Deterministic tools to predict gas assisted gravity drainage recovery factor

Naturally fractured rocks contain most of the world's petroleum reserves.This significant amount of oil can be recovered efficiently by gas assisted gravity drainage(GAGD).Although,GAGD is known as one of the most effective recovery methods in reservoir engineering,the lack of available simulation and mathematical models is considerable in these kinds of reservoirs.The main goal of this study is to provide efficient and accurate methods for predicting the GAGD recovery factor using data driven techniques.The proposed models are developed to relate GAGD recovery factor to the various parameters including model height,matrix porosity and permeability,fracture porosity and permeability,dip angle,viscosity and density of wet and non-wet phases,injection rate,and production time.In this investigation,by considering the effective parameters on GAGD recovery factor,three different efficient,smart,and fast models including artificial neural network(ANN),least square support vector machine(LSSVM),and multi-gene genetic programming(MGGP)are developed and compared in both fractured and homogenous porous media.Buckinghamπtheorem is also used to generate dimensionless numbers to reduce the number of input and output parameters.The efficiency of the proposed models is examined through statistical analysis of R-squared,RMSE,MSE,ARE,and AARE.Moreover,the performance of the generated MGGP correlation is compared to the traditional models.Results demonstrate that the ANN model predicts the GAGD recovery factor more accurately than the LSSVM and MGGP models.The maximum R^(2)of 0.9677 and minimum RMSE of 0.0520 values are obtained by the ANN model.Although the MGGP model has the lowest performance among the other used models(the R2 of 0.896 and the RMSE of 0.0846),the proposed MGGP correlation can predict the GAGD recovery factor in fractured and homogenous reservoirs with high accuracy and reliability compared to the traditional models.Results reveal that the employed models can easily predict GAGD recovery factor without requiring complicate governing equations or running complex and time-consuming simulation models.The approach of this research work improves our understanding about the most significant parameters on GAGD recovery and helps to optimize the stages of the process,and make appropriate economic decisions.

A Comparison Study between the Newly Developed Vertical Wells Steam Assisted Gravity Drainage and the Conventional SAGD Process

A numerical simulation study using the CMG-STAR Simulator was performed to compare the performance of the newly developed process (VWSAGD) utilizing vertical wells to enhance heavy oil recovery during steam assisted gravity drainage against the conventional steam assisted gravity drainage process which utilized horizontal wells (HWSAGD) under the same operating conditions. Two identical reservoir models were simulated for the two processes using 3-Dimensional, black heavy oil model (14° API). Each reservoir type consists of 49 × 49 × 20 grid blocks on a 5-acre model, which incorporated a typical heavy oil reservoir rock and fluid properties taken from the SPE case study, stspe001.dat (CMG 2015 release). A sensitivity analysis for both processes was performed for the grid density, soaking time, steam quality, bottom hole producing pressure, steam injection rate, reservoir thickness, reservoir area, and horizontal to vertical permeability anisotropy. More preferable reservoir conditions are those such as high horizontal to vertical permeability ratio, thick reservoir oil zones, as well as improved reservoir recovery for the VWSAGD process. Under unfavorable conditions such as thin reservoir oil zones, an improved reservoir recovery response was limited for the VWSAGD process and could be uneconomical in real field cases. Finally, the simulation results from this study include cumulative recoveries, Steam oil ratios, produced water-oil ratios, pressure and temperature distributions, and production rates. In addition, the results from this study have shown that the new VWSAGD process is more favorable than the conventional HWSAGD process.

Models of steam-assisted gravity drainage(SAGD) steam chamber expanding velocity in double horizontal wells and its application

The development of steam chamber can be used to evaluate steam-assisted gravity drainage(SAGD) performance. The velocity of steam chamber expanding is the key parameter for evaluating the development of steam chamber. Based on SAGD technology theory and heat transfer theory, two calculation model methods, observation well temperature method and steam chamber edge method for estimating the horizontal expanding velocity of steam chamber, were presented. Through analyzing the monitoring data and numerical simulation results of a typical super heavy oil block developed by SAGD in Fengcheng oilfield in Xinjiang, NW China, the development patterns of steam chamber and temperature variation law in the observation well at different stages are determined. The observed temperature data was used to calculate steam chamber expanding velocity. The calculated chamber velocity at different time was applied to predict the temperature distribution of oil drainage zone at the edge of steam chamber and SAGD oil rate. The results indicate that temperature function of high temperature zone in the observation well temperature curve has a linear relationship with measuring depth.The characteristic section can be used to calculate key parameters such as the angle of the drainage interface, expanding edge and velocity of steam chamber. The field production data verify that the results of the two proposed methods of steam chamber growth are reliable and practical, which can provide theoretical support for the efficient development of SAGD.

新疆油田浅层超稠油SAGD高效低碳开发技术研究与展望

针对“双碳”目标背景下超稠油开发高能耗与油田高质量发展矛盾日益加剧的问题,新疆油田通过SAGD机理研究与现场实践,在维持蒸汽腔高效扩展,突破储层渗流屏障遮挡,提高浅薄层驱泄复合效率,实现水平井长水平段高效均衡产液等方面持续攻关,取得显著效果。采用气体辅助技术,实现蒸汽腔隔热保压增能,油汽比可提高20%;利用立体井网及储层升级扩容技术,改善Ⅲ类超稠油油藏渗流特征,泄油速度可增大20%~40%;采用全密闭生产方式,VHSD产液温度由100℃上升至150℃,采油速度提高50%;深化热采流量控制器(FCD)机理研究,完善油藏-井筒耦合优化设计方法,水平井水平段动用程度可提高20%。“十四五”期间,新疆油田将深化溶剂辅助SAGD、无水SAGD和控温水热裂解等技术研究,逐步完善浅层超稠油低碳高效开发技术系列,该研究可为稠油油藏开发提供借鉴。

带油环凝析气藏衰竭式开发中——后期提高采收率

针对塔里木盆地Y5凝析气藏衰竭式开发过程中地层压力和气井产能快速降低、生产气油比逐渐下降、凝析油密度和黏度逐渐升高、开发效果迅速变差等问题,将生产动态特征与地层流体组分评价相结合,重新认识该气藏为带油环层状边水凝析气藏,并采用数值模拟方法确定其油环厚度。为改善开发效果,提高凝析油气采收率,系统开展带油环凝析气藏衰竭式开发中—后期提高采收率机理研究可知:完善井网、实施循环注气开发能大幅提高油气采收率,注入介质以二氧化碳最佳,气藏自产气次之;注气方式以重力辅助气驱模式最佳。基于气藏类型和提高采收率机理研究,编制了该气藏循环注气提高采收率方案,预测原油采收率较衰竭式开发提高29.96%。该气藏循环注气开发后累计注气0.19×10^(8) m^(3),地层压力恢复4.31 MPa,气井产能恢复到方案实施前的3.09倍,可为其他同类型气藏开发中—后期提高采收率提供借鉴。

苏北盆地江苏油田CO_(2)驱油技术进展及应用

CCUS(碳捕集、利用与封存)技术对绿色低碳转型、实现“双碳”目标意义重大,而CO_(2)驱油埋存是其重要内容。苏北盆地江苏油田针对复杂断块油藏提高采收率的技术瓶颈开展CO_(2)驱油技术攻关及多种类型矿场试验,形成了以重力稳定驱、驱吐协同等为特点的复杂断块油藏CO_(2)驱油的4种差异化模式,成功开展了花26断块“仿水平井”重力稳定驱等技术先导试验,建成了10×10^(4) t的复杂断块油藏CCUS示范工程。江苏油田累计注入液碳量30.34×10^(4) t,累计增油量9.83×10^(4) t,实现了较好的增产效果及经济效益。技术研究及试验可为其他复杂断块油藏的CO_(2)驱开发提供参考借鉴。

基于数值延拓的日月综合借力DRO入轨策略

远距离逆行轨道(DRO)是地月空间中的一类周期轨道,这类轨道具有长期稳定、入轨能量低的特点,可作为未来载人月球和载人火星任务的中转站。对于地球至DRO的两脉冲入轨任务,采用日月综合借力(即同时使用弱稳定边界(WSB)和月球借力(LGA))可以最大化入轨质量,但是这类轨道对初值非常敏感。使用日月综合借力拓展DRO入轨脉冲包络,改进构造方法和提供解析梯度大幅提高多步打靶收敛率,提出2层伪弧长延拓方法进一步降低任务总脉冲。数值仿真采用共振比为2∶1的DRO,脉冲最低解采用“LGA+WSB+2LGA”的飞行模式,飞行时间为123天,近地轨道发射脉冲为3.125 km/s,DRO入轨脉冲仅为19.7 m/s。

小推力航天器逃离太阳系的引力辅助轨迹设计

针对太阳系边界探测,利用形函数轨迹优化算法快速生成连续小推力航天器引力辅助逃离太阳系的三维轨迹,实现在有限燃料条件下的超远距离探测。通过对比有无引力辅助设计的仿真结果,证明了引力辅助技术在逃离太阳系过程中的有效性。仿真结果表明,基于贝塞尔形函数方法的连续小推力轨迹优化算法可以高效地设计出引力辅助逃离太阳系的合理三维初始轨迹,对于初始探测任务的快速设计和分析具有重要意义。

重力辅助CO_(2)驱在姬塬油田H436区的实践

针对姬塬油田侏罗系油藏边底水发育、递减快、采收率低等开发矛盾问题,运用CO_(2)气体重力分异及气顶的膨胀原理,开展重力辅助CO_(2)驱油机理研究、影响因素分析、注采工程方案设计、矿场试验工作。研究表明,要保障重力辅助CO_(2)驱效果,要求油藏是具备一定地层倾角、油层厚度大、隔夹层不发育的背斜构造的轻质油藏,同时要有稳定的气源;要采用高部位均匀注气,低部位逐级开井,平面上混相驱油,采出端控液生产;注采井井筒需要配套气密封及防腐措施,地面要配套紧急截断装置,防止气窜风险。H436区油藏矿场试验表明,重力辅助CO_(2)驱油能够使濒临废弃的侏罗系低渗透油藏“起死回生”,单井日增油达1.57 t,含水率下降35.7%,降水增油效果显著。研究成果为长庆油田探索侏罗系低渗透油藏提高采收率提供了技术方向,同时为国家“双碳”目标储备技术。

泡沫协同注气重力驱提高采收率实验

针对泡沫协同注气重力驱(GAGD)提高采收率效果及机理认识不清的问题,通过三维物理模拟岩心驱替实验,研究泡沫与注气重力驱的协同增油效果;采用大尺寸微观模型开展微观驱替实验,分析油、气、泡沫间的驱替关系与驱油机制。从宏、微观角度,全面揭示泡沫与GAGD组合驱的驱油潜力。结果表明:泡沫与GAGD组合驱替方式可以有效解决GAGD气窜后产油量急剧下降的问题,组合驱岩心实验采收率高达59.4%,远高于GAGD岩心实验采收率(44.9%);气体突破后注泡沫时机越早,泡沫与GAGD组合驱的驱替效果越好;注入泡沫量越多,泡沫与GAGD组合驱效果越好,但这种增幅作用会随着注入量的增多逐渐减小;泡沫与GAGD组合驱的微观驱油机制表现为泡沫封堵主要流动通道,而非主流通道内的泡沫“遇油消泡”,泡沫在孔隙中会残留表面活性剂溶液,形成气-表面活性剂-油模式下的多重驱替方式,将GAGD扩大波及体积的作用与表面活性剂提高驱油效率的作用相结合,协同增效,极大地提高了原油采收率。研究成果为泡沫协同注气重力驱的技术优化与矿场实践提供了依据。

髋关节外骨骼机器人实时助力控制研究

针对下肢乏力人群对日常训练或者出行的需求,设计可穿戴的髋关节外骨骼,实现对人体意图的精确识别,并在摆动期提供实时的助力。为了实现个体化差异和频繁启停下的助力无延时,提出一种基于下肢动力学模型的重力补偿控制策略,实时计算辅助力矩。通过模型仿真验证算法的可行性;再通过自由行和穿戴外骨骼自由行对比测试,分别验证了髋关节外骨骼对于启停切换瞬间的识别度及适应性、均速步行下的适应性、助力的及时性和有效性。实验结果表明,基于重力补偿的控制策略能够适应周期或者非周期步态下的启停切换,并在摆动期无延时的助力。

Low-thrust trajectory optimization in a full ephemeris model

The low-thrust trajectory optimization with complicated constraints must be considered in practical engineering. In most literature, this problem is simplified into a two-body model in which the spacecraft is subject to the gravitational force at the center of mass and the spacecraft＇s own electric propulsion only, and the gravity assist （GA） is modeled as an instantaneous velocity increment. This paper presents a method to solve the fuel-optimal problem of low-thrust trajectory with complicated constraints in a full ephemeris model, which is closer to practical engineering conditions. First, it introduces various perturbations, including a third body＇s gravity, the nonspherical perturbation and the solar radiation pressure in a dynamic equation. Second, it builds two types of equivalent inner constraints to describe the GA. At the same time, the present paper applies a series of techniques, such as a homotopic approach, to enhance the possibility of convergence of the global optimal solution.

CO2 assisted steam flooding in late steam flooding in heavy oil reservoirs

To improve the oil recovery and economic efficiency in heavy oil reservoirs in late steam flooding,taking J6 Block of Xinjiang Oilfield as the research object,3D physical modeling experiments of steam flooding,CO2-foam assisted steam flooding,and CO2 assisted steam flooding under different perforation conditions are conducted,and CO2-assisted steam flooding is proposed for reservoirs in the late stage of steam flooding.The experimental results show that after adjusting the perforation in late steam flooding,the CO2 assisted steam flooding formed a lateral expansion of the steam chamber in the middle and lower parts of the injection well and a development mode for the production of overriding gravity oil drainage in the top chamber of the production well;high temperature water,oil,and CO2 formed stable low-viscosity quasi-single-phase emulsified fluid;and CO2 acted as a thermal insulation in the steam chamber at the top,reduced the steam partial pressure inside the steam chamber,and effectively improved the heat efficiency of injected steam.Based on the three-dimensional physical experiments and the developed situation of the J6 block in Xinjiang Oilfield,the CO2 assisted steam flooding for the J6 block was designed.The application showed that the CO2 assisted steam flooding made the oil vapor ratio increase from 0.12 to 0.16 by 34.0%,the oil recovery increase from 16.1%to 21.5%,and the final oil recovery goes up to 66.5%compared to steam flooding after perforation adjustment.

The relationship between maternal body fat and pre-implantation embryonic weight: Implications for survival and long-term development in an assisted reproductive environment

There can be little argument that embryo quality is one of the most critical factors in the success of assisted reproductive techniques. Yet the current methods of grading embryos are subjective at best. While a number of different groups have described more qualitative means of assessing embryo quality, the current standard remains morphology. Morphology has proven a good standard, but it does not allow for the detection of chromosomal abnormalities nor can it assess the biochemical status of the embryo prior to transfer. This laboratory recently described a method to estimate embryo weight and suggested weight might be a good indicator of biochemical status. The objective of the present study was to determine the relationship between maternal body composition and embryo weight and determine the influence maternal chemistry had on embryo development. The data continue to suggest that maternal body composition, especially body fat, influences the chemical nature of the embryo and may play a critical role in long-term survival.

重力泄水辅助蒸汽驱开采机理及油藏工程设计

针对辽河油田稠油区块蒸汽吞吐后期产量低、转换开发方式难度大的问题,按照“垂向泄水提高热效率、直平采液提高采注比、水平井注汽提干度、注采泄稳定控制扩波及”的技术思路,开展重力泄水辅助蒸汽驱油藏工程研究,进一步明确开采机理并明确了各阶段开发特征,并对油藏工程关键参数进行优化设计。研究表明:采用上下叠置水平井与直井组合的立体井网,实现了平面蒸汽驱替、垂向重力泄水的渗流模式;重力泄水辅助蒸汽驱立体井网可为蒸汽腔的形成创造良好的条件,有效缓解了深层、特-超稠油埋藏深、沿程热损失大造成的井底蒸汽干度低、注采不同平衡等系列矛盾;重力泄水辅助蒸汽驱可划分为直井、水平井井间热连通,重力泄水辅助蒸汽驱驱替阶段和蒸汽驱调整3个阶段;重力泄水辅助蒸汽驱现场试验取得较好的开发效果,预计汽驱结束采收率可达到58.6%,为深层-特深层稠油开发方式转换提供了新途径。研究成果为同类油藏进一步提高采收率提供了借鉴。

基于非稳态热传导的SAGD开发指标预测模型

根据传热学和热采理论,利用程序设计的方法,对考虑边界效应的SAGD(蒸汽辅助重力泄油)非稳态热传导模型和开发关键指标解析解及开发指标的快速预测进行了研究。研究结果表明:(1)现有的非稳态热传导模型对传热外边界的温度假设存在局限性,根据能量守恒原理修正传热外边界条件,建立传热深度与累积传热量的解析关系,可定量计算上覆和下伏地层的热损失;(2)在巴特勒经典SAGD产量模型基础上,推导的蒸汽腔上升及横向扩展阶段和下压阶段的产水量、油汽比和蒸汽热利用率等解析模型,可实现SAGD特定开发阶段或全生命周期开发关键指标的快速预测;(3)通过与实际指标对比,井组生产6.4 a预测油汽比和含水率的符合率均在95%以上,证实了解析模型和程序设计的可靠性;(4)根据准噶尔盆地风城油田重32井区油藏参数,预测分析的不同油层厚度条件下SAGD蒸汽热利用率和关键开发指标表明,蒸汽热利用率大于35%、油汽比大于0.15对应油层厚度应大于12 m。

加拿大油砂非凝析气体辅助SAGD开采特征及影响因素研究

常规SAGD开采蒸汽超覆现象严重、蒸汽腔发育不均匀、后期开发效果差,非凝析气体辅助SAGD开采即SAGP(steam and gas push)可有效改善SAGD开发效果,但SAGP开采机理、开发特征和影响因素仍未完全明确。采用室内实验和数值模拟相结合方法,揭示SAGP开采机理,明确蒸汽腔发育、剩余油分布等开发特征,探讨非凝析气体类型、注入方式、注入时机等因素的影响规律。结果表明:非凝析气体可降低稠油黏度和储层顶部热量损失速率,从而提高稠油可流动性和蒸汽热利用效率;SAGP过程中利用二氧化碳的辅助效果优于甲烷和氮气,尽早注入非凝析气体可形成“椭圆形”蒸汽腔;非凝析气体注入速率为4000 m^(3)/d时效果最好,超过该值非凝析气体会抑制蒸汽腔发育;采用段塞式注入非凝析气体效果优于连续式注入方式,最优段塞长度为2个月。研究结果对于加拿大油砂SAGP高效开发具有重要意义。

一种新型环路重力热管的数值模拟和性能优化

研究了一种新型的环路重力热管(LGHP),并提出一种基于VOF方法的简化两相流数值模型,能够有效地模拟热管蒸发器内部气泡的产生和干涸区的位置,从而研究蒸发器内部工质的流动特性。在数值模拟的基础上改进了蒸发器的流道结构,以延缓水平放置时蒸发器干涸区的出现。通过实验验证发现改进后蒸发器的传热性能得到了很大的提高,蒸发器中制冷剂的液相积存量得以提升,使其极限热通量(CHF)提高到140 kW/m2(加热功率2000.7 W),为改进前CHF的两倍。证明该简化模型在模拟干涸区位置方面具有准确性,可以为进一步的设计和改进平板蒸发器流道结构提供参考。

机器人轮带磨削的重力补偿设计及加工工艺(特邀)

机器人辅助轮带磨削是一种基于计算机控制光学成形技术的确定性加工方法,具有成本低、柔性好、智能程度高且操作空间大的优点,因此机器人辅助轮带磨削作为一种较低成本的高精度、多自由度加工方法逐渐受到关注。文中介绍了所设计的机器人辅助轮带磨削系统结构及其加工原理,装置通过气动系统进行输出压力的柔顺控制。研究了任意加工姿态下机器人辅助轮带磨削中的恒力加载问题,分析了轮带磨削工具悬臂组件重力分量对其末端输出接触力的影响,建立了末端执行器的重力分量模型,并提出了基于姿态传感器的重力补偿控制方法,能够实现0~63 N范围内的恒力控制,并且最大压力波动小于1.82%,重力补偿系统的响应时间小于300 ms,实现了轮带磨削工具在任意姿态下的恒力加载。最后,根据Hertz接触理论和Preston方程完成了磨削工具在工件接触区域内的压强分布和速度分布分析,建立了轮带磨削工具的去除函数模型,并对碳化硅曲面与硫化锌非球面进行修形磨削实验,验证了装置加工的稳定性。

基于DRO的小行星往返飞越探测轨道设计优化方法

远距离逆行轨道(Distant Retrograde Orbits,DRO)是地月系统内一类稳定的周期性轨道,本文研究航天器从DRO轨道站出发,通过月球和地球引力辅助实现飞越探测近地小行星的往返转移轨道设计方法。通过地月引力辅助作用和中途杠杆机动等技术手段减少调整倾角所需的速度增量,扩大在相同速度增量约束下飞越探测小行星的可达范围。同时,通过引入DRO调相轨道,减少DRO逃逸和俘获时的相位约束,将转移轨道段与DRO轨道站的相位解耦,从而降低了该问题的计算复杂度。仿真结果表明,在2 km·s–1的速度增量等约束条件下,通过此研究方法可以实现从DRO轨道站出发飞越探测近地小行星并返回的轨道设计。