中 国 矿 业 大 学本科生毕业设计姓 名:学 号:学 院: 矿业工程学院 专 业: 采矿工程 设计题目: 山阳煤矿3.0 Mt/a新井设计专 题:浅析采场底板突水机理及预测方法指导教师:职 称:教授 2012年6月 徐州中国矿业大学毕业设计任务书学院 矿业工程学院 专业年级 采矿工程2008级 学生姓名任务下达日期:2012年1月8日毕业设计日期:2012年3月12日 至 2012年6月8日毕业设计题目:山阳煤矿3.0 Mt/a新井设计毕业设计专题题目: 浅析采场底板突水机理及预测方法毕业设计主要内容和要求:以实习矿井山阳煤矿条件为基础,完成山阳煤矿3.0Mt/a新井设计主要内容包括:矿井概况、矿井工作制度及设计生产能力、井田开拓、首采区设计、采煤方法、矿井通风系统、矿井运输提升等结合煤矿生产及矿井设计情况,撰写一篇浅析采场底板突水机理及预测方法专题论文完成2010年《中国矿业大学学报》上与采矿有关的科技论文翻译一篇,题目为“Physical simulation of rock burst induced by stress waves”,论文3563字符。
院长签字: 指导教师签字:摘 要一般部分针对澄合山阳矿井进行了井型为3.0Mt/a的新井设计山阳煤矿位于陕西省合阳县境内,井田走向长约12.8km,倾向长约5.5km,面积约70.4km2主采煤层为5号煤层,倾角3~15°,平均倾角7°,平均厚度4.52m井田工业储量为456.25Mt,可采储量316.98Mt,矿井服务年限为75.5a矿井正常涌水量为380.60m3/h,最大涌水量为436.69m3/h;矿井相对瓦斯涌出量为2.256m3/t,属低瓦斯矿井根据井田地质条件,设计采用双立井单水平开拓方式,井田采用带、盘(采)区式布置方式,共划分为六个块段,一个带区,五个采(盘)区,轨道大巷和胶带大巷皆为岩石大巷,布置在五号煤层底板岩层中 针对西四带区采用了带区准备方式,共划分19个分带工作面,并进行了运煤、通风、运料、排矸、供电系统设计针对5401工作面进行了采煤工艺设计该工作面煤层平均厚度为4.52m,平均倾角3°,直接顶为泥岩,老顶为细砂岩工作面采用长壁综采一次采全高采煤法采用双滚筒采煤机割煤,往返一次割两刀采用“三八制”工作制度,截深0.8m,每天八个循环,循环进尺0.8m,月推进度192m。
大巷采用胶带输送机运煤,辅助运输采用架线电机车牵引固定箱式矿车主井采用两套带平衡锤的22t箕斗提煤,副井采用一对1.5t矿车双层四车窄罐笼和一个带平衡锤的1.5t矿车双层四车宽罐笼运料和升降人员专题部分题目为《采场底板突水机理分析及预测》,主要分析了关于采场底板突水的一般机理及影响因素,并总结了如何预测底板突水的方法翻译部分题目为《 Physical simulation of rock burst induced by stress waves》,主要介绍了通过仿真模拟应力波对于岩爆的影响关键词:山阳煤矿;双立井;带区布置;综采大采高;中央并列式ABSTRACTThe general design is about a 3.0 Mt/a new underground mine design of Shanyang coal mine. Shanyang coal mine is located in Heyang,Shananxi province. It’s about 12.8 km on the strike and 5.5 km on the dip,with the70.4km2 total horizontal area. The minable coal seam is 5# with an average thickness of 4.5 m and an average dip of 7°. The proved reserves of this coal mine are 456.25Mt and the minable reserves are 316.98 Mt, with a mine life of 75.5a. The normal mine inflow is 380.60m3/h and the maximum mine inflow is 436.69m3/h. The mine gas emission rate is2.256m3/t which can be recognized as low gas mine. Based on the geological condition of the mine, this design uses a duel-vertical shaft single-level development method,the way ofpreparation are strip and district(panel),which divided into six bands ,and one strip,five districts(panels), and track roadway, belt conveyor roadway and return airway are all rock roadways, arranged in the floor rock of 5# coal seam. The design applies strip preparation against the first band of West four which divided into 19 stirps totally, and conducted coal conveyance, ventilation, gangue conveyance and electricity designing.The design conducted coal mining technology design against the 5401 face. The coal seam average thickness of this working face is 4.52 m and the average dip is3°, the immediate roof is mud stone and the main roof is sand stone. The working face applies fullymechanized longwall full-height coal cavingmethod, and uses double drum shearer cutting coal which cuts twice each working cycle."Three-Eight" working system has been used in this design and the depth-web is 0.8 m with etght working cycles per day, and the advance of a working cycle is 0.8 m and the advance is 192 m per month.Main roadway makes use of belt conveyor to transport coal resource, and trolleylocomotive to be assistant transport. The main shaft uses double 22t skips to lift coal with a balancehammer and the auxiliary shaft uses a twins narrow 1.5 t four-car double-deck cage and a wide 1.5t four-car double-deck cage to lift material and personnel transportation.The monographic studyentitled "Mining Floor Analysis and Forecast of water inrush mechanism",analysis of the mechanism and influencing factors on the stope floor water bursting and summarizes how to predicte it 。
The titleof the translated academic paper is "Physical simulation of rock burst induced by stress waves",through the simulation of stress wave induce rock burst.Keywords:Shanyang coal mine; double vertical shaft;strip mode; full-height coal caving;central parallel; 目录一般部分1 矿区概述及井田地质特征 11.1矿区概述 11.1.1矿区地理位置 11.1.2地形地貌 11.1.3地面河流及水体 21.1.4矿区气象及地震 21.1.5矿区电力供应 21.1.6矿区经济概况 21.2井田地质特征 31.2.1井田地质构造 31.2.2水文地质 61.3煤层特征 91.3.1煤层 91.3.2煤的特性 101.3.3瓦斯、煤尘和煤的自燃 112井田境界及储量 122.1井田境界 122.2矿井工业储量 122.2.1储量计算基础 122.2.2矿井工业储量 132.3 矿井可采储量 142.3.1矿井永久保护煤柱损失量 142.3.2 矿井可采储量 163 矿井工作制度、设计生产能力及服务年限 173.1 矿井工作制度 173.2矿井设计生产能力及服务年限 173.2.1确定依据 173.2.2矿井设计生产能力 173.2.3矿井服务年限 173.2.4井型校核 174 井田开拓 194.1井田开拓的基本问题 194.1.1确定井筒形式、数目、位置及坐标 194.1.2工业场地的位置 204.1.3开采水平的确定及采盘区划分 204.1.4主要开拓巷道 214.1.5开拓方案比较 214.2 矿井基本巷道 274.2.1井筒 274.2.2井底车场及硐室 304.2.3井底车场巷道及硐室支护 324.2.4主要开拓巷道 325 准备方式—带区巷道布置 355.1煤层地质特征 355.1.1带区位置 355.1.2带区煤层特征 355.1.3煤层顶底板岩石构造情况 355.1.4水文地质 355.1.5地质构造 355.1.6地表情况 355.2带区巷道布置及生产系统 355.2.1带区准备方式的确定 355.2.2带区巷道布置 365.2.3带区生产系统 365.2.4带区内巷道掘进方法 375.2.5带区生产能力及采出率 385.3带区车场选型计算 396 采煤方法 406.1 采。