致密混积岩储层物性及孔径分布影响因素——以辽河西部凹陷雷家地区杜家台油层杜三段为例

研究储层物性控制因素对储层评价至关重要.致密混积岩储层所含矿物成分多样, 孔隙结构复杂, 造成储层物性变化大.辽河坳陷西部凹陷雷家地区沙河街组四段位于浅湖-半深湖相带, 其中的杜家台油层杜三段发育方沸石、白云石、长石、石英等多种组分混积储层, 具有较大的致密油资源潜力.根据矿物成分可以将杜三段储层分为泥晶云岩、细粒混积岩和方沸石岩3大类.铸体薄片分析与扫描电镜分析结合, 发现3大类储层均发育中微米孔(孔喉半径>10 μm)-微微米孔(孔喉半径为1~10 μm)-纳米孔(孔喉半径<1 μm)多级孔喉系统.中微米孔主要为粒间溶孔及白云石、方沸石晶间和晶内溶孔.微微米孔主要为白云石晶间孔、碎屑矿物粒间孔及部分微溶孔.大部分白云石晶内溶孔、粘土矿物晶间孔属于纳米孔.高压压汞分析结果表明, 3类致密储层的孔径均具双峰特征.泥晶云岩类储层微微米孔的孔径峰值约为4 μm, 纳米孔的孔径峰值约为10 nm, 二者所占比例分别为25.1%和63.1%.细粒混积岩主要发育中微米孔及纳米孔, 所占比例分别为20.9%和79.1%.方沸石岩类储层的中微米孔和纳米孔所占比例分别为12.1%和85.9%.不同矿物成分发育的孔隙类型及大小控制了混积岩储层的整体孔喉结构, 是造成混积岩储层孔径分布呈双峰特征的主要原因.由于白云石晶间孔连通性好, 方沸石主要以充填物的形式出现, 长石-石英碎屑易溶蚀, 粘土矿物主要发育纳米级晶间孔等原因, 致密混积岩储层孔隙度与方沸石含量负相关, 与长石-石英碎屑含量正相关.在储层中裂缝广泛发育的背景下, 致密混积岩矿物成分与渗透率相关性差.     

自生粘土矿物对文昌A凹陷深部储层的制约

目前关于自生粘土矿物对深层孔隙结构及油气运聚的影响方面的研究十分薄弱.综合利用铸体薄片、全岩XRD、扫描电镜、恒速压汞等测试手段,分析自生粘土矿物对孔隙连通性、孔喉直径及其分布的影响,并结合埋藏史和生烃史探讨了低渗透砂岩不同孔隙结构类型的油气差异富集条件.珠海组深部储层压实作用较强,自生粘土矿物含量较高.碎屑颗粒以线接触-凹凸接触为主,识别出"孔隙+粗喉道"和"喉道主控"2种孔隙结构类型,前者孔隙体积和粗喉道占比较高,后者主要以细喉道为主;自生粘土矿物分割占据大量孔喉空间,自生伊利石主要为孔喉充填型,自生绿泥石主要为颗粒包壳型;珠海组储层与下渐新统恩平组烃源岩不整合接触形成纵向"下生上储"、横向连续分布的有利源储组合,烃源岩持续生烃.珠海组是典型的深埋藏碎屑岩低渗储层,仍具备良好的储集条件,储层发育受机械压实作用和自生粘土矿物共同控制;压实作用是原生孔隙损失的初始因素,以绿泥石和伊利石为代表的自生粘土矿物高度发育是制约优质储层发育的关键因素.      

高邮凹陷永安地区戴南组一段储层特征及主控因素

通过岩心、铸体薄片、扫描电镜、物性分析和孔隙图像分析等资料,对高邮凹陷永安地区戴南组一段砂岩储层特征进行了系统分析,从沉积和成岩两方面对储层物性主控因素进行了研究。研究结果表明:岩石类型为长石岩屑砂岩,成分成熟度较低,粒度偏细,分选中等偏差; 储层物性以低孔低渗为主中孔中渗为辅,孔隙类型有粒间孔、粒间溶孔、粒内溶孔和铸模孔,平均孔径为37.53 μm,喉道主要为可变端面的收缩部分,其次为片状和弯片状喉道,平均喉道半径为10.25 μm,孔喉配位数主要为3,分选性好。沉积作用是高邮凹陷永安地区戴南组一段砂岩储层物性主控因素之一,水动力强分选程度高的沉积环境形成的砂岩粒度大分选好,储层物性好; 不同的成岩作用类型对储层物性具有不同的控制作用,压实和胶结作用导致储层孔隙空间变小,物性变差,而溶蚀作用形成次生孔隙空间,储层物性得到改善,在2 500～2 700 m和2 850～2 950 m处形成了明显的次生孔隙发育带。     

准噶尔盆地乌夏地区二叠系储集层特征及影响因素分析

根据40余口钻井的岩石学资料, 较系统地描述了乌夏地区二叠系储集层特征及其主要影响因素。乌夏地区二叠系储集层类型多样,主要包括陆源碎屑岩、白云（质）岩、火山碎屑岩和火山岩4大类。乌夏地区二叠系储集空间类型以次生孔隙为主,碎屑岩储集层以粒内溶孔、填隙物内溶孔、压裂缝最为发育;白云岩储集层主要发育裂缝,火山碎屑岩储集空间类型则主要为气孔和裂缝,火山岩储集层在乌夏地区分布较少,储集空间主要为气孔。二叠系储集层孔隙结构均属小孔细喉、微孔微细喉、微孔微喉,储集性能中等-差,整体为中、低孔渗储集层。研究认为岩性、粒度、成岩压实、溶蚀及破裂作用是本区储集层质量的主要影响因素：岩性、粒度主要影响储集层性质;压实作用是孔隙损失的主控因素,平均压实减孔量高达23.65％;溶蚀及破裂作用则对改善储集层物性起重要作用;断裂活动也使断裂带附近储集层物性发生明显的改善。根据储集层储集性能及其控制因素,将储集层划分为5种类型,乌夏地区以Ⅲ、Ⅳ、Ⅴ类为主。

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Pore-Throat Combination Types and Gas-Water Relative Permeability Responses of Tight Gas Sandstone Reservoirs in the Zizhou Area of East Ordos Basin,China

With the aim of better understanding the tight gas reservoirs in the Zizhou area of east Ordos Basin, a total of222 samples were collected from 50 wells for a series of experiments. In this study, three pore-throat combination types in sandstones were revealed and confirmed to play a controlling role in the distribution of throat size and the characteristics of gas-water relative permeability. The type-Ⅰ sandstones are dominated by intercrystalline micropores connected by cluster throats, of which the distribution curves of throat size are narrow and have a strong single peak(peak ratio 30%). The pores in the type-Ⅱ sandstones dominantly consist of secondary dissolution pores and intercrystalline micropores, and throats mainly occur as slice-shaped throats along cleavages between rigid grain margins and cluster throats in clay cement.The distribution curves of throat size for the type-Ⅱ sandstones show a bimodal distribution with a substantial low-value region between the peaks(peak ratio 15%). Primary intergranular pores and secondary intergranular pores are mainly found in type-Ⅲ samples, which are connected by various throats. The throat size distribution curves of type-Ⅲ sandstones show a nearly normal distribution with low kurtosis(peak ratio 10%), and the micro-scale throat radii(0.5 μm) constitute a large proportion. From type-Ⅰ to type-Ⅲ sandstones, the irreducible water saturation(Swo) decreased; furthermore, the slope of the curves of Krw/Krg in two-phase saturation zone decreased and the two-phase saturation zone increased,indicating that the gas relative flow ability increased. Variations of the permeability exist in sandstones with different porethroat combination types, which indicate the type-Ⅲ sandstones are better reservoirs, followed by type-Ⅱ sandstones and type-Ⅰ sandstones. As an important factor affecting the reservoir quality, the pore-throat combination type in sandstones is the cumulative expression of lithology and diagenetic modifications with strong heterogeneity.     

辽河坳陷西部凹陷南段古近系沙河街组致密砂岩特征与成因机制*

渤海湾盆地辽河坳陷西部凹陷南段古近系沙河街组中发现了低产油气流和工业油气流,储集层具有低—特低孔隙度、特低—超低渗透率、低压的特征,属于典型的致密砂岩储集层。应用大量的薄片、扫描电镜、粒度分析、压汞和物性等测试资料,研究了致密砂岩的微观特征,探讨了致密砂岩的形成机理。研究结果表明,致密砂岩(孔隙度小于10.0%)大多发育在凹陷区;矿物成分、粒度、分选、磨圆等沉积学参数与致密砂岩的形成关系不大;致密砂岩的孔隙类型主要为次生孔隙,孔隙结构整体上具有中孔径、微细喉以及喉道分选不均匀等特征;机械压实作用和胶结作用导致了致密砂岩的形成,该致密砂岩属于次生型致密砂岩。     

准噶尔盆地西北缘侏罗系储层

准噶尔盆地西北缘侏罗系陆相碎屑岩储层的岩性差异较大，岩性对物性的控制作用明显。储层的孔隙类型多样，不同类型的孔隙在发育规模、丰度及有效性方面都存在显差异，次生溶蚀孔隙、原生粒间孔隙和残余粒间孔隙是最重要的有效孔隙类型。储层渗透率与孔隙度之间存在较好的半对数相关关系。通过设置一定的孔隙度和渗透率参数界线，对储层储集性能进行评价，将侏罗系储层的孔渗性能划分为5个级别，可与当前流行的砂岩储层孔渗性能分级相对应。通过对大量压汞参数样本的聚类分析，将储层的孔隙结构划分为4个类型。通过各类参数统计及曲线形态对比，对孔隙结构类型进行了定量结合定性的优劣评价。最后，结合孔渗性能级别、储集空间类型、孔隙结构类型、岩性等特征，对准噶尔盆地西北缘侏罗系储层进行了综合分类评价。     

低渗透砂岩储层微观孔隙结构特征——以鄂尔多斯盆地志靖—安塞地区延长组长9油层组为例

通过物性分析、铸体薄片、扫描电镜技术、常规高压压汞技术、恒速压汞技术等,对选自鄂尔多斯盆地志靖—安塞地区长9段低渗透砂岩储层样品进行测试分析,获取储层孔隙、喉道的形态、类型、连通程度等信息,确定孔喉大小、分选情况和连通性的定量参数。研究表明,研究层位孔隙类型主要为残余粒间孔、溶孔、微孔。将孔隙组合特征分为4种类型,储层孔隙结构具多样性。样品孔喉结构整体上具有大孔隙、细喉道的特点,微细喉道的发育是造成物性渗透率超低的主要原因。储层孔隙结构的多样性及不均一性是导致储层非均质性的主要原因。     

东北晚中生代断陷盆地J3—K1储层孔隙组合特征及孔隙结构类型

论述了东北晚中生代断陷盆了Ｊ３－Ｋ１储层的孔隙组合特征及砂岩储层的孔隙结构类型,砂岩储层的孔隙组合为５种类型,正常粒间孔及缩小粒间孔组合;正常粒间孔及粒间扩大溶孔组合;粒间扩大溶孔及铸模孔组合;粒内溶孔及胶结物内溶孔组合,微孔和裂缝与少量原生粒间孔及残余缩小溶孔组合;特殊储层的孔隙组合因储层类型的不同而异,砾岩储层以砾间孔隙＋砾间填隙物孔隙为主,安山岩储层为气孔＋裂缝或气孔＋裂缝＋砾（粒）间空隙。     

曲流河相储层特征及其主控因素分析:以鄂尔多斯盆地胡尖山油田延9为例

阐明微相控制下的储层展布及其微观特征,对揭示油气差异富集规律,实现有利储层的评价具有重要意义。为阐明曲流河相储层特征及主控因素,以鄂尔多斯盆地胡尖山油田延9储层为例,以岩心观察描述及取样分析为基础,综合运用粒度分析、铸体薄片、扫描电子显微镜、压汞法、黏土矿物X射线衍射和常规物性分析,并结合测井资料宏观印证。结果表明:胡尖山油田延9发育曲流河相,主要包括河道(河床滞留沉积)、边滩、天然堤及河漫滩微相。储层岩性主要为长石岩屑砂岩及岩屑长石砂岩,储集空间主要为残余粒间孔和长石溶孔构成的溶孔-粒间孔组合。可识别中细喉道、细喉道及微细喉道三种主要喉道类型。孔隙度主要集中在11.51%~18.87%之间,渗透率主要为(2.08~79.86)×10^-3μm²,属于中低孔-中低渗特低渗-中大孔细喉型储层。黏土矿物、硅质及钙质的胶结作用和机械压实作用是储层致密的主因,长石颗粒及部分胶结物的溶蚀作用以及绿泥石膜对压实及胶结作用的抑制,利于原生孔隙的保存,但当绿泥石含量超过0.3%时,物性变化趋势不明显。     

伊通盆地鹿乡断陷双阳组储层孔隙结构特征及其控制因素

通过对钻井岩芯及铸体薄片、扫描电镜观察,结合压汞分析测试,研究了伊通盆地鹿乡断陷双阳组储层的孔隙结构特征。结果表明:储层成因类型主要为扇三角洲砂体,部分为水下扇砂体;储层砂体孔隙类型以次生溶蚀孔隙为主,部分为原生粒间孔隙,具体可见粒内溶孔、原生粒间孔和粒间溶蚀扩大孔等;孔隙喉道较小,分选不好,连通性差,总体为低孔低渗型储层,其中,双阳组二段储层略好于双三段,双一段最差。双阳组储层孔隙结构特征主要受砂体成因类型和成岩作用的控制,此外,岩石粒度和构造作用也对孔隙结构有一定的控制作用。     

Petrophysical characterisation of tight sandstone gas reservoirs using nuclear magnetic resonance: a case study of the upper Paleozoic strata in the Kangning area,eastern margin of the Ordos Basin,China

Residual and movable porosity are significant parameters for characterising petrophysical properties, especially in tight reservoirs. Eight tight sandstone samples from the upper Paleozoic gas-bearing strata in the Kangning area, from the eastern margin of the Ordos Basin, were analysed using nuclear magnetic resonance (NMR), scanning electron microscopy (SEM), petrography, and porosity and permeability tests. The lithology and pore types were identified and classified using petrography and SEM. The residual and movable porosity were obtained with NMR. In addition, NMR was used to visualise pore structure and pore size distribution. The results suggest that the upper Paleozoic sandstones in the study area mainly comprise feldspathic litharenite and litharenite. The sandstone porosity and permeability are low, with means of 5.9% and 0.549 mD, respectively. Four pore types exist in the tight sandstones: residual primary pores, grain dissolution pores, micropores (clay-dominated) and microfractures. The T₂ spectra under water-saturated conditions correlate with pore size and can be used to distinguish small and large pores based on the transverse relaxation time cutoff value of 10 ms, which corresponds to a pore diameter of 0.232 μm. Small pores account for 72% of the pores in the tight sandstones. The continuous bimodal T₂ spectra suggest good connectivity between small and large pores, despite the low porosity and permeability. In this study, the movable porosity of the major tight sandstone gas reservoirs is higher than the residual porosity, which confirms the effective evaluation of movable porosity to tight sandstone reservoirs, based on NMR experiments.     

华庆地区长63段低渗储层特征及优质储层主控因素

综合运用岩心观察、薄片鉴定、物性分析、压汞分析及试油分析等技术方法,对华庆地区长6₃段低渗储层特征进行了系统研究,分析了低渗储层的成因,并探讨了优质储层的主控因素。结果表明,华庆地区长6₃段储层的厚层块状砂岩主要由具有液化流性质的砂质碎屑流沉积形成的相对较厚块状砂岩纵向叠置组成。岩石类型主要为长石砂岩,其次为岩屑长石砂岩;储层具有低孔特低孔-特低渗透超低渗透特征;储集空间主要包括粒间原生孔隙、次生溶蚀孔隙及晶间微孔隙,为小孔微细喉型孔隙结构。杂基含量高、成分成熟度和结构成熟度差是华庆地区长6₃低渗储层形成的主控因素,压实作用对其形成起到强化作用。沉积鼎盛时期水动力强的主力沉积期次,形成泥质含量较低的砂岩是优质储层形成的主控因素,而较大的储层厚度是优质储层形成的必要条件。     

Pore Size Distribution of a Tight Sandstone Reservoir and its Effect on Micro Pore-throat Structure: A Case Study of the Chang 7 Member of the Xin’anbian Block,Ordos Basin,China

Pore distribution and micro pore-throat structure characteristics are significant for tight oil reservoir evaluation, but their relationship remains unclear. This paper selects the tight sandstone reservoir of the Chang 7 member of the Xin’anbian Block in the Ordos Basin as the research object and analyzes the pore size distribution and micro pore-throat structure using field emission scanning electron microscopy(FE-SEM), high-pressure mercury injection(HPMI), highpressure mercury injection, and nuclear magnetic resonance(NMR) analyses. The study finds that:(1) Based on the pore size distribution, the tight sandstone reservoir is characterized by three main patterns with different peak amplitudes. The former peak corresponds to the nanopore scale, and the latter peak corresponds to the micropore scale. Then, the tight sandstone reservoir is categorized into three types: type 1 reservoir contains more nanopores with a nanopore-to-micropore volume ratio of 82:18;type 2 reservoir has a nanopore-to-micropore volume ratio of 47:53;and type 3 reservoir contains more micropores with a nanopore-to-micropore volume ratio of 35:65.(2) Affected by the pore size distribution, the throat radius distributions of different reservoir types are notably offset. The type 1 reservoir throat radius distribution curve is weakly unimodal, with a relatively dispersed distribution and peak ranging from 0.01 μm to 0.025 μm. The type 2 reservoir’s throat radius distribution curve is single-peaked with a wide distribution range and peak from 0.1 μm to 0.25 μm. The type 3 reservoir’s throat radius distribution curve is single-peaked with a relatively narrow distribution and peak from 0.1 μm to 0.25 μm. With increasing micropore volume, pore-throat structure characteristics gradually improve.(3) The correlation between micropore permeability and porosity exceeds that of nanopores, indicating that the development of micropores notably influences the seepage capacity. In the type 1 reservoir, only the mean radius and effective porosity have suitable correlations with the nanopore and micropore porosities. The pore-throat structure parameters of the type 2 and 3 reservoirs have reasonable correlations with the nanopore and micropore porosities, indicating that the development of these types of reservoirs is affected by the pore size distribution. This study is of great significance for evaluating lacustrine tight sandstone reservoirs in China. The research results can provide guidance for evaluating tight sandstone reservoirs in other regions based on pore size distribution.     

Controlling Effects of Tight Reservoir Micropore Structures on Seepage Ability: A Case Study of the Upper Paleozoic of the Eastern Ordos Basin,China

In this study, the types of micropores in a reservoir are analyzed using casting thin section(CTS) observation and scanning electron microscopy(SEM) experiments. The high-pressure mercury injection(HPMI) and constant-rate mercury injection(CRMI) experiments are performed to study the micropore structure of the reservoir. Nuclear magnetic resonance(NMR), gas-water relative seepage, and gas-water two-phase displacement studies are performed to examine the seepage ability and parameters of the reservoir, and further analyses are done to confirm the controlling effects of reservoir micropore structures on seepage ability. The experimental results show that Benxi, Taiyuan, Shanxi, and Shihezi formations in the study area are typical ultra-low porosity and ultra-low permeability reservoirs. Owing to compaction and later diagenetic transformation, they contain few primary pores. Secondary pores are the main pore types of reservoirs in the study area. Six main types of secondary pores are: intergranular dissolved pores, intragranular dissolved pores, lithic dissolved pores, intercrystalline dissolved pores, micropores, and microfracture. The results show that reservoirs with small pore-throat radius, medium displacement pressure, and large differences in pore-throat structures are present in the study area. The four types of micropore structures observed are: lower displacement pressure and fine pores with medium-fine throats, low displacement pressure and fine micropores with fine throats, medium displacement pressure and micropores with micro-fine throats, and high displacement pressure and micropores with micro throats. The micropore structure is complex, and the reservoir seepage ability is poor in the study areas. The movable fluid saturation, range of the gas-water two-phase seepage zone, and displacement types are the three parameters that well represent the reservoir seepage ability. According to the characteristic parameters of microscopic pore structure and seepage characteristics, the reservoirs in the study area are classified into four types(Ⅰ–Ⅳ), and types Ⅰ, Ⅱ, and Ⅲ are the main types observed. From type Ⅰ to type Ⅳ, the displacement pressure increases, and the movable fluid saturation and gas-water two-phase seepage zone decrease, and the displacement type changes from the reticulation-uniform displacement to dendritic and snake like.     

Research on reservoir characteristics of Chang7 tight oil based on nano-CT

The microstructure characteristics of the reservoir are closely related to the seepage capacity of the reservoir. Compared with conventional reservoirs and low permeability reservoirs, the tight oil is stored in a smaller nanoporous space. The microscopic pore structure of reservoir is the geometrical shape, size, distribution, and interconnected relationship of porosity and throat. The experiment was conducted on several tight rock samples taken from the Chang 7 formation in Xunyi county of Ordos Basin, China. Based on nano-CT scanning and advanced image processing technology Avizo, we build a three-dimensional comprehensive pore and throat network model. In the result of our study, reservoir space types are dissolution pores with mineral particles inside in the pore network model. Then, the pore throat morphology in the forms of small globular and tubular with SEM was explained. There is a big difference in quantity distribution at different locations, which is limited to the permeability of samples. Pore types are mostly round tubular and long tubular, while isolated pores account for a significant proportion. Through making and analyzing the three-dimensional structure of interconnected pores, obtained their specific forms and the division of connectivity types.     

碳酸盐岩早期差异成储路径及其对储集性能的影响:以滨里海盆地N油田石炭系KT-Ⅰ与KT-Ⅱ层系为例*

以滨里海盆地N油田石炭系KT-Ⅰ与KT-Ⅱ层系碳酸盐岩储集层为例,综合岩心、薄片、扫描电镜、高压压汞、常规物性分析以及各类测试资料,对碳酸盐岩储集层特征以及早期成储路径展开系统研究,并进一步探讨成储路径与储集层孔喉结构和质量的关系。结果表明,KT-Ⅰ层系以云岩类储集层为主,颗粒灰岩次之,其中云岩类储集层以晶间(溶)孔、小型溶洞为主,孔喉连通性好,为高孔—高渗的孔洞型储集层, 而颗粒灰岩类储集层以粒内溶孔、铸模孔及生物体腔孔发育为特征,孔喉连通性差,属中孔—低渗的孔隙型储集层。KT-Ⅱ层系以粒间(溶)孔和生物体腔孔发育的颗粒灰岩为特征,为中高孔—高渗的孔隙型储集层。进一步分析表明,KT-Ⅰ层系云岩与灰岩储集层单旋回厚度小,皆受高频海平面升降变化驱动的早成岩期岩溶的控制, 而KT-Ⅱ层系单旋回厚度大,颗粒滩未经历早期岩溶的改造。 3类储集层的成储路径分别为: (1)KT-Ⅰ云岩类储集层,准同生期白云石化作用导致矿物相转变并使得部分矿物更易遭受溶蚀→早成岩期岩溶作用控制储集层的形成→云岩抗压溶岩石骨架有利于储集层的保护; (2)KT-Ⅰ颗粒灰岩储集层,早成岩期岩溶作用优化储集层→初期压实控制胶结流体通道进而控制胶结作用—粒间孔与粒内孔差异胶结控制储集层的保护; (3)KT-Ⅱ颗粒灰岩储集层,原始沉积环境控制储集层的形成→初期压实与早期胶结作用控制储集层的保护。成储路径差异控制了不同的孔渗特征与孔喉结构,而孔喉结构进一步控制了早期岩溶型云岩、早期岩溶型颗粒灰岩、原生孔保存型颗粒灰岩3种储集层的质量。研究结果将为具类似特征的碳酸盐岩储集层成因分析提供参考,也因发现了云岩较灰岩更易早期溶蚀的现象而具有较为重要的岩溶地质学意义。     

松辽盆地龙西地区泉四段低孔低渗砂岩性及微观孔隙结构特征研究

通过岩心观察、镜下薄片、扫描电镜和X衍射、物性和压汞等资料分析,对松辽盆地龙西地区泉四段低孔低渗砂岩的岩石学特征、储层物性及微观孔隙结构特征进行了研究。研究表明,松辽盆地龙西地区泉四段砂岩主要为长石岩屑砂岩,其次为岩屑长石砂岩,成分和结构成熟度较低,储层物性明显呈现出低孔低渗特征,孔隙类型以残余粒间孔和溶蚀孔为主,孔喉半径较小,相对小孔喉所占比率较大,孔喉分选和连通性较差,非均质性强。在总体孔喉较小的背景下,随着较大孔喉半径的增大储层物性变好,而储层物性随着孔喉集中程度的增强而变差。根据经典的孔喉分类标准,将松辽盆地龙西地区泉四段低孔低渗透储层分为4类：细孔细喉型、微孔细喉型、微孔微细喉型和微孔微喉道型。     

苏北盆地金湖凹陷古近系戴南组孔隙演化及次生孔隙成因分析

金湖凹陷戴南组储层总体为一套中低孔-中低渗碎屑储层,次生孔隙是本区最有效、最重要的孔隙类型,而搞清次生孔隙的分布规律及其成因成为下一步有利储层预测的关键。文中综合利用岩心、普通薄片、铸体薄片、扫描电镜及物性参数等资料,对戴南组储层的岩石类型、物性特征、孔隙类型及次生孔隙分布规律进行了综合分析,并从溶蚀作用的发育条件入手探讨了次生孔隙的成因,以期为下一步有利储层预测和勘探开发提供科学依据。研究认为,金湖凹陷戴南组碎屑岩储层主要发育于三角洲、扇三角洲和滨浅湖,受沉积相带控制,储层类型复杂,以不等粒砂岩、含砾不等粒砂岩、细砂岩及粉砂岩为主,不同地区岩性存在差异。根据岩性三角图,砂岩类型以长石岩屑质石英砂岩为主。砂岩成分成熟度中等偏低,结构成熟度中等。戴南组砂岩孔隙度峰值分布在12.0%~14.0%,渗透率峰值分布在1~10 mD。不同沉积环境和地区储层物性也存在一定差异。三角洲前缘亚相的储层物性最好,平均孔隙度约19.4%,平均渗透率约134.2 mD,岩性以细砂岩为主,主要分布于研究区西部和中部。扇三角洲物性次之,平均孔隙度约12.5%,平均渗透率约6.2 mD,岩性以含砾不等粒砂岩为主,位于桐城断裂带东南部便1井附近。滨浅湖亚相的储层物性最差,岩性以粉砂岩为主,平均孔隙度约8.3%,平均渗透率约2.3 mD。戴南组储层孔隙分为原生孔隙和次生孔隙两大类,以次生粒间溶蚀孔隙为主。溶蚀孔隙包括粒间溶孔、粒内溶孔和铸模孔。粒间溶孔多由粒间碳酸盐胶结物如方解石、白云石、铁方解石等溶蚀后形成,粒内溶孔主要是长石及碳酸盐岩屑被选择性溶解而形成,可见白云石晶粒溶解留下的铸模孔。戴南组储层中的原生孔隙相对较少,主要以石英次生加大后的残余粒间孔的形式存在,发育于埋藏较浅的井如新庄1井、关1-1井。戴南组储层孔隙经历了由原生到次生的演化过程。总体上,在浅于约1 100 m,储层主要处于早成岩A阶段,以原生孔隙为主。在1 100~1 500 m,储层处于早成岩B阶段,形成混合孔隙段。超过1 500 m,储层进入中成岩A阶段,原生孔隙消失殆尽,基本上以次生孔隙为主。戴南组储层存在3个次生孔隙发育带:第一次生孔隙发育带在1 200~1 600 m,分布于埋藏相对较浅-中等的井区;第二次生孔隙发育带分布在1 800~2 800 m;第三次生孔隙发育带在2 900~3 000 m左右。第一、二次生孔隙发育带次生孔隙的绝对值较大,说明溶蚀作用较强。戴南组储层次生孔隙发育与方解石、白云石胶结物的溶蚀及长石碎屑和碳酸盐岩岩屑的溶蚀有关。烃源岩成熟排烃是次生孔隙发育的主控因素;碳酸盐胶结物发育提供了次生孔隙发育的物质基础;长石的溶蚀对次生孔隙发育有一定的贡献;次生孔隙的形成与黏土矿物的相互转化有一定的关系;断裂活动进一步促使了次生孔隙的发育。     

页岩油层系储集层微观孔隙非均质性及控制因素——以吉木萨尔凹陷芦草沟组为例

吉木萨尔芦草沟组页岩油层系岩性复杂,揭示不同类型储集层微观孔隙特征及非均质性控制因素,有利于指导该区页岩油甜点评价及优选。本文优选芦草沟组30块页岩油储集层样品,采用场发射扫描电镜、高压压汞、核磁共振等实验手段,刻画页岩油储集层微观孔隙结构,探讨混积型页岩油孔隙非均质性的控制因素。结果表明,芦草沟组发育7类孔隙和3类孔喉组合;随渗透率降低,粒间孔、粒间溶蚀孔等大孔减小,粒内溶蚀孔和晶间孔增加,"大孔-细喉"组合过渡为"短导管"和"树形网络"组合,孔径及可动饱和度均降低。页岩油孔喉非均质性主要受控于粒度和方解石、黏土胶结,前者决定较大孔(>1μm)能否发育,后者进一步缩小孔隙或孔喉,增加非均质性;在两者联合控制下,孔隙度与孔喉参数的相关性较差。