Automation software design and application for fully mechanized working face
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摘要: 针对综采工作面高效开采需求,以及开采过程中面临的自动化软件产品缺乏,通用的工业组态软件缺乏行业针对性、设备接口协议繁多、对业务场景的适应性不足等问题,提出了一种面向综采工作面的自动化软件设计方案。面向综采工作面的自动化软件包括井下服务端、地面服务端、地面客户端3层架构。井下服务端是整个架构的基础,由驱动层、数据库模块、模型逻辑层、数据可视化层构成。驱动层负责接入适配工作面的各类设备及通信协议,实现与各设备的实时双向通信。数据库模块包括实时数据库和历史数据库,实时数据库为驱动层提供实时读写服务,历史数据库为驱动层提供数据记录服务。针对煤矿开采业务场景构建了综采工作面的数据模型,模型逻辑层用以解决软件缺乏行业针对性和适应性不足的问题。模型逻辑层通过与驱动层交互实现设备数据的实时上传和控制指令的实时下发,为数据可视化提供数据驱动,并且通过加载控制分析组件,完成各类设备的协同控制和数据分析功能。数据可视化层集成了多种数据展示技术,便于对数据进行多维度展示。实际应用效果表明:① 在辅助生产方面,该自动化软件应用后,可以实现对工作面工况信息和设备状态的连续在线实时监测,支持对工作面设备的远程集中控制,将井下需要在各设备附近的多人值守减少至2人在监控中心远程集中监控,有效减少了操作人员数量。② 在提升自动化的高级应用方面,该自动化软件应用后,对各系统数据进行分类融合,实现了多类设备自动化协同控制功能,提升了综采工作面自动化水平。
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关键词:
- 综采工作面自动化系统 /
- 自动化软件 /
- 综采设备 /
- 井下服务端 /
- 数据可视化
Abstract: In view of the demand for efficient mining of fully mechanized working face, the lack of automation software products in the mining process, the lack of industry pertinence of general industrial configuration software, the variety of equipment interface protocols and the lack of adaptability to business scenes, a design scheme of automation software for fully mechanized working face is proposed. The automation software of fully mechanized working face comprises a three-layer structure of an underground server, a ground server and a ground client. The underground server is the foundation of the whole architecture, which is composed of a driver layer, a database module, a model logic layer and a data visualization layer. The driver layer is responsible for accessing all kinds of equipment and communication protocols adapted to the working face, and realizing real-time two-way communication with each piece of equipment. The database module comprises a real-time database and a historical database. The real-time database provides real-time read-write service for the driver layer, and the historical database provides data recording service for the driver layer. The data model of the fully mechanized working face is constructed according to the business scene of coal mining. The logic layer of the model is used to solve the problem of lack of industry pertinence and adaptability of software. The model logic layer realizes real-time uploading of equipment data and real-time issuing of control instructions through interaction with the equipment layer. The layer provides data drive for data visualization. The layer completes collaborative control and data analysis functions of various equipment through loading control analysis components. The data visualization layer integrates a variety of data display technologies to facilitate the multi-dimensional display of data. The practical application results show the following points. ① In the aspect of auxiliary production, after the application of the automation software, the continuous online real-time monitoring of working condition information and equipment state of the working face can be realized. The remote centralized control of the working face equipment is supported. The number of underground operators who need to be on duty near each piece of equipment is reduced to two persons in the monitoring center for remote centralized monitoring. This effectively reduces the number of operators. ② In the advanced application of automation, after the application of the automation software, the data of each system is classified and fused. The automatic collaborative control function of multiple types of equipment is realized. The automation level of the fully mechanized working face is improved. -
图 1 面向综采工作面的自动化软件架构
Figure 1. Automation software architecture of fully mechanized working face
图 8 面向综采工作面的自动化软件部署
Figure 8. Automation software deployment of fully mechanized working face
图 9 自动化软件应用前井下工作人员分布
Figure 9. Distribution of underground personnel before automation software application
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