Enrichment model and major controlling factors of below-source tight oil in Lower Cretaceous Fuyu reservoirs in northern Songliao Basin,NE China

Based on the geochemical,seismic,logging and drilling data,the Fuyu reservoirs of the Lower Cretaceous Quantou Formation in northern Songliao Basin are systematically studied in terms of the geological characteristics,the tight oil enrichment model and its major controlling factors.First,the Quantou Formation is overlaid by high-quality source rocks of the Upper Cretaceous Qingshankou Formation,with the development of nose structure around sag and the broad and continuous distribution of sand bodies.The reservoirs are tight on the whole.Second,the configuration of multiple elements,such as high-quality source rocks,reservoir rocks,fault,overpressure and structure,controls the tight oil enrichment in the Fuyu reservoirs.The source-reservoir combination controls the tight oil distribution pattern.The pressure difference between source and reservoir drives the charging of tight oil.The fault-sandbody transport system determines the migration and accumulation of oil and gas.The positive structure is the favorable place for tight oil enrichment,and the fault-horst zone is the key part of syncline area for tight oil exploration.Third,based on the source-reservoir relationship,transport mode,accumulation dynamics and other elements,three tight oil enrichment models are recognized in the Fuyu reservoirs:(1)vertical or lateral migration of hydrocarbon from source rocks to adjacent reservoir rocks,that is,driven by overpressure,hydrocarbon generated is migrated vertically or laterally to and accumulates in the adjacent reservoir rocks;(2)transport of hydrocarbon through faults between separated source and reservoirs,that is,driven by overpressure,hydrocarbon migrates downward through faults to the sandbodies that are separated from the source rocks;and(3)migration of hydrocarbon through faults and sandbodies between separated source and reservoirs,that is,driven by overpressure,hydrocarbon migrates downwards through faults to the reservoir rocks that are separated from the source rocks,and then migrates laterally through sandbodies.Fourth,the differences in oil source conditions,charging drive,fault distribution,sandbody and reservoir physical properties cause the differential enrichment of tight oil in the Fuyu reservoirs.Comprehensive analysis suggests that the Fuyu reservoir in the Qijia-Gulong Sag has good conditions for tight oil enrichment and has been less explored,and it is an important new zone for tight oil exploration in the future.

Effect of Shale Reservoir Characteristics on Shale Oil Movability in the Lower Third Member of the Shahejie Formation, Zhanhua Sag

To reveal the effect of shale reservoir characteristics on the movability of shale oil and its action mechanism in the lower third member of the Shahejie Formation(Es3l), samples with different features were selected and analyzed using N2 adsorption, high-pressure mercury injection capillary pressure(MICP), nuclear magnetic resonance(NMR), high-speed centrifugation, and displacement image techniques. The results show that shale pore structure characteristics control shale oil movability directly. Movable oil saturation has a positive relationship with pore volume for radius > 2 μm, as larger pores often have higher movable oil saturation, indicating that movable oil is present in relatively larger pores. The main reasons for this are as follows. The relatively smaller pores often have oil-wetting properties because of organic matter, which has an unfavorable effect on the flow of oil, while the relatively larger pores are often wetted by water, which is helpful to shale oil movability. The rich surface provided by the relatively smaller pores is beneficial to the adsorption of immovable oil. Meanwhile, the relatively larger pores create significant pore volume for movable oil. Moreover, the larger pores often have good pore connectivity. Pores and fractures are interconnected to form a complex fracture network, which provides a good permeability channel for shale oil flow. The smaller pores are mostly distributed separately;thus, they are not conducive to the flow of shale oil. The mineral composition and fabric macroscopically affect the movability of shale oil. Calcite plays an active role in shale oil movability by increasing the brittleness of shale and is more likely to form micro-cracks under the same stress background. Clay does not utilize shale oil flow because of its large specific surface area and its block effect. The bedding structure increases the large-scale storage space and improves the connectivity of pores at different scales, which is conducive to the movability of shale oil.

Petroleum geochemistry and origin of shallow-buried saline lacustrine oils in the slope zone of the Mahu sag, Junggar Basin, NW China

Recently, significant oil discoveries have been made in the shallower pay zones of the Jurassic Badaowan Formation (J_(1)b) in the Mahu Sag, Junggar Basin, Northwest China. However, little work has been done on the geochemical characteristics and origins of the oil in the J_(1)b reservoir. This study analyzes 44 oil and 14 source rock samples from the area in order to reveal their organic geochemical characteristics and the origins of the oils. The J_(1)b oils are characterized by a low Pr/Ph ratio and high β-carotene and gammacerane indices, which indicate that they were mainly generated from source rocks deposited in a hypersaline environment. The oils are also extremely enhanced in C_(29) regular steranes, possibly derived from halophilic algae. Oil-source correlation shows that the oils were derived from the Lower Permian Fengcheng Formation (P_(1)f) source rocks, which were deposited in a strongly stratified and highly saline water column with a predominance of algal/bacterial input in the organic matter. The source rocks of the Middle Permian lower-Wuerhe Formation (P_(2)w), which were deposited in fresh to slightly saline water conditions with a greater input of terrigenous organic matter, make only a minor contribution to the J_(1)b oils. The reconstruction of the oil accumulation process shows that the J_(1)b oil reservoir may have been twice charged during Late Jurassic–Early Cretaceous and the Paleogene–Neogene, respectively. A large amount volume of hydrocarbons generated in the P_(1)f source rock and leaked from T_(1)b oil reservoirs migrated along faults connecting source beds and shallow-buried secondary faults into Jurassic traps, resulting in large-scale accumulations in J_(1)b. These results are crucial for understanding the petroleum system of the Mahu Sag and will provide valuable guidance for petroleum exploration in the shallower formations in the slope area of the sag.

Classification of microscopic pore-throats and the grading evaluation on shale oil reservoirs

On the basis of the characterization of microscopic pore-throats in shale oil reservoirs by high-pressure mercury intrusion technique, a grading evaluation standard of shale oil reservoirs and a lower limit for reservoir formation were established. Simultaneously, a new method for the classification of shale oil flow units based on logging data was established. A new classification scheme for shale oil reservoirs was proposed according to the inflection points and fractal features of mercury injection curves: microscopic pore-throats(less than 25 nm), small pore-throats(25-100 nm), medium pore-throats(100-1 000 nm) and big pore-throats(greater than 1 000 nm). Correspondingly, the shale reservoirs are divided into four classes, I, II, III and IV according to the number of microscopic pores they contain, and the average pore-throat radii corresponding to the dividing points are 150 nm, 70 nm and 10 nm respectively. By using the correlation between permeability and pore-throat radius, the permeability thresholds for the reservoir classification are determined at 1.00× 10^(-3) μm^2, 0.40×10^(-3) μm^2 and 0.05×10^(-3) μm^2 respectively. By using the exponential relationship between porosity and permeability of the same hydrodynamic flow unit, a new method was set up to evaluate the reservoir flow belt index and to identify shale oil flow units with logging data. The application in the Dongying sag shows that the standard proposed is suitable for grading evaluation of shale oil reservoirs.

基于机器学习的低含油饱和度砂岩储层参数预测——以准噶尔盆地夏子街油田夏77井区下克拉玛依组为例

准噶尔盆地夏子街油田夏77井区块下克拉玛依组(简称克下组)特低孔特低渗油藏油水关系复杂、产量低、储层含水高,且具有低含油饱和度、孔渗相关性差、储层参数与测井响应关系不清晰、油水层识别困难等特征,常规储层参数评价及预测方法适用性差。通过对岩性、物性、含油性分析,明确了克下组储层岩性为砂砾岩、砂质砾岩,黏土矿物以伊蒙混层为主;储层为以原生粒间孔和残余粒间孔为主要储集空间的低孔隙度、特低渗透率储集层。通过建立含油饱和度解释模型,确定了本区油藏属于低饱和度油藏,含油饱和度一般为36%~55%。砂砾岩储层物性和含油性优于中细砂岩,储层物性控制含油性,呈现低饱和度特征,电性受含油性和岩性双重影响。通过低含油饱和度油藏形成机理研究,认为储层微观孔隙结构是形成低含油饱和度的主要原因。通过对敏感参数优选,基于自然伽马、电阻率和声波时差测井等资料,引入基于机器学习的BP神经网络技术,对夏子街油田夏77井区块克下组油藏进行了孔隙度、渗透率和含水饱和度的计算及预测,储层参数预测精度均高于80%,相关结论及方法可为低含油饱和度致密砂岩储层的物性参数预测提供依据和参考。

松辽盆地北部下白垩统扶余油层源下致密油富集模式及主控因素

基于地球化学、地震、测井和钻井等资料,对松辽盆地北部下白垩统泉头组扶余油层地质特征、致密油富集主控因素及富集模式等进行系统分析。研究表明:①泉头组上覆上白垩统青山口组优质烃源岩,环凹鼻状构造发育,沉积砂体大面积连续分布,储层整体致密;②优质烃源岩、储层、断裂、超压和构造等多要素配置联合控制扶余油层致密油富集。源储匹配关系控制致密油分布格局;源储压差为致密油富集提供充注动力;断砂输导体系决定油气运移和富集;正向构造是致密油富集的有利场所,断垒带是向斜区致密油勘探重点突破区带;③基于源储关系、输导方式、富集动力等要素建立扶余油层致密油3种富集模式,一是源储对接油气垂向或侧向直排式:“源储紧邻、超压驱动、油气垂向倒灌或源储侧向对接运聚”;二是源储分离断裂输导式:“源储分离、超压驱动、断裂输导,油气通过断层向下运移到砂体富集”;三是源储分离断砂匹配式:“源储分离、超压驱动、断裂输导、砂体调整、油气下排后通过砂体侧向运移富集”;④油源条件、充注动力、断裂分布、砂体以及储层物性等方面的差异性造成扶余油层致密油的差异富集,齐家—古龙凹陷扶余油层具有较好富集条件,勘探程度低,是未来致密油探索重要新区带。

四川盆地下侏罗统自流井组陆相页岩油气地质特征

四川盆地下侏罗统自流井组发育东岳庙段和大安寨段两套富有机质页岩层系,主要为湖相沉积的页岩夹粉砂岩、介壳灰岩。基于页岩、介壳灰岩和粉砂岩之间的组合特征,自流井组共识别出3类7种岩相组合类型。页岩有机质丰度中等,有机质类型以Ⅱ1、Ⅱ2型为主,热演化程度中等,油气共存。页岩储集空间既有无机孔,也有有机质孔,局部发育微裂缝。自流井组页岩中无机矿物与有机质、有机质与有机质孔的配置关系控制着页岩源—储配置的有效性,在较高的演化程度下,随着TOC的增大有机质孔隙度增大,页岩的源—储配置关系变好。刚性矿物稳定支撑格架下保存的固体沥青个体大,内部有机质孔数量多、孔径大;黏土矿物不稳定支撑格架下保存的沥青呈长条形,内部的有机质孔孔径较小。基于页岩层系不同岩性源—储耦合条件评价结果,页岩的源—储耦合条件明显优于夹层,源—储耦合条件好的优质页岩层段是页岩油气的甜点层段,其中黏土质页岩最好,(含)介壳灰质页岩、(含)粉砂质页岩为次;介壳灰岩和粉(细)砂岩夹层不具备烃源条件且储集条件差,只能与相邻的富有机质页岩形成近源聚集体系。

准噶尔盆地盆1井西凹陷侏罗系三工河组凝析气藏特征及成因机制

基于油气地球化学、试油结果与凝析气相态分析实验等资料,采用盆地模拟技术分析了准噶尔盆地盆1井西凹陷前哨井区侏罗系三工河组凝析气藏特征,并对凝析气藏的成藏过程与成因机制进行了详细研究。研究结果表明:①盆1井西凹陷侏罗系三工河组凝析气藏为构造-岩性油气藏,优质储层岩性主要为灰色细—中粒长石岩屑砂岩,孔隙度为2.70%~16.10%,平均为12.10%,渗透率为0.016~109.000 mD,平均为14.170 mD,属于中孔、低渗储层,与下伏的二叠系风城组和下乌尔禾组2套烃源岩形成了良好的储-盖组合。②研究区凝析油表现为低密度、低黏度、低凝固点和低含蜡量等特征,正构烷烃以低—中碳数为主,为下乌尔禾组烃源岩成熟—高成熟阶段的产物。③研究区凝析气藏天然气组分以烃类气为主,甲烷与乙烷碳同位素值分布集中,分别为-37.40‰~-36.84‰与-27.55‰~-26.54‰,为腐殖型烃源岩裂解气,来源于下乌尔禾组烃源岩。④研究区下乌尔禾组烃源岩于古近纪早期生成的凝析油气经过不断调整最终于新近纪早期充注形成凝析气藏,从成藏至现今储层流体组分未发生改变,油气藏相态类型也未发生改变,为原生型凝析气藏。

天赐湾地区长4+5油层组薄油层有效储层下限测井评价

为实现鄂尔多斯盆地天赐湾地区长4+5油层组薄油层的精细刻画,需要开展系统的有效储层下限综合评价。利用该地区主力油层长4+5^(2)亚段大量地质、实验、测井、生产资料,系统研究了致密油藏储层特征并提出有效储层下限标准。研究结果表明,工区长4+52亚段储层的岩性以细粒长石砂岩为主,砂岩粒度曲线具有2段式特征。孔隙度主要分布在8%~16%,峰值区间分布在10%~13%;渗透率主要分布在0.2~5.6 mD^(*),存在2个峰值区间,分别为0.3~0.4 mD及1.4~5.6 mD。渗透率高于1.0 mD的相对高渗优质储层的平均孔喉半径大于0.14μm且分选系数大于2.5。长4+52亚段有效储层的含油级别为油迹级及油斑级,物性下限标准为孔隙度9.0%、渗透率0.3 mD。此外,储层有效厚度电性参数,包括测井孔隙度、含油饱和度、电阻率及声波时差的下限分别为9.0%、40.0%、15Ω・m及225μs/m。结合岩心、测试、测井及试油资料构建的致密油油水层识别标准在薄油层应用中是可靠的。

四川盆地蓬莱—中江地区震旦系灯影组二段成藏特征

通过钻井、岩心、测录井及地震资料的综合分析,系统研究了四川盆地蓬莱—中江地区震旦系灯影组二段气藏的成藏特征。研究结果表明:(1)四川盆地灯影组沉积期,随着海水侵入,古陆多被淹没或侵蚀夷平,盆地逐渐演变为碳酸盐岩台地。灯二上亚段沉积期,川中北斜坡蓬莱—中江地区以发育台地边缘滩相和台地边缘丘相为特色,并可细分为滩核、滩缘、滩间海、丘核、丘缘、丘间海6种亚相,是储层发育的有利相带。(2)研究区灯二上亚段储层以藻云岩、藻砂屑云岩为主要储集岩,发育残余粒间孔+粒间溶孔型、粒内溶孔+藻格架孔型、裂缝型与孔洞型4种类型的储层,储层厚度分布特征与沉积相分布特征较吻合,位于台地边缘丘滩核的储层累积厚度大。(3)研究区灯二上亚段气藏的天然气主要来源于筇竹寺组烃源岩,烃源岩厚度大、有机碳含量及热演化程度高,气藏具备较好的烃源条件和封盖条件,具有“上生下储上盖”和“旁生侧储上盖”2种较好的生-储-盖配置关系。(4)研究区油气充注主要发生于三叠纪—白垩纪,为多期“准连续”型,灯二上亚段气藏主要经历了奥陶纪—志留纪古油气藏聚集阶段、志留纪—石炭纪古油藏破坏阶段、二叠纪—三叠纪再次生烃成油藏阶段和三叠纪—侏罗纪原油裂解生气阶段。

渤海海域明下段岩性油藏油柱高度分布规律及影响因素

渤海海域明下段岩性油藏特征、储量规模差异大,油柱高度作为油藏评价的关键参数,直接影响油藏储量规模,其分布规律及影响因素认识不清。基于渤海海域约460个明下段岩性油藏勘探开发数据,在充分了解地质背景的基础上,利用统计手段并结合地球化学证据,厘清了浅层明下段岩性油藏油柱高度空间展布规律,通过进一步分析油柱高度与油气充注强度、区域盖层展布、圈闭类型和断砂耦合程度等成藏要素关系,明确了油柱高度影响因素。结果表明:①受油气充注强度控制,明下段岩性油藏油柱高度平面上具有“凸起区小、凹陷区大”特征,平均油柱高度相差约2倍;②受区域盖层控制,纵向上具有“盖层之上油柱高度小、盖层之下油柱高度大”特征,下部Ⅲ/Ⅳ油组平均油柱高度为Ⅰ/Ⅱ油组约2倍;③受油气汇聚部位与侧封保存能力控制,高点依靠断裂侧封油藏油柱高度普遍高于岩性尖灭油藏的油柱高度,平均油柱高度相差约2.5倍;④明下段油气成藏受断砂耦合程度影响,但凸起区与凹陷区断裂油气运移能力差异较大,凸起区切穿馆陶组区域油气输导层断裂可起到运移作用,而凹陷区切穿深部汇聚脊的断裂才可作为有效的油源断裂。渤海海域明下段岩性油藏油柱高度分布规律及影响因素,对后续岩性油藏价值勘探、精细勘探具有借鉴意义。

东营凹陷深层自源型油气成藏模式与勘探实践

东营凹陷深层是以“红层”为典型特征的沙河街组四段下亚段(沙四下亚段)—孔店组,该套层系沉积厚度大、储量发现少,蕴含着极大的勘探潜力。综合深层烃源岩评价、高成熟油源对比及自源型油气成藏模式的系统分析,明确了深层沙四下亚段和孔店组二段(孔二段)两套烃源岩的基本特征,落实了深层的资源潜力,同时深入剖析关键成藏要素条件,建立了自源型差异油气成藏模式。研究表明,深层孔二段烃源岩有机质类型为Ⅱ_(1)—Ⅲ型,评价为过成熟中等烃源岩;沙四下亚段烃源岩有机质类型为Ⅰ—Ⅱ_(1)型,评价为成熟优质烃源岩。利用原型盆地的井—震追踪落实烃源岩展布,进而评价出深层资源量为11.35×10^(8)t。同时,建立了两种自源型油气藏的差异成藏模式,一种是陡坡带沙四下亚段烃源岩直接对接深层砂砾岩储层,匹配形成凝析油气—常规油的纵向有序油气藏;另一种是南部斜坡带孔店组源内的“源—断—储—圈”差异油气运聚模式。分析认为,基于东营凹陷深层烃源岩品质与规模的深化认识,以及两种自源型油藏模式的认识可将勘探目的层至少下探1500m,初步估算新增圈闭资源量近2×10^(8)t,东营凹陷深层自源型油藏预计在“十四五”期间迎来重大突破。

四川盆地泸州印支期古隆起嘉陵江组油气分布规律及勘探开发前景

勘探开发实践证实四川盆地泸州古隆起下三叠统嘉陵江组存在一个印支期的古油藏,但多年来未得到充分重视。近期,该古隆起核部完钻的德胜1井和胜探1井均见良好油气显示,其中,德胜1井嘉陵江组测试获得轻质工业油流,展示出泸州古隆起古油藏具有良好的油气勘探开发潜力。为此,根据全油碳同位素、轻烃、生物标志化合物等地球化学指标,采取排他法重新评价了嘉陵江组原油来源,通过分析储层的沥青类型和特征剖析了原油的成因,探讨了古油藏演变及油气分布规律、古隆起演化与古油藏的关系,并明确了古隆起的油气勘探开发前景。研究结果表明:(1)泸州古隆起嘉陵江组原油及凝析油主要来自下伏志留系海相烃源岩,油气充注具有多期多源特征;(2)印支运动早幕,泸州古隆起嘉陵江组古油藏形成;(3)古隆起核部剥蚀强,古油藏上部次生变化形成氧化降解沥青封堵带,下部原油得以保存,气侵作用弱,以产油为主;核部边缘剥蚀弱,古油藏原油保存好,烃源断层发育,气侵作用强,形成含油气藏;(4)古隆起的演化和古油藏的演变控制了现今油气分布格局,核部产原油,核部边缘产凝析油气。结论认为:(1)嘉陵江组古油藏规模巨大,以沥青质衬边消失为古油藏边界估算面积为8000 km2,高度为136 m;(2)古隆起上向斜及斜坡构造油气勘探程度低,是未来油藏及含油气藏勘探开发的重要领域;(3)该认识对于气多油少的四川盆地具有重要的现实意义。

吉木萨尔凹陷芦草沟组混积型页岩油可动性实验

为确定吉木萨尔凹陷芦草沟组页岩油藏储集层孔喉结构及其原油可动性,利用薄片、扫描电镜、高压压汞等划分储集层;通过驱替与核磁共振联测实验,开展页岩油可动性评价,揭示可动油占比、孔径变化规律及其控制因素,建立页岩油可动性定量评价模型。芦草沟组发育粒间孔型、粒间-溶蚀-晶间孔型、溶蚀孔型、溶蚀-晶间孔型和晶间孔型5类储集空间。粒间孔型发育在粉—细砂岩相和砂质白云岩相中,可动性最好;溶蚀孔型主要发育在白云质粉砂岩相中,可动性中等;其他类型主要发育在泥岩相、泥质白云岩相和石灰质砂岩相中,可动性稍差。厘定页岩油可动孔喉下限为20 nm,可动性明显提高的孔喉界限为60 nm和150 nm,试油产能与之对应较好。页岩油赋存特征和孔喉结构共同影响页岩油可动性,粉—细砂岩相和白云质粉砂岩相的孔喉及页岩油赋存均最佳,为芦草沟组页岩油最有利开发岩相。

致密砂岩层内非均质性及含油下限——以鄂尔多斯盆地三叠系延长组长7段为例

致密油成为世界石油勘探领域一大亮点并显示出巨大勘探潜力,中国致密油分布广且具独特地质特征。通过鄂尔多斯盆地三叠系延长组长7油层组岩心观察,发现层内单砂体级别上存在较强含油非均质性,利用薄片、氯仿沥青抽提、场发射扫描电镜、微米CT、高压压汞、N2气体吸附以及砂岩X射线衍射(XRD),对非均质性砂岩成岩特征、含油性、微观孔喉、孔径分布以及岩石矿物组成进行分析。结果显示:钙质胶结是导致致密砂岩储层非均质性的原因;残留烃含量相差约6倍;致密砂岩均主要发育纳米级喉道(直径<1μm)。根据残留含油量和介孔平均孔径以及含油量与孔隙度的图版,认为介孔平均孔径15nm、孔隙度2%可能是致密油的含油下限,该认识将对非常规致密油的勘探选区和资源量计算提供依据和参考。

歧口凹陷斜坡区油气成藏与勘探实践

经过50多年的勘探开发,黄骅坳陷歧口凹陷已经进入高勘探阶段,寻找大规模构造油气藏的难度越来越大,斜坡区地层-岩性油气藏成为勘探的重点。在凹陷整体研究解剖的基础上,探讨了大型缓坡区地质分异特征,提出了缓坡区高、中、低三分性的新认识,高、中、低斜坡生储盖组合配置不同,油气运聚与分布差异明显。高斜坡沟槽控砂,优势运移汇聚相富集;中斜坡坡折控砂,优势构造岩性相富集;低斜坡远扇控砂,优势源储耦合相富集。大型斜坡、砂体、烃源岩的有效配置决定了斜坡区具有形成大面积地层-岩性油气藏的条件。经勘探实践,在歧口凹陷埕北、歧北和板桥三个斜坡区均获重大发现,并实现了规模增储,证实了斜坡区是断陷湖盆内油气预探突破与规模增储的主要方向之一。

鄂尔多斯盆地长7油层组有效储层物性下限的确定

鄂尔多斯盆地长7油层组在湖盆中心大面积连续分布,孔隙度主要分布在4％～ 12％,渗透率一般小于0.3mD,属于典型的致密砂岩储层.而划分致密油含油边界关键技术之一是确定有效储层的物性下限.在测井解释、试油数据、储层物性分析等地质资料的基础上,根据统计学原理和超低渗透油藏流体渗流机理,分别采用经验统计法、物性试油法、孔隙度一渗透率交会法、油气驱替模拟实验法以及最小流动孔喉半径法5种方法,对该区有效储层物性下限展开研究.经过研究和综合对比,确定了长7油层组有效储层物性下限值为孔隙度5.7％、渗透率0.0276mD.

聚油古地貌成因类型及其有利成藏条件分析--以鄂尔多斯盆地上里塬地区前侏罗纪古地貌为例

运用地层厚度印模法(延9+延10+富县组地层厚度)恢复出了陇东上里塬地区前侏罗纪古地貌形态,其形态为一级甘陕古河呈近东西向分布,二级庆西古河位于研究区南部向北注入甘陕古河,研究区的北部和南部分别发育姬塬和演武高地,在高地和河谷的过度带分别发育姬塬南斜坡和演武北斜坡,此外,在一级河谷中央还发育有河间丘,在斜坡上发育残丘、残梁次一级单元的古地貌。在此基础上,结合下侏罗统油藏分布特征和规律,提出了聚油古地貌概念,即在油气成藏过程中,能够有机的将油气成藏要素组合,进而使得形成有机的成藏配置条件,使之对油气成藏起着决定性作用的古地貌单元;划分出了研究区内对下侏罗统油藏成藏起主控作用的残梁、残丘、河间丘3种聚油古地貌类型,聚油古地貌主要存在河流袭夺、河流转型、分水岭侵蚀3种成因模式。研究表明,聚油古地貌使得研究区下侏罗统油藏形成了构造主导、岩性控制的构造+岩性的成藏模式,聚油古地貌对下侏罗统油藏成藏创造的有利成藏条件为:①具有刚性特征的聚油古地貌与上覆的延安组"软地层"所产生的差异压实小幅度背斜和穹窿构造;②聚油古地貌容易形成河道砂体分割和披盖砂帽,进而形成的孤立透镜状储层砂体。

鄂尔多斯盆地延长组下组合地层水特征及其油气地质意义

鄂尔多斯盆地中生界延长组下组合长10—长8油层组油水分布关系复杂,地层水特征及其与油藏的关系缺少系统研究。为明确地层水性质及其与油藏的关系以及地层水矿化度对测井精细解释的影响,基于地层水样品筛选,通过对鄂尔多斯盆地延长组1万余个地层水水样测试数据分析,研究地层水性质及分布特征,分析地层水矿化度、特征参数等的油气地质意义。结果表明,鄂尔多斯盆地中生界延长组地层水性质具有区带性分布的特点,各油层组地层水矿化度自西缘冲断带、天环坳陷轴部向湖盆中部总体呈先增加后减小的趋势;延长组下组合地层水矿化度较低,平均为28.4 g/L,属盐水地层水类型,以CaCl2型为主。地层水的离子组成、矿化度、同位素、特征参数等较为相近,且明显不同于其他油层组地层水特征,属于同一流体系统;地层水钠氯系数、脱硫系数、变质系数等特征参数表明,盆地中生界延长组下组合油藏的封闭性整体较好,油藏及出油井点主要分布在地层水矿化度相对较高的区域,西缘冲断带部分油藏受构造作用影响进行了调整改造,油藏封闭性变差;湖盆中部高阻水层、天环坳陷轴部低阻油层发育,地层水矿化度是影响测井解释的重要因素。该研究成果为鄂尔多斯盆地中生界延长组流体系统研究以及复杂油水关系分布的测井精细识别提供了依据。

松辽盆地泉头组三、四段河流相储层岩性油藏控制因素及分布规律

依据大量钻井、测井、地震及实验室分析资料,应用陆相层序地层学、沉积地质学及油气成藏理论,通过成藏条件研究认识到,松辽盆地扶杨油层为河流相低孔、低渗储层,上覆的白垩系青山口组一段湖相泥岩既是烃源岩又是区域性盖层,因此具有上生下储式成藏特征。油?源对比表明,油气垂直下排最大距离可达550 m,平均约300 m。明水组沉积末期,盆地反转应力场产生了大量断穿烃源岩及扶杨油层的断层并在源岩及储层内产生大量裂缝,同时源岩进入生烃高峰期,于是在构造应力及生烃超压作用下油气沿断层及裂缝下排到扶杨油层而成藏。因此,明水组沉积末期成为油气成藏的主要时期。曲流河点砂坝具有较好的物性,是油气的主要储集体。受浅水湖泊形成的泥岩盖层影响,形成了两套含油层系,油藏主要发育在近油源的扶余油层,盆地范围内具有统一的油?水界面。青山口组一段高成熟烃源岩控制了油藏主要分布在中央坳陷区,较低的砂地比决定了扶杨油层以发育岩性油藏为主。