張雙樓礦5.0Mta新井設計【含CAD圖紙+文檔】,含CAD圖紙+文檔,張雙樓礦,mta,設計,cad,圖紙,文檔 摘 要 一般部分針對張雙樓礦井進行了井型為1.8Mt/a的新井設計。張雙樓礦井位于江蘇省徐州市境內(nèi)，井田走向長約9.52km，傾向長約3.27km，面積約32.06km2。主采煤層為9煤，平均傾角20°，平均厚度5.8m。井田工業(yè)儲量為267.74Mt，可采儲量173.19Mt，礦井服務年限為74a。礦井正常涌水量為294m3/h，最大涌水量為453m3/h；礦井相對瓦斯涌出量為1.64m3/t，屬低瓦斯礦井。 根據(jù)井田地質條件，設計采用立井兩水平（暗斜井延深）開拓方式，井田采用全采區(qū)式布置方式，共劃分為十個采區(qū)，軌道大巷、運輸大巷皆為巖石大巷，布置在9煤層底板巖層中。由于本礦井為低瓦斯礦井，故采用中央并列式為主要通風方式，另掘西風井輔助通風。 針對首采區(qū)西二采區(qū)采用了采區(qū)準備方式，采用兩翼對角式開采，共分為11個區(qū)段，并進行了運煤、通風、運料、排矸、供電系統(tǒng)設計。 針對9201工作面進行了采煤工藝設計。該工作面煤層平均厚度為5.6m，平均傾角19°，直接頂為砂質泥巖，老頂為泥巖。工作面采用長壁綜采放頂煤一次采全高采煤法。采用雙滾筒采煤機割煤，往返一次割兩刀。采用“四六制”工作制度，截深0.8m，每天六個循環(huán)，循環(huán)進尺4.8m，月推進度144m。 大巷采用膠帶輸送機運煤，輔助運輸采用直流架線式電機車牽引固定箱式礦車。主井采用兩套帶平衡錘的12t箕斗提煤，副井采用多繩摩擦式提升機提升，裝備一套標準罐籠。 專題部分題目為《綜采工作面的瓦斯涌出規(guī)律及瓦斯涌出量的預測》，本文較系統(tǒng)的論述了煤層瓦斯的賦存狀態(tài)與煤對瓦斯的吸附作用以及煤層瓦斯運移的基本規(guī)律，通過資料的收集、整理和分析，總結了綜采工作面瓦斯?jié)舛确植?、采空區(qū)瓦斯流動及其濃度分布規(guī)律。 翻譯部分題目為《Efficient mine microseismic monitoring》，主要介紹了高效礦井微震監(jiān)測方案的重要問題。 關鍵詞：張雙樓礦井； 立井兩水平； 采區(qū)布置； 綜采放頂煤； 中央并列式； 軟巖巷道； 瓦斯涌出規(guī)律； 瓦斯涌出量； 微震監(jiān)測 ABSTRACT The general design is about a 1.80 Mt/a new underground mine design of Zhangshuanglou coal mine. Zhangshuanglou coal mine is located in Xuzhou, JiangSu province. It’s about 9.52 km on the strike and 3.27 km on the dip, with the 32.06 km2 total horizontal area. The minable coal seam is 9# with an average thickness of 5.8 m and an average dip of 20°. The proved reserves of this coal mine are 267.74 Mt and the minable reserves are 173.19 Mt, with a mine life of 74 a. The normal mine inflow is 294 m3/h and the maximum mine inflow is 453 m3/h. The mine gas emission rate is 1.64 m3/t which can be recognized as low gas mine. Based on the geological condition of the mine, this design uses a shaft two level(dark deep inclined shaft extension) development method, and full mining area preparation ,which divided into ten mining area, and track roadway and belt conveyor roadway are all rock roadways, arranged in the floor rock of 9# coal seam. Taking into account of the low gas emission, mine main ventilation method use central listed ventilation. The design applies mining area preparation against the first band of West Two which divided into 11 section totally, and conducted coal conveyance, ventilation, gangue conveyance and electricity designing. The design conducted coal mining technology design against the 9201 face. The coal seam average thickness of this working face is 5.6 m and the average dip is 19°, the immediate roof is sandy mudstone and the main roof is mudstone. The working face applies longwall top coal caving mining mining method, and uses double drum shearer cutting coal which cuts twice each working cycle. "Four-Six" working system has been used in this design and the depth-web is 0.8 m with six working cycles per day, and the advance of a working cycle is 4.8 m and the advance is 144 m per month. Main roadway makes use of belt conveyor to transport coal resource, and DC overhead line electric locomotive traction fixed box-type tramcar to be assistant transport. The main shaft uses double 12t skips to lift coal with a balance hammer and the auxiliary shaft uses multirope friction hoist mention and a standard cage. The monographic study entitled " Longwall Face Gas Emission Law and Gas Emission Prediction ". This article discusses the basic law of the mode of occurrence of the coal seam gas adsorption of coal gas and coal seam gas migration and by data collection, collation and analysis, summed up the gas concentration distribution of mechanized mining face and goaf gas flow and concentration distribution of the law. The title of the translated academic paper is " Efficient mine microseismic monitoring ". This paper mainly introduces the important issue of efficient mine microseismic monitoring programs. Keywords:Zhangshuanglou coal mine; shaft two level; mining area layout; comprehensive caving; central parallel; soft rock roadway; gas emission law; gas emission prediction; microseismic monitoring