煤田地质与勘探
煤田地質與勘探
매전지질여감탐
COAL GEOLOGY & EXPLORATION
2014年
5期
17-24
,共8页
低煤阶%煤层气系统%侏罗系%次生生物气%演化阶段%鄂尔多斯盆地
低煤階%煤層氣繫統%侏囉繫%次生生物氣%縯化階段%鄂爾多斯盆地
저매계%매층기계통%주라계%차생생물기%연화계단%악이다사분지
low rank%CBM system%Jurassic%secondary biogenic gas%evolution stages%Ordos basin
低煤阶煤层气作为一种非常规天然气资源,具有良好的勘探开发前景。我国低煤阶煤层气资源丰富,进行低煤阶煤层气系统演化分析,对其富集成藏及开发具有重要的理论意义。鄂尔多斯盆地煤层甲烷的碳同位素δ13C1为-33.1‰~-80.0‰,氢同位素4CHdD 为-235‰~-268‰。该盆地侏罗系煤层气藏主要有次生生物气与热成因气构成的混合型煤层气藏和热成因气藏两种类型。据构造热事件、煤层气组分及成因,结合不同阶段的煤层埋深、变质程度和生气特征等,将鄂尔多斯盆地侏罗系低煤阶煤层气系统演化划分为4个阶段:煤系浅埋-原生生物气阶段﹑煤系深埋-热成因气阶段﹑煤系抬升-吸附气逃逸散失阶段﹑煤系局部沉降-次生生物气补充阶段。其中,煤系深埋-热成因气阶段和局部沉降-次生生物气阶段是低煤阶煤层气资源的主要形成阶段。次生生物气的补充是鄂尔多斯盆地侏罗系低煤阶煤层气成功开发的重要气源。鄂尔多斯盆地侏罗系煤层气藏应属于单斜式富气成藏模式。
低煤階煤層氣作為一種非常規天然氣資源,具有良好的勘探開髮前景。我國低煤階煤層氣資源豐富,進行低煤階煤層氣繫統縯化分析,對其富集成藏及開髮具有重要的理論意義。鄂爾多斯盆地煤層甲烷的碳同位素δ13C1為-33.1‰~-80.0‰,氫同位素4CHdD 為-235‰~-268‰。該盆地侏囉繫煤層氣藏主要有次生生物氣與熱成因氣構成的混閤型煤層氣藏和熱成因氣藏兩種類型。據構造熱事件、煤層氣組分及成因,結閤不同階段的煤層埋深、變質程度和生氣特徵等,將鄂爾多斯盆地侏囉繫低煤階煤層氣繫統縯化劃分為4箇階段:煤繫淺埋-原生生物氣階段﹑煤繫深埋-熱成因氣階段﹑煤繫抬升-吸附氣逃逸散失階段﹑煤繫跼部沉降-次生生物氣補充階段。其中,煤繫深埋-熱成因氣階段和跼部沉降-次生生物氣階段是低煤階煤層氣資源的主要形成階段。次生生物氣的補充是鄂爾多斯盆地侏囉繫低煤階煤層氣成功開髮的重要氣源。鄂爾多斯盆地侏囉繫煤層氣藏應屬于單斜式富氣成藏模式。
저매계매층기작위일충비상규천연기자원,구유량호적감탐개발전경。아국저매계매층기자원봉부,진행저매계매층기계통연화분석,대기부집성장급개발구유중요적이론의의。악이다사분지매층갑완적탄동위소δ13C1위-33.1‰~-80.0‰,경동위소4CHdD 위-235‰~-268‰。해분지주라계매층기장주요유차생생물기여열성인기구성적혼합형매층기장화열성인기장량충류형。거구조열사건、매층기조분급성인,결합불동계단적매층매심、변질정도화생기특정등,장악이다사분지주라계저매계매층기계통연화화분위4개계단:매계천매-원생생물기계단﹑매계심매-열성인기계단﹑매계태승-흡부기도일산실계단﹑매계국부침강-차생생물기보충계단。기중,매계심매-열성인기계단화국부침강-차생생물기계단시저매계매층기자원적주요형성계단。차생생물기적보충시악이다사분지주라계저매계매층기성공개발적중요기원。악이다사분지주라계매층기장응속우단사식부기성장모식。
coalbed methane of low rank coal as an unconventional gas resource, has good development prospect. There are abundant CBM resources of low rank coal in China. It is of important significance for the study of CBM accumulation and CBM development to analyze the evaluation of CBM system of low rank coal. Generally, CBM is compositionally dominated by methane withδ13C1 values ranging approximately from -33.1‰ ~ -80‰,CH4dDfrom -235‰ ~ -268‰. In Ordos basin, there are mainly two types of CBM reservoir: mixed reservoir of secondary biogenetic gas and reservoir of thermogenetic gas. Based on the analyses of CBM components, tectonic thermal event, sedimentary and burial history of Jurassic coal-bearing strata, combined with metamorphism and gas generation process of coals, Jurassic CBM system in Ordos basin is subdivided into four evolutionary stages as follows: shallowly-buried peat and early biogenic gas stage, deeply buried coal seams and thermogenic gas stage, stage of coal measures lifting and escape as well as loss of adsorbed gas, stage of local subsidence of coal measures and compliment of secondary biogenetic gas. Among them, the stage of deep burial and thermogenetic gas, the stage of local subsidence and secondary biogenetic gas are major CBM-forming stages. Supplement of secondary biogenic gas is an important gas source for successful CBM development of Jurassic low rank coal in Ordos basin. The CBM reservoirs of Jurassic in Ordos basin belongs to the typical monoclinic mode of gas enrichment and reservoir formation.