The Geoscience Frontier of Gulong Shale Oil:Revealing the Role of Continental Shale from Oil Generation to Production

The clay mineral content of Daqing Gulong shale is in the range of about 35%–45%,with particle sizes less than 0.0039 mm.The horizontal fluidity of oil in Gulong shale is poor,with near-zero vertical flowability.As a result,Gulong shale has been considered to lack commercial value.In recent years,however,interdisciplinary research in geoscience,percolation mechanics,thermodynamics,and surface mechanics has demonstrated that Gulong shale oil has a high degree of maturity and a high residual hydrocarbon content.The expulsion efficiency of Gulong shale in the high mature stage is 32%–48%.Favorable storage spaces in Gulong shale include connecting pores and lamellar fractures developed between and within organic matter and clay mineral complexes.The shale oil mainly occurs in micro-and nano-pores,bedding fractures,and lamellar fractures,with a high gas–oil ratio and medium–high movable oil saturation.Gulong shale has the characteristics of high hardness,a high elastic modulus,and high fracture toughness.This study achieves breakthroughs in the exploration and development of Gulong shale,including the theories of hydrocarbon generation and accumulation,the technologies of mobility and fracturing,and recoverability.It confirms the major transition of Gulong shale from oil generation to oil production,which has extremely significant scientific value and application potential for China’s petroleum industry.

Key theoretical and technical issues and countermeasures for effective development of Gulong shale oil, Daqing Oilfield, NE China

Aiming at the four issues of underground storage state,exploitation mechanism,crude oil flow and efficient recovery,the key theoretical and technical issues and countermeasures for effective development of Gulong shale oil are put forward.Through key exploration and research on fluid occurrence,fluid phase change,exploitation mechanism,oil start-up mechanism,flow regime/pattern,exploitation mode and enhanced oil recovery(EOR)of shale reservoirs with different storage spaces,multi-scale occurrence states of shale oil and phase behavior of fluid in nano confined space were provided,the multi-phase,multi-scale flow mode and production mechanism with hydraulic fracture-shale bedding fracture-matrix infiltration as the core was clarified,and a multi-scale flow mathematical model and recoverable reserves evaluation method were preliminarily established.The feasibility of development mode with early energy replenishment and recovery factor of 3o%was discussed.Based on these,the researches of key theories and technologies for effective development of Gulong shale oil are proposed to focus on:(1)in-situ sampling and non-destructive testing of core and fluid;(2)high-temperature,high-pressure,nano-scale laboratory simulation experiment;(3)fusion of multi-scale multi-flow regime numerical simulation technology and large-scale application software;(4)waterless(CO_(2))fracturing technique and the fracturing technique for increasing the vertical fracture height;(5)early energy replenishment to enhance oil recovery;(6)lifecycle technical and economic evaluation.Moreover,a series of exploitation tests should be performed on site as soon as possible to verify the theoretical understanding,optimize the exploitation mode,form supporting technologies,and provide a generalizable development model,thereby supporting and guiding the effective development and production of Gulong shale oil.

In-situ hydrocarbon formation and accumulation mechanisms of micro- and nano-scale pore-fracture in Gulong shale, Songliao Basin, NE China

By conducting experimental analyses, including thermal pyrolysis, micro-/nano-CT, argon-ion polishing field emission scanning electron microscopy (FE-SEM), confocal laser scanning microscopy (CLSM), and two-dimensional nuclear magnetic resonance (2D NMR), the Gulong shale oil in the Songliao Basin was investigated with respect to formation model, pore structure and accumulation mechanism. First, in the Gulong shale, there are a large number of pico-algae, nano-algae and dinoflagellates, which were formed in brackish water environment and constituted the hydrogen-rich oil source materials of shale. Second, most of the oil-generating materials of the Qingshankou Formation shale exist in the form of organo-clay complex. During organic matter thermal evolution, clay minerals had double effects of suppression and catalytic hydrogenation, which expanded shale oil window and increased light hydrocarbon yield. Third, the formation of storage space in the Gulong Shale was related to dissolution and hydrocarbon generation. With the diagenesis, micro-/nano-pores increased, pore diameter decreased and more bedding fractures appeared, which jointly gave rise to the unique reservoir with dual media (i.e. nano-scale pores and micro-scale bedding fractures) in the Gulong shale. Fourth, the micro-/nano-scale oil storage unit in the Gulong shale exhibits independent oil/gas occurrence phase, and shows that all-size pores contain oils, which occur in condensate state in micropores or in oil-gas two phase (or liquid) state in macropores/mesopores. The understanding about Gulong shale oil formation and accumulation mechanism has theoretical and practical significance for advancing continental shale oil exploration in China.

Practice and development suggestions of hydraulic fracturing technology in the Gulong shale oil reservoirs of Songliao Basin, NE China

This paper reviews the multiple rounds of upgrades of the hydraulic fracturing technology used in the Gulong shale oil reservoirs and gives suggestions about stimulation technology development in relation to the production performance of Gulong shale oil wells.Under the control of high-density bedding fractures,fracturing in the Gulong shale results in a complex fracture morphology,yet with highly suppressed fracture height and length.Hydraulic fracturing fails to generate artificial fractures with sufficient lengths and heights,which is a main restraint on the effective stimulation in the Gulong shale oil reservoirs.In this regard,the fracturing design shall follow the strategy of"controlling near-wellbore complex fractures and maximizing the extension of main fractures"Increasing the proportions of guar gum fracturing fluids,reducing perforation clusters within one fracturing stage,raising pump rates and appropriately exploiting stress interference are conducive to fracture propagation and lead to a considerably expanded stimulated reservoir volume(SRV).The upgraded main hydraulic fracturing technology is much more applicable to the Gulong shale oil reservoirs.It accelerates the oil production with a low flowback rate and lifts oil cut during the initial production of well groups,which both help to improve well production.It is suggested to optimize the hydraulic fracturing technology in six aspects,namely,suppressing propagation of near-wellbore microfractures,improving the pumping scheme of CO_(2),managing the perforating density,enhancing multi-proppant combination,reviewing well pattern/spacing,and discreetly applying fiber-assisted injection,so as to improve the SRv,the distal fracture complexity and the long-term fracture conductivity.

Gulong shale oil enrichment mechanism and orderly distribution of conventional–unconventional oils in the Cretaceous Qingshankou Formation,Songliao Basin,NE China

Through the study of organic matter enrichment,hydrocarbon generation and accumulation process of black shale of the Cretaceous Qingshankou Formation in the Songliao Basin,the enrichment mechanism of Gulong shale oil and the distribution of conventional–unconventional oil are revealed.The Songliao Basin is a huge interior lake basin formed in the Early Cretaceous under the control of the subduction and retreat of the western Pacific plate and the massive horizontal displacement of the Tanlu Fault Zone in Northeast China.During the deposition of the Qingshankou Formation,strong terrestrial hydrological cycle led to the lake level rise of the ancient Songliao Basin and the input of a large amount of nutrients,resulting in planktonic bacteria and algae flourish.Intermittent seawater intrusion events promoted the formation of salinization stratification and anoxic environment in the lake,which were beneficial to the enrichment of organic matters.Biomarkers analysis confirms that the biogenic organic matter of planktonic bacteria and algae modified by microorganisms plays an important role in the formation of high-quality source rocks with high oil generation capability.There are four favorable conditions for the enrichment of light shale oil in the Qingshankou Formation of the Gulong Sag,Songliao Basin:the moderate organic matter abundance and high oil potential provide sufficient material basis for oil enrichment;high degree of thermal evolution makes shale oil have high GOR and good mobility;low hydrocarbon expulsion efficiency leads to a high content of retained hydrocarbons in the source rock;and the confinement effect of intra-layer cement in the high maturity stage induces the efficient accumulation of light shale oil.The restoration of hydrocarbon accumulation process suggests that liquid hydrocarbons generated in the early(low–medium maturity)stage of the Qingshankou Formation source rocks accumulated in placanticline and slope after long-distance secondary migration,forming high-quality conventional and tight oil reservoirs.Light oil generated in the late(medium–high maturity)stage accumulated in situ,forming about 15 billion tons of Gulong shale oil resources,which finally enabled the orderly distribution of conventional–unconventional oils that are contiguous horizontally and superposed vertically within the basin,showing a complete pattern of“whole petroleum system”with conventional oil,tight oil and shale oil in sequence.

Shale oil enrichment evaluation and production law in Gulong Sag,Songliao Basin,NE China

Based on the results of drilling,tests and simulation experiments,the shales of the Cretaceous Qingshankou Formation in the Gulong Sag of the Songliao Basin are discussed with respect to hydrocarbon generation evolution,shale oil occurrence,and pore/fracture evolution mechanism.In conjunction with a substantial amount of oil testing and production data,the Gulong shale oil enrichment layers are evaluated and the production behaviors and decline law are analyzed.The results are drawn in four aspects.First,the Gulong shales are in the stage of extensive hydrocarbon expulsion when R_(0) is 1.0%-1.2%,with the peak hydrocarbon expulsion efficiency of 49.5%approximately.In the low-medium maturity stage,shale oil migrates from kerogen to rocks and organic pores/fractures.In the medium-high maturity stage,shale oil transforms from adsorbed state to free state.Second,the clay mineral intergranular pores/fractures,dissolution pores,and organic pores make up the majority of the pore structure.During the transformation,clay minerals undergo significant intergranular pore/fracture development between the minerals such as illite and illite/smectite mixed layer.A network of pores/fractures is formed by organic matter cracking.Third,free hydrocarbon content,effective porosity,total porosity,and brittle mineral content are the core indicators for the evaluation of shale oil enrichment layers.Class-I layers are defined as free hydrocarbon content equal or greater than 6.0 mg/g,effective porosity equal or greater than 3.5%,total porosity equal or greater than 8.0%,and brittle mineral content equal or greater than 50%.It is believed that the favourable oil layers are Q2-Q3 and Q8-Q9.Fourth,the horizontal wells in the core area of the light oil zone exhibit a high cumulative production in the first year,and present a hyperbolic production decline pattern,with the decline index of 0.85-0.95,the first-year decline rate of 14.5%-26.5%,and the single-well estimated ultimate recovery(EUR)greater than 2.0×10^(4)t.In practical exploration and production,more efforts will be devoted to the clarification of hydrocarbon generation and expulsion mechanisms,accurate testing of porosity and hydrocarbon content/phase of shale under formation conditions,precise delineation of the boundary of enrichment area,relationship between mechanical properties and stimulated reservoir volume,and enhanced oil recovery,in order to improve the EUR and achieve a large-scale,efficient development of shale oil.

古龙页岩油勘探开发进展及发展对策

古龙页岩油是继常规油之后最为现实的接替资源,目前已经成为大庆油田增储上产的主要领域。通过系统阐述古龙页岩油勘探开发历程和分区带落实资源潜力,为古龙页岩油未来发展制定合理规划。结果表明:古龙页岩油主要经历了勘探评价、先导试验和扩大试验3个勘探开发阶段;富有机质页岩具有面积广、厚度大、生油能力强等特点,页岩油富集的物质基础雄厚;古龙页岩油纵向上主要富集于下油组(Q_(1)―Q_(4)油层)和上油组的Q_(9)油层,平面上具有全盆地分布的特征,在古龙凹陷深凹区地质条件最为优越;按照轻质油带核心区―斜坡区―稀油带―低熟页岩油的规划,逐步对古龙页岩油实施勘探研究及开发动用;基于原生源储的富集规律,建立了原位成藏理论,古龙页岩油提交了12.68×10^(8)t的预测地质储量及2.04×10^(8)t的探明地质储量,指导了国家级示范区及全国重点实验室建设;应用体积法估算轻质油带Q9油层资源量为9.6×10^(8)t,轻质油带Q_(2)―Q_(8)油层整体资源量为38.8×10^(8)t,三肇地区稀油带资源量达11×10^(8)t以上,能够有效支撑古龙页岩油革命行动目标。通过加强理论研究,推动技术进步,推进管理创新,实现降本增效,古龙页岩油必将成为大庆油田资源接续和百年油田建设的重要领域。

古龙页岩油开发试验钻井设计优化与实践

古龙页岩油与国内外陆相页岩油相比,陆相淡水沉积环境的青山口组黏土矿物体积分数较高,且多孔多缝,呈纹层状结构,易发生层间散裂、性脆,易吸水膨胀垮塌,独特的地质特性给古龙页岩油钻井带来了巨大挑战。针对钻井过程中容易出现井壁失稳、井漏、摩擦阻力大、钻井周期长等钻井技术难题,从平台井部署、井身结构、井眼轨道、提速技术、钻井液、固井等方面开展优化技术研究,创新采用了“双二维”轨道模型、“一趟钻”技术、油基钻井液、多级固井顶替等一系列新技术。结果表明:与GYP1井相比,试验区的平均钻井速度从11.44 m/h提高至27.75 m/h、水平段固井质量优质率从71.51%提升至86.27%,平均钻井周期从108.17 d缩短至26.82 d。研究成果为古龙页岩油实现储量动用最大化、施工效率最优化提供了强有力的技术支撑,也为古龙页岩油立体化、规模化、效益化开发奠定了基础,对推进中国陆相页岩油技术革命具有重要指导意义。

松辽盆地古龙凹陷青山口组页岩油储层中的重力坠落砂脉的发现及其意义

古龙页岩油是松辽盆地重要的接替资源,资源量可达151亿吨之多。从沉积和岩石学特点上看,古龙青山口组页岩最大的特点之一是广泛发育了一种很特殊的砂脉,所以这也是探讨古龙青山口组页岩形成环境的一个重要信息。古龙青山口组页岩油储层中的砂脉总体规模较小,宽度多在1~2 mm,可见长度(或高度)多在1~2 cm,大部分弯曲如肠,少数微曲;多倾斜产出,倾斜方向有一定规律,隔180°对称;一般发育在灰黑色的泥页岩中,少量发育在粉砂岩和白云岩(结核)中。砂脉的上部或顶部一般都有一层粉砂,与砂脉紧密相连,是砂脉的“根”;而砂脉的底部一般都是灰黑色的泥页岩,见不到粉砂层,所以揭示形成砂脉的源物质是来自于顶部的粉砂层,而不是底部。初步研究认为,古龙青山口组页岩油储层中的岩脉有两种成因:第一种是高压液化充注,形成了规模较大的砂脉;第二种由密度倒置引起的重力沉降形成风暴把(粉)砂级颗粒快速搬运到刚沉积的黏土之上,由于风暴浪的振荡,使粉砂液化流动,再加上黏土的密度较小和粉砂层的密度较大,使得粉砂在重力的驱动下沉降到黏土中形成砂脉。研究古龙页岩油储层中的砂脉具有4个意义:1)可以研究砂脉形成时的沉积环境、沉积过程和沉积物状态;2)可以研究泥页岩的成岩压实率;3)辅助确定白云岩(结核)的形成时间;4)可以辅助储层评价。

松辽盆地古龙凹陷青山口组页岩层系岩相类型及旋回模式

综合运用岩心观察、薄片鉴定、地球化学测试及马尔科夫链分析,对古龙凹陷青山口组页岩层系岩相类型及旋回模式进行了探讨。按照“有机质丰度-沉积构造-矿物组成-纹层密度-岩性”分类标准,将古龙凹陷青山口组页岩层系划分出7种岩相:高有机质高密度纹层黏土质页岩(A)、高有机质高密度纹层长英质页岩(B)、中有机质低密度纹层长英质页岩(C)、低有机质低密度纹层长英质页岩(D)、低有机质层状粉砂岩(E)、低有机质层状介屑灰岩(F)和低有机质层状白云岩(G)。依据岩相组合模式及其展布特征,划分为3种旋回模式:①静水旋回模式(A-B-C-A),主要发育在高水位体系域;②浊流旋回模式(A-B-C/D/E-A),主要发育于水进体系域和水退体系域;③白云岩旋回模式(A-B-C-D/G-A),在水进、高水位和水退体系域均有发育。古龙凹陷西侧主要发育浊流旋回,中央主要发育静水旋回,东侧三肇凹陷主要发育静水-白云岩旋回。旋回模式的分布主要受物源、古气候和古盐度的影响。

松辽盆地古龙页岩油富集耦合机制

大庆油田生产实践证实松辽盆地青山口组古龙页岩油具有巨大的勘探开发潜力,但页岩油富集的耦合机制仍不明确,制约了页岩油成藏理论及油气富集区的认识。通过岩心精描、古地温恢复、常微量元素分析、场发射环境扫描电镜分析、二维核磁分析等技术,明确了古龙页岩油富集的耦合机制。松辽盆地古龙页岩油富集受宏、微观多因素耦合控制:宏观上,古龙页岩油富集受控于43.99~77.28℃/km古地温梯度的高温热盆、大规模发育的富氢高有机质页岩、温湿淡水-微咸水还原水体环境及较强的顶底板封存能力4个地质因素;微观上,古龙页岩油富集受控于以有机质成熟度为主线的生烃与成储同步演化耦合,随着页岩成熟度不断增高,干酪根不断裂解,生烃量增加,有机缝孔的占比逐渐增大,无机孔占比逐渐减少,生成的油气由重质向轻质转化,吸附油占比减小,游离油占比增大。当Ro大于1.3%时,孔壁表面润湿性由亲水性向亲油性转变,原油不断从小尺度孔隙向大尺度孔隙渗流。研究成果可为古龙页岩油成藏理论认识的深化及富集区优选提供重要依据。

松辽盆地古龙页岩油富集规律及有利区分布

近年的勘探开发实践已经证实松辽盆地白垩系发育的页岩油资源潜力巨大,但页岩油富集规律不清、有利区分布不明的问题制约了古龙页岩油勘探开发的快速推进。基于古龙全区多口井的取心及全面实验分析,系统开展页岩油含油性、储集性以及动用条件分析,明确页岩油富集分布规律,建立有利区划分标准,系统评价了松辽盆地齐家−古龙凹陷页岩油有利区。结果表明:沉积背景控制了页岩矿物组分及薄夹层岩性纵向上的规律性;明确了烃源岩丰度及热演化程度控“油”,有机质生烃演化及成岩演化控“储”,核磁可动孔隙度和脆性矿物含量控“动用”的富集可动主控要素。古龙页岩油纵向上在下部的Q_(1)—Q_(4)油层以纯页岩为主,含油性最好,但黏土矿物含量最高,工程品质较差,一类有利区主要分布在齐家-古龙凹陷北部及南部的部分区域,二类有利区基本覆盖齐家-古龙凹陷,分布面积最大;中部的Q_(5)—Q_(7)油层为页岩夹薄层白云岩,含油性中等,工程品质中等,核磁可动孔隙度最低,一类有利区部分发育于齐家−古龙凹陷北部,面积最小,二类有利区分布与R_(o)>1.2%范围相近,面积小于Q_(1)—Q_(4)油层;Q_(8)—Q_(9)油层岩性为页岩夹薄层粉砂岩,含油性较好,黏土矿物含量相对最低,工程品质最好,核磁可动孔隙度最大,可动条件最好,一类有利区分布面积最大,R_(o)>1.2%范围内基本均有分布,二类有利区分布与Q_(8)—Q_(9)油层相似。研究成果可为古龙页岩油的下一步勘探开发提供理论指导。

核磁共振测井在古龙页岩油评价中的应用

古龙页岩油储层黏土含量高,孔隙结构较为复杂,微米-纳米孔喉及微裂缝发育,利用常规方法评价储层孔隙结构及物性、含油性具有较大难度。针对以上难题,在岩石物理实验基础上,提出了核磁共振变T_(2)谱截止值有效孔隙度计算方法和考虑小孔隙含油的二维核磁共振含油饱和度计算模型,并通过核磁共振区间孔隙度分析,厘清了古龙页岩储层孔隙结构。利用该方法计算的有效孔隙度平均相对误差为7.3%,含油饱和度平均绝对误差为4.0%,这不仅提高了计算储量关键参数的解释精度,还为后续开发提供了技术保障。该技术流程和方法对于类似页岩油的有效孔隙度和含油饱和度的评价同样具有指导意义,有助于推动页岩油等非常规油气资源的开发利用。

高黏土陆相页岩实验技术及其应用

页岩储层“四性”实验评价是页岩油勘探开发的重要基础及核心。现有实验技术存在页岩含油量检测不准、微纳米孔隙测量视域小及代表性差、流动性直接测量参数缺乏等难题,不适应古龙页岩油生产需求。通过研发实验装备、确定实验条件,建立基于保压密闭岩心“四性”实验技术及流程。结果表明:古龙高成熟和成熟页岩含油量测定较国标法可减少损失71%和50%,应用新建不同成熟度页岩含油量恢复模型,恢复了国标法现场录井页岩含油量数据;高成熟与低成熟阶段页岩中干酪根有机质、不同赋存状态油和水定量特征差别明显,受干酪根有机质向页岩油转化及演化程度的控制;页岩孔缝组合构成规模储集空间及流动网络通道,储集空间分为2大类7亚类12种类型,总孔隙度高于粉砂质岩、灰质岩、云质岩;确定页岩油上部、中部、下部油层组含油性与流动性特征,圆柱状页岩样品驱替油率为16%~43%,同一地层温度(100℃)不同驱替压力(10~50 MPa)下的超临界CO_(2)驱替使孔隙度增加4.51百分点、渗透率增加0.53×10^(-3)μm^(2)。研究成果为页岩油规模增储和效益上产提供了实验依据。

古龙页岩油高温高压注CO_(2)驱动用效果

为了明确古龙页岩油高温高压注CO_(2)驱动用效果,首先根据页岩压汞和氮气吸附实验结果,给出页岩T2值与孔喉半径转换系数,根据饱和页岩的T2谱特征,将页岩孔隙分为小孔、中大孔和页理缝;然后通过计算页岩油采出程度,考察吞吐周期、闷井时间、裂缝对吞吐驱油效果的影响,并且分析吞吐后岩心孔隙结构的改变程度;最后对比页岩油CO_(2)吞吐和CO_(2)驱替的驱油效果,并给出最优的驱油方式。结果表明:吞吐动用幅度最大的是中大孔和页理缝中的页岩油,小孔中的页岩油采出程度最低,增加闷井时间,页岩油采出程度仅提高0.81百分点,压裂可以使小孔中的页岩油采出程度提高11.33百分点,使小孔中的页岩油得到有效动用;吞吐比驱替可以使页岩油采出程度提高30.98百分点,并且可以动用干岩样中的页岩油,效果优于驱替;驱吞结合驱油方式比只进行吞吐可以使页岩油采出程度提高12.88百分点以上,并且可以大幅度提高小孔中页岩油的采出程度;吞吐后岩心孔隙结构发生明显变化,页岩砂砾含量不同是导致页岩吞吐前后孔隙结构变化差异大的重要原因。研究成果可为古龙页岩油矿场实践提供重要的基础参数。

松辽盆地古龙页岩纳米孔喉体系中页岩油组分及成熟度分异效应

陆相页岩油储层中石油的微运移效应会导致微观孔隙空间中赋存的页岩油性质发生分异,然而页岩储层孔隙半径较小,孔喉结构复杂,很难通过常规手段对其进行精细刻画,导致对页岩油的微观富集机理认识不清。通过对松辽盆地古龙凹陷青山口组页岩岩心样品进行分步-接力抽提、低温氮气吸附实验,并开展全烃气相色谱、族组分定量、饱和烃气相色谱质谱和金刚烷双质谱等地球化学分析,揭示出页岩储层纳米孔喉体系内的石油组分和成熟度分异效应。结果表明,古龙页岩孔隙以介孔为主,随着页岩样品粒径的逐级减小,更多初始连通性较差的孔隙会被释放出来,同时微观纳米孔喉中烃类的重质组分相对增加,极性更强,页岩油的成熟度也相对更高,这与不同连通性孔隙空间中页岩油的排烃和微运移效应具有一定的相关性。研究成果可为精细表征页岩油的微观赋存特征,阐明页岩油储层烃类微观差异富集机理提供有效的技术手段,同时也为页岩油的可动性评价和甜点优选提供可靠的理论依据。

松辽盆地古龙页岩油储层干酪根的有机元素组成及其N元素的地球化学意义

对青山口组页岩的317件干酪根样品进行了工业、元素及能谱分析,对样品进行两次校正,引入合理评价干酪根C、H、O、N的指标C_(cc)、H_(cc)、O_(cc)、N_(cc)概念。研究结果显示:古龙凹陷青山口组泥页岩Ⅰ型干酪根具有较高的H_(cc)、N_(cc)和很低的O_(cc),而Ⅲ型干酪根的O_(cc)则较高,H_(cc)、N_(cc)较低。Ⅱ干酪根的H_(cc)和N_(cc)低于Ⅰ型干酪根,而高于Ⅲ型干酪根;Ⅱ干酪根的O_(cc)高于Ⅰ型和Ⅲ型干酪根。N_(cc)主要以有机官能团(NH3+)方式存在的于黏土的F-F纳缝中,而不是存在于黏土晶胞间的无机N(NH4)。微量元素研究表明,古龙青山口组页岩油储层沉积时经历了十几次干旱咸水环境,因为咸水环境有利于形成黏土的F-F凝聚,使发育有NH3+官能团的有机质被吸附在黏土片的F-F纳缝之间。随着深度的增加,N_(cc)的克分子量增加速率是C_(cc)克分子量增加速率的0.96~2.04倍,在青山口组1300~2550m深度内青一段干酪根的N_(cc)含量明显比上部的干酪根相对高,主要原因与下部青一段藻类较富集有关,其次与H_(cc)的快速脱落而使N_(cc)相对富集有关,间接地揭示了青一段生烃能力较上部强。通过研究N_(cc)可以间接地知道古环境中的咸度、黏土的孔隙类型及其干酪根的来源。经过论证,O_(cc)和N_(cc)越大,页岩的封存性也就越好,含油气性也越好。因此,O_(cc)和N_(cc)值可以作为判别页岩油发育程度的指标。古龙页岩油储层的N_(cc)和O_(cc)的研究可以提供一些重要的沉积环境、地球化学、黏土结构、干酪根有机质类型和成岩成储及成藏等信息,应该受到重视。

松辽盆地古龙凹陷白垩系青山口组页岩油储层中微米孔缝特征及油气意义

通过岩心观察、薄片鉴定、电子背散射、二次成像及能谱分析等多种实验手段,对松辽盆地古龙凹陷白垩系青山口组页岩油储层中的微米孔和微米缝进行了研究。研究结果表明:(1)古龙凹陷页岩油储层岩性为以页岩为主的细粒碎屑岩,矿物成分以黏土和长英质为主,在结构上显示出泥岩或页岩的特点,整体为长英质页岩;储层中微米孔、缝发育,类型多样。(2)研究区微米孔直径一般为1~2μm,最大可达70μm,多呈近圆形、扁圆形、多角形和不规则形,按成因可分为压实应力屏蔽孔、成岩自生孔、溶蚀孔、生排烃扩张孔、有机质孔和硅藻残留孔6类;压实应力屏蔽孔多发育在刚性矿物的两侧;成岩自生孔常发育在白云石、绿泥石、伊利石等成岩自生矿物中,以晶间孔为主;溶蚀孔多发育在碳酸盐矿物中,内部可见次生菌丝状絮凝体;生排烃扩张孔多呈垂直或近垂直成列产出,与轻质油形成的二次生烃和排烃有关;有机质孔发育在有机质内部,与植物的残留细胞及轻质油和天然气的充填有关;硅藻残留孔主要发育在硅藻内部和边缘,孔径较大,一般为数微米至数十微米。(3)研究区微米缝以顺层为主,宽一般为1~10μm,最大可达100μm,长主要为数微米至数十微米,可见毫米级;可分为成岩收缩缝、溶蚀缝、生排烃扩张缝和构造/剪切缝4类,成岩收缩缝以张性缝为主,缝弯曲,缝壁参差不齐;溶蚀缝宽度可达60~70μm,裂缝内可见自生黏土,缝两侧有黄铁矿、磷灰石和白云石等自生矿物;生排烃扩张缝两侧多锯齿状参差不齐,绕过刚性矿物;构造/剪切微米缝一般平直,有与剪切相关的其他裂缝伴生。(4)研究区不同尺度的孔、缝之间连通性较好,形成了“纳米孔+纳米缝、微米孔+微米缝、毫米孔+毫米缝”三级储集和输导体系。

基于地震波形驱动层序格架建立及页岩岩相特征研究--以松辽盆地古龙页岩油5号试验区为例

松辽盆地古龙凹陷页岩油具有良好的富集条件和勘探开发潜力,已开展规模开发试验。目前,青山口组内部的细分层序地层研究还不够深入,影响古龙页岩油地质综合研究、甜点预测及部署。以松辽盆地古龙页岩油5号试验区为例,以地震层序地层学理论为指导,针对页岩型页岩油横向沉积相对稳定的特点,采用各向异性扩散滤波、层序识别与选取等手段,地震处理、解释及地质结合,使得地震波形可指示地质层位,形成基于地震波形驱动的层序格架建立技术。该技术实现了地震波形向沉积地层地质含义的快速转化,在研究区青山口组识别出1个二级、1个三级及8个四级层序界面,划分为Q1—Q9共9个小层,分析了各小层的格架特征,为页岩油岩相和甜点精细预测奠定基础。基于细分层地层格架,通过分析TOC、沉积构造、矿物成分、页理密度4个评价参数,建立了古龙页岩油页岩型岩相划分标准,划分为10类亚相。以研究区Q1—Q4小层为例,页岩岩相划分为3类亚相,描述了其平面分布特征。基于以上研究,结合含油性、脆性及物性等6个页岩油甜点参数的预测成果,在5号试验区优化布井11口,单井平均日产油在10t以上,有效支撑了松辽盆地古龙页岩油的效益勘探开发。

松辽盆地古龙页岩油富集机制与常规—非常规油有序分布

通过对松辽盆地白垩系青山口组黑色页岩有机质富集、生烃和成藏过程研究,揭示古龙页岩油富集机理及常规—非常规油气分布规律。松辽盆地是在早白垩世受西太平洋板块俯冲后撤影响、郯庐断裂带在中国东北地区发生大规模水平位移的背景上形成的一个巨大内陆湖盆。青山口组沉积期间,陆地水文循环强烈,松辽古湖盆湖平面上升,大量营养物输入使浮游菌藻类生物繁盛,间歇性海侵促进水体咸化分层和缺氧环境形成,有利于有机质富集;生物标志化合物分析表明,经微生物改造的浮游菌藻类生源有机质对高生油能力的优质烃源岩形成具有重要作用。松辽盆地古龙凹陷青山口组轻质页岩油层内富集具有4方面有利条件:①中等有机质丰度和高生油潜力为页岩油富集提供了充足的物质基础;②较高的热演化程度使得页岩油具有较高的气油比(GOR)和良好的可动性;③较低的排烃效率导致滞留在源岩中烃类含量高;④高成熟阶段的层内胶结封闭效应导致轻质页岩油高效聚集。成藏过程恢复表明,青山口组烃源岩早期中低成熟阶段生成的液态烃经二次运移后在长垣和斜坡聚集形成优质的常规油藏和致密油藏;后期中高成熟阶段生成的轻质油原地聚集,形成约150×10^(8) t的古龙页岩油资源,最终使盆地内地油气分布呈横向连片、垂向叠加、常规—非常规序次分布的特征,表现为常规油—致密油—页岩油有序聚集的完整“全油气系统”格局。