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。一般部分为东荣一矿1.2 Mt/a的新井设计,东荣一矿位于黑龙江省集贤县境内,交通十分便利。井田走向(东西)长平均约7 km,倾向(南北)长平均约4km,井田水平面积为28 km2。主采煤层一层,即16#煤层,平均倾角18.0,厚约2.96 m。井田工业储量为335.75 Mt,可采储量238.67Mt,矿井服务年限为103a。井田地质条件简单。表土层平均厚度147 m;矿井正常涌水量为327 m3/h,最大涌水量为714m3/h;煤层硬度系数f=2.3,煤质牌号为长焰煤;矿井相对瓦斯涌出量为3.73 m3/min,属低瓦斯矿井;
2、煤层有自然发火倾向,煤尘无爆炸危险。矿井采用双平硐两水平开拓,采煤方法为走向长壁采煤法。大巷采用带式输送机运煤,辅助运输采用1.4 t固定箱式矿车。设计首采区采用采区准备方式,工作面长度210 m,采用一次采全高采煤法,全部跨落法处理采空区。矿井采用“三八”制作业,两班半生产,半班检修。日进6个循环,循环进尺0.8m,日产量4412.06 t。矿井采用两翼对角式通风。通风容易时期矿井总需风量3324 m3/min,矿井通风总阻力856.2 Pa,风阻0.321 Ns2/m8,等积孔3.20 m2,矿井通风容易。矿井通风困难时期矿井总风量3324 m3/min,矿井通风总阻力1224 Pa,风阻
3、0.459 Ns2/m8,等积孔2.86 m2,矿井通风中等困难。设计矿井的吨煤成本180 元/t。专题部分题目是矿井冲击矿压及防治措施。翻译部分是从1981年至2011年煤柱设计智能演变英文原文题目为: The evolution of intelligent coalpillar design: 1981-2011关键词:立井;上下山开采;采区;走向长壁采煤法;两翼对角式ABSTRACTThis design can be divided into three sections: general design, monographic study and translation of an
4、 academic paper.The general design is about a 1.2 Mt/a new underground mine design of Dongrong No.1 Coal Mine that lies in Jixian country Heilongjiang province, the traffic is very convenient. Its about 7.0 km on the strike and 4.0km on the dip,with the 28.0 km2 total horizontal area. The minable co
5、al seam of this mine is only 2 with an average thickness of 3.50 m and an average dip of 18.0. The proved reserves of this coal mine are 335.75 Mt and the minable reserves are 238.67 Mt, with a mine life of 103 years .The geological condition of the mine is relatively simple. The normal mine inflow
6、is 100 m3/h and the maximum mine inflow is 200 m3/h. It is anthracite coal spontaneous combustion tendency, and its a coal that has no dust explosion.This mine adopts opening up by adits with two mining level. The adopted coal winning method is longwall mining to the dip or to the rise. Main roadway
7、 makes use of belt conveyor to transport coal resource, and mine car to be assistant transport.Designed first mining district makes use of the method of preparation in mining area , the length of working face is 230 m, which uses fully-mechanized coal mining technology, and fully caving method to de
8、al with goaf. The working system is “three-eight”,with two and half teams mining, and the other overhauling. Every mining team makes three working cycle, with seven working cycle everyday. Advance of working cycle is 0.6 m, and quantity of 4402.06 ton coal is maked everyday.The mine makes use of dia
9、gonal ventilation method. At the easy time of mine ventilation, the total air quantity is 3324 m3 per minute, the total mine ventilation resistance is 693.3 Pa, the coefficient of resistance is 0.226 Ns2/m8, equivalent orifice is 3.20 m2. At the difficult time of mine ventilation, the total air quan
10、tity is about 3324 m3 per minute, the total mine ventilation resistance is 1396.3 Pa, the coefficient of resistance is 0.459 Ns2/m8, equivalent orifice is 2.80 m2. The cost of the designed mine is 180 yuan per ton.The monographic study is deformation and failure mechanism and roof timbering techniqu
11、e study on roadway of composite roof.The translated academic paper is about implications for stress measurement programs and numerical stability analysis of faults in mines. Its title is that The evolution of intelligent coalpillar design: 1981-2011Keywords:vertical shaft ; up-dip and down-dip mingi
12、ng; mining area ; longwall mining on the strike ; diagonal ventilation 目录一般部分1井田概况及地质特征11.1 井田概况11.1.1交通位置11.1.2地形地貌及水系11.1.3气象21.1.4地震21.1.5矿区内工农业及煤炭生产、建设情况21.2 地质特征21.2.1区域地质21.2.2井田地质21.2.3岩浆岩31.2.4煤层31.2.5煤质31.2.6水文地质31.2.7其它开采技术条件51.3对资源条件的评价51.3.1对井田地质构造的评价51.3.2对煤层赋存条件的评价51.3.3对水文地质条件的评价61.3.
13、4对煤层其它开采条件的评价71.4结论72 井田境界及储量82.1井田境界82.1.1井田范围82.2矿井地质储量82.2.1储量计算基础82.2.2矿井地质储量计算92.2.3储量计算方法92.3矿井地质储量92.3.1储量计算基础92.3.2矿井地质储量计算92.3.3矿井工业储量计算102.4 矿井可采储量112.4.1井田边界断层及内部断层保护煤柱112.4.2工业广场保护煤柱122.4.3天窗保护煤柱132.4.4风井保护煤柱142.4.5大巷保护煤柱143 矿井工作制度、设计生产能力及服务年限153.1矿井工作制度153.2矿井设计生产能力及服务年限153.2.1确定依据153.2
14、.2矿井设计生产能力153.2.3矿井服务年限153.2.4井型校核164 井田开拓174.1井田开拓的基本问题174.1.1确定井筒形式、数目、位置174.1.2阶段划分和开采水平的确定194.1.3井田划分194.1.4主要开拓巷道204.1.5开拓方案比较204.2矿井基本巷道274.2.1井筒274.2.2井底车场及硐室314.2.3大巷324.2.4巷道支护365 准备方式采区巷道布置375.1煤层地质特征375.1.1采区位置375.1.2采区煤层特征375.1.3煤层顶底板岩石构造情况375.1.4水文地质375.1.5地质构造375.1.6地表情况375.2采区巷道布置及生产系
15、统375.2.1采区准备方式的确定375.2.2采区巷道布置375.2.3采区生产系统385.2.4首采区生产能力及采出率395.3采区车场选型计算405.3.1采区车场的形式405.3.2采区车场的调车方式415.3.3采区主要硐室布置416 采煤方法436.1采煤工艺方式436.1.1 采区煤层特征及地质条件436.1.2确定采煤工艺方式436.1.3回采工作面参数436.1.4回采工作面采煤机、刮板输送机选型446.1.5采煤工作面支护方式466.1.6端头支护及超前支护方式486.1.7各工艺过程注意事项496.1.8采煤工作面正规循环作业506.1.9 16101首采工作面回采巷道布置526.2.0回采巷道参数527 井下运输597.1概述597.1.1井下运输设计的原始条件和数据597.1.2运输距离和货载量597.1.3矿井运输系统597.2带区运输设备选择607.2.1设备选型原则607.2.2带区设备的选型607.2.3带区运输能
