气顶砂岩油藏型储气库运行上限压力和库容量定量评价研究

提高运行上限压力是增加储气库工作气量最直接、最有效且综合效益最优的方案。通过在矿场井中原位实测得到的最小主应力,对冀东南堡油田1-29气顶砂岩油藏型储气库的运行上限压力和库容量进行了定量评价,研究结果表明:基于最小主应力准则,盖层发生拉张破坏对应的上限压力最低,即根据实测最小主应力确定南堡油田1-29储气库的运行上限压力为27.2 MPa。基于有效库容计算模型,综合考虑气层含水量、残余水和边缘孔隙以及油层的波及系数、气驱液效率和含油空间利用率等因素,将上限压力从原始地层压力22.5 MPa提升到27.2 MPa,储气库的有效库容从15.46×10^(8)m^(3)增加到18.14×10^(8)m^(3),库容量增加约17.3%,预期可显著提升储气库的经济效益。研究成果对其他地下储气库运行上限压力和库容量定量评价具有一定参考价值。

移动场景下高速可见光通信系统硬件电路设计

针对移动场景下高速可见光通信中存在信号衰减快与系统带宽受限问题,创新设计了能够实现高速、稳定可见光通信系统的自适应均衡硬件电路。首先,从自适应控制接收信号衰减角度,提出一种面向移动可见光通信的自适应增益电路设计方案。其次,从补偿通信系统频响衰减角度,设计了一种模拟预均衡与后均衡电路。最后,基于所设计的电路搭建了可见光通信硬件测试平台。实验结果表明,将自适应均衡电路应用于可见光通信系统中,可以有效提高通信速率,还可有效克服移动过程中信号衰减与中断问题。

一种基于RIS的宽带毫米波SISO定位方法

针对毫米波定位过程中空间宽带效应产生的影响,该文基于可重构智能超表面(RIS)和单输入单输出(SISO)毫米波系统提出一种新颖的3维(3D)定位估计方法。首先,通过设计RIS相位,利用快速傅里叶逆变换(IFFT)粗略地估计直射路径的视距(LoS)时延、RIS路径的虚拟视距(VLoS)时延以及RIS与用户之间的出发角(AoD)等信道参数。然后,利用拟牛顿法修正上述参数进而估计用户的位置坐标。通过仿真模拟对比了所提宽带估计方法和传统的窄带估计方法的定位性能,结果表明,通过考虑空间宽带效应,带宽为240 MHz时定位精度大约可提高10%,随着带宽增大超过800 MHz时定位性能可提高超过20%。

油气藏型储气库地质体完整性内涵与评价技术

地下储气库(以下简称储气库)全生命周期完整性管理已成为其长期安全有效运行的重要保障,目前我国油气藏型储气库完整性及其评价技术以地面设施和注采井为主,地质完整性评价对象与概念不明确且缺乏系统的评价技术。为此,在总结相关研究成果的基础上,提出了以储气地质体为评价对象的地质体完整性概念,建立了油气藏型储气库地质体完整性评价技术体系,并以新疆呼图壁储气库为实例开展了储气库地质体完整性评价。研究结果表明:①储气库地质体完整性是指在储气库运行过程中,储气地质体各组成部分能够满足运行要求、安全经济地完成季节与应急调峰任务的各项性能指标的完整程度,其内涵是在储气库运行生命周期内,地质体的储层以及盖层、断层和圈闭可以为用户持续稳定提供气量,并保证储气库安全运行,其核心是在储气库运行生命周期内保持天然气存储的可靠性、安全性和经济性的程度;②地质体完整性评价技术体系由圈闭有效性、盖层完整性、断层稳定性、储层稳定性4项评价技术构成;③评价结果显示,呼图壁储气库具有提高上限压力扩大调峰气量的潜力。结论认为,油气藏型储气库地质体完整性评价技术体系的建立,健全了储气库完整性评价技术系列,对油气藏型储气库长期安全有效运行、提高运行上限压力、增强调峰能力等具有指导作用和应用价值。

气藏型地下储气库地质体注采运行风险分级与管控

地下储气库(以下简称储气库)是由储气地质体、储气库井、地面设施组成的储气系统,其中储气地质体是必不可少的重要组成部分。目前气藏型储气地质体在完整性评价方面中研究较多,对风险分析与风险等级划分尚属空白。为此,在分析气藏型储气构造密封性失效的风险的基础上,完善了气藏型储气地质体的概念,然后对储气构造的危害因素进行识别、分析、等级划分。研究结果表明:(1)气藏型储气地质体是由储气构造和监测构造组成的地下三维空间内地层、构造、流体等的集合体;(2)气藏型储气地质体的风险评价技术系列由储气构造密封性失效、储气空间体积减少两项风险分析技术构成;(3)气藏型储气地质体风险等级从低到高可划分为Ⅰ级、Ⅱ级、Ⅲ级,分别对应可接受、可容忍、不可接受三类风险。结论认为,气藏型储气地质体风险分析与分级体系的建立,弥补了储气库风险分析缺少地质体的缺陷,为气藏型储气库安全运行管理提供了重要支撑,有力地保障了“天然气银行”的正常运行。

气藏型储气库井注采动态不稳定流分析方法

针对现有不稳定流分析方法的局限性,结合强非均质气藏型储气库注采运行特点,建立了考虑储气库多周期注采历史动态等复杂因素的动态不稳定流分析方法,并绘制了相关理论图版。提出了适合储气库井交变工况的“三点两段”式注采动态不稳定流分析新模式,“三点”指循环注采的3个时间点,即建库注气起始点、注采分析段起始点和结束点,“两段”指历史流动段和注采分析段。研究发现:储气库井注采过程中无因次拟压力和无因次拟压力积分曲线前期下掉;无因次拟压力积分导数曲线中间过渡区存在采气期曲线上凸、注气期曲线下凹的现象,不同流动历史下的曲线具有非典型性。新方法实现了储气库注采动态不稳定流分析,呼图壁储气库典型井的实际应用表明,新方法压力历史拟合精度高,解释参数关联性强,应用结果可靠。

气藏型储气库注采全过程油气相行为模拟

在分析气藏向储气库转化过程中流体相行为的基础上,建立了描述储气库注采全过程油气相行为特征的数学模型和模拟方法,并以辽河双6带油环气藏型储气库为典型实例,模拟验证了数学模型的可靠性和精度,揭示了流体相行为特征与作用机理。研究表明:注气形成库容阶段,油气相行为表现为气顶气对油环油以蒸发抽提为主、溶解扩散作用为辅,气顶气轻质组分含量升高,中间和重质组分含量降低,密度、黏度增大;油环油重质组分含量降低,轻质、中间组分含量升高,密度、黏度减小,体积系数、溶解油气比增大。储气库周期注采稳定运行阶段,油气相行为表现为气顶气对油环油的蒸发抽提能力逐渐减弱,而溶解扩散作用逐渐增强,气顶气中间组分含量缓慢降低,轻质组分含量缓慢上升,气顶气逐步轻质化,但对密度、黏度影响较小;油环油重质组分含量增大,中间组分含量降低,密度、黏度升高,体积系数、溶解油气比减小。

水侵气藏型储气库注采相渗滞后数值模拟修正方法

以天然岩心气水多周期互驱相渗测定实验为基础,揭示了储气库多周期注采相渗滞后效应,结合Carlson和Killough经典相渗滞后理论,建立了水侵气藏型储气库多周期注采相渗滞后数值模拟修正方法,并通过建立的中低渗透砂岩水侵气藏型储气库地质模型,系统研究了多周期注采相渗滞后效应对储气库流体宏观分布规律和生产运行指标的影响。研究表明:水侵气藏型储气库高速注采运行过程中存在相渗滞后效应,该效应的存在使储气库气水过渡区宽度、厚度增加,高效储气区不断收缩,含气孔隙体积峰值变化幅度减小,进而降低储气库的库容、工作气量及高效运行寿命等;数值模拟中若不考虑相渗滞后效应的影响,预测的储气库运行指标将存在较大误差,采用Killough和Carlson方法可对储气库相渗滞后效应进行修正,提高预测精度,其中Killough方法对实例模型的适应性更好。

气藏型地下储气库动态密封性评价——以新疆H地下储气库为例

为了有效指导地下储气库(以下简称储气库)运行上限压力和动态监测井网的优化调整、保障储气库运行安全,以目前中国库容最大、调峰能力最强的新疆H储气库为研究对象,根据储气库高速往复注采地应力场交替变化的特点,综合地质、地震、测井和各类室内岩心实验结果,建立了H储气库区域尺度三维精细地质模型和三维动态地质力学模型,综合评价了H储气库在经历原气藏14年衰竭式开发及其改建储气库后长期高速注采气过程中交变应力下的圈闭动态密封性。研究结果表明:①H储气库地层压力的变化对区域地应力场具有显著影响;②原H气藏开发后断裂两侧地应力具有较大差异,但盖层未发生变形破坏,作为含气边界的控藏断裂也未发生滑移,保证了H气藏改建储气库的安全性;③由于H储气库高速注采导致地应力场变得更加不均衡,对储气库注采井的完整性具有潜在的负面影响;④H储气库在长期高速注采运行过程中盖层未发生剪切和拉张破坏,但地质力学数值模拟显示储气库长期高速注采导致储层南部的H断裂两侧形成最大约5 cm的相对错动变形,H断裂的密封性成为影响储气库完整性的薄弱区域;⑤建议在储气库南部H断裂上盘部署监测井,加强注采动态监测。结论认为,该项研究从定性和定量两个方面评估了气藏型储气库在交变应力作用下圈闭的动态密封性,对保障H储气库长期注采运行安全具有重要的指导作用。

气藏型储气库温度敏感性及其对气井注采能力的影响

气藏型储气库交替注采工况下的储层温度变化是影响渗透率乃至储气库注采能力的关键因素。为探究砂岩储层渗透率的温度敏感性规律及其对气井注采能力的影响,在储气库运行的温度范围内设计了多轮次交变温度下渗透率温度敏感性实验,模拟气藏型储气库储层温度的周期性变化。实验结果表明:(1)储层渗透率随温度升高而减小,随温度降低而增大,且多轮次交变温度下渗透率表现出滞后效应,随升降温轮次增加滞后效应逐渐减弱;(2)储层渗透率温度敏感性规律不同于应力敏感,渗透率与温度呈线性相关,且单轮升降温过程中滞后效应强弱不随温度改变;(3)基于实验结果建立了考虑渗透率温度敏感性的气井产能方程,研究发现忽略储层渗透率温度敏感性将低估气井注采能力,且储层埋藏越深、气井注采气量越大时,温度敏感性对注采能力的影响越大。

低渗火山岩气藏渗吸机理实验研究

为深入研究喷发成岩的强非均质性火山岩气藏渗吸机理,综合使用气水驱替、核磁共振、X-CT成像等实验进行分析。结果表明,火山岩实验样品自发渗吸含水饱和度增加主要发生在渗吸初期的2 h,渗吸24 h已基本达到稳定状态,储层渗透率越小渗吸水饱和度越大。自发渗吸过程中微小孔隙渗吸速度和渗吸水分布比例均大于较大孔隙,约有80%的渗吸水分布在微小孔隙,残余气主要分布在较大孔隙中。而动态渗吸过程中较大孔隙渗吸速度和渗吸水分布比例均大于微小孔隙。复杂火山岩气藏自发与动态渗吸残余气饱和度分别为18.51%和6.55%,渗吸效率分别为48.62%和80.25%,渗透率越小,渗吸效率越高,但残余气饱和度与孔隙度之间不存在明显的对应关系。

油藏改建地下储气库库容量计算方法

库容量计算是地下储气库(以下简称储气库)建库地质方案设计的核心研究内容之一,油藏建库由于存在气油水三相渗流和复杂的气—油组分交换相行为,其库容形成机理与气藏建库具有显著差别。为此,基于多轮气驱、相平衡实验和数值模拟等研究,剖析了油藏建库库容形成机理及其影响因素,结合建库不同阶段储层流体分布及运移特征,提出了将建库油藏纵向划分为气驱纯油带、气驱水淹带/油水过渡带和纯水带3个不同区带,进行差异化计算库容量的新思路,并建立了以“有效储气孔隙体积”为核心,综合考虑不同流体区带注气微观驱替效率、宏观波及系数、剩余油二次饱和溶解及其性质变化等多相渗流和相行为的油藏建库库容量多因素预测数学模型和计算方法。研究结果表明:①油藏水驱后气驱改建储气库,微观气驱效率和宏观波及系数是影响油藏建库库容规模的主控因素;②剩余油二次饱和溶解及其体积收缩对库容规模具有一定的影响,原油挥发性越强、建库稳定剩余油越多,剩余油二次饱和溶解和原油性质变化对库容量影响越显著;③冀东油田堡古2挥发性油藏建库次生气顶自由气有效库容量为18.61×10^(8)m^(3),其中气—油组分交换相行为引起的建库稳定剩余油收缩增加库容量为2.81×10^(8)m^(3),贡献率为15.1%,自由气和剩余油二次饱和溶解总库容量为28.60×10^(8)m^(3)。结论认为,该方法在冀东油田堡古2号、南堡1号储气库进行了应用实践,所建立的油藏库容计算模型具有良好的应用效果,但由于油藏建库机理较气藏更为复杂,目前水淹区和纯油区的宏观波及系数和微观驱替效率以室内试验、数值模拟计算为主,高强度注采引发的气窜、气油水互锁等对库容的形成将产生较大影响,建库运行过程中需加强动态监测,实时修正数值模型,并建立合理的注气和排液技术界限,合理控制油气界面稳定扩展,提升达容达产效率。

基于案例分析的库仑应力变化触发地震机理探索

在许多地震触发研究案例中,不少学者都利用大地震造成的库仑应力变化研讨其对后续地震的影响,但众多结果中存在的共同规律尚未得到很好的统计与归纳。基于库仑应力变化理论,通过统计多个地震序列与典型事件中库仑应力研究结果,分别从震级\,触发距离\,触发地震库仑应力变化(ΔCFS)以及触发时间4个方面进行分析。结果表明,静态库仑应力的最优影响范围在5~50km间,触发地震的应力条件多在0.01~0.4MPa,触发地震震级与距离和主震震级无明显对应关系;动态触发的作用范围在100~2500km间,主震震级通常较高,触发地震的震级都小于主震震级,在几个典型远程触发的事件分析中,主震震级与可触发距离呈正相关,但触发次数与其他所分析因素均无关;震后应力转移的三种机制,从理论上合理地解释了长时间尺度延迟触发的现象,但精确计算应力转移的量值可能对库仑应力变化与触发地震之间关系的更合理解释有推动作用,需引起关注。

基于渗流-温度双场耦合的油藏型储气库数值模拟

调峰保供是储气库的职能,建库指标的精确预测,事关新钻井数量和投资。复杂断块油藏改建储气库后,多周期高速注采过程均为油气水三相流动,油、气高压物性参数受温度影响极大,在进行复杂断块油藏型储气库数值模拟时,若忽略冷气注入温度场扰动和高速非达西附加压力损失,可能会导致储气库数值模拟指标预测精度降低。为提高指标预测精度,以复杂断块油藏型储气库为例,结合流体黏温及高速非达西实验,建立了渗流-温度双场耦合数学模型。基于有限体积法(FVM),在空间上采用两点通量近似方案(TPFA),在时间上采用后向(隐式)欧拉格式对模型进行离散求解。高精度拟合了衰竭开发阶段区块、单井物质平衡及压力,实例开展了储气库运行指标敏感性分析。结果表明:冷气注入温度场扰动、高速非达西效应分别是累产油、气量误差的主控因素;井控温度范围随注气速度增加呈对数上升,油气相渗流能力大幅下降时水相渗流能力反而上升,使得采出液量增多、地层压力下降;高速非达西附加压降造成天然气注入后部分采不出,随着储气库多周期运行,天然气储量及压力逐渐增加。

Key technologies and practice for gas field storage facility construction of complex geological conditions in China

In view of complex geological characteristics and alternating loading conditions associated with cyclic large amount of gas injection and withdrawal in underground gas storage(UGS) of China, a series of key gas storage construction technologies were established, mainly including UGS site selection and evaluation, key index design, well drilling and completion, surface engineering and operational risk warning and assessment, etc. The effect of field application was discussed and summarized. Firstly, trap dynamic sealing capacity evaluation technology for conversion of UGS from the fault depleted or partially depleted gas reservoirs. A key index design method mainly based on the effective gas storage capacity design for water flooded heterogeneous gas reservoirs was proposed. To effectively guide the engineering construction of UGS, the safe well drilling, high quality cementing and high pressure and large flow surface injection and production engineering optimization suitable for long-term alternate loading condition and ultra-deep and ultra-low temperature formation were developed. The core surface equipment like high pressure gas injection compressor can be manufactured by our own. Last, the full-system operational risk warning and assessment technology for UGS was set up. The above 5 key technologies have been utilized in site selection, development scheme design, engineering construction and annual operations of 6 UGS groups, e.g. the Hutubi UGS in Xinjiang. To date, designed main indexes are highly consistent with actural performance, the 6 UGS groups have the load capacity of over 7.5 billion cubic meters of working gas volume and all the storage facilities have been running efficiently and safely.

Numerical simulation-based correction of relative permeability hysteresis in water-invaded underground gas storage during multi-cycle injection and production

By conducting relative permeability experiments of multi-cycle gas-water displacement and imbibition on natural cores,we discuss relative permeability hysteresis effect in underground gas storage during multi-cycle injection and production.A correction method for relative permeability hysteresis in numerical simulation of water-invaded gas storage has been worked out using the Carlson and Killough models.A geologic model of water-invaded sandstone gas storage with medium-low permeability is built to investigate the impacts of relative permeability hysteresis on fluid distribution and production performance during multi-cycle injection and production of the gas storage.The study shows that relative permeability hysteresis effect occurs during high-speed injection and production in gas storage converted from water-invaded gas reservoir,and leads to increase of gas-water transition zone width and thickness,shrinkage of the area of high-efficiency gas storage,and decrease of the peak value variation of pore volume containing gas,and then reduces the storage capacity,working gas volume,and high-efficiency operation span of the gas storage.Numerical simulations exhibit large prediction errors of performance indexes if this hysteresis effect is not considered.Killough and Carlson methods can be used to correct the relative permeability hysteresis effect in water-invaded underground gas storage to improve the prediction accuracy.The Killough method has better adaptability to the example model.

基于UWB的指纹定位算法研究

针对在医院室内非视距环境中,多径现象明显、测距误差较大的问题,本文基于超宽带技术(Ultra-wideband,UWB)功耗低、多径分辨率高、测距精度高等优点,研究了位置指纹法的定位原理与NN指纹定位法及其改进算法。实验采用基于飞行时间(Time of Fight,TOF)测距数据作为指纹建立数据库,分别研究了NN算法和WKNN的定位性能,并进行误差分析。结果表明两种算法均能达到厘米级的定位精度,且WKNN算法相对NN算法的定位误差改善了18.09%,提高了在非视距环境中定位的精确度和稳健性。

Simulation of petroleum phase behavior in injection and production process of underground gas storage in a gas reservoir

On the basis of analyzing the fluid phase behavior during the transformation from gas reservoir to gas storage,a mathematical model and an experimental simulation method are established to describe the oil-gas phase behavior during the whole injection-production process of gas storage.The underground gas storage in the Liaohe Shuang 6 gas reservoir with oil rim is taken as a typical example to verify the reliability and accuracy of the mathematical model and reveal characteristics and mechanisms of fluid phase behavior.In the gas injection stage of the gas storage,the phase behavior is characterized by mainly evaporation and extraction and secondarily dissolution and diffusion of gas in the cap to oil in the oil rim of the reservoir;the gas in gas cap increases in light component content,decreases in contents of intermediate and heavy components,and increases in density and viscosity.The oil of the ring decreases in content of heavy components,increases in contents of light and intermediate components,decreases in density and viscosity,and increases in volume factor and solution gas oil ratio.In the stable operation stage of periodic injection-production of gas storage,the phase behavior shows that the evaporation and extraction capacity of injection gas in the cap to oil rim is weakened step by step,the phase behavior gradually changes into dissolution and diffusion.The gas in gas cap decreases in content of intermediate components,increases in content of light components slowly,and becomes lighter;but changes hardly in density and viscosity.The oil in the oil rim increases in content of heavy components,decreases in content of intermediate components,rises in density and viscosity,and drops in volume factor and solution gas oil ratio.

An analysis method of injection and production dynamic transient flow in a gas field storage facility

A dynamic transient flow analysis method considering complex factors such as the cyclic injection and production history in a gas field storage facility was established in view of the limitations of the existing methods for transient flow analysis and the characteristics of the injection-production operation of strongly heterogeneous gas reservoirs, and the corresponding theoretical charts were drawn. In addition, an injection-production dynamic transient flow analysis model named "three points and two stages" suitable for an underground gas storage(UGS) well with alternate working conditions was proposed. The "three points" refer to three time points during cyclic injection and production, namely, the starting point of gas injection for UGS construction, the beginning and ending points of the injection-production analysis stage;and the "two stages" refer to historical flow stage and injection-production analysis stage. The study shows that the dimensionless pseudo-pressure and dimensionless pseudo-pressure integral curves of UGS well flex downward in the early stage of the injection and production process, and the dimensionless pseudo-pressure integral derivative curve is convex during the gas production period and concave during the gas injection period, and the curves under different flow histories have atypical features. The new method present in this paper can analyze transient flow of UGS accurately. The application of this method to typical wells in Hutubi gas storage shows that the new method can fit the pressure history accurately, and obtain reliable parameters and results.

中国地下储气库地质理论与应用

中国地下储气库经历了20余年的发展,由20世纪末的起步摸索期进入目前的快速发展阶段,亟需建立一套适用于中国复杂地质条件与大吞大吐、交变应力运行工况下的储气库地质理论。在借鉴国外储气库和总结中国储气库建设运行经验的基础上,提出了储气地质体与储气库地质理论的概念,创建了以储气地质体为评价对象、以储气圈闭构造地质学、储气空间储层地质学、交变载荷岩石力学、孔隙空间动用渗流力学等为主要内容的储气库地质理论体系,指导了地下储气库的选址评价、建库方案和扩容达产调整方案编制,对加快中国储气库建设,保障储气库长期安全高效运行意义重大,应用前景广阔。