Because of the influence of hydrocarbons,especially adsorbed hydrocarbons,on the detection of cracked hydrocarbon(S2)and total organic carbon(TOC),the hydrogen index(HI)-based hydrocarbon generation model deviates fro...Because of the influence of hydrocarbons,especially adsorbed hydrocarbons,on the detection of cracked hydrocarbon(S2)and total organic carbon(TOC),the hydrogen index(HI)-based hydrocarbon generation model deviates from actual practice.In this study,the shale in the first member of the Qingshankou Formation in the central depression of the Songliao Basin,where in northeastern China,was taken as the research object and a correction method for S2 and TOC was established.By correcting the experimental results of different maturity samples,the actual hydrocarbon generation model has been revealed,the differences before and after correction compared,and the evolutionary characteristics of the adsorbed hydrocarbon content were clarified.The results show that the organic matter enters the hydrocarbon generation threshold at R_(o)-0.5% and reaches the hydrocarbon generation peak at R_(o)-1.0% and that the hydrocarbon generation process ends at R_(o)-1.3%.The hydrocarbon generation model established based on the measured values has a‘lag effect’compared to actual values,and this extends the hydrocarbon generation window of organic matter and delays the hydrocarbon generation peak.With the increase of maturity,adsorbed hydrocarbon content shows the characteristics of‘first increasing,then stabilizing,and then decreasing’,and reache s the most abundant stage at Roof 0.9%-1.3%.展开更多
A quantitative evaluation model that integrates kerogen adsorption and clay pore adsorption of shale oil was proposed,and the evaluation charts of adsorption-swelling capacity of kerogen(Mk)and adsorbed oil capacity o...A quantitative evaluation model that integrates kerogen adsorption and clay pore adsorption of shale oil was proposed,and the evaluation charts of adsorption-swelling capacity of kerogen(Mk)and adsorbed oil capacity of clay minerals(Mc)were established,taking the 1st member of Cretaceous Qingshankou Formation in the northern Songliao Basin as an example.The model and charts were derived from swelling oil experiments performed on naturally evolved kerogens and adsorbed oil experiments on clays(separated from shale core samples).They were constructed on the basis of clarifying the control law of kerogen maturity evolution on its adsorption-swelling capacity,and considering the effect of both the clay pore surface area that occupied by adsorbed oil and formation temperature.The results are obtained in four aspects:(1)For the Qing 1 Member shale,with the increase of maturity,Mk decreases.Given Ro of 0.83%–1.65%,Mk is about 50–250 mg/g.(2)The clay in shale adsorbs asphaltene.Mc is 0.63 mg/m^(2),and about 15%of the clay pore surface is occupied by adsorbed oil.(3)In the low to medium maturity stages,the shale oil adsorption is controlled by organic matter.When Ro>1.3%,the shale oil adsorption capacity is contributed by clay pores.(4)The oil adsorption capacity evaluated on the surface at room temperature is 8%–22%(avg.15%)higher than that is held in the formations.The proposed evaluation model reveals the occurrence mechanisms of shale oils with different maturities,and provides a new insight for estimating the reserves of shale oil under formation temperature conditions.展开更多
Objective It has long been controversial that whether authigenic chlorite coatings in sandstone reservoirs can prevent precipitation of siliceous cements.It is commonly believed that chlorite coatings(also called chlo...Objective It has long been controversial that whether authigenic chlorite coatings in sandstone reservoirs can prevent precipitation of siliceous cements.It is commonly believed that chlorite coatings(also called chlorite films,chlorite linings,or chlorite rims)may prevent quartz overgrowth,and thus help the preservation of original pores in sandstone reservoirs.Recently,however,this assumption has been challenged by reservoir geologists.This dispute cannot be solved by mere analysis of thin sections,nor by chemical equations and diagenesis analysis.The main objective of the present contribution is to shed light on展开更多
To accurately measure and evaluate reserves is critical for ensuring successful production of unconventional oil and gas. This work proposes a volumetric model to evaluate the tight sandstone gas reserves of the Permi...To accurately measure and evaluate reserves is critical for ensuring successful production of unconventional oil and gas. This work proposes a volumetric model to evaluate the tight sandstone gas reserves of the Permian Sulige gas field in the Ordos Basin. The reserves can be determined by four major parameters of reservoir cutoffs, net pay, gas-bearing area and compression factor Z, which are controlled by reservoir characteristics and sedimentation. Well logging, seismic analysis, core analysis and gas testing, as well as thin section identification and SEM analysis were used to analyze the pore evolution and pore-throat structure. The porosity and permeability cutoffs are determined by distribution function curve,empirical statistics and intersection plot. Net pay and gas-bearing area are determined based on the cutoffs, gas testing and sand body distribution, and the compression factor Z is obtained by gas component. The results demonstrate that the reservoir in the Sulige gas field is characterized by ultralow porosity and permeability, and the cutoffs of porosity and permeability are 5% and 0.15×10^(–3) μm^2, respectively. The net pay and gas-bearing area are mainly affected by the sedimentary facies, sand body types and distribution. The gas component is dominated by methane which accounts for more than 90%, and the compression factor Z of H_8(P_2h_8) and S_1(P_1s_1) are 0.98 and 0.985, respectively. The distributary channels stacked and overlapped, forming a wide and thick sand body with good developed intergranular pores and intercrystalline pores. The upper part of channel sand with good porosity and permeability can be sweet spot for gas exploration. The complete set of calculation systems proposed for tight gas reserve calculation has proved to be effective based on application and feedback. This model provides a new concept and consideration for reserve prediction and calculation in other areas.展开更多
1 Introduction There is a set of organic rich shale at E22S4sub-member in damnintun sag.The organic material is typically type I.In recent years,breakthrough was obtained in shale oil exploration.The wettability of or...1 Introduction There is a set of organic rich shale at E22S4sub-member in damnintun sag.The organic material is typically type I.In recent years,breakthrough was obtained in shale oil exploration.The wettability of organic and inorganic pore is different.As a result,the mobility of oil in organic and inorganic pore is different.So it’s necessary to展开更多
1 Introduction The brittleness of the shale mineral content has important influence on mud shale reservoir exploitation,high brittleness mineral content areas are generally believed to the benefit of the fracture sect...1 Introduction The brittleness of the shale mineral content has important influence on mud shale reservoir exploitation,high brittleness mineral content areas are generally believed to the benefit of the fracture section.But brittleness mineral content not on behalf of the rock strength,some展开更多
有机质及其相关孔隙吸附行为的研究对于揭示页岩油赋存状态与机理有重要意义。不同于以往采用石墨烯模型代替有机质的方法,研究采用真实的干酪根分子模型(Ⅱ-C型),基于GAFF(general Amber force field)力场模拟了有机孔内页岩油多组分...有机质及其相关孔隙吸附行为的研究对于揭示页岩油赋存状态与机理有重要意义。不同于以往采用石墨烯模型代替有机质的方法,研究采用真实的干酪根分子模型(Ⅱ-C型),基于GAFF(general Amber force field)力场模拟了有机孔内页岩油多组分体系下的吸附行为。结果表明:(1)与石墨烯仅能模拟壁面吸附不同,干酪根对页岩油具有吸附和吸收双重作用:壁面上存在页岩油竞争吸附,以极性和重质组分吸附为主,而骨架中则存在页岩油组分吸收现象,小分子迁移距离较远。页岩油在干酪根壁面上的吸附和在骨架中的迁移受控于页岩油与干酪根相互作用能的强弱及分子大小,重质组分表现出“强吸附-弱吸收”、轻质组分呈“弱吸附-强吸收”的特征。(2)页岩油组分的吸收使得干酪根骨架和孔隙发生变化,表现出新孔隙的形成、原有孔隙的扩大和部分塌陷。干酪根的塑性对吸收页岩油进而膨胀起重要作用,干酪根塑性较强时(干酪根成熟度低),页岩油更容易被吸收从而引发明显的干酪根骨架膨胀,反之,干酪根膨胀较弱。(3)温度增加会促进干酪根骨架吸收芳香烃分子萘和非极性分子甲酸、乙醇以及噻吩,降低干酪根壁面的吸附作用,同时有利于饱和烃类分子的脱附。压力对页岩油在干酪根中的吸附和吸收影响不明显。研究利用真实的干酪根分子模型,首次创新性地模拟了干酪根吸附和吸收页岩油组分的现象,对于客观揭示页岩油在干酪根中赋存状态及赋存机理具有重要帮助。展开更多
基金funded by the National Natural Science Foundation of China(Grant No.42072147)the Qingdao Postdoctoral Science Foundation(Grant No.ZX20210070)。
文摘Because of the influence of hydrocarbons,especially adsorbed hydrocarbons,on the detection of cracked hydrocarbon(S2)and total organic carbon(TOC),the hydrogen index(HI)-based hydrocarbon generation model deviates from actual practice.In this study,the shale in the first member of the Qingshankou Formation in the central depression of the Songliao Basin,where in northeastern China,was taken as the research object and a correction method for S2 and TOC was established.By correcting the experimental results of different maturity samples,the actual hydrocarbon generation model has been revealed,the differences before and after correction compared,and the evolutionary characteristics of the adsorbed hydrocarbon content were clarified.The results show that the organic matter enters the hydrocarbon generation threshold at R_(o)-0.5% and reaches the hydrocarbon generation peak at R_(o)-1.0% and that the hydrocarbon generation process ends at R_(o)-1.3%.The hydrocarbon generation model established based on the measured values has a‘lag effect’compared to actual values,and this extends the hydrocarbon generation window of organic matter and delays the hydrocarbon generation peak.With the increase of maturity,adsorbed hydrocarbon content shows the characteristics of‘first increasing,then stabilizing,and then decreasing’,and reache s the most abundant stage at Roof 0.9%-1.3%.
基金Supported by the National Natural Science Foundation of China(42102154,41922015,42072147)China Postdoctoral Science Foundation(2021M690168)Postdoctoral Innovation Talent Support Program of Shandong Province(SDBX2021004).
文摘A quantitative evaluation model that integrates kerogen adsorption and clay pore adsorption of shale oil was proposed,and the evaluation charts of adsorption-swelling capacity of kerogen(Mk)and adsorbed oil capacity of clay minerals(Mc)were established,taking the 1st member of Cretaceous Qingshankou Formation in the northern Songliao Basin as an example.The model and charts were derived from swelling oil experiments performed on naturally evolved kerogens and adsorbed oil experiments on clays(separated from shale core samples).They were constructed on the basis of clarifying the control law of kerogen maturity evolution on its adsorption-swelling capacity,and considering the effect of both the clay pore surface area that occupied by adsorbed oil and formation temperature.The results are obtained in four aspects:(1)For the Qing 1 Member shale,with the increase of maturity,Mk decreases.Given Ro of 0.83%–1.65%,Mk is about 50–250 mg/g.(2)The clay in shale adsorbs asphaltene.Mc is 0.63 mg/m^(2),and about 15%of the clay pore surface is occupied by adsorbed oil.(3)In the low to medium maturity stages,the shale oil adsorption is controlled by organic matter.When Ro>1.3%,the shale oil adsorption capacity is contributed by clay pores.(4)The oil adsorption capacity evaluated on the surface at room temperature is 8%–22%(avg.15%)higher than that is held in the formations.The proposed evaluation model reveals the occurrence mechanisms of shale oils with different maturities,and provides a new insight for estimating the reserves of shale oil under formation temperature conditions.
基金supported by the National Natural Science Foundation of China(grant No.41402120)Shandong University of Science and Technology Research Fund(grant No.2015TDJH101)
文摘Objective It has long been controversial that whether authigenic chlorite coatings in sandstone reservoirs can prevent precipitation of siliceous cements.It is commonly believed that chlorite coatings(also called chlorite films,chlorite linings,or chlorite rims)may prevent quartz overgrowth,and thus help the preservation of original pores in sandstone reservoirs.Recently,however,this assumption has been challenged by reservoir geologists.This dispute cannot be solved by mere analysis of thin sections,nor by chemical equations and diagenesis analysis.The main objective of the present contribution is to shed light on
基金funded by the Geological Survey Project of the China Geological Survey (grants No. DD20189614, DD20160173)the National Science Foundation of China (grants No. 41702204, 41402120)
文摘To accurately measure and evaluate reserves is critical for ensuring successful production of unconventional oil and gas. This work proposes a volumetric model to evaluate the tight sandstone gas reserves of the Permian Sulige gas field in the Ordos Basin. The reserves can be determined by four major parameters of reservoir cutoffs, net pay, gas-bearing area and compression factor Z, which are controlled by reservoir characteristics and sedimentation. Well logging, seismic analysis, core analysis and gas testing, as well as thin section identification and SEM analysis were used to analyze the pore evolution and pore-throat structure. The porosity and permeability cutoffs are determined by distribution function curve,empirical statistics and intersection plot. Net pay and gas-bearing area are determined based on the cutoffs, gas testing and sand body distribution, and the compression factor Z is obtained by gas component. The results demonstrate that the reservoir in the Sulige gas field is characterized by ultralow porosity and permeability, and the cutoffs of porosity and permeability are 5% and 0.15×10^(–3) μm^2, respectively. The net pay and gas-bearing area are mainly affected by the sedimentary facies, sand body types and distribution. The gas component is dominated by methane which accounts for more than 90%, and the compression factor Z of H_8(P_2h_8) and S_1(P_1s_1) are 0.98 and 0.985, respectively. The distributary channels stacked and overlapped, forming a wide and thick sand body with good developed intergranular pores and intercrystalline pores. The upper part of channel sand with good porosity and permeability can be sweet spot for gas exploration. The complete set of calculation systems proposed for tight gas reserve calculation has proved to be effective based on application and feedback. This model provides a new concept and consideration for reserve prediction and calculation in other areas.
基金funded by National Natural Science Foundation of China(41330313)National Natural Science Foundation of China(41172134)+3 种基金“the Fundamental Research Funds for the Central Universities”(13CX05013A)“the Fundamental Research Funds for the Central Universities”(15CX06013A)Postgraduate Innovation Project(YCX2015002)Innovation Fund of CNPC(2011D-5006-0101)
文摘1 Introduction There is a set of organic rich shale at E22S4sub-member in damnintun sag.The organic material is typically type I.In recent years,breakthrough was obtained in shale oil exploration.The wettability of organic and inorganic pore is different.As a result,the mobility of oil in organic and inorganic pore is different.So it’s necessary to
基金funded by National Natural Science Foundation of China(41330313)National Natural Science Foundation of China(41172134)+3 种基金“the Fundamental Research Funds for the Central Universities”(13CX05013A)“the Fundamental Research Funds for the Central Universities”(15CX06013A)Postgraduate Innovation Project(YCX2015002)Innovation Fund of CNPC(2011D-5006-0101)
文摘1 Introduction The brittleness of the shale mineral content has important influence on mud shale reservoir exploitation,high brittleness mineral content areas are generally believed to the benefit of the fracture section.But brittleness mineral content not on behalf of the rock strength,some
文摘有机质及其相关孔隙吸附行为的研究对于揭示页岩油赋存状态与机理有重要意义。不同于以往采用石墨烯模型代替有机质的方法,研究采用真实的干酪根分子模型(Ⅱ-C型),基于GAFF(general Amber force field)力场模拟了有机孔内页岩油多组分体系下的吸附行为。结果表明:(1)与石墨烯仅能模拟壁面吸附不同,干酪根对页岩油具有吸附和吸收双重作用:壁面上存在页岩油竞争吸附,以极性和重质组分吸附为主,而骨架中则存在页岩油组分吸收现象,小分子迁移距离较远。页岩油在干酪根壁面上的吸附和在骨架中的迁移受控于页岩油与干酪根相互作用能的强弱及分子大小,重质组分表现出“强吸附-弱吸收”、轻质组分呈“弱吸附-强吸收”的特征。(2)页岩油组分的吸收使得干酪根骨架和孔隙发生变化,表现出新孔隙的形成、原有孔隙的扩大和部分塌陷。干酪根的塑性对吸收页岩油进而膨胀起重要作用,干酪根塑性较强时(干酪根成熟度低),页岩油更容易被吸收从而引发明显的干酪根骨架膨胀,反之,干酪根膨胀较弱。(3)温度增加会促进干酪根骨架吸收芳香烃分子萘和非极性分子甲酸、乙醇以及噻吩,降低干酪根壁面的吸附作用,同时有利于饱和烃类分子的脱附。压力对页岩油在干酪根中的吸附和吸收影响不明显。研究利用真实的干酪根分子模型,首次创新性地模拟了干酪根吸附和吸收页岩油组分的现象,对于客观揭示页岩油在干酪根中赋存状态及赋存机理具有重要帮助。