1、摘 要本设计包括三个部分:一般设计部分、专题设计部分和翻译部分。一般部分针对淮南丁集矿井进行了井型为1.8 Mt/a的新井设计。丁集矿井位于安徽省淮南市境内,交通较为便利。井田走向长约7.0 km,倾向长约5.5km,面积约48 km2。主采煤层为11-2#煤层,平均倾角56,平均厚度3.49 m。井田工业储量为234.9Mt,可采储量175.6 Mt,矿井服务年限为75.02 a。矿井正常涌水量为180m3/h,最大涌水量为220m3/h;矿井相对瓦斯涌出量为5.79 m3/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,井田采用带区采区式布置方式,共划分为七个带区和两个采
2、区,轨道大巷、胶带机大巷皆为岩石大巷,布置在11-2#煤层底板岩层中。考虑到本矿井为低瓦斯矿井,矿井通风方式采用两翼对角式通风,并在开采前预掘底板瓦斯抽排巷进行瓦斯提前卸压抽放。 针对东一带区采用了带区准备方式,共划分8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11201工作面进行了采煤工艺设计。该工作面煤层平均厚度为3.49 m,平均倾角5,直接顶为的碳质泥岩,老顶为粉砂岩。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,每天六个循环,循环进尺4.8m,月推进度144 m。大巷采用胶带输送机运煤,辅助运输采
3、用蓄电池式电机车牵引固定箱式矿车。主井采用两套带平衡锤的16t箕斗提煤,副井采用一对1.5 t矿车双层四车窄罐笼和一个带平衡锤的1.5 t矿车双层四车宽罐笼运料和升降人员。专题部分题目是煤矿冲击矿压,翻译部分题目为Fuzzy evaluation on geological conditions of coal seam in China,主要介绍了现行数值模拟实验中岩体特性参数的选取依据及在工程现场的应用。关键词:丁集矿井;双立井;带区布置;综采大采高;两翼对角式;软岩巷道;矿压观测ABSTRACTThis design can be divided into three sections:
4、 General design, Monographic study and Translation of an academic paper.The general design is about a 1.80 Mt/a new underground mine design of Dingji coal mine. Dingji coal mine is located in Huainan, Anhui province, and the traffic is quite convenient. Its about 7.0 km on the strike and 5.5 km on t
5、he dip, with the 48.0 km2 total horizontal area. The minable coal seam is 11-2# with an average thickness of 3.49 m and an average dip of 5. The proved reserves of this coal mine are 234.9 Mt and the minable reserves are 175.6 Mt, with a mine life of 75.02 a. The normal mine inflow is 180 m3/h and t
6、he maximum mine inflow is 220 m3/h. The mine gas emission rate is 5.79 m3/t which can be recognised as low gas mine. Based on the geological condition of the mine, this design uses a two-shaft single-level development method, Ida-style layout with full band mode, divided into 8 bands total, track ro
7、adway, belt conveyor roadway and return airway are all rock roadways, arranged in the floor rock of 11-2# coal seam. Taking into account of the low gas emission, mine ventilation method use two diagonal wings ventilation, and excave bottom gas drainage roadway before mining to relief gas pressure in
8、 advance.Designed first mining district makes use of the method of the band mode preparation, the length of working face is 240 m, which uses fully-mechanized coal caving mining methods. The working system is “three-eight”which produces 330 d/a.Main roadway makes use of belt conveyor to transport co
9、al resource, and battery locomotive to be assistant transport. The monographic study entitled Case Study and Research of Deep Soft Rock Pressure Observation, The title of the translated academic paper is “Fuzzy evaluation on geological conditions of coal seam in China”.Keywords:Dingji coal mine;doub
10、le vertical shaft; band mode; large mining height; two diagonal wings ventilation; soft rock roadway; pressure observation目 录一般部分1 矿区概况与井田地质特征11.1概况11.1.1地理位置与交通11.1.2地形地貌及水系11.1.3 气象及地震11.1.4 矿井开发情况21.2井田地质特征31.2.1地层31.2.2构造41.2.3 水文地质特征41.3煤层51.3.1煤层51.3.2煤质、煤类与煤的用途51.4开采技术条件61.4.1矿井涌水61.4.2煤层顶底板岩
11、性特征81.4.3煤层瓦斯91.4.4地热92 井田境界和储量112.1井田境界112.1.1井田边界112.2矿井工业储量112.2.1矿井储量计算基础112.2.2矿井地质储量计算112.2.3矿井工业储量计算112.3 矿井可采储量122.3.1井田边界煤柱122.3.2工业广场煤柱122.3.3断层保护煤柱132.3.4大巷保护煤柱132.3.5矿井可采储量133 矿井工作制度、设计生产能力及服务年限143.1矿井工作制度143.2矿井设计生产能力及服务年限143.2.1矿井设计生产能力确定依据143.2.2矿井设计生产能力143.2.3矿井的服务年限143.2.4井型校核154 井田
12、开拓164.1井田开拓的基本问题164.1.1确定井筒形式、数目、位置及坐标164.1.2主、副井井筒位置的选择174.1.3工业广场的位置、形状和面积的确定184.1.4开采水平的确定及井田的再划分184.1.5主要开拓巷道184.1.6井田开拓方案提出与比较194.2 矿井基本巷道234.2.1井筒234.2.2开拓巷道264.2.3井底车场及硐室284.2.3巷道支护295 准备方式带区巷道布置325.1煤层地质特征325.1.1带区位置325.1.2带区煤层特征325.1.3煤层顶底板325.1.4水文地质325.1.5地质构造325.1.6煤层瓦斯325.1.7煤尘和自燃335.1.
13、8地表情况335.2 带区巷道布置及生产系统335.2.1带区准备方式的确定335.2.2带区巷道布置335.2.3带区生产系统345.2.4带区内巷道掘进方法355.2.5带区生产能力及采出率355.3带区车场选型设计365.3.1带区下部车场365.3.2带区煤仓375.3.3带区变电所376 采煤方法386.1采煤工艺方式386.1.1带区煤层特征及地质条件386.1.2确定采煤工艺方式386.1.3回采工作面参数的确定396.1.4回采工作面采煤机、刮板输送机选型396.1.5回采工作面支护方式416.1.6端头支护及超前支护方式436.1.7各工艺过程注意事项446.1.8回采工作面
14、正规循环作业456.2首采工作面巷道布置476.2.1回采巷道布置方式476.2.2回采巷道参数477 井下运输497.1概述497.1.1矿井设计生产能力及工作制度497.1.2运输距离和货载量497.1.3矿井运输系统497.2带区运输设备选择507.2.1设备选型原则507.2.2带区运输设备选型507.2.3带区运输设备能力验算527.3大巷运输设备选择538 矿井提升558.1概述558.2主副井提升558.2.1主井提升558.2.2副井提升579 矿井通风及安全589.1矿井通风系统的选择589.1.1矿井通风系统的基本要求589.1.2矿井通风系统的确定589.1.3采区通风系
15、统的确定599.2矿井风量计算609.2.1通风容易时期和通风困难时期采煤方案的确定609.2.2各用风地点的用风量和矿井总用风量639.2.3风量分配及风速验算669.2.4通风构筑物679.3矿井通风阻力计算679.3.1计算原则679.3.2矿井最大阻力路线689.3.3矿井通风阻力计算689.4选择矿井通风设备729.4.1选择主要通风机的基本原则729.4.2通风机风压的确定729.4.3主要通风机工况点749.4.4 主要通风机的选择及风机性能曲线749.4.5电动机选型779.5安全灾害的预防措施779.5.1预防瓦斯和煤尘爆炸的措施779.5.2预防井下火灾的措施789.5.3防水措施7810 设计矿井基本技术经济指标79参考文献80专题部分煤
