型构建[25]

    Figure  5.  Construction of coal gangue recognition model combining transfer learning and structure optimization[25]

    图  6  基于机器视觉的煤岩分界识别效果

    Figure  6.  Recognition effect of coal-rock boundary based on machine vision

    图  7  基于机器视觉的带式输送机故障识别

    Figure  7.  Belt conveyor fault recognition based on machine vision

    图  8  液压支架姿态视觉测量模型[70]

    Figure  8.  Visual measurement model of hydraulic support attitude[70]

    图  9  刮板输送机直线度测量

    Figure  9.  Scraper conveyor straightness measurement

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  • 收稿日期:  2022-10-29
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