冲沟地貌下浅埋煤层开采矿压规律及顶板控制技术

采矿与安全工程学报 ›› 2015, Vol. 32 ›› Issue (6): 877-882.

冲沟地貌下浅埋煤层开采矿压规律及顶板控制技术

中国矿业大学矿业工程学院，深部煤炭资源开采教育部重点实验室，江苏徐州 221116

收稿日期:2015-04-06 出版日期:2015-11-15 发布日期:2015-12-04
作者简介:王方田(1985—)，男，河南省永城市人，博士，讲师，从事浅埋煤层、薄煤层采矿方法、矿山压力与岩层控制方面的研究。
基金资助:
国家自然科学基金项目(51304202)；江苏省自然科学基金项目(BK20130190)；江苏省高校优势学科建设项目；中央高校基本科研业务费专项资金项目(2014XT01)；中国矿业大学青年科技基金项目(2013QNA28)

Ground pressure rules and roof control technology for the longwall mining of shallow seam beneath the gully topography

Received:2015-04-06 Online:2015-11-15 Published:2015-12-04

摘要/Abstract

摘要： 神东煤田高头窑矿区具有冲沟发育、坡体变化大等地貌特征，在沟谷下浅埋煤层进行长壁开采容易诱发顶板切冒、支架压毁等灾害。结合色连一号矿首采工作面地质条件，建立了冲沟下 “支架-围岩”作用关系模型，确定了背沟开采时合理支架工作阻力为11 000 kN。分析了4.0 m 和3.2 m 采高时煤壁塑性区发育、顶板压力和下沉量变化规律，得到矿压显现剧烈程度呈现“背沟段>向沟段>沟底段>正常开采段”的特征。工作面矿压实时监测表明，冲沟下开采顶板来压期间支架最大工作阻力及来压动载系数均有明显增大。现场应用加强矿压监测预报、局部降低采高、工作面快速推进等措施，确保了冲沟下浅埋煤层安全高效开采。

关键词: 浅埋煤层, 冲沟地貌, 支架阻力, 动载矿压, 安全高效开采

Abstract: Gaotouyao Mine Area, located in the Shendong Coal Field, has typical topography features of developmental gully and large change for the slopes, thence many accidents, such as roof slice type caving and hydraulic support being iron-bound, are inclined to happen during the longwall mining of the shallow coal seams beneath the gully topography. According to the field conditions of the first longwall panel, Selian No. 1 Coal Mine, a “support-surrounding rock” relationship model has been established, and the reasonable support working resistance has been determined to be 11 000 kN in the back-gully mining period. The coal wall plastic zone development, roof pressure and roof deflection have been analyzed while the mining height are 4.0 m and 3.2 m respectively. And the strata pressure behavior degree presents a characteristic of “back-gully mining period > toward-gully mining period > bottom-gully mining period > normal mining period”. The real-time monitoring results indicate that the max support working resistance and the roof weighting dynamic factor of the gully period are larger than these of the normal mining period. Many roof control measures, including enhancement mine pressure monitoring and forecasting, regional lower mining height and rapid advance speed, are implemented in the field, hence safe and efficient mining of shallow seam beneath the gully topography has been guaranteed.

Key words: shallow coal seams, gully topography, support working resistance, dynamic mine pressure, safe and efficient mining

王方田，屠世浩，张艳伟，宋启，闫瑞龙，段超华. 冲沟地貌下浅埋煤层开采矿压规律及顶板控制技术[J]. 采矿与安全工程学报, 2015, 32(6): 877-882.

WANG Fangtian，TU Shihao，ZHANG Yanwei，SONG Qi，YAN Ruilong，DUAN Chaohua. Ground pressure rules and roof control technology for the longwall mining of shallow seam beneath the gully topography[J]. Journal of Mining & Safety Engineering, 2015, 32(6): 877-882.

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