不同岩性顶板组合煤岩生排滞气模拟实验及勘探启示

Hydrocarbon generation-expulsion-retention simulation experiments of coal rock with different roof lithology combinations and its implications for exploration

  • 摘要: 为揭示顶板岩性对煤层气形成富集的控制机制,以鄂尔多斯盆地东北缘清水河地区石炭系太原组低阶煤为研究对象,基于盆地中东部D探区的实际地质背景,设计了温度—压力模拟条件,利用生排烃模拟装置开展了砂岩、灰岩、泥岩3种岩性顶板条件下的煤岩生排滞气模拟实验。结果表明:(1)3种顶板条件下,总烃气产率随热演化程度增加而持续升高,在镜质体反射率(Ro)为1.2%(模拟温度370 ℃)之后快速增长,Ro增至2.0%(模拟温度450 ℃)后增速趋缓,其中灰岩顶板条件产率最高。(2)滞留烃气能力与顶板突破压力呈显著正相关:灰岩顶板(突破压力80.12 MPa)封闭性最强,其煤岩滞留烃气产率占比及单位岩石滞留气含量在各演化阶段(尤其是Ro≥1.5%,模拟温度大于400 ℃)均最高;泥岩顶板(突破压力25.43 MPa)次之;砂岩顶板(突破压力8.77 MPa)最低。在Ro=1.5%时,灰岩、泥岩顶板组合的滞留烃气含量分别为砂岩顶板组合的1.33和1.23倍。顶板岩性通过控制生烃期超压流体的排出效率,从源头上控制煤层气的最大富集程度。高突破压力顶板(灰岩、泥岩)能有效封存游离气、维持储层压力,从而保障高含气量。勘探实践证实,鄂尔多斯盆地D探区灰岩/泥岩顶板煤层的含气量显著高于砂岩顶板煤层。研究明确了“源—储—盖”系统中顶板的关键控藏作用,指出鄂尔多斯、鄂西渝东等地区“灰煤”、“泥煤”组合发育区是煤层气勘探的有利目标。

     

    Abstract: To investigate the controlling mechanism of roof lithology on coalbed methane (CBM) formation and enrichment, low-rank coals from the Carboniferous Taiyuan Formation in the Qingshuihe area, northeastern Ordos Basin, were selected as the research objects. Based on the actual geological background of exploration area D in the central-eastern Ordos Basin, temperature-pressure simulation conditions were designed. Using a hydrocarbon generation-expulsion simulation apparatus, hydrocarbon generation-expulsion-retention simulation experiments were conducted on coal rocks under three roof lithologies (sandstone, limestone, mudstone). The results showed that: (1) Under the three roof conditions, the total hydrocarbon gas yield continuously increased with thermal maturity. It increased rapidly after the vitrinite reflectance (Ro) reached 1.2% (simulated temperature 370 ℃), and then the growth rate slowed down after Ro reached 2.0% (simulated temperature 450 ℃). Among the three roof conditions, limestone roof yielded the highest gas production. (2) The gas retention capacity was significantly positively correlated with roof breakthrough pressure. The limestone roof (breakthrough pressure 80.12 MPa) had the strongest sealing capacity, and its coal rock exhibited the highest ratio of retained hydrocarbon gas and the highest retained gas content per unit rock at all evolution stages, especially when Ro ≥ 1.50% (simulated temperature > 400 ℃). The mudstone roof (breakthrough pressure 25.43 MPa) ranked second, and the sandstone roof (breakthrough pressure 8.77 MPa) was the lowest. At Ro = 1.50%, the retained gas content under limestone and mudstone roof combinations was 1.33 and 1.23 times that of the sandstone roof combination, respectively. Roof lithology controlled the maximum enrichment degree of CBM at the source by governing the expulsion efficiency of overpressured fluids during the hydrocarbon generation stage. High-breakthrough-pressure roofs (limestone, mudstone) effectively sealed free gas and maintained reservoir pressure, thereby ensuring high gas content. Exploration practices confirmed that in exploration area D of the Ordos Basin, the gas content in coal seams with limestone/mudstone roofs was significantly higher than that of those with sandstone roofs. This study clarifies the critical role of roof in the "source-reservoir-seal" system and suggests that areas with "limestone-coal" and "mudstone-coal" combinations in regions such as the Ordos Basin, western Hubei, and eastern Chongqing are favorable targets for CBM exploration.

     

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