Characteristics and control factors of feldspar dissolution in gravity flow sandstone of Chang 7 Member,Triassic Yanchang Formation,Ordos Basin,NW China

To clarify the formation and distribution of feldspar dissolution pores and predict the distribution of high-quality reservoir in gravity flow sandstone of the 7^(th) member of Triassic Yanchang Formation(Chang 7 Member)in the Ordos Basin,thin sections,scanning electron microscopy,energy spectrum analysis,X-ray diffraction whole rock analysis,and dissolution experiments are employed in this study to investigate the characteristics and control factors of feldspar dissolution pores.The results show that:(1)Three types of diagenetic processes are observed in the feldspar of Chang 7 sandstone in the study area:secondary overgrowth of feldspar,replacement by clay and calcite,and dissolution of detrital feldspar.(2)The feldspar dissolution of Chang 7 tight sandstone is caused by organic acid,and is further affected by the type of feldspar,the degree of early feldspar alteration,and the buffering effect of mica debris on organic acid.(3)Feldspars have varying degrees of dissolution.Potassium feldspar is more susceptible to dissolution than plagioclase.Among potassium feldspar,orthoclase is more soluble than microcline,and unaltered feldspar is more soluble than early kaolinized or sericitized feldspar.(4)The dissolution experiment demonstrated that the presence of mica can hinder the dissolution of feldspar.Mica of the same mass has a significantly stronger capacity to consume organic acids than feldspar.(5)Dissolution pores in feldspar of Chang 7 Member are more abundant in areas with low mica content,and they improve the reservoir physical properties,while in areas with high mica content,the number of feldspar dissolution pores decreases significantly.

Microfacies and diagenetic alteration in a semi-deep to deep lacustrine shale: The Yanchang Formation in the Ordos Basin, China

The mineralogical development and diagenetic sequence of lacustrine shales in the Chang 7 Member of the Yanchang Formation in the Ordos Basin are detailed studied.A model of their depositional system and a diagenetic diagram are proposed in this study.Through detailed petrographic,mineralogical,and elemental analyses,four distinct shale types are identified:argillaceous shale,siliceous shale,calcareous shale,and carbonate,clay,and silt-bearing shale.The main diagenetic process in argillaceous shale is the transformation of illite to smectite,negatively impacting shale porosity.Siliceous shale undergoes carbonate cementation and quartz dissolution,contributing to increased porosity,particularly in mesopores.Calcareous shale experiences diagenesis characterised by carbonate formation and dissolution,with a prevalence of siderite.In carbonate,clay,and silt-bearing shale,the dissolution of K-feldspar contributes to illitization of kaolinite.Argillaceous shale,characterised by more clay minerals and lower mesopore volume,is identified as a potential hydrocarbon seal.Siliceous shale,with the highest pore volume and abundant inter-mineral pores,emerges as a promising shale oil reservoir.These findings contribute to a comprehensive understanding of shale properties,aiding in the prediction of shale oil exploration potential in the studied area.

Oderly accumulation theory of shale system petroleum resource and its prospecting significance-A case study of Chang 7 Member of Yanchang Formation in Ordos Basin

1 Introduction Shale formations bear abundant mineral resource and*unconventional petroleum resource,and the unconventional petroleum resource that contain in the shale formation should be integrated and researched.

Geological characteristics and exploration of shale oil in Chang 7 Member of Triassic Yanchang Formation, Ordos Basin, NW China

A set of shale-dominated source rocks series were deposited during the heyday of lake basin development in the Member 7 of Triassic Yanchang Formation,Ordos Basin,and the thickness is about 110 m.Aimed at whether this layer can form large-scale oil enrichment of industrial value,comprehensive geological research and exploration practice have been carried out for years and obtained the following important geologic findings.Firstly,widely distributed black shale and dark mudstone with an average organic matter abundance of 13.81%and 3.74%,respectively,lay solid material foundation for the formation of shale oil.Secondly,sandy rocks sandwiched in thick organic-rich shale formations constitute an oil-rich"sweet spot",the average thickness of thin sandstone is 3.5 m.Thirdly,fine-grained sandstone and siltstone reservoirs have mainly small pores of 2–8μm and throats of 20–150 nm in radius,but with a large number of micro-pores and nano-throats,through fracturing,the reservoirs can provide good conductivity for the fluid in it.Fourthly,continued high-intensity hydrocarbon generation led to a pressure difference between the source rock and thin-layer reservoir of up to 8–16 MPa during geological history,driven by the high pressure,the oil charged into the reservoirs in large area,with oil saturation reaching more than 70%.Under the guidance of the above theory,in 2019,the Qingcheng Oilfield with geologic oil reserves of billion ton order was proved in the classⅠmulti-stage superimposed sandstone shale reservoir of Chang 7 Member by the Changqing Oilfield Branch through implementation of overall exploration and horizontal well volume fracturing.Two risk exploration horizontal wells were deployed for the classⅡthick layer mud shale interbedded with thin layers of silt-and fine-sandstones reservoir in the Chang 73 submember,and they were tested high yield oil flows of more than 100 tons per day,marking major breakthroughs in petroleum exploration in classⅠshale reservoirs.The new discoveries have expanded the domain of unconventional petroleum exploration.

Factors controlling the reservoir accumulation of Triassic Chang 6 Member in Jiyuan-Wuqi area,Ordos Basin,NW China

In the Triassic Yanchang Formation, Jiyuan-Wuqi area, Ordos Basin, the Chang 6 reservoir is contacted to the Chang 7 high-quality source rock, but the oil pools are unevenly distributed, and complex in oil and water distribution. Through cores observation and fracture statistics, combined with comprehensive analyses of physical property, mercury injection, logging and geochemical data, and comparisons of the sandbodies scales, reservoir physical properties, argillaceous laminae and fractures between source and reservoir in the eastern and western oil-bearing areas and in the central water producing area, it is found that the hydrocarbon accumulation patterns are different in the eastern, central and western areas, and the characteristics of hydrocarbon migration under the background of double-provenance were sorted out. The study results show that the crude oil in the eastern area has different Pr/Ph and sterane distribution from that in the western area. The oil and gas primarily migrated vertically. The high-quality source rocks and favorable source-reservoir-cap combinations lay the foundation for large-scale oil and gas accumulations. Vertically, the oil and gas enrichment is controlled by the scale of sandbody and the difference of physical properties, while on the plane, it is controlled by the connectivity of sandbodies, the argillaceous laminae between source rock and reservoir, the reservoir physical property and the fractures. The sandbodies of oil-rich zones in the eastern and western areas have large thickness, low shale content, good physical properties, weak heterogeneity, few argillaceous laminae and abundant fractures, all of which are favorable for the vertical migration and accumulation of oil and gas. In contrast, in the middle area with converging provenances, the reservoirs, composed of thin sandbodies, features rapid variation in lithology and physical properties, strong heterogeneity, poor continuity of sandbodies, abundant argillaceous laminae between source rock and reservoir, and few fractures, makes it difficult for the oil and gas to migrate vertically, and results in low oil enrichment degree ultimately. For the exploration of continental multiple-provenance tight reservoirs, not only the good-property source rocks and reservoirs, but more importantly the source-reservoir contact relationship and the effect of fractures on the hydrocarbon migration and accumulation should be considered.

Formation patterns of Chang 9 oil reservoir in Triassic Yanchang Formation, Ordos Basin, NW China

Based on analysis of main controlling factors of Chang 9, the source rock, driving force of migration, migration and accumulation modes, reservoir forming stages and model and enrichment law of Chang 9 reservoir were examined. The study showed that the oil of Chang 9 reservoir in the Jiyuan and Longdong(Eastern Gansu) areas came primarily from the source rock of Chang 7 Member, but the oil of Chang 9 reservoir in the Zhidan area came primarily from the source rock of Chang 9 Member. There developed lithologic-structural oil reservoirs in Gufengzhuang-Mahuangshan area in northwest Jiyuan, structural-lithologic oil reservoirs in east Jiyuan, and lithologic reservoirs in Huachi–Qingcheng area and Zhidan area. The overpressure of Chang 7 Member was the driving force of oil migration. The burial history showed that Chang 9 Member experienced two stages of reservoir forming, the reservoir formed in the Late Jurassic was smaller in charging scope and scale, and the Early Cretaceous was the period when the source rock generated oil and gas massively and the Chang 9 reservoir came into being. Along with the tectonic movements, Chang 7 bottom structure turned from high in the west and lower in the East in the sedimentary stage to high in the east and lower in the west in the hydrocarbon accumulation stage and at last to gentle western-leaning monoclinal structure at present. In Early Cretaceous, the Chang 7 bottom structure was the lowest in the west of Huanxian-Huachi-Wuqi-Dingbian areas, so the oil migrated laterally towards the higher positions around after entering the reservoir. In the main reservoir forming period, Chang 7 bottom had an ancient anticline in Mahuangshan-Hongjingzi area of west Jiyuan, controlling the oil reservoir distribution in west Jiyuan.

鄂尔多斯盆地富县地区长8段油气成藏主控因素研究

近年来,富县地区延长组长8段油层组发现了工业油流井,但平面分布不均,具有点状含油的特点,勘探开发总体显示出该区具有多层位含油、局部层位富集的特征,但油水分布主控因素与富集规律尚不清楚,制约了该区下组合油气的勘探开发,为此,基于钻井和生产资料,分析了研究区长8段油层组的油藏类型、主控因素和成藏模式,研究表明,区内长8段油藏类型主要为上倾尖灭岩性油藏、透镜状岩性油藏和致密层遮挡岩性油藏;油气成藏受烃源岩、储层物性、砂体厚度、局部构造共同控制;长8段油气成藏模式为典型的三明治型,有利于致密油的形成。

鄂尔多斯盆地延长组7-8段深水沉积特征及演化规律

为明确鄂尔多斯盆地富县-志丹地区延长组7-8段深水细粒层系沉积特征及演化规律,利用研究区测录井、岩心、薄片,结合总有机碳(total organic carbon,TOC)、全岩X射线衍射等资料识别细粒沉积岩的岩相类型,分为粉砂岩和泥页岩2大类,细分为7亚类,分别是风暴粉砂岩、地震滑塌粉砂岩、异重流粉砂岩;中低有机质纹层状长英质页岩、高有机质纹层状长英质页岩、高有机质纹层状黏土岩、低有机质块状长英质页岩。利用标志层、测井响应特征、地球化学等高精度测试资料将研究区长7-8段划分为一个Ⅲ级层序、3个体系域、7个准层序组,并建立剖面精度到准层序组(10~20 m)的精细层序地层格架;讨论精细层序地层格架演变约束下的细粒沉积岩分布规律。对于粉砂岩:低位和高位体系域晚期水深相对较小,受风暴影响大,发育风暴粉砂岩;高位体系域早期,受陆源洪水影响,发育异重流粉砂岩;地震滑塌粉砂岩的分布受幕式构造运动控制,在低位和湖侵体系域均有分布:对于泥页岩:中低有机质泥页岩分布在低位和高位体系域晚期,高有机质泥页岩则分布在湖侵和高位体系域早期。可见湖平面的升降变化控制了不同岩相类型的垂向分布,体现为粉砂岩与泥页岩高频互层,其中地震滑塌粉砂岩主要受控于幕式构造运动。此外,平面岩相分布规律表明,泥页岩和粉砂岩生储配置关系较好,且分布范围较广,整体呈条带状沿物源方向平行岸线分布,是岩性油气藏勘探开发有利区。

陇东地区HQ区块东部长8致密砂岩储集层成岩相划分

为确定鄂尔多斯盆地陇东地区HQ区块东部长8致密砂岩储集层成岩相及其演化规律,综合铸体薄片、岩石物性、岩心、测井等资料,在划分单砂层岩心成岩相和测井相后,采用优势相法,对研究区长8含油层系成岩相进行分类,筛选出对油气勘探有利的成岩相,预测其有利成岩相带展布。依据成岩作用的影响,可将目的层成岩相划分为5类:剩余粒间孔与长石溶蚀相、绿泥石胶结剩余粒间孔相、绿泥石与伊利石强胶结相、自生碳酸盐胶结相和黏土杂基压实相。剩余粒间孔与长石溶蚀相为研究区最利于油气储集的成岩相类型,有利成岩相总体上呈条带状展布,连续性较好,分布面积较大,研究区中部是有利成岩相带的主要发育区。

鄂尔多斯盆地长7段重力流砂岩长石溶蚀特征及控制因素

基于岩心薄片、扫描电镜、能谱分析、X射线衍射全岩分析及溶蚀实验,研究鄂尔多斯盆地三叠系延长组7段(简称长7段)重力流砂岩中长石溶孔发育特征及控制因素,明确长石溶孔的形成与分布,为预测优质储集层分布提供依据。研究表明:(1)研究区长7段砂岩中的长石经历3类成岩作用:长石次生加大、黏土以及方解石的交代、长石碎屑的溶蚀作用。(2)长7段致密砂岩中的长石溶蚀主要源于有机酸溶蚀,此外还受长石类型、长石早期蚀变程度以及砂岩中云母碎屑对有机酸的缓冲作用影响。(3)不同长石的溶蚀程度不同,表现为钾长石较斜长石易溶蚀,钾长石中正长石较微斜长石易溶,未蚀变的长石较早期高岭土或绢云母化的长石易溶蚀。(4)溶蚀实验显示云母的存在会抑制长石溶蚀,相同质量的云母对有机酸的消耗能力明显强于长石。(5)在云母含量低的情况下,长7段砂岩长石溶孔较为发育,储集层物性得以改善,而云母含量较高的地区长石溶孔则明显减少。

鄂尔多斯盆地富县地区三叠系延长组长7页岩油特征及其主控因素

鄂尔多斯盆地富县地区三叠系延长组长7页岩段具有埋深浅、油质轻、油井产能变化大、资源潜力大的特点,明确油藏的富集主控因素是进行高效勘探的关键。根据富县地区长7页岩段铸体薄片、物性、扫描电镜等测试分析结果,结合岩心、测井、地震等资料,对该区长7段地层特征进行了研究,并对其主控因素展开讨论。研究区长7段广泛发育灰色—深灰色—灰黑色烃源岩,其岩性为泥岩和泥页岩,有机质类型主要为Ⅰ—Ⅱ_(2)型,源岩的镜质体反射率(R_(o))值为0.81%~1.1%,生烃能力强。砂岩储层以细粒长石砂岩为主,孔隙类型以粒内孔、残余粒间孔、溶蚀孔隙和原生粒间孔为主;储层致密,孔隙度主要分布在2.0%~16.0%之间,渗透率主要分布在(0.01~1.20)×10^(-3)μm^(2)之间。砂岩夹层的物性以及距离断裂的远近影响储层的含油性:储层粒度越粗、物性越好,含油气性也越好。储层物性受控于两方面因素:一是沉积微相,水下分流河道微相物性最好,河口坝微相次之;二是成岩作用,早成岩期绿泥石强胶结及方解石弱胶结有助于物性甜点的形成。断层的发育和断层性质对富县地区长7页岩油的富集至关重要。统计发现,当断层断距超过10 m且井筒距断裂在1 km以内时,难以获得工业油流;当断距小于7 m且井筒距离大断裂超过1 km以上时,容易获得工业油流。

鄂尔多斯盆地合水地区三叠系长7段夹层型页岩油储层特征及主控因素

运用铸体薄片、扫描电镜、黏土矿物X射线衍射、电子探针、阴极发光、高压压汞、物性测试等资料,对鄂尔多斯盆地西南部合水地区三叠系延长组长7段夹层型页岩油储层特征及储层致密化主控因素进行了研究,建立了储层定量评价标准,并预测出有利储层分布。研究结果表明:(1)鄂尔多斯盆地合水地区三叠系长7段夹层型页岩油储层主要为岩屑长石砂岩与长石岩屑砂岩,成分成熟度低、填隙物含量高、孔喉结构复杂,具有高孔低渗特征。(2)胶结作用是研究区长7段夹层型页岩油储层致密化的主控因素,储层平均视胶结率为86.3%,达到强胶结程度,以自生黏土矿物中的伊利石胶结为主;压实作用对储层致密化起次要作用,储层平均视压实率为46.0%,为中等压实程度;溶蚀作用降低了储层的致密化程度,但储层渗流能力较低,酸性流体难以大规模溶蚀,平均视溶蚀率仅为13.8%,为弱溶蚀程度。(3)受中等压实—弱溶蚀—强胶结成岩作用的影响,储层非均质性较强,成岩系数差异较大。Ⅰ类储层成岩系数大于2.4,Ⅱ1类储层成岩系数为1.8~2.4,Ⅱ2类储层成岩系数为1.2~<1.8,Ⅲ类储层成岩系数小于1.2,Ⅰ类与Ⅱ1类储层为有利储层。区域上中部混源区有利储层发育规模最大,是勘探的主要目标区。

鄂尔多斯盆地东南部长7段页岩油气富集主控因素

为明确鄂尔多斯盆地东南部长7段页岩油气富集主控因素,综合钻井、测井、岩心分析化验等资料,对研究区长7段页岩油气富集程度及其机理进行研究。页岩解析气量与烃源岩总有机碳含量呈正比,有机质含量控制页岩油气的总含量,有机质发育大量孔隙,页岩油气以吸附态和游离态赋存于有机孔隙中。储集层孔隙结构和孔隙度影响页岩油气的含量及赋存状态,吸附油气主要赋存于微孔中,游离油气主要赋存于中孔和大孔中,但中孔中游离气含量高于大孔,而孔隙度越大,页岩中油气绝对含量越高。砂岩夹层和富有机质页岩的配置关系控制着页岩油气的富集部位,根据粉砂岩、细砂岩与页岩的关系,延长组长7段页岩油气可划分为近源和源内2类,源内又可分为砂岩与页岩互层型、页岩夹砂岩型和页岩型;下伏于富有机质页岩中的砂体和透镜状砂体油气含量最高,其次是上覆于富有机质页岩的砂体和呈舌状或指状与富有机质页岩接触的砂体。

鄂尔多斯盆地吴堡地区延长组长8致密砂岩油藏成藏主控因素

鄂尔多斯盆地三叠系延长组长8油层组为近年来发现的勘探开发新层系,勘探实践证实其成藏条件优越,勘探潜力大。本文以盆地中南部志丹县吴堡地区为例,对该区长8油藏成藏条件及分布规律进行了研究,结果表明:长8油藏油源主要来自于上覆长73烃源岩、长8内部烃源岩和长9顶部烃源岩,具有良好的生储层组合配置;主成藏期运移动力主要为生烃增压等形成的异常高压,油气充注到长8致密储层后主要以近距离垂向和侧向运移为主;成岩作用加剧了储层非均质性,形成成岩遮挡型准连续型油气聚集。长8油藏平面及层位分布主要受控于有效烃源岩展布、储层质量和有效盖层的控制,多种地质因素共同形成现今长8油藏分布格局。

鄂尔多斯盆地马岭地区长8储层成岩作用与有利成岩相带

运用常规薄片、铸体薄片、X射线衍射、阴极发光及扫描电镜等实验手段,研究鄂尔多斯盆地马岭地区延长组长8砂岩储集层成岩作用类型及其对储层的影响,划分成岩相并预测有利成岩相带。研究结果表明,研究区长8储层经历了压实、胶结、溶解及交代等多种成岩作用,压实作用和晚期含铁碳酸盐胶结作用使砂岩孔隙大量减少,显著降低储层物性,而溶解作用产生了较多次生孔隙,使储层物性得到明显改善。根据储层物性的主控成岩作用,结合孔隙类型,该区砂岩储集层划分为强溶蚀剩余粒间孔+溶蚀孔相、弱胶结剩余粒间孔相、黏土矿物胶结相、碳酸盐胶结相和强压实相5种成岩相,其中强溶蚀剩余粒间孔+溶蚀孔相和弱胶结剩余粒间孔相储层物性较好,是储层发育的有利成岩相带。

苏里格气田二叠系盒_8段储集层的成岩作用及孔隙演化

鄂尔多斯盆地北部内蒙古自治区鄂多克旗—乌审旗一带 ,长庆油田公司的天然气勘探取得了重大突破 ,发现了苏里格气田 ,含气面积约 6 0 0 0km2 。圈闭类型为岩性圈闭气藏 ,下石盒子组为主要目的层 ,储集岩为一套中、粗粒砂岩 ,储集空间以各类次生孔隙为主。成岩作用对储层的影响有利有弊 ,压实与胶结作用使原生孔隙几乎丧失贻尽 ,溶蚀作用所形成的次生孔隙改善了砂岩储层的孔渗性。砂岩储集层埋深在 2 85 0～ 310 0m时 ,最有利于次生孔隙的形成。成功地预测次生孔隙发育区 ,将是寻找高产富集区的关键。

鄂尔多斯盆地中部三叠系延长组7段烃组分的运移分异作用

鄂尔多斯盆地延长组7段页岩体系是泥岩、页岩和砂岩的组合体。为了深入揭示页岩油组分在不同岩性中的运移分异现象,针对鄂尔多斯盆地中部地区开展了典型烃类组分的运移分异研究。研究表明:在不同的岩性中4类族组分含量存在差异。砂岩中饱和烃(SAT)含量高,非烃与沥青质(NSO+Asph)含量低。页岩和泥岩的SAT含量低,NSO+Asph含量高。砂岩的n C_(11-15)烃类组分含量较高,nC_(23-39)烃类组分含量较低;页岩和泥岩的nC_(11-15)烃类组分含量较低,nC_(23-39)烃类组分含量较高。页岩和泥岩的Pr/Ph,Pr/nC_(17)和Ph/n C_(18)等含量比值参数数值变化大,砂岩的数值变化小。页岩和泥岩的C_(27)/C_(29)规则甾烷含量比值较低,砂岩则较高。页岩和泥岩的藿烷Ts/Tm与Ts/(Ts+Tm)比值较低,砂岩则较高。页岩和泥岩的C_(32)升藿烷22S/(22S+22R)比值变化较大,砂岩则具有相对集中的数值。砂岩的伽马蜡烷指数较高且数值分布范围较广,而页岩与泥岩则相反;页岩和泥岩8β(H)-补身烷/8β(H)-升补身烷的含量比值普遍大于1,而砂岩的数值普遍小于1。综合研究认为,不同石油组分在烃源岩内部的分布差异是吸附差异和不同石油组分运移分异共同导致的。

湖相细粒沉积岩颗粒微观力学特征及类型划分——以鄂尔多斯盆地上三叠统延长组7段页岩为例

细粒沉积岩蕴藏着丰富的油气资源,为了研究细粒沉积岩颗粒微观结构及力学特征,以鄂尔多斯盆地上三叠统延长组7段细粒沉积岩为例,开展了扫描电镜观察和纳米压痕实验分析,据此研究细粒沉积颗粒的几何特征和微观力学性质。研究认为:用粒径、扁平度、棱角性、硬度和弹性模量5个特征参数,可将细粒沉积岩划分为粒度+棱角型、扁平度+棱角型、扁平度+棱角+弹性模量+硬度型、弹性模量+硬度型、棱角+弹性模量+硬度型和粒度+棱角+弹性模量型6种主要颗粒类型;接着,根据颗粒类型的相对含量,进一步将颗粒类型划分为5种组合类型;最后,分析了细粒沉积颗粒类型与矿物类型之间的耦合关系。细粒沉积岩颗粒微观分类方案的建立,有助于理解细粒沉积岩微观结构特征,预测地质“甜点”空间分布,对细粒沉积岩的油气资源评价和效益开发具有重要的理论和科学意义。

陕北安塞地区延长组长8段裂缝发育特征

应用相似露头及岩心裂缝统计分析技术、地下裂缝古地磁定向技术对鄂尔多斯盆地安塞地区延长组长8段裂缝发育程度及其特征进行研究,并与注水开发动态裂缝监测结果进行对比,发现安塞地区三叠系延长组长8段碎屑岩普遍发育天然裂缝,裂缝形成时期主要为燕山期和喜山期,裂缝以构造裂缝为主,裂缝面均直立、裂缝间距20～40 cm,受局部构造应力场控制裂缝发育程度和组系存在差异;古地磁定向天然显裂缝及微裂缝方位计有4组,其中东北及其东南方向裂缝最位发育,平均方位角分别为64.5°及141.5°,次为东西向裂缝,平均方位角为190°,南北向裂缝不发育,平均方位为2.5°.注水开发动态裂缝监测结果表明:在现今北东60°～80°最大主应力作用下,人工裂缝优先沿北东向天然显裂缝开启延伸,注水效果明显,局部引起油井水窜,而西北-东南方向储层裂缝张开程度差,注水效果不明显,在注水开发中应充分考虑裂缝特征进行井网型式及其压裂作业参数优化。

鄂尔多斯盆地陕北地区三叠系长7段致密油分布特征及控制因素

综合利用地球化学、扫描电镜、岩心薄片、测井等资料以及油井生产数据等,对鄂尔多斯盆地陕北地区三叠系延长组7段储层特征、烃源岩特征和致密油分布特征进行了分析,从烃源岩展布、输导体系和源-储组合关系3个方面对致密油差异富集控制因素进行了探讨,并总结了成藏模式。研究结果表明:(1)陕北地区长7段致密砂岩储层主要分布在一亚段(长71)和二亚段(长72),以灰色—灰白色长石砂岩和岩屑长石砂岩为主,长71和长72平均孔隙度分别为5.56%和7.32%,平均渗透率分别为0.097 m D和0.110 m D,长72储层物性更好;孔隙空间以溶孔为主,发育少量粒间孔。(2)研究区烃类主要来源于本地长72顶部和长73这2套烃源岩,平均厚度大于20 m,有机质丰度高,平均TOC值为3.02%,干酪根类型以Ⅰ型和Ⅱ1型为主,处于生烃高峰期,平均生烃量为270.2×10^(4)t/km^(2),长73烃源岩生烃潜力更大,供烃至长72储层,长71致密油来源于长72烃源岩;新安边地区三角洲前缘亚相末端的长72储层中致密油由湖盆烃源岩侧向供烃。(3)研究区致密油富集受烃源岩展布、砂体连通性以及源-储组合共同控制,在长72更富集,在新安边地区分布面积最大,安塞地区无大规模致密油聚集;纵向上和平面上致密油的聚集差异受控于烃源岩厚度和源-储组合关系,下生上储、上下生油而中间储集和砂泥互层时含油性更好;新安边地区三角洲前缘亚相末端的长72致密油聚集规模大于三角洲前缘主体,是由于三角洲前缘末端发育的局部连通砂体阻碍了湖盆烃类物质的侧向运移。(4)研究区致密油为“源控-砂控”成藏模式,远源河道优势砂体尖灭处和近源局部连通的砂体是有利勘探区。