用压力-瞬态分析方法评价水驱双层裂缝对致密储层的影响

IF 2.1 4区 工程技术 Q3 ENERGY & FUELS
Zhipeng Wang, Z. Ning, J. Zhan, Wen-ming Guo
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引用次数: 0

摘要

水驱会打开天然裂缝,形成诱导裂缝,这与水力裂缝不同,因为水力裂缝中填充了支撑剂,而诱导裂缝中没有填充支撑剂。天然裂缝通过注水连接。但由于水驱压力有限,诱导裂缝不能贯穿整个储层,而是在垂向上形成多条平行的诱导裂缝带。目前,采用常规的有限导流率方法拟合现场数据,会得到不合理的结果,尤其是裂缝半长、导流率、储层渗透率等数据,导致无法及时发现水侵。本文提出了考虑诱导裂缝动态闭合(IDC)、诱导裂缝动态储存(DIS)和诱导裂缝径向流动(IRF)效应的水驱诱导双层裂缝(WIBF)模型。解释了两种创新的流动形式,即动态诱导裂缝流动和早期径向流动。在WIBF模型中引入了五个创新参数来描述IDC、DIS和IRF效应。利用格林方程和纽曼乘积法对WIBF模型进行了计算和求解。推导了诱导裂缝储存系数和半长度闭合方程,以表征其独特的诱导裂缝性质。分析和数值方法验证了模型的准确性。通过对一个类型域实例的匹配,验证了该模型的实用性。结果表明,与常规有限电导率模型相比,该模型与现场情况吻合较好,解释参数与注水剖面和现场实际资料吻合较好。压力导数曲线呈现一条较早的水平线,为双层裂缝的压力响应。如果流型被错误地识别为伪径向流动,则得到的一些参数将是荒谬的,渗透率将被放大许多倍。总之,建立了描述诱发裂缝的物理和数学模型。推导了诱导裂缝储存系数和半长方程。模型匹配和方程计算方法相互验证,提高了所得参数的精度。对动态诱导裂缝半长进行定量解释,使工程师在水侵前采取措施。该模型还为合理合理地充填井网或确定井距提供了一些参数。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Evaluation of Effects of Waterflooding-Induced Bilayer Fractures on Tight Reservoir Using Pressure-Transient Analysis Method
Waterflooding will open natural fractures to form induced fractures, which differ from hydraulic fractures because the hydraulic fracture is filled with proppant but the induced fracture is not. Natural fractures are connected by waterflooding. However, because the waterflooding pressure is limited, induced fractures cannot run through the entire reservoir but instead form multiple parallel induced-fracture bands in the vertical direction. Currently, using conventional finite-conductivity methods to match field data will obtain unreasonable results, especially the half-length, conductivity of fracture, and reservoir permeability, which lead to the water breakthrough, which cannot be found in time. This paper presents the waterflooding-induced bilayer fracture (WIBF) model, considering induced-fracture dynamic closure (IDC), dynamic induced-fracture storage (DIS), and induced-fracture radial flow (IRF) effects. Two innovative flow regimes are interpreted, which are dynamic induced-fracture flow and early radial flow regimes. Five innovation parameters are introduced into the WIBF model to describe the IDC, DIS, and IRF effects. The WIBF model is calculated and solved by the Green equation and Newman product methods. Induced-fracture storage coefficient and half-length closure equations are derived to characterize the unique induced-fracture properties. Analytical and numerical methods verify the model’s accuracy. The WIBF model matches a type field case to prove its practicability. Results show that compared with the conventional finite-conductivity model, the proposed model matches the field case well and the interpreted parameters are consistent with the water injection profile and actual field data. The pressure derivative curve shows an early horizontal line, identified as a pressure response of bilayer-induced fractures. If the flow regime is misidentified as pseudoradial flow, some obtained parameters will be absurd, and permeability will be amplified many times. In conclusion, physical and mathematical models are established to describe induced fracture. Induced-fracture storage coefficient and half-length equations are derived. Model matching and equation calculation methods are mutually validated to improve the accuracy of the obtained parameters. Dynamic induced-fracture half-length is interpreted quantitatively to make the engineer take action before the water breakthrough. The model in this paper also provides some parameters for infilling well patterns or determining well spacing economically.
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来源期刊
CiteScore
5.30
自引率
0.00%
发文量
68
审稿时长
12 months
期刊介绍: Covers the application of a wide range of topics, including reservoir characterization, geology and geophysics, core analysis, well logging, well testing, reservoir management, enhanced oil recovery, fluid mechanics, performance prediction, reservoir simulation, digital energy, uncertainty/risk assessment, information management, resource and reserve evaluation, portfolio/asset management, project valuation, and petroleum economics.
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