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综掘系统视觉处理技术研究现状及发展趋势

杜雨馨 张贺 王树臣 张建化

杜雨馨,张贺,王树臣,等. 综掘系统视觉处理技术研究现状及发展趋势[J]. 工矿自动化,2023,49(11):22-38, 75.  doi: 10.13272/j.issn.1671-251x.2023090042
引用本文: 杜雨馨,张贺,王树臣,等. 综掘系统视觉处理技术研究现状及发展趋势[J]. 工矿自动化,2023,49(11):22-38, 75.  doi: 10.13272/j.issn.1671-251x.2023090042
DU Yuxin, ZHANG He, WANG Shuchen, et al. Research status and development trend of visual processing technology for fully mechanized excavation systems[J]. Journal of Mine Automation,2023,49(11):22-38, 75.  doi: 10.13272/j.issn.1671-251x.2023090042
Citation: DU Yuxin, ZHANG He, WANG Shuchen, et al. Research status and development trend of visual processing technology for fully mechanized excavation systems[J]. Journal of Mine Automation,2023,49(11):22-38, 75.  doi: 10.13272/j.issn.1671-251x.2023090042

综掘系统视觉处理技术研究现状及发展趋势

doi: 10.13272/j.issn.1671-251x.2023090042
基金项目: 国家重点研发计划项目(2019YFC1805404); 江苏省高校自然科学研究面上项目(20KJB510050);徐州市重点研发计划(现代农业)项目(KC21135)。
详细信息
    作者简介:

    杜雨馨(1991—),女,江苏徐州人,讲师, 博士,研究方向为检测技术与自动化装置,E-mail:928107333@qq.com

  • 中图分类号: TD632

Research status and development trend of visual processing technology for fully mechanized excavation systems

  • 摘要: 机器视觉技术具有非接触测量、获取信息量大、数据处理能力强等优点,将其应用于综掘工作面,对于提高综掘工作效率、保障人员设备安全、减少事故发生具有重要意义。综述了近年来视觉处理技术在煤矿综掘系统中的具体应用与发展情况,依据综掘工作面的任务分工,结合具体实际案例,重点分析了机器视觉技术在视觉检测与定位、安全监测与事故预防、装备自动化与智能化等方面的应用。通过分析不同应用场景中各类视觉检测系统的结构与检测原理,明确了视觉处理技术在综掘工作面工程应用中的技术性能、工作流程及优缺点。分析了视觉技术在综掘工作面应用中存在的挑战,包括环境适应性问题、成像视野范围较窄、智能算法的鲁棒性和可靠性尚待提高等。指出多传感器信息融合技术、设备群协同控制技术与数字孪生驱动远程监控技术是基于机器视觉的煤矿智能化装备体系未来需要重点发展的新方向。

     

  • 图  1  不同文献中的悬臂式掘进机位姿检测透视投影模型

    Figure  1.  Perspective projection models for the position and posture detection of the boom-type roadheader in different literatures

    图  2  悬臂式掘进机截割头位姿视觉检测模型

    Figure  2.  Visual detection model for the position and posture of the boom-type roadheader's cutting head

    图  3  煤矸石图像识别方法[64]

    Figure  3.  Coal gangue image recognition methods[64]

    图  4  煤流参数检测方法

    Figure  4.  Coal flow parameters detection methods

    图  5  围岩变形监测间接标志物

    Figure  5.  Indirect indicators for surrounding rock deformation monitoring

    图  6  输送带纵向撕裂的视觉检测方法

    Figure  6.  Visual detection methods for longitudinal tearing of conveyor belts

    图  7  新型掘进类机器人

    Figure  7.  New types of tunneling robot

    表  1  各类视觉传感器的工作原理与常见应用场景

    Table  1.   Working principles and common application scenarios of various visual sensors

    视觉传感器 基本原理 优势 劣势 实物 综掘工作面应用
    单目视觉系统 小孔成像,利用尺度不变性确定深度 结构简单、成本低、便于标定和识别 通过单张图片无法确定物体的真实大小
    KBA127矿用隔
    爆型摄像仪
    位姿检测[4]、目标识别[5]、参数检测[6]、环境监测[7]、设备状态检测[8]
    双目视觉系统 双光热像仪 基于红外热辐射原理,可同时获取场景的可见光信息和温度信息 能见度不受限制、宽波段测量 分辨率有限、成本较高
    YRH600B矿用
    防爆热像仪
    人员安全监测[9]、设备状态监测[10]、环境安全评估[11]
    立体视觉相机 由2个单目相机组成,利用三角测量原理估计像素空间坐标 可获取深度信息、基线距越大量程越远 工作视场小、配置与标定复杂、实时性差
    STEEReoCAM
    立体相机
    位姿检测[12]、参数测量[13]、巷道三维重建[14]
    多目视觉系统 由多个单目相机从多视点获取同一个目标场景,基于双目测量原理重构像素空间坐标 获取信息丰富、包含冗余信息、解决了双目视觉系统匹配的多义性、匹配与定位精度高 配置与标定更加烦琐、匹配算法更复杂、计算量更大、实时性更差
    NileCAM81_
    CUOAGX
    多摄像头系统
    几何参数测量[15]、物体表面重建[16]、巷道三维重建[17]、轨迹预测[18]
    结构光相机 由相机和投影装置组成,利用红外结构光/ToF原理,通过发射接收光测距 直接获取RGB图像和深度图像、测量精度高 测量范围窄、噪声大、视野小、易受光源干扰、无法测量透射材质
    Realsense 深度
    相机 D435
    导航定位[19]、SLAM[20]、参数测量[21]、行人识别[22]、物体表面三维重建[23]
    下载: 导出CSV

    表  2  机器视觉在安全监测与事故预防中的应用分析

    Table  2.   Application analysis of machine vision in safety monitoring and accident prevention

    应用场景现有方法及原理存在问题解决方法
    围岩变形监测直接法直接拍摄巷道图像,经特征提取与点云配准,重构巷道三维信息;间接法将人工特征标志物固定在巷道表面,通过标志物变化,间接反映巷道变形直接法监测精度高,但数据处理量大;间接法处理速度快,但数据较为稀疏将2种方法相结合,提高监测精度与效率
    火灾监测通过提取图像中的火焰、烟雾等特征,或借助红外成像技术,使用机器学习算法或深度学习模型对提取的特征进行分析和识别,以确定是否存在火灾煤矿火灾具有偶然性,对于早期火灾的识别,精准度与快速性有待提高借助多源信息融合技术,将视频检测信息与多传感器信息融合,实现火灾预判
    人员安全监测通过图像处理技术识别人体特征,如头部、肢体轮廓、姿势等,分析人员行为动态,监测潜在安全风险和异常情况;或将人员位置和状态信息与预设的安全规则进行比较,触发相应的实时监控和报警机制井下能见度低、空间狭窄、大型装备多,图像背景复杂多变,干扰人员检测的准确性结合声音、红外等传感器,实现对矿井环境和人员的多维度监测,提高整体监测可靠性
    输送带异常监测采用可见光成像、红外热成像、结构光成像等,经特征提取与目标识别,实现输送带异物、撕裂、跑偏等异常状态监测受低照度、高矿尘等环境因素影响,目标识别的准确度难以得到保证深度学习等智能算法的应用可有效提高识别准确度
    下载: 导出CSV

    表  3  机器视觉在装备自动化与智能化中的应用分析

    Table  3.   Application analysis of machine vision in equipment automation and intelligence

    应用
    场景
    方法原理当前进展存在问题
    掘进
    系统
    通过特征提取与参数解算,对巷道掘进设备进行监测和控制,实时获取设备状态、位置及可能存在的故障或异常情况,并为掘进机械提供实时导航信息实现了基于机器视觉的悬臂式掘进机机身定位与截割头位姿检测、掘进工作面稳定性与岩层变化监测预警等;研制了新型掘进类机器人和系统,如护盾式智能掘进机器人系统、综掘巷道掘进机器人系统、煤矿大断面智能快速掘锚成套装备、煤矿高阶智能快速掘进系统等掘进装备体积较大、结构复杂,成像装置不易安装,光路易被遮挡,会导致成像不完整或质量不佳,影响机器视觉在巷道掘进系统中的应用效果
    锚护
    系统
    通过图像处理提取锚护装备的关键特征及支护参数,以识别可能存在的安全隐患或为锚护控制提供参数依据应用视觉技术,在传统锚护工艺的基础上进行自动化改进,如通过监测支护参数变化提高支护精度,通过智能识别钢带锚孔实现锚具精准控制等;开发出掘锚一体化机、钻锚机器人、浆液喷护机器人等新型装备锚护系统的检测通常需要实时响应,但图像处理和识别的速度可能受到环境因素、硬件性能和算法复杂度的限制
    转载运输系统通过视觉技术识别输送设备参数、状态、障碍物等,实现转载运输系统的自动化控制和智能化管理,提高运输效率和安全性通过煤流量检测实现运输系统优化节能,通过目标识别监测运输装备的实时位置和状态,实现运输智能调度;实现运输装备机器人化,开发出钢丝绳牵引式机器人巡检系统、带式输送机检测机器人、煤矸自动分拣机器人等如何应用多传感器融合技术进一步提高运输装备机器人化的智能程度,保障系统对复杂环境的适应能力
    下载: 导出CSV
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出版历程
  • 收稿日期:  2023-09-12
  • 修回日期:  2023-11-05
  • 网络出版日期:  2023-11-27

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