Evaluation of the dynamic sealing performance of cap rocks of underground gas storage under multi-cycle alternating loads

The static sealing of underground gas storage(UGS),including the integrity of cap rocks and the stability of faults,is analyzed from a macro perspective using a comprehensive geological evaluation method.Changes in pore structure,permeability,and mechanical strength of cap rocks under cyclic loads may impact the rock sealing integrity during the injection and recovery phases of UGS.In this work,the mechanical deformation and failure tests of rocks,as well as rock damage tests under alternating loads,are conducted to analyze the changes in the strength and permeability of rocks under multiple-cycle intense injection and recovery of UGS.Additionally,this study proposes an evaluation method for the dynamic sealing performance of UGS cap rocks under multi-cycle alternating loads.The findings suggest that the failure strength(70%)can be used as the critical value for rock failure,thus providing theoretical support for determining the upper limit of operating pressure and the number of injection-recovery cycles for the safe operation of a UGS system.

Controlling effects of cap rocks on the formation of deep geothermal resources

Cap rocks with high thermal insulation are important for deep geothermal systems at a depth of 3000‒6000 m.Based on the deep geothermal geological conditions in the Fujian-Guangdong-Hainan area of South China,this study established an ideal geological model of reservoir-cap rock assemblages and simulated the geothermal field distribution of cap rocks of different thicknesses and thermal conductivity.The simulation results show that the vertical geothermal temperature distribution in an uplifted area of a depression was present as inverted mirror reflections relative to the elevated area of the basement.Specifically,the isotherms above the elevated area are convex in shape,while those below the elevated area are concave.There is a temperature equilibrium line between the convex and concave isotherms.The heat flow moves from the depressed area to the uplifted area below the temperature equilibrium line and migrates in an opposite direction above the line.On this base,this study conducted the inversion of geothermal temperature fields in typical areas with thin,moderately thick,and thick cap rocks.The results indicate that,at the depth of 3000e6000 m,areas with thin cap rocks(igneous rock zone in the coastal area of Fujian)mainly host moderate-to low-temperature hydrothermal resources;areas with moderately thick cap rocks(Yuezhong Depression)have the geothermal temperature ranging between 100℃and 200℃and may develop moderate-to high-temperature hydrothermal resources and hot dry rocks(HDRs),with the former superimposing on the latter;and areas with thick cap rocks(onshore Beibuwan Basin)have a geothermal temperature of 120‒220℃,and contains mainly moderate-to high-temperature hydrothermal resources and HDRs.Therefore,it is recommended that the evaluation,exploitation,and utilization of deep geothermal resources be carried out according to the burial depth of the temperature equilibrium line and the specific demand for geothermal resources.

Source Rock and Cap Rock Controls on the Upper Ordovician Wufeng Formation–Lower Silurian Longmaxi Formation Shale Gas Accumulation in the Sichuan Basin and its Peripheral Areas

Objective The Upper Ordovician Wufeng Formation-Lower Silurian Longmaxi Formation is one of the priority interval for shale gas exploration in the Sichuan Basin and its peripheral areas, and commercial shale gas has been discovered from this interval in Jiaoshiba, Changning and Weiyuan shale gas fields in Sichuan Province. However, there is no significant discovery in other parts of the basin due to the different quality of black shale and the differences of tectonic evolution. Based on the progress of shale gas geological theory and exploration discoveries, as well as the theory of ＂source rock and cap rock controls on hydrocarbon accumulation＂, of the Upper Ordovician the main controlling factors Wufeng Formation-Lower Silurian Longmaxi Formation shale gas enrichment in the Sichuan Basin and its peripheral areas were analyzed, and the source rock and cap rock controls on the shale gas were also discussed. The results can provide new insights for the next shale gas exploration in this area.

Cap rock blast caving of cavity under open pit bench

A laser technique based scanning system was employed to make a comprehensive scanning through borehole forunmapped cavity under open pit bench,then the three-dimensional data will be obtained,and these data were used for theoreticalanalysis and numerical simulation to analyze the stability of cap rock.Acoustic emission techniques were also adopted to carry outlong term real time rupture monitoring in cap rock.Therefore,a complete safety evaluation system for the cap rock was establishedto ensure safe operation of subsequent blasting processes.The ideal way of eliminating collapse hazard of such cavity is cap rockcaving through deep-hole blasting,thus,two deep-hole blasting schemes named as vertical deep-hole blasting scheme and one-timeraise driving integrated with deep-hole bench blasting scheme were proposed.The vertical deep-hole blasting scheme has moreexplosive consumption,but the relatively simple blasting net work structure can greatly reduce workloads.However,the one-timeraise driving integrated with deep-hole bench blasting scheme can obviously reduce explosive consumption,but the higher technicalrequirements on drilling,explosive charging and blasting network will increase workloads.

Control of hydrocarbon accumulation by Lower Paleozoic cap rocks in the Tazhong Low Rise, Central Uplift, Tarim Basin, West China

Despite the absence of regional cap rocks in the Lower Paleozoic for the entire Tazhong Low Rise,several sets of effective local cap rocks are well preserved on the Northern Slope.Of these the best is the Ordovician mudstone of the Sangtamu Formation; the second is the Silurian Red Mudstone Member of the Tatairtag Formation and the marl of the Ordovician Lianglitag Formation; and the third is the gray mudstone of the Silurian Kepingtag Formation.The dense limestone of the Ordovician Yingshan Formation and the gypsum of the Middle Cambrian have shown initial sealing capacity.These effective cap rocks are closely related to the distribution of Lower Palaeozoic hydrocarbons in the Tazhong Low Rise.With well-preserved Sangtamu Formation mudstone and its location close to migration pathways,rich Lower Paleozoic hydrocarbon accumulation can be found on the Northem Slope.Vertically,most of the reserves are distributed below the Sangtamu Formation mudstone; areally,hydrocarbons are mainly found in the areas with well-developed Sangtamu Formation mudstone and Lianglitag Formation marl.Burial history and hydrocarbon charging history show that the evolution of Lower Palaeozoic cap rocks controlled the accumulation of hydrocarbon in the Tazhong Low Rise.Take the Red Mudstone Member of the Tatairtag Formation and Sangtamu Formation mudstone for examples：1） In the hydrocarbon charging time of the Late Caledonian-Early Hercynian,with top surfaces at burial depths of over 1,100 m,the cap rocks were able to seal oil and gas; 2） During the intense uplifting of the Devonian,the cap rocks with top surfaces at burial depths of 200-800 m and 500-1,100 m respectively were denuded in local areas,thus hydrocarbons trapped in earlier time were degraded to widespread bitumen; 3） In the hydrocarbon charging time of the Late Hercynian and Himalayan,the top surfaces of the cap rocks were at burial depths of over 2,000 m without intense uplifting and denudation thereafter,so trapped hydrocarbons were preserved.Based on cap rocks,the Ordovician Penglaiba Formation and Lower Cambrian dolomite could be potential targets for exploration on the Tazhong Northern Slope,and combined with hydrocarbon migration,less risk would be involved.

Dolomite genesis and reservoir-cap rock assemblage in carbonate-evaporite paragenesis system

Regarding to the problem on the reservoir-cap rock assemblage evaluation in the carbonate-evaporite paragenesis system,this study examined the dolomite and reservoirs genesis and the characteristics of reservoir-cap rock assemblage.Based on the literature research of the global carbonate reservoirs and the case study on four profiles of carbonate-evaporite succession,together with geological and experimental work,three aspects of understandings are achieved.(1)Lithology of carbonate-evaporite paragenesis system is mainly composed of microbial limestone/bioclastic limestone,microbial dolomite,gypsum dolomite and gypsum salt rock deposited sequentially under the climatic conditions from humid to arid,and vice versa,and an abrupt climate change event would lead to the lack of one or more rock types.(2)There developed two kinds of dolomite(precipitation and metasomatism)and three kinds of reservoirs in the carbonate-evaporite system;and the carbon dioxide and organic acid generated during early microorganism degradation and late microbial dolomite pyrolysis process,and early dolomitization are the main factors affecting the development of microbial dolomite reservoirs with good quality.(3)In theory,there are 14 types of reservoir-cap rock assemblages of six categories in the carbonate-evaporite system,but oil and gas discoveries are mainly in four types of reservoir-cap rock assemblages,namely"microbial limestone/bioclastic limestone–microbial dolomite–gypsum dolomite–gypsum salt rock","microbial limestone/bioclastic limestone–gypsum salt rock","microbial dolomite–gypsum dolomite–gypsum salt rock"and"gypsum dolomite–microbial dolomite–tight carbonate or clastic rock".These four kinds of reservoir-cap rock assemblages should be related with the climate change rules in the geologic history,and have good exploration prospects.

New Computerized Method for the Geochemical Classification of Precambrian Carbonate Rocks: Case of a Set of African Cap Carbonates

Post-sedimentary transformations have masked or completely obliterated the structures and textures of Precambrian carbonate rocks. Therefore, methods of classification of the carbonate rocks founded on the observation of primary structures or textural characteristics are ill-adapted. Consequently, only certain geochemical classification methods allow us to distinguish the various rock-types in the case of Neoproterozoic carbonates. After presenting the most suitable geochemical classifications, we propose a new classification into 14 groups based on a regular ternary diagram with computerized data input. For each sample of carbonate rock, analysis of calcium and magnesium contents allows us to calculate the input data for our diagram i.e. the percentages of Calcite, Dolomite and Insoluble Residue. To automate the application of this diagram, input parameters are created in a descriptive file “Roches.ternaires.txt” using an option called “Ternaires” in the “Diagrammes” software developed by Roland Simler. Thirty cap carbonates of Africa are used to validate this new method.

Mineralogical and Geochemical Characteristics of Caprock Formations Used for Storage and Sequestration of Carbon Dioxide

The main objective of the present study is to characterize cap rock formation used for geological storage of carbon dioxide (CO2). The petrophysical properties of several rocks were studied before CO2 injection. This step is necessary for an understanding of CO2-brine-rock interactions. The mineralogical composition of several clay samples collected from real storage sites located in the south of Tunisia was determined by X-ray diffraction (XRD) and Scanning Electron Microscopy (SEM) coupled to a probe EDS, infrared spectroscopy, thermal analysis and fluorescence spectra. The obtained experimental results reveal that illite, calcite and quartz are the dominant clay minerals. Dolomite and albite are also present. Besides, SEM analysis shows laminated structure for these samples which suggests low crystallinity. This sample contains a higher content of Fe, Cl, Ca and O. The clay cover may also be useful in storage process by immobilizing the migration of CO2 outer of the geological site and activating the process of mineral sequestration.

准噶尔盆地盆1井西凹陷石炭系火山岩凝析气藏的发现与勘探启示

准噶尔盆地石炭系火山岩油气藏是油气勘探的重点领域之一。根据录测井资料、地球化学分析数据及岩石薄片鉴定资料,结合地球物理方法,厘清了准噶尔盆地盆1井西凹陷石炭系火山岩油气成藏的主控因素,总结出深层火山岩气藏富集规律,明确了有利勘探方向。研究结果表明:(1)准噶尔盆地盆1井西凹陷风城组烃源岩厚度为100~300 m,面积约为5 400 km2,整体进入生凝析油—干气阶段,生气强度大于20×108m3/km2,为凹陷提供了丰富的天然气源。(2)研究区石炭系火山岩岩性复杂,爆发作用形成的安山质火山角砾岩受到风化淋滤作用,可形成物性较好的风化壳型储层。石炭系—二叠系大型不整合面和广泛发育的深大断裂是重要的输导体系,二叠系上乌尔禾组泥岩作为区域盖层,为凝析气成藏提供了保存条件,油藏主要分布在高部位,气藏分布于低部位。(3)通过“两宽一高”(宽方位、宽频带、高密度)技术,提高地震成像精度,联合时-频电磁技术(TFEM),实现了石炭系火山岩的精细刻画,为深层油气藏的勘探提供了有力支撑。石西16井的重大突破,证实了盆1井西凹陷石炭系火山岩具有巨大的勘探潜力。

中西非裂谷系富油凹陷石油地质特征与勘探方向

基于地震、钻井、烃源岩测试分析等资料,对中西非裂谷系主要盆地富油凹陷石油地质特征进行研究,并探讨未来油气勘探方向。研究表明:中非裂谷系发育下白垩统湖相优质烃源岩,西非裂谷系发育上白垩统陆源海相优质烃源岩,两类烃源岩为中西非裂谷系油气富集提供了物质基础。中西非裂谷系发育包括基岩在内的多套储集层,并存在下白垩统、上白垩统和古近系3套区域盖层。晚中生代以来,受中非剪切带右旋走滑作用等地球动力学因素的影响,中西非裂谷系不同方向的盆地在裂谷作用期次、区域盖层发育层段、圈闭类型及成藏模式等方面存在差异。其中,北东—南西向盆地主要保存了早白垩世一期裂谷层序,区域盖层位于下白垩统裂陷期地层内,形成反转背斜、花状构造及基岩潜山等圈闭类型,发育“源储一体、源内成藏”及“源上储下、源下成藏”两种成藏模式;北西—南东向盆地具有多期裂谷叠置特征,发育上白垩统和古近系区域盖层,形成披覆背斜、断背斜、反向断块等圈闭类型,以“源下储上、源上成藏”为主要成藏模式。多期叠置裂谷盆地的源内成藏组合、强反转盆地的源内岩性油藏及页岩油是中西非裂谷系盆地未来勘探的重要领域。

辽东郑屯地区基于广域电磁法的深孔验证

辽东金矿床的发育被认为受变质核杂岩体系叠加拆离断层带控制,传统观点判定永宁盆地永宁组盖层厚度达到几千米以上,阻碍含矿流体的运移的同时,不利于形成大规模金属矿床。辽东地区矿床深部探测投入少、研究程度低,勘查探测深度长期局限于1 km以内。本文在郑屯地区采用广域电磁法获得了3 km以浅的电阻率分布特征,厘清了辽东盖层厚度为千米左右,突破了对永宁组巨厚盖层的传统认识;进一步施工2 km深钻开展验证,在孔深1 345 m处发现永宁组地层与下伏太古宙基底呈不整合接触关系,界面附近未见明显的构造拆离迹象。本研究证实永宁盆地盖层厚度仅为千米左右,结合区内多期活动断裂构造和密集分布的浅成岩脉群,初步判定永宁盆地的成矿地质背景类似胶东金矿集区,推测存在华北克拉通破坏时期含矿变质流体或岩浆热液运移至界面上部成矿的可能。辽东地区具有实现多金属找矿突破的潜力,广域电磁法勘探为深地成矿预测指明了方向。

Petroleum geological characteristics and exploration targets of the oil-rich sags in the Central and West African Rift System

Based on seismic,drilling,and source rock analysis data,the petroleum geological characteristics and future exploration direction of the oil-rich sags in the Central and West African Rift System(CWARS)are discussed.The study shows that the Central African Rift System mainly develops high-quality lacustrine source rocks in the Lower Cretaceous,and the West African Rift System mainly develops high-quality terrigenous organic matter-rich marine source rocks in the Upper Cretaceous,and the two types of source rocks provide a material basis for the enrichment of oil and gas in the CWARS.Multiple sets of reservoir rocks including fractured basement and three sets of regional cap rocks in the Lower Cretaceous,the Upper Cretaceous,and the Paleogene are developed in the CWARS.Since the Late Mesozoic,due to the geodynamic factors including the dextral strike-slip movement of the Central African Shear Zone,the basins in different directions of the CWARS differ in terms of rifting stages,intervals of regional cap rocks,trap types and accumulation models.The NE-SW trending basins have mainly preserved one stage of rifting in the Early Cretaceous,with regional cap rocks developed in the Lower Cretaceous strata,forming traps of reverse anticlines,flower-shaped structures and basement buried hill,and two types of hydrocarbon accumulation models of"source and reservoir in the same formation,and accumulation inside source rocks"and"up-source and down-reservoir,and accumulation below source rocks".The NW–SE basins are characterized by multiple rifting stages superimposition,with the development of regional cap rocks in the Upper Cretaceous and Paleogene,forming traps of draping anticlines,faulted anticlines,antithetic fault blocks and the accumulation model of"down-source and up-reservoir,and accumulation above source rocks".The combination of reservoir and cap rocks inside source rocks of basins with multiple superimposed rifting stages,as well as the lithologic reservoirs and the shale oil inside source rocks of strong inversion basins are important fields for future exploration in basins of the CWARS.

油气倒灌会发生吗?——与王永诗先生商榷

针对石油地质学中油气倒灌会否发生的问题,根据渗流力学的相关理论,通过理论分析深入研究了油气的运移成藏机理及地层超压的形成机理,并获得以下主要认识:1)运移与流动不同,流动需要压差驱动,运移不需要压差驱动,油气运移是浮力作用下的离散流或滴流;2)油气可以向上运移,油气倒灌不会发生,因为缺少动力的驱动;3)室内实验没有模拟地下情况,压差大,流速高,属于油气流动,而非油气运移;4)泥岩地层为开放地层,并不存在超压,地层水通过流动可以平衡地层压力;5)油气被地层水分割包围,可以出现超压,超压部分被毛管压力所平衡;6)上生下储式并不存在,烃源岩不一定位于油气藏的正下方,侧向运移也可以实现油气成藏。

深水硬质岩嵌入式承台无封底施工关键技术

深水嵌入式承台基础施工中,需将泥面开挖至封底混凝土以下并对基底进行清理,以保证封底混凝土的高度和浇筑质量。对于地质条件良好的硬质岩,存在开挖困难、水下作业工期长、质量控制难、施工成本高等问题。该文依托重庆嘉华轨道专用桥主墩承台施工,采用理论分析、数值计算和工程实施验证相结合的方法,形成一种深水硬质岩嵌入式承台无封底施工技术。该施工技术,采用开挖壁体基槽并浇筑基槽混凝土的方式取代大体积封底混凝土,达到为承台施工提供干作业环境的目的,可将承台范围内基坑开挖由水下作业转为干作业,缩短水下开挖作业工期,节约水下混凝土用量,提高施工质量和施工效率,降低施工成本。

氦气资源的盖层特征探究--以塔里木盆地为例

良好的盖层封盖条件是氦气资源得到保护的关键,在氦气资源潜力评估中有着重要的意义。目前对于氦气资源盖层特征的研究仍处于空白阶段,笔者等对盖层的封盖机理及宏观-微观特征与氦气封盖效果之间的关系进行了探究,认为氦气在地层中保存的封盖机理主要包括物性、压力、浓度三重封闭。盖层对于氦气的封盖效果受一系列微观特征(孔隙度、渗透率、突破压力、中值半径)与宏观特征(岩性、厚度、成岩作用、连续性、构造作用)影响,含氦气藏载体气类型的不同也会使盖层对于氦气的封闭能力产生差异。基于笔者等归纳出的盖层特征与氦气封盖效果的关系,对塔里木盆地内具有一定的生氦潜力的和田河区块、雅克拉区块、古城区块的氦气资源盖层条件进行评估,评估结果对应实际勘探中含氦气藏的分布情况。综合分析塔里木盆地含氦气藏盖层特征,发现常规评价油气藏封盖条件的方法并不完全适用于氦气资源盖层条件的评估,精准化分析含氦气藏盖层条件的方法仍需进一步探索。

储气库运行上限压力的确定方法及在板中北储气库的应用

大港油田板中北储气库位于板桥断层上升盘,为断层切割的半背斜构造,属于断块型储气库,断层和盖层的承压能力决定了储气库运行的上限压力。针对缺乏考虑力学完整性的储气库上限压力的研究现状,从地质力学角度出发,综合三维地震解释成果、XMAC测井地应力解释成果、岩石力学测试等资料,基于岩石脆性破裂理论对研究区盖层的水力封闭能力和断层的稳定性进行了评价,以确定考虑力学完整性的储气库安全运行上限压力。结果表明:板中北储气库盖层水力封闭能力上限为39.30 MPa,断层稳定性薄弱点位于2条断层的交叉位置,最小活化压力为30.57 MPa;综合盖层水力封闭能力上限和断层稳定性可知,板中北储气库运行上限压力为30.57 MPa,而设计运行上限压力为30.50 MPa,设计较为合理。研究成果对于储气库上限压力的设计具有指导意义。

含水层地下储氢圈闭盖层密封性评价——以Y含水圈闭为例

结合国内外含水层储气库建设中影响盖层密封性的关键指标,构建含水层地下储氢圈闭盖层密封性评价体系,分析得出适合中国含水层盖层密封性评价方法——层次分析法,并运用层次分析法和多因子综合评价法相结合的方法定性分析了华东某油气区内的Y含水圈闭盖层静态密封能力。结果表明:(1)盖层静态密封性评价体系中直接盖层厚度、岩石脆性等传统评价因素占比较高,其次为地层水的酸碱性、矿物类型等特殊因素。(2)基于层次分析法和多因子综合评价法分析可知,Y含水圈闭的盖层在静态条件下具备一定的封气能力,能够在一定程度上封隔储集层中的氢气,避免氢气逸散。研究表明,该评价体系可为初步评价含水层地下储氢盖层密封性提供一定的指导与理论依据。

川中古隆起北斜坡寒武系龙王庙组油气成藏特征及演化模式

利用测井、录井、岩心分析化验等资料,对川中古隆起北斜坡下寒武统龙王庙组油气成藏条件、油气充注特征及成藏演化模式展开了深入研究。研究结果表明:(1)川中古隆起北斜坡下寒武统龙王庙组天然气具备良好的成藏条件,下伏筇竹寺组烃源岩在北斜坡腹部及西侧裂陷槽存在2个生烃中心,其TOC平均值分别为1.90%和3.46%,有机质以Ⅰ型干酪根为主,可提供充足且优质的烃源;龙王庙组内部发育的颗粒滩体岩溶储层与上覆高台组厚层致密泥质云岩,构成了优势储-盖组合;区内广泛发育的油源断裂可作为纵向优势运移通道高效输导油气。(2)研究区龙王庙组具3期成藏特征:晚三叠世末期(约214~206 Ma)发生第1期充注,大量成熟油聚集形成古油藏;早侏罗世末期(约193~186 Ma)发生第2期充注,表现为“多油少气”混合充注;中侏罗世末期(约170~164 Ma)发生第3期充注,大量油裂解气充注储层并聚集形成现今气藏。(3)研究区龙王庙组油气成藏演化可划分为4个阶段:加里东早期—二叠纪前少量低熟油充注阶段、二叠纪—三叠纪大量成熟油充注形成古油藏阶段、中侏罗世—白垩纪古油藏被破坏形成裂解气藏阶段以及晚白垩世至今气藏调整阶段。

苏北盆地刘庄储气库密封性评价研究

对储气库密闭性进行评价是其建设与运行的重要任务,苏北盆地刘庄储气库属于断层控制的断鼻构造边水储气库,通过岩石力学实验与理论分析相结合的方法,从盖层和断层2个方面综合评价刘庄储气库的密封性;从宏观、微观和力学方面评价盖层密封强度;从侧向和垂向评价断层密封能力。研究表明:阜宁组二段一砂组与阜宁组三段二砂组泥岩为研究区内的巨厚盖层,该盖层全区分布且区域分布稳定,岩性组合优越,其黏土矿物含量在30%以上,储气库盖层杨氏模量和脆性指数整体相对较低,杨氏模量普遍小于20 GPa,脆性指数普遍小于45%,黏土矿物组成以伊蒙混层矿物为主,遇水易膨胀,盖层具有良好的油气封堵性。刘①断层断距和倾角均较大,结合研究区内断层面正压力法和上覆地层埋深的经验得出控藏断层垂向密封;砂泥对接定性方法和泥岩涂抹因子定量方法均证明刘庄控藏断层具有较强的侧向封堵性。

环渤中缓坡带盖层逐级破裂与油气阶梯跃升式运移

随着渤海凸起区勘探程度的提高,缓坡带成为重要的勘探接替区,但缓坡带勘探成功率较低,油气运移模式及运移路径精准预测是制约勘探成败的关键因素。以环渤中地区为重点,分析了断陷盆地缓坡带多层输导体系条件下盖层破裂与油气运移的关系,总结了相应的油气运移模式,并基于运移模式开展油气三维运移模拟,实现了缓坡带油气运移路径的精细预测。研究表明:①渤中凹陷周缘缓坡带普遍具有“盖-断双控阶梯式”油气成藏模式,主要包括古近系近源和新近系源外2类油气藏。近源成藏的油气直接来自于烃源岩,在东营组区域盖层控制下沿古近系第一输导层顺层运移;源外成藏的油气来自于二次调整运移的充注点,油气顺断层突破东营组盖层后,沿新近系多层楼式输导层呈阶梯式充注运移。②累计盖层断接厚度小于450m是下伏盖层破裂及浅层输导层充注发生的触发条件。③受盖层减薄和断裂活动的耦合控制,缓坡带不同构造部位油气运聚的阶梯环带不同,可以通过“盖-断耦合”分析来预测油气的空间分布,基于这一思路创新开展阶梯跃升式油气立体运移模拟,在蓬莱19-3缓坡带综合预测成功率达88%。④由于坡折断带坡坪转换的正断层的密集发育,加上盖层厚度及其断接厚度的剧烈变化,坡折带之下的斜坡外带通常为近源成藏,油气勘探应该以中深层为主;坡折带之上的斜坡内带,油气通常在源外成藏,油气勘探应该以浅层为主。该研究成果对于断陷盆地缓坡带油气勘探有利方向预测有着重要作用。