祁東煤礦3.0Mta新井設計含5張CAD圖.zip,祁東,煤礦,3.0,Mta,設計,CAD 祁東煤礦3.0Mt/a新井設計 摘 要 本設計包括三個部分：一般部分、專題部分和翻譯部分。 一般部分為祁煤礦3.0 Mt/a新井設計。一般部分共包括10章：1.礦區(qū)概況與井田地質特征；2.井田境界和儲量；3.礦井工作制度和設計生產能力及服務年限；4.井田開拓；5.準備方式―采區(qū)巷道布置；6.采煤方法；7.井下運輸；8.礦井提升；9.礦井通風及安全；10. 礦井基本技術經濟指標。 祁東煤礦位于安徽省宿州市東南，京滬鐵路西側，井田中心距宿州市約20km，交通便利。井田形狀近似長方形，東西長約9 km，南北寬約3.0 km，面積約24 km2。井田內開采61煤層和71煤層，先采61，做為解放層開采，后開采71煤。煤層傾角12~15°，平均12、3°。煤層平均厚度61煤層7.5 m，71煤7.0 m。井田地質條件較為簡單。 礦井工業(yè)儲量為330.2297Mt，可采儲量為220.6853Mt。礦井設計生產能力為3.0Mt/a。礦井服務年限61.3 a。礦井涌水量不大，正常涌水量為436m3/h，最大涌水量為586 m3/h。61煤相對瓦斯涌出量為10 m3/t，屬高瓦斯煤層。礦井煤塵無爆炸危險性，煤層不易自燃，自然發(fā)火等級為Ⅲ級。 礦井采用暗斜井兩水平開拓，下行開采。一礦一面，采煤方法為綜合機械化放頂煤開采。全礦采用膠帶運輸機運煤，輔助運輸前期采用1.5 t固定箱礦車，后期采用齒軌車運輸。礦井通風方式前后期均為為采區(qū)式通風。 礦井年工作日為330 d，日凈提升時間16 h，工作制度為“四六制”。 專題部分題目是煤炭地下氣化開采技術基礎研究。以一些煤礦工程實例為例，通過建立模型進行分析計算，研究了煤炭地下氣化過程中頂板巖層移動特征、煤炭地下氣化過程中半焦孔隙結構的變化規(guī)律以及煤炭地下氣化過程中覆巖應力場的數(shù)值，得出關于以上三方面的相關結論。 翻譯部分是一篇關于煤層氣恢復技術的論文，英文題目為 Simulation of CO2-geosequestration enhanced coal bed methane recovery with a deformation-flow coupled model 關鍵詞：新井設計；綜合機械化放頂煤開采;采區(qū)式通風；立井開拓；采區(qū) ABSTRACT This design includes three parts: the general part, special subject part and translation part. The general part is a new design of Qidong mine. This design includes ten chapters: 1.An outline of the mine field geology; 2.Boundary and the reserves of mine; 3.The service life and working system of mine; 4.Development engineering of coalfield; 5.The layout of mining area; 6.The method used in coal mining; 7. Transportation of the underground; 8.The lifting of the mine; 9. The ventilation and the safety operation of the mine; 10.The basic economic and technical norms. The Qidong mine locates at the crosspart of Qixian, Xisipo and Guzhen of Suzhou in Anhui province, 20 km away from the center of the town. And the transportation is very convenience. The shape of minefield is like a rectangle which has a length of 9 km in the east and west and a width of 3 km in the south and north on average. The total plane area of the mine is about 24 km2. There are two coal seams in the mine —NO.61 and NO. 71. Mining the NO.61 coal seam firstly.The angle is about 9.05~13.8 degree with an average of 12 and the thickness of both coal seams is about 7.0 m. The minefield geological condition is simple. The proved reserves of the minefield are 330.2297 million tons. The recoverable reserves are 220.6853 million tons. The designed productive capacity is 3.0 million tons per year. The service life is 61.3 years. The normal water flow of the mine is 437 m3 per hour and the max water flow is 586 m3 per hour. The Relative gas discharge quantity is 10 m3 per ton, whichmeans it is a high gaseous mine. The coal seam is hardly spontaneous combustion and the level of spontaneous combustion is Ⅲ. Apart from coal without gas, the coal seam is of high explosion hazard. The development of the mine is double levels with vertical shaft at the first level and inclind shaft at the second level. The number of the working faces is only one. The mining method is Comprehensive mechanization with putting off the top coal technology. Several belt conveyers undertake the job of coal transport in the mine and the auxiliary transportation system is centralized juxtapose. The ventilation method is diagonal ventilation system. The working days in a year are 330. Everyday it takes 16 hours in lifting the coal. The working system in the mine is “four-six”. The title of the special subject part is “Underground Coal Gasification in mining technology basic research”. By some examples of coal mine project, analyzed and calculated by modeling, Study the mobility characteristics of the roof strata in underground coal gasification process, the variation of the semi-coke pore structure in the process of underground coal gasification and underground coal gasification process in the overburden rock stress field value, conclusions drawn on these three aspects wind stress, the evolution of deformation is obtained when the dual roadway deformation, Deputy Lane by the basic law of mining and the left pillar set a reasonable size, with similar conditions Roadway reference. The translated academic paper is about classification technique for danger classes of coal and gas outburst in deep coal mines. Its title is “Simulation of CO2-geosequestration enhanced coal bed methane recovery with a deformation-flow coupled model”. Keywords: design of mine; fully mechanized mining with top coal caving technology；Mining area ventilation；vertical shaft development；mining distr