煤矿智能化掘进关键技术研究

李飞; 张林; 尚宇琦; 孔德中; 王玉亮; 陈龙; 张枝伟

doi:10.13272/j.issn.1671-251x.2022100062

煤矿智能化掘进关键技术研究

doi: 10.13272/j.issn.1671-251x.2022100062

李飞^1,,
张林¹,
尚宇琦¹,
孔德中^1, ,,
王玉亮¹,
陈龙¹,
张枝伟^{2, 3}

1.
贵州大学矿业学院, 贵州贵阳　550025
2.
贵州省煤矿设计研究院有限公司, 贵州贵阳　550025
3.
贵州省矿山安全科学研究院有限公司, 贵州贵阳　550025

基金项目: 国家自然科学基金地区科学基金项目(52164002，52164005)；贵州省科技厅科技支撑项目(黔科合支撑〔2020〕2Y032号，黔科合支撑〔2020〕2Y033号)。

详细信息

作者简介:
李飞（1999—），男，山东临沂人，硕士研究生，主要研究方向为矿山压力与岩层控制，E-mail：1763850957@qq.com

通讯作者:
孔德中（1989—），男，河南永城人，教授，博士，博士研究生导师，主要研究方向为矿山压力与岩层控制，E-mail：dzkong@gzu.edu.cn

中图分类号: TD67
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出版历程
- 收稿日期: 2022-10-19
- 修回日期: 2023-03-30
- 网络出版日期: 2023-04-27

Research on key technologies of coal mine intelligent excavation

1.
Mining College of Guizhou University, Guiyang 550025, China
2.
Guizhou Coal Mine Design Research Institute Co., Ltd., Guiyang 550025, China
3.
Guizhou Mine Safety Scientific Research Institute Co., Ltd., Guiyang 550025, China

摘要

摘要: 介绍了近年来煤矿巷道掘进主要技术(悬臂式掘进机综掘技术、连续采煤机掘进技术及掘锚一体化掘进技术）的研究成果，分析了这3种主要巷道掘进技术在我国的适用性及推广价值，指出：① 悬臂式掘进机综掘技术仅能“前掘后锚”，掘进与支护的过程不能同时进行，限制了掘进效率。② 连续采煤机掘进技术仅可在近水平煤层条件下进行，且对顶板的稳定程度有一定要求，适用性不强。③ 掘锚一体化掘进技术仅适用于巷道断面大的单巷快速掘进，所用到的掘锚一体机机身大且价格昂贵，并对所掘进巷道的底板稳定性有一定的要求。相比连续采煤机掘进技术，掘锚一体化掘进技术在我国有较好的应用前景。将原有掘进机的掘进功能拓展为掘进兼支护的功能，这对掘锚一体化掘进技术的研究与普及可起到推动作用。分析了近年来煤矿巷道机器人化智能掘进技术中智能截割、远程智能监控、智能协同控制3个方面的研究成果，得出：① 智能截割技术主要集中在对煤岩自适应识别方面的研究。② 远程智能监控技术已从远程实时监测向远程可视化监控方向发展，虚拟仿真技术的发展将井下掘进巷道的情况可视化地展现在地面，并将控制信号反馈到掘进工作面来对掘进工作面掘进机组进行远程同步控制，成为当前巷道掘进远程监控智能化的重要标志。③ 目前针对智能协同控制技术的研究较少。探讨了煤矿巷道掘进智能化的发展方向：加强掘进设备集成协同化、设备模块化组合、5G矿用无线网络设备、掘进远程智能监控系统及难掘慢掘巷道掘进工程等方面的研究。
- 巷道快速掘进 /
- 悬臂式掘进机综掘技术 /
- 连续采煤机掘进技术 /
- 掘锚一体化掘进技术 /
- 智能截割 /
- 远程智能监控 /
- 智能协同控制
Abstract: This paper introduces the research results of the main coal mine roadway excavation technologies in recent years. The technologies include cantilever roadheader comprehensive excavation technology, continuous shearer tunneling technology, and integrated excavation technology. The applicability and promotion value of these three main roadway excavation technologies in China is analyzed. The following points are pointed out. ① The comprehensive excavation technology of the cantilever roadheader can only "excavate before anchoring". The excavation and support processes cannot be carried out simultaneously, which limits the excavation efficiency. ② The continuous shearer tunneling technology can only be carried out in near horizontal coal seam conditions. It has certain requirements for the stability of the roof. The applicability is weak. ③ The integrated excavation technology is only suitable for rapid excavation of single roadways with large cross-sections. The integrated excavation and anchoring machine used is large and expensive. The machine has certain requirements for the stability of the bottom plate of the excavated roadways. Compared to the continuous mining machine excavation technology, the integrated excavation technology has a good application prospect in China. Expanding the excavation function of the original roadheader to the function of excavation and support can promote the research and application of integrated excavation and anchoring technology. The study analyzes the research achievements of intelligent cutting, remote intelligent monitoring, and intelligent collaborative control in the robotized intelligent excavation technology of coal mine roadways in recent years. The following points are concluded. ① Intelligent cutting technology mainly focuses on the research of adaptive recognition of coal and rock. ② Remote intelligent monitoring technology has evolved from remote real-time monitoring to remote visual monitoring. The development of virtual simulation technology visualizes the situation of underground excavation roadways on the ground. And it feeds back control signals to the excavation working face to remotely synchronize and control the excavation working face roadheader unit. This becomes an important symbol of the current intelligent remote monitoring of roadway excavation. ③ There is currently limited research on intelligent collaborative control technology. This study explores the development directions of intelligent coal mine roadway excavation. The directions include strengthening the integration and collaboration of excavation equipment, modular combination of equipment, 5G mining wireless network equipment, remote intelligent monitoring system for excavation, and research on difficult and slow excavation roadway excavation engineering.

HTML全文

图 1 悬臂式掘进机综掘机组

1−悬臂式掘进机；2−机载锚杆钻机；3−桥式转载机；4−带式输送机。

Figure 1. Cantilever roadheader comprehensive excavation unit

下载: 全尺寸图片幻灯片

图 2 连续采煤机掘进技术的掘进与支护设备

Figure 2. Continuous shearer tunneling technology tunneling and support equipment

下载: 全尺寸图片幻灯片

图 3 连续采煤机掘进技术用于双巷掘进中设备布置

1−连续采煤机；2−梭车；3−主运输巷；4−破碎机；5−带式输送机；6−锚杆钻车；7−辅运输巷；8−铲车；9−联络巷。

Figure 3. Continuous shearer tunneling technology is used for equipment layout in double roadways tunneling

下载: 全尺寸图片幻灯片

图 4 掘锚一体机机组

1−掘锚一体机；2−锚杆钻车；3−桥式转载机。

Figure 4. Excavation anchor integrated tunneling unitt

下载: 全尺寸图片幻灯片

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