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1.
Natural gas hydrate (NGH) is an important future resource for the 21st century and a strategic resource with potential for commercial development in the third energy transition. It is of great significance to accurately predict the productivity of hydrate-bearing sediments (HBS). The multi-phase seepage parameters of HBS include permeability, porosity, which is closely related to permeability, and hydrate saturation, which has a direct impact on hydrate content. Existing research has shown that these multi-phase seepage parameters have a great impact on HBS productivity. Permeability directly affects the transmission of pressure-drop and discharge of methane gas, porosity and initial hydrate saturation affect the amount of hydrate decomposition and transmission process of pressure-drop, and also indirectly affect temperature variation of the reservoir. Considering the spatial heterogeneity of multi-phase seepage parameters, a depressurization production model with layered heterogeneity is established based on the clayey silt hydrate reservoir at W11 station in the Shenhu Sea area of the South China Sea. Tough + Hydrate software was used to calculate the production model; the process of gas production and seepage parameter evolution under different multi-phase seepage conditions were obtained. A sensitivity analysis of the parameters affecting the reservoir productivity was conducted so that: (a) a HBS model with layered heterogeneity can better describe the transmission process of pressure and thermal compensation mechanism of hydrate reservoir; (b) considering the multi-phase seepage parameter heterogeneity, the influence degrees of the parameters on HBS productivity were permeability, porosity and initial hydrate saturation, in order from large to small, and the influence of permeability was significantly greater than that of other parameters; (c) the production potential of the clayey silt reservoir should not only be determined by hydrate content or seepage capacity, but also by the comprehensive effect of the two; and (d) time scales need to be considered when studying the effects of changes in multi-phase seepage parameters on HBS productivity. 相似文献
2.
在使用TOUGH+HYDRATE程序进行水合物开采数值模拟时常用van Genuchten模型计算毛管力,而毛管力大小直接影响水合物开采过程中的产气和产水,因此在数值模拟过程中正确选用模型参数尤为必要。我国某海域天然气水合物储层为未胶结泥质粉砂储层,常规的毛管力测定方法如压汞法、离心法等对该类岩心并不适用,如何测定该类岩心的毛管力并将其应用于van Genuchten模型参数选取具有重要意义。本文探讨了如何应用土壤水分特征曲线测定实验间接获取该类岩心的毛管力数据,为验证该方法的可行性,本文对参考文献[7]中公开的粉砂土壤水分特征曲线测定实验数据进行换算和拟合后得到T+H程序所需的van Genuchten模型参数,结果可为泥质粉砂储层水合物产能研究工作提供参考。 相似文献
3.
叶建良 秦绪文 谢文卫 卢海龙 马宝金 邱海峻 梁金强 陆敬安 匡增桂 陆程 梁前勇 魏士鹏 于彦江 刘春生 李彬 申凯翔 史浩贤 卢秋平 李晶 寇贝贝 宋刚 李博 张贺恩 陆红锋 马超 董一飞 边航 《中国地质》2020,47(3):557-568
泥质粉砂型天然气水合物被认为是储量最大开采难度亦最大的水合物储层,2017年南海天然气水合物试采,初步验证了此类水合物储层具备可开采性。在总结前次试采认识的基础上,对试采矿体进行优选、精细评价、数值与试验模拟和陆地试验,中国地质调查局于2019年10月—2020年4月在南海水深1225 m神狐海域进行了第二次天然气水合物试采。本次试采攻克了钻井井口稳定性、水平井定向钻进、储层增产改造与防砂、精准降压等一系列深水浅软地层水平井技术难题,实现连续产气30 d,总产气量86.14×104m3,日均产气2.87×104m3,是首次试采日产气量的5.57倍,大大提高了日产气量和产气总量。试采监测结果表明,整个试采过程海底、海水及大气甲烷含量无异常。本次成功试采进一步表明,泥质粉砂储层天然气水合物具备可安全高效开采的可行性。 相似文献
4.
【研究目的】中国地质调查局先后于2017年、2020年在南海北部神狐海域成功实施两轮水合物试采,创造了产气时间最长、产气总量最大、日均产气量最高等多项世界纪录,了解和掌握南海天然气水合物开采储层相变与渗流机理,有助于进一步揭示该类型水合物分解机理、产出规律、增产机制等,可为中国海域水合物资源规模高效开采提供理论基础。【研究方法】基于两轮试采实践,笔者通过深入研究发现,储层结构表征、水合物相变、多相渗流与增渗、产能模拟与调控是制约水合物分解产气效率的重要因素。【研究结果】研究表明,南海水合物相变具有分解温度低,易在储层内形成二次水合物等特点,是由渗流场-应力场-温度场-化学场共同作用的复杂系统;多相渗流作用主要受控于未固结储层的物性特征、水合物相变、开采方式等多元因素影响,具有较强的甲烷吸附性、绝对渗透率易突变、气相流动能力弱等特点;围绕南海水合物长期、稳定、高效开采目标,需要在初始储层改造基础上,通过实施储层二次改造,进一步优化提高储层渗流能力,实现增渗扩产目的。【结论】随着天然气水合物产业化进程不断向前推进,还需要着力解决大规模长时间产气过程中温度压力微观变化及物质能源交换响应机制以及水合物高效分解、二次生成边界条件等难题。创新点:南海水合物相变是由渗流场-应力场-温度场-化学场共同作用的复杂系统;南海泥质粉砂储层具有较强的甲烷吸附性、绝对渗透率易突变、气相流动能力弱等特点,多相渗流机理复杂。 相似文献
5.
《China Geology》2018,1(4):493-504
In May and July of 2017, China Geological Survey (CGS), and Guangzhou Marine Geological Survey (GMGS) carried out a production test of gas hydrate in the Shenhu area of the South China Sea and acquired a breakthrough of two months continuous gas production and nearly 3.1 × 105 m3 of production. The gas hydrate reservoir in the Shenhu area of China, is mainly composed of fine-grained clay silt with low permeability, and very difficult for exploitation, which is very different from those discovered in the USA, and Canada (both are conglomerate), Japan (generally coarse sand) and India (fracture-filled gas hydrate). Based on 3D seismic data preserved-amplitude processing and fine imaging, combined with logging-while-drilling (LWD) and core analysis data, this paper discusses the identification and reservoir characterization of gas hydrate orebodies in the Shenhu production test area. We also describe the distribution characteristics of the gas hydrate deposits and provided reliable data support for the optimization of the production well location. Through BSR feature recognition, seismic attribute analysis, model based seismic inversion and gas hydrate reservoir characterization, this paper describes two relatively independent gas hydrate orebodies in the Shenhu area, which are distributed in the north-south strip and tend to be thicker in the middle and thinner at the edge. The effective thickness of one orebody is bigger but the distribution area is relatively small. The model calculation results show that the distribution area of the gas hydrate orebody controlled by W18/W19 is about 11.24 km2, with an average thickness of 19 m and a maximum thickness of 39 m, and the distribution area of the gas hydrate orebody controlled by W11/W17 is about 6.42 km2, with an average thickness of 26 m and a maximum thickness of 90 m. 相似文献
6.
2017年神狐海域第一次试开采成功后,许多学者应用数值模拟对试采数据进行研究,但模拟结果与实际试采数据存在偏差.为了探求原因,本研究建立了二维柱坐标系下水合物降压开采数学模型,开发了相应的程序,能够模拟渗透率等储层参数非均匀分布条件下开采过程,同时能够模拟开采井压力等动态参数对开采过程的影响.通过数值实验,得出偏差原因:(1)泥质粉砂型储层存在水敏性,水合物分解产生的淡水引起粘土膨胀,使渗透率下降;(2)须将开采井压力作为动态输入参量.据此,修正了渗透率模型,考虑了开采井压力随时间的变化,得到的模拟产气量与试采数据十分接近,使降压开采数值模拟更逼近实际情况. 相似文献
7.
回顾了25年来国内外水合物开采数值模拟研究的进展,分析了影响水合物开采过程的主要机理,即传热、气液流动和水合物分解。将已有的模型分为热力开采、降压开采和综合3种模型,并对各种模型所具有的特点进行了讨论。综合分析认为,TOUGH Fx/HYDRATE模型充分考虑了多相多组分并借鉴上述3类开采方式,可模拟开采过程中气液流动和相态变化,具有较高的应用价值。最后探讨了目前模型的主要问题以及发展方向,认为水合物矿藏岩石的绝对渗透率、相对渗透率、热传导系数等关键参数的测量及确定是精确模拟水合物开采过程的重要因素。 相似文献
8.
深海水合物赋存于一定的温度和压力环境下,降压开采时降压速率对分解产气速率和储层变形特性影响显著。利用浙江大学自主研发的水合物降压开采试验装置,通过伺服控制降压速率,初步开展了水合物储层模型降压开采试验,研究了储层温度场、孔压场、产气量等的响应特性,探讨了降压速率对产气效率和储层变形特性的影响规律。试验表明:水合物竖井降压开采时,开采井周围储层温度率先下降,分解域由井周逐步向周围发展。适当提高降压速率能够提高储层开采效率,但降压速率过快时易导致水合物重生成,反而不利于水合物高效持续稳定开采,开采时应选择合理的降压速率以达到最优产气效率。开采过程中根据储层孔隙与外界连通程度,储层孔隙状态可分为完全封闭型、局部封闭型和开放型3种类型。储层开采试验完成后,浅层土体出现 3 种不同变形特征的区域:I 区为井周土层,呈漏斗型下陷;II 区土层平坦,无明显扰动痕迹;III 区为边界土层,该处水气产出受阻导致部分气体向上迁移引起土丘状隆起带出现。这些变形特征与气体在储层中的迁移路径和运移模式相关。通过相似性分析,给出了模型与原型分解时间和产气量等的对应关系。 相似文献
9.
With the implementation of the production tests in permafrost and offshore regions in Canada, US, Japan, and China, the study of natural gas hydrate has progressed into the stage of technology development for industrial exploitation. The depressurization method is considered as a better strategy to produce gas from hydrate reservoirs based on production tests and laboratory experiments. Multi-well production is proposed to improve gas production efficiency, to meet the requirement for industrial production. For evaluating the applicability of multi-well production to hydrate exploitation, a 2D model is established, with numerical simulations of the performance of the multi-well pattern carried out. To understand the dissociation behavior of gas hydrate, the pressure and temperature distributions in the hydrate reservoir are specified, and the change in permeability of reservoir sediments is investigated. The results obtained indicate that multi-well production can improve the well connectivity, accelerate hydrate dissociation, enhance gas production rate and reduce water production as compared with single-well production. 相似文献
10.
天然气水合物是一种潜在的能源资源,开采过程中,水合物的分解会造成工程和地质等安全隐患。为研究降压开采过程中多因素综合影响条件下沉积物的力学性质,在自主研发的低温高压三轴仪上进行了不同围压条件下含水合物沉积物的剪切试验。试验结合常规三轴剪切及一个试样多级加荷的方法,并加入了水合物的降压分解过程。结果表明:水合物的存在可以显著提高沉积物的抗剪强度。在降压分解过程中,含水合物沉积物试样的力学强度受到有效围压和孔隙中水合物含量的综合影响。前期试样由于孔隙压力降低导致有效围压大幅增加,试样抗剪强度增大,后期由于水合物含量的大幅降低,试样在较高有效围压下抗剪强度下降。有效围压对含水合物沉积物试样的体积应变有较大的影响,较高的有效围压会导致含水合物试样产生显著的剪缩现象。 相似文献
11.
Large borehole with multi-lateral branches: A novel solution for exploitation of clayey silt hydrate
《China Geology》2019,2(3):333-341
ontact area are two main ways to raise the productivity of hydrate. An exploitation technique based on large borehole with multi-lateral branches (LB & MB) was proposed in this paper. This technique is mainly intended for the clayey silt hydrate reservoir in the South China Sea, and its main purpose is to alleviate the sand output from formation for maintaining the stability of the reservoir and to greatly increase the gas productivity of the reservoir. In this paper, the following aspects were mainly expounded: definition of the basic geometric parameters for layout of multi-lateral branches in clayey silt hydrate reservoir, simulation of the stimulation effect of a typical well profile with two branches, and prediction and simulation of the reservoir failure risk in a well profile with eight branches. The results show that the LB & MB effectively improves the flow field in the formation, raises the productivity of the reservoir and may also help to decrease the produced water-gas ratio (WGR). When the lateral branches spacing is too small, the failure zones around adjacent lateral branches overlap each other, possibly causing reservoir failure in a larger range. Therefore, the geometric parameters of multi-lateral branches depend on the dual control of the productivity and geotechnical risk factor of reservoir. Further study is being carried out, so as to obtain the optimal combination of parameters of multi-lateral branches. 相似文献
12.
天然气水合物粉晶X射线衍射测试参数优化及分析方法 总被引:1,自引:1,他引:0
天然气水合物是由烃类气体和水在低温高压下形成的一种非化学计量的笼型晶体水合物,在常温常压下极易分解,需要在低温条件下对其进行测试。本文针对天然气水合物这一特殊样品,重点研究其粉晶X射线衍射测试条件,系统地探讨了步长、扫描速度、累加次数及测试温度等因素对测试结果的影响,优化了仪器参数,建立了粉晶X射线衍射测试天然气水合物晶体结构的方法,并应用到实验合成的甲烷水合物和我国南海珠江口盆地钻获的天然气水合物样品的晶体结构测试中。结果表明,我国南海珠江口盆地的天然气水合物样品与实验合成的甲烷水合物结构相同,均属立方晶系,为典型的Ⅰ型水合物,晶胞参数分别为11.9309×10~(-10)m和11.9135×10~(-10)m。该技术可准确获得天然气水合物的结构信息,为我国天然气水合物的深入研究提供技术支撑。 相似文献
13.
我国南海北陆坡水合物富集区广泛发育古滑坡,若水合物开采不当可能导致古滑坡再次滑动。为了探究水合物开采诱发古滑坡再启滑机制,针对含下卧型水合物藏和伴生型水合物藏的两个典型古滑坡体,在边坡极限平衡分析框架内考虑了水合物开采过程中的瞬态孔压与土体抗剪强度变化,分析了水合物开采过程中不同古滑坡体的稳定性演变与失稳模式。研究表明,水合物分解导致所赋存土体的胶结强度弱化,同时逸出气体可能被阻滞于渗透性较低的古滑坡体下方,从而形成横向扩展的高压区。下卧型储层边坡的潜在滑移面贯穿古滑移面,一般表现为滑动型滑坡;开采初期因孔压积聚而导致边坡稳定性降低,开采中后期因二次水合物生成可能导致边坡稳定性有所回升,在本文计算条件下未触发古滑坡复活。伴生型储层边坡的稳定性受土体强度劣化与孔压积聚的共同影响,水合物开采导致古滑坡重新滑动,表现为滑塌型滑坡。 相似文献
14.
Methane hydrate (MH, also called fiery ice) exists in forms of pore filling, cementing and load-bearing skeleton in the methane hydrate bearing sediment (MHBS) and affects its mechanical behavior greatly. To study the changes of macro-scale and micro-scale mechanical behaviors of MHBS during exploitation by thermal recovery and depressurization methods, a novel 2D thermo-hydro-mechanical bonded contact model was proposed and implemented into a platform of distinct element method (DEM), PFC2D. MHBS samples were first biaxially compressed to different deviator stress levels to model different in-situ stress conditions. With the deviator stress maintained at constant, the temperature was then raised to simulate the thermal recovery process or the pore water pressure (i.e. confining pressure for MH bond) was decreased to simulate the depressurization process. DEM simulation results showed that: during exploitation, the axial strain increased with the increase of temperature (in the thermal recovery method) or decrease of pore water pressure (in the depressurization method); sample collapsed during MH dissociation if the deviator stress applied was larger than the compression strength of a pure host sand sample; sample experienced volume contraction but its void ratio was slightly larger than the pure host sand sample at the same axial strain throughout the test. By comparison with the laboratory test results, the new model was validated to be capable of reproducing the exploitation process by thermal recovery and depressurization methods. In addition, some micro-scale parameters, such as contact distribution, bond distribution, and averaged pure rotation rate, were also analyzed to investigate their relationships with the macroscopic responses. 相似文献
15.
Natural gas hydrates (NGHs) are globally recognized as an important type of strategic alternative energy due to their high combustion efficiency, cleanness, and large amounts of resources. The NGHs reservoirs in the South China Sea (SCS) mainly consist of clayey silts. NGHs reservoirs of this type boast the largest distribution range and the highest percentage of resources among NGHs reservoirs in the world. However, they are more difficult to exploit than sandy reservoirs. The China Geological Survey successfully carried out two NGHs production tests in the Shenhu Area in the northern SCS in 2017 and 2020, setting multiple world records, such as the longest gas production time, the highest total gas production, and the highest average daily gas production, as well as achieving a series of innovative theoretical results. As suggested by the in-depth research on the two production tests, key factors that restrict the gas production efficiency of hydrate dissociation include reservoir structure characterization, hydrate phase transition, multiphase seepage and permeability enhancement, and the simulation and regulation of production capacity, among which the hydrate phase transition and seepage mechanism are crucial. Study results reveal that the hydrate phase transition in the SCS is characterized by low dissociation temperature, is prone to produce secondary hydrates in the reservoirs, and is a complex process under the combined effects of the seepage, stress, temperature, and chemical fields. The multiphase seepage is controlled by multiple factors such as the physical properties of unconsolidated reservoirs, the hydrate phase transition, and exploitation methods and is characterized by strong methane adsorption, abrupt changes in absolute permeability, and the weak flow capacity of gas. To ensure the long-term, stable, and efficient NGHs exploitation in the SCS, it is necessary to further enhance the reservoir seepage capacity and increase gas production through secondary reservoir stimulation based on initial reservoir stimulation. With the constant progress in the NGHs industrialization, great efforts should be made to tackle the difficulties, such as determining the micro-change in temperature and pressure, the response mechanisms of material-energy exchange, the methods for efficient NGHs dissociation, and the boundary conditions for the formation of secondary hydrates in the large-scale, long-term gas production.©2022 China Geology Editorial Office. 相似文献
16.
深盆气藏地质特征与研究意义——以鄂尔多斯盆地为例 总被引:4,自引:1,他引:4
深盆气藏位于构造下倾部位或盆地中央,上部含水,是具有特殊成藏地质条件的非常规气藏,深盆气藏具以下特征;气在水在上的气水倒置,气藏流体压力低于静水压力,烃源岩与气藏紧密伴生,源岩生气量大供气充足,油气热演化程度高,储层具低孔隙度低渗透率,单井产量低但地质储量大等,本以我国鄂尔多斯盆地为例进一步阐明深盆气藏的特征,国外对深盆气藏研究极为重视,天然气的产量也占有很大比重,在我国研究程度较低,深盆气的深入研究对我国天然气的勘探开发有重要意义。 相似文献
17.
天然气水合物是未来极具潜力的新型高效清洁替代能源。在分析水合物开采面临的瓶颈问题的基础上,提出了一种全新的天然气水合物开采方法——原位补热降压充填开采法。该方法将氧化钙(CaO)粉末注入天然水合物储层,降压开采天然气,天然气水合物分解产生的水和氧化钙粉末迅速反应,产生的大量热量补充天然气水合物的分解热。本文利用基于有限体积法的新型天然气水合物模拟器,构建三维地质模型对该方法进行产能数值模拟评价。模拟结果表明相较于常规水平井方法以及水平井结合压裂开采方案,该方法对生产的促进效应明显,尤其是与水平井结合压裂开采方案相比该方法的累积产气量明显提高,但累积产水量没有显著变化,开采效率显著提升。施工工艺中裂缝等效渗透率和氧化钙注入量两个关键参数的敏感性分析结果表明在压裂过程中,压裂技术的增产效果会随着等效渗透率的提高而逐渐减弱。除此之外,氧化钙注入量越大,增产效应越明显,并且提高氧化钙注入量只会提高产气量,不会显著提高产水量,所以理论上注入量越大,产气效率越高。与此同时,该方法在不同渗透性能的天然气水合物储层中均有一定的适用性,其中针对低渗储层的促进效应更为显著。综合上述结论,本文从三维模型理论计算的角度定量化验证了原位补热降压充填开采方法的潜在价值,期待为将来的水合物试采工作提供一定参考。 相似文献
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海底水合物矿藏降压开采与甲烷气体扩散过程的数值模拟 总被引:1,自引:1,他引:0
在深海条件下采用单井降压法开采的天然气水合物矿藏中,利用TOUGH+HYDRATE软件对其开采过程和甲烷气体扩散过程进行数值模拟。物理模型由上至下依次为上盖层、水合物沉积层和下盖层。将上、下盖层外边界的温度设为恒定,与含水合物沉积层之间有热量和质量交换,数值模型采用二维圆柱坐标网格。模拟结果表明开采过程中井口产气速率是一个升高—降低—波动升高的过程,水合物分解产生的气体有一部分通过上盖层溢出,能在一定程度上增加大气中温室气体的量。开采初期水合物分解速率降低的主要原因是水合物分解产生的甲烷气体在地层中大量累积,开采后期水合物分解速率产生波动的主要原因是发生"气穴现象"。井口附近由于压力变化较快水合物分解最为剧烈,其附近有个低温区存在。上、下盖层附近水合物分解速率也较快。 相似文献
19.
为研究联合法开采天然气水合物,在水合物三维实验开采模拟平台中利用双水平井进行降压联合注温水开采水合物实验,得到温度和压力分布、产气、产水、三相饱和度变化与开采方法的传热特性。整个开采过程可以分为自由气释放阶段、静置阶段、降压开采阶段和注热开采阶段。研究结果表明在自由气释放阶段和静置阶段有二次水合物生成。在注热阶段,水合物在降压和注热的协同作用下进行分解。反应釜中的水合物最终被完全分解,并且本研究的能效比高于前人利用垂直井进行降压联合热吞吐分解水合物的能效比,表明利用双水平井进行降压联合注温水是一种有效的分解水合物的方法。 相似文献
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二十多年来,南海天然气水合物勘查评价均主要集中在南海北部大陆边缘陆坡深水区,且先后在珠江口盆地神狐、珠江口盆地东部海域调查区和琼东南盆地陵水-松南调查区取得了天然气水合物勘查试采的重大突破及进展,陆续发现了两个大规模的天然气水合物藏,初步评价预测南海天然气水合物资源规模达800亿吨油当量左右,取得了南海天然气水合物勘探的阶段性重大成果.然而,南海天然气水合物资源进一步深化和拓展勘探的有利领域在哪里?尤其是可持续滚动勘探的战略接替区及选区在何处?其与目前陆坡深水油气及水合物勘探紧密相邻的外陆坡-洋陆过渡带(OCT)乃至洋盆区是否具有天然气水合物形成的地质条件?根据海洋地质调查及初步的地质综合分析研究,认为外陆坡-洋陆过渡带乃至洋盆区具备天然气水合物成藏的基本地质条件,可作为南海未来天然气水合物勘查的战略接替区和可持续滚动勘探的战略选区及资源远景区.针对这些影响和决定将来天然气水合物勘探决策部署及走向等关键问题进行初步分析与探讨,抛砖引玉希望能够对未来南海天然气水合物资源勘查评价及战略接替区之选择有所裨益! 相似文献