基于边缘计算的顶板压力监测关键技术研究OA
Research on key technologies of roof pressure monitoring based on edge computing
随着煤矿开采深度的增加,顶板事故成为威胁矿山安全的主要隐患之一.传统的顶板压力监测技术普遍依赖地面中心站进行数据处理,存在数据传输延迟大、带宽占用峰值高、实时预警能力弱等问题,难以满足复杂井下环境对动态监测的迫切需求.为此,提出了一种基于边缘计算的顶板压力监测技术,通过将计算能力下沉至网络边缘节点,实现压力数据的本地化实时处理与智能分析,显著提升了监测系统的响应速度与可靠性.首先,针对顶板压力监测场景设计了具备多源异构数据融合能力的边缘计算节点,节点集成高精度压力传感器、液压支架活塞伸缩量及环境参数采集模块,结合自适应滤波算法与轻量化异常检测模型,完成数据预处理与初步特征提取,有效降低冗余数据上传量;其次,构建了"感知层-边缘层-云平台"3 级分布式监测架构,边缘层通过协同计算实现压力动态趋势预测与风险分级预警,云平台负责全局数据存储与模型优化迭代,兼顾实时性与长期数据分析需求;此外,提出了基于深度强化学习的边缘资源动态调度策略,优化计算任务分配与能耗管理,保障边缘节点在井下复杂环境中的长期稳定运行.试验结果表明,相较于传统云计算模式,边缘计算方案具有本地最短传输路径和本地数据计算能力,将压力传感器无线发射功率由 10 dbm降为 4 dbm,显著降低了设备能耗,同时无线数据传输成功率提升至 100%,危险状态预警时间由 8.2 min降至 3.5 min,提升了顶板压力监测的实时预警能力.
With the increase of coal mining depth,roof accidents have become one of the main hidden dangers threatening mine safety.Traditional roof pressure monitoring technology generally relies on ground central stations for data processing,which has problems such as large data transmission delay,high bandwidth peak occupancy,and weak real-time warning capabilities,making it difficult to meet the urgent needs of dynamic monitoring in complex underground environments.Therefore,we propose a roof pres-sure monitoring technology based on edge computing.By sinking the computing power to the edge nodes of the network,the local real-time processing and intelligent analysis of pressure data are realized,and the response speed and reliability of the monitoring system are significantly improved.Firstly,for the roof pressure monitoring scenario,an edge computing node with multi-source het-erogeneous data fusion capability is designed.The node integrates high-precision pressure sensors,hydraulic support piston expan-sion and contraction,and environmental parameter acquisition modules,and combines with adaptive filtering algorithms and light-weight anomaly detection models,to complete data preprocessing and preliminary feature extraction,effectively reducing the amount of redundant data uploaded.Secondly,a three-level distributed monitoring architecture of"perception layer-edge layer-cloud plat-form"has been constructed.The edge layer achieves dynamic trend prediction and risk grading warning through collaborative com-puting,while the cloud platform is responsible for global data storage and model optimization iteration,balancing real-time and long-term data analysis needs.In addition,a dynamic scheduling strategy for edge resources based on deep reinforcement learning is pro-posed to optimize computing task allocation and energy management,ensuring the long-term stable operation of edge nodes in com-plex underground environments.The experimental results show that compared with the traditional cloud computing mode,the edge computing scheme has the shortest local transmission path and local data computing capability.The wireless transmission power of the pressure sensor is reduced from 10 dbm to 4 dbm,significantly reducing the energy consumption of the equipment.At the same time,the success rate of wireless data transmission is increased to 100%,and the warning time of dangerous states is increased from 8.2 min to 3.5 min,which improves the real-time warning capability of roof pressure monitoring.
刘立仁;霍雷敏;谷民帅;陈博;袁强;王志伟;黄友胜
陕西德源府谷能源有限公司三道沟煤矿,陕西 榆林 719000陕西德源府谷能源有限公司三道沟煤矿,陕西 榆林 719000陕西德源府谷能源有限公司三道沟煤矿,陕西 榆林 719000陕西德源府谷能源有限公司三道沟煤矿,陕西 榆林 719000陕西德源府谷能源有限公司三道沟煤矿,陕西 榆林 719000陕西德源府谷能源有限公司三道沟煤矿,陕西 榆林 719000中煤科工集团重庆研究院有限公司,重庆 400039
矿业与冶金
边缘计算顶板压力监测多源数据融合动态调度矿山安全
edge computingroof pressure monitoringmulti-source data fusiondynamic schedulingmine safety
《煤矿安全》 2026 (3)
227-236,10
天地科技股份有限公司科技创新创业资金专项资助项目(2024-TD-ZD013-05)
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