Forecasting Long-Term Gas Production of Dewatered Coal Seams and Fractured Gas Shales

Spivey, J.P.; Semmelbeck, M.E.

doi:10.2118/29580-ms

Cited by 37 publications

(15 citation statements)

References 9 publications

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“…The most recent efforts to accurately analyze production data analytically come from Spivey and Semmelbeck (1995) and Clarkson et al (2007). Spivey and Semmelbeck (1995) used a numerical reservoir simulator to demonstrate the behavior of coalbed methane and shale gas reservoirs. Their model is simply a high porosity fracture sandwiched between two low k φ "matrix" layers (i.e.…”

Section: Spivey and Semmelbeckmentioning

confidence: 99%

Production Data Analysis of Shale Gas Reservoirs

Lewis

Hughes

2008

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Unconventional shale gas reservoirs have become a very important part of the resource base throughout the world, but especially in the United States. Production data analysis techniques using various forms of material balance time originally put forth by Palacio and Blasingame (1993) have been proposed and validated in recent publications for a variety of problems (including shale gas and coalbed methane systems) using an adjusted system compressibility function similar to that proposed by Bumb and McKee (1988) to account for adsorbed gas. These modified material balance solutions allow for "type curves" (rate or pressure solutions) to be used in a conventional analysis manner. The significant challenge in the application of production data analysis for shale gas systems is to determine what the parameter values (analysis results) represent within the context of the inherent complexity of these systems. In this work we propose a slight (but substantive) modification to material balance time and apply the technique to synthetic and field data to assess the capability of this approach for the analysis of production data from gas shales. The formulation we use is that of Cox, et al. (2002) which provides a means for evaluation production data as an equivalent "well test", where we are able to observe characteristic flow regimes in the data and constrain several of the key parameters of interests in shale gas systems. While the field results are difficult to corroborate, the relative magnitudes of the parameters we obtained appear to be reasonable. Introduction The vast majority of gas production in the United States comes from what are known as conventional hydrocarbon reservoirs. However, these conventional reservoirs are becoming increasingly difficult to find and exploit. In an era of rising prices for crude oil and natural gas, the ability to produce these commodities from unconventional reservoirs becomes very important. The United States Geological Survey states that, among other things, an unconventional reservoir must have regional extent, very large hydrocarbon reserves in place, a low expected ultimate recovery, a low matrix permeability and typically has a lack of a traditional trapping mechanism (Schenk, 2002). In particular, shale gas reservoirs present a unique problem to the petroleum industry in that they may contain natural gas in the pore spaces of the very tight reservoir rock, in the pore spaces of natural fractures in the formation and on the surface of the rock grains themselves which is referred to as adsorbed gas (Montgomery, et al., 2005). This sorbed gas presents difficulties in that desorption time, desorption pressure, and volume of the adsorbed gas all play a role in how this gas affects the production of the total system. Adsorption can allow for significantly larger quantities of gas to be in place and possibly produced. Historically, the first commercially successful gas production in the U.S. came from what would now be considered an unconventional reservoir in the Appalachian Basin in 1821. Currently, some of the largest gas fields in North America are unconventional, shale gas reservoirs such as the Lewis Shale of the San Juan Basin, the Barnett Shale of the Fort Worth Basin, and the Antrim Shale of the Michigan Basin. In addition, gas production from unconventional reservoirs accounts for roughly 2% of total U.S. dry gas production (Hill, et al., 2007). Shale gas reservoirs present numerous challenges to analysis that conventional reservoirs simply do not provide. The first of these challenges is the dual porosity nature of these reservoirs. Similar to carbonate reservoirs, shale gas reservoirs almost always have two different storage volumes for hydrocarbons, the rock matrix and the natural fractures (Gale, et al., 2007). Because of the plastic nature of shale formations, these natural fractures are generally isolated or closed due to the pressure of the overburden rock (Gale, et al., 2007). Consequently, their very low matrix permeability, usually on the order of hundreds of nanodarcies (nd), makes un-stimulated, conventional production difficult, if not impossible. Therefore, almost every well in a shale gas reservoir must be hydraulically stimulated (fractured) to achieve economical production. These hydraulic fracture treatments are believed to re-activate and re-connect the natural fracture network (Gale, et al., 2007).

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Section: Spivey and Semmelbeckmentioning

confidence: 99%

Production Data Analysis of Shale Gas Reservoirs

Lewis

Hughes

2008

All Days

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“…然而, 绝大部分的煤层气藏具有低渗特征, 储层内部的流体饱和度分布不能被忽略. 考虑应力敏感与基质收缩效应, Spivey和Semmelbeck [18] 通过物质守恒原理建立产能预测模型, 但该模型采用的是平均含水饱和度概念, 不能描述储层饱和度分布. Xu等人 [19] 提出一种能简单预测煤层气井解吸区扩展规律的半解析模型, 考虑了不同生产阶段储层内部的压力展布, 但忽略了储层单元内流体饱和度分布.…”

Section: Clarkson模型仅能适用于煤层气井的生产早期和晚期unclassified

A mathematic model for characterizing the relationship between coal reservoir pressure and fluid saturation

Sun¹,

Li²,

Xu³

et al. 2018

Sci. Sin.-Tech.

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“…(Gerami et al, 2007) illustrated, through mathematical derivation, that the solution to flow equation for gas reservoirs could be extended to CBM reservoirs if the definition of total compressibility is modified to include sorption compressibility. The same concept, with no mathematical derivation, was previously suggested by Spivey and Semmelbeck (Spivey and Semmelbeck, 1995) and Clarkson et al (Clarkson et al, 2006). As such, total compressibility as defined in Equation (12) was further modified to: c t ¼ c f þ s w c w þ s g c g þ c d (14) Sorption compressibility, similar to gas compressibility, is a strong function of pressure and becomes increasingly more important as reservoir pressure declines.…”

Section: Type Curve Matchingmentioning

confidence: 99%

Selected topics in coalbed methane reservoirs

Morad

2012

Journal of Natural Gas Science and Engineering

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Forecasting Long-Term Gas Production of Dewatered Coal Seams and Fractured Gas Shales

Cited by 37 publications

References 9 publications

Production Data Analysis of Shale Gas Reservoirs

Production Data Analysis of Shale Gas Reservoirs

A mathematic model for characterizing the relationship between coal reservoir pressure and fluid saturation

Selected topics in coalbed methane reservoirs

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