Evolution of Authigenic Minerals and Porosity in the Deep Formation of Paleogene of Jiyang Sub-basin

The clastic rocks in the depth of 2800-6000 m of the Paleogene in Jiyang sub-basin had undergone the middle diagenesis and late diagenesis.The reservoirs in main areas of the sub-basin developed 2-6 secondary pores zones.The reservoirs in the stage A of middle diagenesis of Bonan fault zone in Zhanhua depression and of the gentle slope belt of Chezhen depression are controlled by the acidic diagenetic medium and developed one secondary pores zone in each diagenetic sub-stage respectively.The contents ofautogenic quartz,pyrite and kaolinite are quite high in these reservoirs.The reservoirs’

Impact of volcanism on the formation and hydrocarbon generation of organic-rich shale in the Jiyang Depression, Bohai Bay Basin, China

Globally,most organic-rich shales are deposited with volcanic ash layers.Volcanic ash,a source for many sedimentary basins,can affect the sedimentary water environment,alter the primary productivity,and preserve the organic matter(OM)through physical,chemical,and biological reactions.With an increasing number of breakthroughs in shale oil exploration in the Bohai Bay Basin in recent years,less attention has been paid to the crucial role of volcanic impact especially its influence on the OM enrichment and hydrocarbon formation.Here,we studied the petrology,mineralogy,and geochemical characteristics of the organic-rich shale in the upper submember of the fourth member(Es_(4)^(1))and the lower submember of the third member(Es_(3)^(3))of the Shahejie Formation,aiming to better understand the volcanic impact on organic-rich shale formation.Our results show that total organic carbon is higher in the upper shale intervals rich in volcanic ash with enriched light rare earth elements and moderate Eu anomalies.This indicates that volcanism promoted OM formation before or after the eruption.The positive correlation between Eu/Eu*and Post-Archean Australian Shale indicates hydrothermal activity before the volcanic eruption.The plane graph of the hydrocarbon-generating intensity(S1+S2)suggests that the heat released by volcanism promoted hydrocarbon generation.Meanwhile,the nutrients carried by volcanic ash promoted biological blooms during Es_(4)^(1 )and Es_(3)^(3) deposition,yielding a high primary productivity.Biological blooms consume large amounts of oxygen and form anoxic environments conducive to the burial and preservation of OM.Therefore,this study helps to further understand the organic-inorganic interactions caused by typical geological events and provides a guide for the next step of shale oil exploration and development in other lacustrine basins in China.

Shale oil development techniques and application based on ternary-element storage and flow concept in Jiyang Depression,Bohai Bay Basin,East China

The ternary-element storage and flow concept for shale oil reservoirs in Jiyang Depression of Bohai Bay Basin,East China,was proposed based on the data of more than 10000 m cores and the production of more than 60 horizontal wells.The synergy of three elements(storage,fracture and pressure)contributes to the enrichment and high production of shale oil in Jiyang Depression.The storage element controls the enrichment of shale oil;specifically,the presence of inorganic pores and fractures,as well as laminae of lime-mud rocks,in the saline lake basin,is conducive to the storage of shale oil,and the high hydrocarbon generating capacity and free hydrocarbon content are the material basis for high production.The fracture element controls the shale oil flow;specifically,natural fractures act as flow channels for shale oil to migrate and accumulate,and induced fractures communicate natural fractures to form complex fracture network,which is fundamental to high production.The pressure element controls the high and stable production of shale oil;specifically,the high formation pressure provides the drive force for the migration and accumulation of hydrocarbons,and fracturing stimulation significantly increases the elastic energy of rock and fluid,improves the imbibition replacement of oil in the pores/fractures,and reduces the stress sensitivity,guaranteeing the stable production of shale oil for a long time.Based on the ternary-element storage and flow concept,a 3D development technology was formed,with the core techniques of 3D well pattern optimization,3D balanced fracturing,and full-cycle optimization of adjustment and control.This technology effectively guides the production and provides a support to the large-scale beneficial development of shale oil in Jiyang Depression.

Formation mechanism and model for sand lens reservoirs in the Jiyang Sub-basin,East China

The Bohai Bay basin comprises some very important and well documented subtle traps known in China, which have been the major exploration focus and have become a major petroleum play since the 1990s. However, recent exploration showed that the oil-bearing proper-ties of some sand lens reservoirs may vary significantly and the accumulation mechanisms for these lithological subtle traps are not well understood. Based on statistical analysis of oil-bearing properties for 123 sand lens reservoirs in the Jiyang Sub-basin and combined with detailed anatomy of typical sand lens reservoirs and NMR experiments, it has been shown that the structural and sedimentary factors, hydrocarbon generation and expulsion conditions of the sur-rounding source rocks, as well as the petrophysical properties of sand lens reservoirs are the main controlling factors for the formation of sand lens reservoirs. The formation of a sand lens reservoir depends on the interaction between the hydrocarbon accumulation driving force and the resistance force. The driving force is made up of the differential capillary pressure between sandstones and sources rocks and the hydrocarbon diffusion force, and as well as the hydro-carbon expansion force. The resistance force is the friction resistance force for hydrocarbons and water to move through the pore throats of the sand lens. The sedimentary environment, source rock condition and sand reservoir properties can change from unfavorable to favorable depend-ing on the combination of these factors. When these three factors all reach certain thresholds, the sand lens reservoirs may begin to be filled by hydrocarbons. When all of these conditions be-come favorable for the formation of sand lens reservoirs, the reservoir would have high oil satu-ration. This approach has been applied to evaluating the potential of petroleum accumulation in the sand lens reservoirs in the third member of the Neogene Shahejie Formation in the Jiyang Sub-basin.

Structural characteristics of continental carbonate-rich shale and shale oil movability: A case study of the Paleogene Shahejie Formation shale in Jiyang Depression, Bohai Bay Basin, China

Based on rock mineral and geochemical analysis, microscopic observation, physical property measurement, and thin laminae separation test, etc., the characteristics of typical laminae of the Paleogene Shahejie Formation carbonate-rich shale in the Jiyang Depression were analyzed, and the organic matter abundance, reservoir properties, and oil-bearing properties of different laminae were compared. Typical shale storage-seepage structures were classified, and the mobility of oil in different types of shale storage-seepage structure was compared. The results show that the repeated superposition of mud laminae and calcite laminae are the main layer structure of carbonate-rich shales. The calcite laminae are divided into micritic calcite laminae, sparry calcite laminae and fibrous calcite vein. The mud-rich laminae are the main contributor to the organic matter abundance and porosity of shale, with the best hydrocarbon generation potential, reservoir capacity, and oil-bearing property. The micritic calcite laminae also have relatively good hydrocarbon generation potential, reservoir capacity and oil-bearing property. The sparry calcite laminae and fibrous calcite vein have good permeability and conductivity. Four types of shale storage-seepage structure are developed in the carbonate-rich shale, and the mobility of oil in each type of storage-seepage structure is in descending order: sparry calcite laminae enriched shale storage-seepage structure, mixed calcite laminae enriched shale storage-seepage structure, fibrous calcite vein enriched shale storage-seepage structure, and micritic calcite laminae enriched shale storage-seepage structure. The exploration targets of carbonate-rich shale in the Jiyang Depression Shahejie Formation are different in terms of storage-seepage structure at different thermal evolution stages.

Assessing Water Resources Access of Nouhao Sub-Basin, Burkina Faso

Water resource access in the Nouhao sub-basin, assessed based on the availability of drinking water mobilization facilities, the availability of water for uses and the quality of drinking water, revealed that in 2017 the basin was covered by 1249 modern water point, main drinking water sources. On average, the sub-basin shows a ratio of 271 users per drinking water point. Communal level shows some disparity with Bittou recording the highest number of people per drinking water point, i.e., around 537. Water that can be captured in the entire sub-basin meets only 42% of the total water needs from the three mains uses: irrigation, domestic consumption and livestock. The highest demander among these uses is Irrigation with 75% of the need, i.e., approximately 12,859,995 m3. Water in 33% drinking sources of this sub basin is of poor quality. Arsenic, one of the quality parameters studied, is found in some communes of the sub-basin. 11% of the water points in Bissiga are arsenic polluted making this commune the most arsenic contaminated location. The vulnerability maps deducted from lack of water for uses;lack of drinking water works and poor water quality shows so, the exposure level of the sub-basin’ communes to some potential risks related to low water resources access.

Assessment of Climate Change’s Impacts on River Flows in the Songwe Sub-Basin

River flow in the Songwe sub-basin is predicted to alter due to climate change, which would have an impact on aquatic habitats, infrastructure, and people’s way of life. Therefore, the influence of climate change should be taken into account when making decisions about the sustainable management of water resources in the sub-basin. This study looked into how river discharge would react to climate change in the future. By contrasting hydrological characteristics simulated under historical climate (1981-2010) with projected climate (2011-2040, 2041-2070, and 2071-2100) under two emission scenarios, the effects of climate change on river flow were evaluated (RCP 4.5 and RCP 8.5). The ensemble average of four CORDEX regional climate models was built to address the issue of uncertainty introduced by the climate models. The SWAT model was force-calibrated using the results from the generated ensemble average for the RCP 4.5 and RCP 8.5 emission scenarios in order to mimic the river flow during past (1981-2010) and future (2011-2100) events. The increase in river flows for the Songwe sub-basin is predicted to be largest during the rainy season by both the RCP 4.5 and RCP 8.5 scenarios. Under RCP 8.5, the abrupt decrease in river flow is anticipated to reach its maximum in March 2037, when the discharge will be 44.84 m3/sec, and in March 2027, when the discharge will be 48 m3/sec. The extreme surge in river flow will peak, according to the RCA4, in February 2023, in April 2083 under RCP 4.5, and, according to the CCLM4 and RCA4, in November 2027 and November 2046, respectively. The expected decrease and increase in river flow throughout both the dry and wet seasons may have an impact on the management of the sub-water basin’s resources, biodiversity, and hydraulic structures. The right adaptations and mitigation strategies should be adopted in order to lessen the negative consequences of climate change on precipitation, temperature, and river flow in the sub-basin.

济阳页岩油开发“三元”储渗理论技术与实践

基于济阳坳陷页岩油储层上万米岩心资料与60余口水平井的开发实践,提出济阳页岩油“储元”、“缝元”、“压元”的“三元”储渗理论。“三元”协同支撑济阳页岩油的富集高产:“储元”控制页岩油的富集,咸化湖盆无机孔-缝及灰-泥优质纹层组构发育利于页岩油储集,高生烃能力、高游离烃含量为高产提供物质基础;“缝元”控制页岩油的渗流,天然裂缝为页岩油的运移和聚集提供渗流通道,压裂改造缝沟通天然裂缝形成复杂缝网,为高产提供渗流基础;“压元”控制页岩油的高产稳产,高地层压力为油气运聚提供原始动力,压裂增能可进一步提高岩石及流体弹性能,强化孔缝原油渗吸置换,减缓应力敏感性,为长期稳产提供能量基础。基于“三元”储渗理论,形成了以立体井网优化、立体均衡压裂、全周期优化调控为核心的立体开发技术,有效指导了现场生产实施,为济阳页岩油规模化效益开发提供技术支撑。

济阳坳陷古近系沙三下—沙四上亚段咸化湖盆证据及页岩油气地质意义

济阳坳陷是渤海湾盆地常规油气最为富集的坳陷之一,也是页岩油获得全面战略性勘探突破的坳陷,古近系沙河街组发育沙三下亚段、沙四上亚段2套主力烃源岩,其沉积环境颇受争议。利用页岩系统取芯井岩石学、元素地球化学、同位素和包裹体等资料对页岩沉积环境进行系统研究。结果表明:古近系沙三下—沙四上亚段页岩为气候控制下的咸化湖盆的产物,主要发育富碳酸盐纹层状岩相,碳酸盐矿物质量分数高,多呈纹层状、透镜状产出,平均质量分数为43%,背散射扫描电镜下部分页岩样品发现NaCl、BaSO_(4)和SrSO_(4)典型的咸化湖盆标志性矿物,页岩沉积期水体盐度相对较高;水体环境的w(Sr)/w(Ba)大于1,Sr元素质量分数大于500μg/g,B元素质量分数大于75×10^(-6),相当硼质量分数主要分布在300×10^(-6)~700×10^(-6),均显示为咸化环境;页岩w(^(87)Sr)/w(^(86)Sr)为0.710 7~0.712 4,明显高于同期海水的w(^(87)Sr)/w(^(86)Sr),结合对应稀土元素Ce正异常特征,认为沉积期水体条件受控于盆地自身环境,与海侵没有必然联系;碳酸盐矿物δ^(18)O主要分布在-11‰~-3‰,δ^(13)C主要分布在0~6‰,δ^(18)O、δ^(13)C均偏大,与沉积期湖盆气候相对干旱、湖水蒸发作用增强有关;页岩中检测到气液两相原生盐水包裹体均一化温度范围在32.5~45.3℃,对应盐度范围为19.21%~27.78%,成岩早期地层流体盐度较高;气候控制下的咸水环境为富碳酸盐页岩形成提供条件,奠定济阳坳陷古近系沙三下—沙四上亚段页岩油富集高产的基础。

济阳坳陷成熟探区油气精细勘探理论进展与实践

济阳坳陷作为渤海湾盆地成熟探区之一,经过了60多年勘探开发,为实现油气勘探的持续发展,亟需解决油气资源潜力、勘探方向及成藏规律等理论认识问题。通过对主力生烃层系大量烃源岩样品沉积环境、有机地球化学特征的分析测试及生排烃模拟实验,对比研究了不同类型烃源岩生排烃演化过程及生烃潜力,发现咸化环境烃源岩具有古生产力高、活化能低的特点,建立了陆相湖盆“咸化富烃”生排烃模式,突破了以淡水环境烃源岩为主力油气来源的传统认识;通过分析深层储层成岩演化过程中孔隙度与地层流体酸碱性质变化的关系,指出“早期强胶结、后期强溶蚀”是深层储层形成大量次生溶蚀孔隙的重要原因,解决了高地温背景下深层碎屑岩有效储层成因问题;基于济阳坳陷勘探实践,总结提出了断陷盆地从洼陷带到斜坡带,依次发育岩性、构造-岩性、岩性-构造及构造油气藏的油气藏类型有序分布规律。创新形成了“咸化富烃、酸碱控储、有序成藏”的成熟探区油气精细勘探理论认识,明确了剩余资源潜力,指出了深层的勘探方向,使油气勘探由被动转移转为主动探索;并创新建立了适用于精细勘探阶段的“勘探层单元”划分、优选方法,形成了成熟探区“七步走”的精细勘探评价流程。结合济阳坳陷地质新认识、最新一轮油气资源评价结果,指出今后重点勘探方向及增储领域,为油田的长期效益可持续发展提供了重要保障。

基于综合物探的济阳坳陷潜山型干热岩靶区优选

济阳坳陷蕴藏着丰富的地热资源,开展深层干热岩的系统评价对于坳陷地热资源综合利用具有重要意义。本文利用收集的1∶20万重力数据38870 km^(2)、1∶5万航磁数据26630 km^(2)和胜利油田以往实施的钻井、地震勘探资料,采用Parker-Oldenburg反演迭代算法、重力-地震联合剥层方法、重磁正反演等方法,开展莫霍面、居里面、壳断裂-岩石圈断裂、基底构造和基底岩性等地热地球物理研究。通过实施大地电磁测深剖面116 km,验证了壳幔过渡带熔融体发育特征。从居里面深度、莫霍面深度、地温梯度、热储层岩性、盖层厚度、潜山规模6个方面评价优选了5处干热岩靶区。济阳坳陷具“壳幔生热、构造控热、潜山储热、盖层保温”四位一体地热成因特征,是以“传导型干热-水热共存、对流型水热补充”为主要特征的盆地复合型地热系统,潜山型干热岩靶区具有进一步勘探和开发的前景。

济阳坳陷古近系沙四段——沙三段页岩油立体评价探索与实践

济阳坳陷为中国东部典型的陆相断陷盆地,古近系沙河街组沙四段—沙三段沉积一套巨厚的中低成熟度页岩油储层,资源量超100×10^(8)t,目前处于评价试验阶段,勘探开发前景广阔。针对陆相页岩油岩相复杂、储集空间多样、非均质性强、烃源岩厚度大的特点,以地震、测井、录井、取心及实验分析等资料为基础,开展烃源岩有利岩相、储集性、含油性、可动性、可压裂性“四性”评价,通过评价井部署和井组先导试验实施,形成以甜点立体评价、井网立体优化、水平井立体压裂为核心的评价技术,落实资源潜力及技术适应性,为优选建产区带、实现规模化开发产能建设提供重要支撑。通过博兴、牛庄和民丰等地区立体评价试验,落实甜点评价标准可靠性、井距层距合理性和压裂工艺适应性,建成中国石化首个10万吨级页岩油先导试验井组,有力支撑了济阳陆相断陷湖盆页岩油国家级示范区的高效建设。

胜利济阳页岩油开发进展与攻关方向

为了实现济阳陆相断陷盆地中低演化程度页岩油的有效开发,2019年以来,依托万米系统取心、十万余块次的岩心测试,在博兴、牛庄、民丰等洼陷同时开展系统评价,单井评价及立体井组开发均取得突破。博兴洼陷开展了3层楼8口井的先导试验,建成中国石化首个10万吨级页岩油开发井组;牛庄洼陷开展了5层楼20口井大平台立体开发井组试验,已全部投产;民丰洼陷按照“大平台整体部署、小井组分步实施”的模式,整体评价、立体开发试验全面展开。樊页平1、丰页1-1HF井等28口井峰值日产油量超百吨,30口井累计产油量超万吨。基于基础研究与开发实践,提出了济阳页岩油“储-缝-压”三元储渗理论认识,攻关形成了页岩油开发实验技术、开发甜点立体精细评价技术、建模数模一体化技术、立体开发优化调控技术,初步构建了胜利特色的陆相断陷盆地页岩油立体开发理论技术体系,有效支撑了胜利济阳页岩油国家级示范区建设。

中国东西部陆相页岩油地质特征差异性分析及其对富集规律影响——以胜利探区为例

以胜利探区为例,系统对比研究了中国东西部陆相湖盆页岩油地质特征差异性及其对富集规律的影响。济阳坳陷沙四段上亚段—沙三段下亚段在古地貌、古气候、古水体介质等因素共同控制下,富有机质纹层状碳酸盐页岩大规模分布,富有机质黏土纹层成烃与富碳酸盐纹层成储协同演化为游离烃规模富集提供了有利条件。准噶尔盆地西北缘哈山地区风城组强裂陷作用导致强烈火山活动,在火山喷发物质与古气候共同影响下,富有机质纹层状含碱长英页岩相大规模分布,且成烃成储演化过程中形成较多的长英质矿物,并伴生大量的基质溶蚀孔和晶间孔,为页岩油富集奠定了重要基础。哈山地区在多期逆冲推覆过程中,准原地系统持续生烃、油多气少和相对较好的保存条件以及构造覆压、生烃增压作用产生的异常高压为页岩油高产提供了必要条件。准噶尔盆地东南缘(准东南)芦草沟组在海迹湖咸水环境下,受火山凝灰质与微生物作用影响,形成了富有机质纹层状页岩相夹贫有机质层状白云岩相的主要岩相组合类型。博格达山周缘山前构造带芦草沟组富有机质页岩均进入成熟演化阶段,胜利探区构造相对稳定区具备页岩油勘探前景。

济阳坳陷常规探明石油地质储量增长规律及未来10年增储趋势

济阳坳陷常规石油领域一直是胜利油田勘探开发主战场,至今已经历了60余年勘探开发,整体进入成熟勘探阶段,但每年仍具有较大的增储规模,这与传统认为的含油气盆地探明石油地质储量增长趋势不一致。济阳坳陷常规探明石油地质储量增长规律如何?未来能否继续保持较强的增储态势?其主要的增储领域有哪些?这些事关胜利油田勘探决策的重要问题亟需研究明确。通过梳理济阳坳陷勘探历程,分析其地质特征、资源条件、探井工作量投入、理论技术、资源序列等勘探要素,揭示济阳坳陷常规石油勘探发现规律,运用“帚状”模型预测法、资源探明速率法等方法预测常规探明石油地质储量增长趋势,结合主要增储领域剖析,明确济阳坳陷常规石油未来增储规模及有利方向。结果表明:济阳坳陷复杂的地质特征、较为雄厚的剩余资源基础决定其勘探对象的多样性、勘探过程的曲折性和勘探历史的长期性;在保证相对稳定的探井工作量投入,持续开展勘探理论及关键技术的攻关,保持相对合理的资源序列等条件下,济阳坳陷常规石油仍能保持较长时期的稳定增储;在当前经济技术条件及勘探投入相对保障的情况下,未来10年济阳坳陷仍可贡献常规探明石油地质储量2.5×10^(8)t左右;指出济阳坳陷新近系河道砂岩油藏、沙四段上亚段—沙三段岩性油气藏等成熟领域仍是稳定增储的压舱石,孔店组—沙四段下亚段深层领域是重要的规模增储领域,前古近系潜山领域是富集高产的有利方向。今后,应紧密跟踪非常规与新能源领域的勘探进展,对济阳坳陷常规探明石油地质储量增长规律及增储趋势等研究结果进行不断地完善和修正,以期更符合油田勘探发展态势,指导油田勘探决策。

济阳坳陷深层地热资源研究进展与下步展望

济阳坳陷地热资源分布范围广、资源潜力大,是胜利油区未来地热资源开发利用的重要方向。为科学、高效地开发利用济阳坳陷地热资源,系统梳理了关于济阳坳陷水热型和干热岩型地热资源的热储层、热盖层、热源等地热地质条件,分别计算了2类地热资源的资源量,揭示其地热资源潜力。研究结果表明,济阳坳陷水热型地热资源主要赋存在馆陶组、东营组及下古生界等,其中馆陶组为水热型地热资源潜力最大的层系,分布广、资源量大,是下步重点勘探开发利用层系。济阳坳陷属于“冷壳热幔型”沉积盆地,具有较高的大地热流值,干热岩型地热资源热储层主要为太古宇的岩浆岩和变质岩,深部地幔热流是其主要热源,热储层分布面积大,温度均较高,其资源丰度为渤海湾盆地中最高。济阳坳陷地热资源丰富,为加快其开发利用步伐,建议水热型地热资源要加强地热资源与油气的关系及资源分区评价2项关键工作;干热岩型地热资源的勘探开发仍处于起步探索阶段,今后需要重点加强其热储层类型的选择与热源机制2个方面的研究。

济阳坳陷潜山风险勘探方向浅析

济阳坳陷油气资源丰富,但随着勘探程度的不断深入,古近系常规油气藏的勘探难度不断加大,亟需拓展新领域,保障资源有效接替。济阳坳陷地层发育齐全,前古近系潜山分布广、厚度大,勘探潜力显著,但受限于深层潜山形成时间早、经历地质演化历程复杂、深部地震资料品质差等因素,勘探效果相对较差。近年来,随着实验技术持续攻关、基础地质研究不断深化、地震资料处理手段更加丰富,潜山钻探获得了不少好苗头,形成了多期构造共控成山、多套源岩联合供烃、多元共控优势成储、多种模式有序控藏的潜山油气成藏认识。通过对已发现油气藏的深入解剖,同时借鉴邻区的勘探经验,明确了济阳坳陷深层潜山勘探的风险方向和勘探目标,为济阳坳陷油气勘探潜力的进一步挖掘指明了方向。具体来讲,各层系的风险勘探方向为:太古界潜山内幕的断缝体、断溶体圈闭等;下古生界隐蔽性断块圈闭以及内幕颗粒滩、沿层溶蚀作用形成的岩性圈闭;上古生界埋深大于2000m的深层煤系气藏;中生界裂缝-砂体双控的岩性圈闭。

中国东部陆相断陷盆地页岩油开发理论认识与技术实践——以济阳页岩油为例

以济阳页岩油为代表的中国东部陆相断陷盆地页岩油取得产能突破,但埋藏深、厚度大、成熟度低,地层温度高、压力大,原油流动能力差的特点,使其实现高产稳产面临巨大挑战。基于万米岩心及90余口水平井生产实践,深化发展了“储-缝-压”三元储渗理论,以此为指导形成了页岩油开发甜点立体评价、立体开发优化设计、立体均衡压裂等济阳页岩油开发关键技术体系。理论研究和实践表明:孔隙和多尺度、多类型发育的微缝组成“双储”系统,控制着储集空间及油气富集规律,是高产稳产的物质基础;支撑缝与激活缝耦合形成跨纳米-厘米尺度的“双缝”系统,具有梯级启动特征,是高产稳产的渗流路径;地层保压性好的前提下,压裂增能可有效提高孔缝的渗流能力、增加渗吸置换效率,同时精细控压实现能场协同耦合,可进一步释放页岩油藏产能,保压增压“双压”协同是高产稳产的能量保障;以三元储渗理论为指导形成的开发关键技术体系为多洼陷多层系产能突破提供了有效的技术支撑,对促进中国东部陆相断陷盆地页岩油规模效益开发具有重要意义。

页岩储层孔隙结构表征及物性下限确定方法及应用

针对页岩储层孔隙结构和物性下限认识不清,严重制约了页岩油储量计算及高效开发的问题,以济阳坳陷古近系沙河街组新义深9、利页1、樊页1井为研究对象,利用N_(2)吸附、高压压汞、物性测定等实验方法,对页岩储层的孔隙结构进行全尺寸表征,并综合运用束缚水饱和度法、压汞排驱压力法、最小流动孔喉半径法和试油法确定页岩储层的物性下限。研究表明:N_(2)吸附实验主要表征页岩样品的小孔,研究区孔隙形态主要有墨水瓶形、过渡形及平板状夹缝形,主要发育纳米级孔隙,孔隙半径为1.50~40.00 nm,平均孔隙半径为16.00 nm;高压压汞实验主要表征页岩样品的中孔和宏孔,孔喉半径为0.03~66.13μm;综合计算页岩储层孔隙度下限为1.30%~3.82%,渗透率下限为0.03~0.12 mD,最小流动孔喉半径为14.60~23.50 nm,平均值为17.76 nm。研究成果可为济阳坳陷页岩油的储量计算及储层评价提供参数指标和技术支撑。

济阳坳陷沾化东部古—中生界潜山构造样式与成藏模式

济阳坳陷古—中生界潜山经历多期挤压、伸展、走滑及剥蚀等构造作用的叠加,以沾化东部潜山为例,利用丰富的钻井与地震资料,在潜山构造层划分的基础上,剖析了潜山构造演化及构造特征,总结了潜山构造样式,建立了油气成藏模式。研究结果表明,晚古生代以来,在多期不同方向、不同性质构造运动的作用下,沾化东部古—中生界潜山经历了4期挤压作用、2期伸展作用、2期走滑作用、4期剥蚀作用,形成了高位、中位和低位3类潜山,发育了伸展、挤压、走滑与剥蚀4类9种构造样式。依据构造样式及潜山地层残留和上覆盖层的差异,建立了3类潜山成藏模式,其油气来源、油气富集层段及富集特征各不相同,其中高位潜山斜坡带上古生界与中生界、中位潜山下古生界和低位潜山中紧靠油源的潜山各层系油气成藏条件最为有利,油气富集程度高,是研究区下一步重点勘探对象。