Production Analysis of Horizontal Wells in a Two-Region Composite Reservoir Considering Formation Damage

Abstract

The horizontal well is extensively used to exploit oil at the Bohai offshore oilfield, China. It has been proved by practice that formation damage always happens during the production of wells. However, it is a challenging task to evaluate the formation damage for horizontal wells. In this paper, a flow model considering formation damage is established for horizontal wells. The reservoir geometry is divided into two regions: the inner region represents the region of formation damage and the outer region that without damage. The finite element method is used to solve the flow model. The well production rate can be determined by using the material balance method. For different scenarios, such as when the horizontal well is completely in the inner region or when the horizontal well passes through two regions, the effects of some key parameters such as damage radius, damage region permeability, and well position on the oil production rate and pressure distribution characteristics are analyzed. The results show that a smaller damage radius, higher damage zone permeability, and a horizontal well closer to or in greater contact with the outer region result in a higher oil production rate and faster pressure drop propagation. The presented model and obtained results enrich production analysis of horizontal wells in a two-region composite reservoir considering formation damage, which has significance for efficient offshore reservoir development.

Introduction

Formation damage is a condition most commonly caused by wellbore fluids used during drilling, completion, and workover operations (Krueger, 1988; Civan, 2015; Xu et al., 2016). It impairs the permeability of reservoir rocks, thereby reducing the natural productivity of reservoirs (The Defining Series: Formation Damage, Schlumberger, slb.com). Before drilling the reservoir, the rocks, clay minerals, and fluids are at an equilibrium. After opening the reservoir, the original equilibrium state is broken due to the external fluid, which will harm the oil and gas reservoir and reduce the production capacity of oil and gas. Changes in the physical and chemical properties of rocks and fluids in the formation are the most fundamental causes of formation damage. The categories of formation damage mechanisms can be divided into mechanical, chemical, biological, and thermal.

Field development practice on onshore oilfields indicates that formation damage can lead to low production efficiency for wells, and the effect of formation damage on reservoir properties and well performance should be carefully evaluated. Shen et al. studied the effects of key reservoir and production parameters (matrix porosity and permeability, fracture porosity and permeability, Langmuir pressure and volume, diffusion coefficient, shut-in time, drawdowns, and injection rate) on the process of water retention and gas production in the shale gas reservoirs (Shen et al., 2016). Zhang et al. investigated the effects of the related reservoir properties and production parameters on the characteristics of effective reserve utilization in tight sandstone reservoirs, which provide a better understanding of reservoir pressure distribution and effective utilization of reserves to optimize the gas recovery and development (Zhang et al., 2020).

Commonly, transient pressure responses and rate decline analysis are applied to inverse the formation parameters such as skin factor, damage zone radius, and damage zone permeability. As the parameters in the damaged zone and undamaged zone are always different, a composite reservoir model must be established. A large number of previous studies have focused on the curves type of horizontal wells. In 1973, Gringarten and Ramey proposed source function and green function methods which are used as powerful tools in solving unsteady flow problems for horizontal wells (Gringarten and Ramey, 1973). Clonts and Ramey presented an analytical solution for a uniform flux horizontal drainhole in an anisotropic reservoir (Clonts and Ramey, 1986). Log-log type curves are presented for various drainhole radii and can be used to determine reservoir parameters such as permeability or drainhole half length. Goode and Thambynayagam proposed an analytical solution by solving the three-dimensional diffusion equation with successive integral transforms for the pressure response during drawdown and buildup of a horizontal well (Goode and Thambynayagam, 1987). Daviau et al. (Daviau et al., 1988) proposed a new solution to analyze the pressure response by semi-log and log-log curves. They found that a circular radial flow will happen in early time and a horizontal pseudo-radial flow will happen in late time. Then, Ozkan and Raghavan (Ozkan and Raghavan, 1991a; Ozkan and Raghavan, 1991b; Ozkan, 1994) proposed a new source function approach to study transient pressure behaviors of different well patterns, such as those of vertical wells and horizontal wells, in various reservoirs. This method remains one of the primary solving methods in the performance analysis family. Park and Zhan simplified the horizontal well into a line source and analyzed the wellbore storage and skin effect (Park and Zhan, 2002). Ezulike and Igbokoyi achieved a three-dimensional point source semi-analytical solution in composite reservoir systems (Ezulike and Igbokoyi, 2012). Shi et al. (Shi et al., 2012) developed the well test model for horizontal wells in a two-zone composite reservoir and presented the field interpretation example. Nie et al. established a new transient well test and rate decline analysis model for a horizontal well in multiple-zone composite reservoirs. The negative skin is considered in their model (Nie et al., 2011). Zhao et al. established a composite model to describe the stimulated reservoir volume for multiple hydraulic fractured horizontal wells (Zhao et al., 2014). Yuan et al. (Yuan et al., 2018) proposed a semi-analytical solution for well pressure transient analysis and transient rate analysis of multistage fractured horizontal wells in composite reservoirs in which two regions with different formation parameters are considered. By now, the semi-analytical methods have been widely used for transient pressure responses and rate decline analysis in unconventional oil and gas reservoirs (Jiang et al., 2014; Xu et al., 2015; Zeng et al., 2015; Zhang et al., 2016; Ren and Guo, 2017; Zhao et al., 2018; Zhang et al., 2019; Yao et al., 2020).

To the best of our knowledge, although it has been decades since people started studying well performance analysis theories of horizontal wells, there exists a little model that can successfully calculate the performance behavior for reservoirs with formation damage. In this paper, the composite reservoir model is extended to evaluate the formation damage effect on well production. The mathematical equation is derived for the inner region and outer region. The inner region characterizes the damaged zone. The damaged zone can have an irregular boundary. To solve the flow model, the finite element method is employed. The horizontal well production rate is calculated by using the material balance method. The effect of damage radius, damage region permeability, and well position on oil production rate is analyzed.

The paper is organized as follows: section 1 is the introduction; section 2 is the mathematical model; section 3 is the solution workflow; section 4 is the sensitivity analysis.

System Description

Physical Model

The schematic diagram for a horizontal well in a composite reservoir is shown in Figure 1. The reservoir has two regions, the inner and outer region, each of which have different reservoir properties. The model assumptions are as follows: 1) the interface between the inner region and outer region is irregular (commonly, the inner region can be assumed to have a circular shape and the radius can be assumed to be r₁); 2) the reservoir is horizontal with a uniform thickness of h and original pressure pi; 3) for the inner region, the horizontal permeability is K_h1, the vertical permeability is Kv1, the compressibility C_t1, and the porosity is φ₁ while for the outer region, they are K_h2, K_v2, C_t2, and φ₂, respectively; 4) the influence of gravity and capillary forces is ignored. In this paper, assuming that the inner region is the damage region, we considered the scenario when the horizontal well is entirely in the inner region (Figure 1A) and when the horizontal well passes through two regions (Figures 1B,C).

FIGURE 1

Mathematical Model

With an orthogonal coordinate system, the flow equation can be expressed as follows:

The flow equation in the inner region is

The flow equation in the outer region is

If the sink or source is ignored, Eqs. 1, 2 can be simplified into the following:

The flow equation in the inner region is

The flow equation in the outer region isWith initial conditionand outer boundaryand interface condition

Here, x, y, and z are the directional coordinates, m; r is the radial distance from the origin of a point in the XY plane; L is the well length, m; k₁ and k₂ are the permeability in inner and outer regions, respectively,m²; p_1,2 are reservoir pressure in inner and outer regions, respectively, Pa; p_i is reference pressure, Pa; μ is viscosity, Pa·s; t is time, sec; C_t is the compressibility factor, 1/Pa; and φ_1,2 are the formation porosity in inner and outer regions, respectively, fraction.

Model Solution

Solution Method

In this study, we use the finite element method to solve the equation system. The basic function is defined as follows:

The displacement function is

We can get the integrating form for the inner region and outer region:

The final equation form is as follos:

Material Balance Method

Combined with the natural energy production calculation formula, the finite element numerical method is used to solve and analyze the oil production rate under different damage degrees in the process of oilfield development. Natural energy production means the volume of fluid displaced by natural energy due to pore compression and liquid expansion.

Oil production of reservoir driven by natural energy can be obtained from the following formula:

The finite element numerical solution method introduced in Section 3.1 can obtain the pressure values of each position in the composite reservoir at each time. However, because the pressure values at different positions in the composite reservoir are not equal at different times, volume integration is performed over the entire reservoir. The production rate considering formation damage can be obtained by the following formula:Where △V is the reserves, m³; C_t is the comprehensive compressibility, 1/Pa; V_f is the composite reservoir volume, m³; p_i is the original pressure of reservoir, Pa; p_b is reservoir saturation pressure, Pa; N_p is the cumulative oil production corresponding to the total pressure drop, m³; p_t is the pressure at a certain position in the reservoir at time t, Pa; p_w is bottom hole pressure, Pa; φ are the formation porosity; C_f is the formation fluid compressibility, 1/Pa; and C_l is the formation rock compressibility, 1/Pa.

Discussion and Analysis

Typical Transient Pressure Distribution and production Rate Decline Curve

Figures 2A–C shows the typical transient pressure distribution of horizontal well in the inner region, horizontal well passing through two regions on both sides and horizontal well passing through two regions on single sides, respectively. The transient pressure profiles of the three typical cases describe the pressure distributions at different times in the three typical cases. By comparison, the pressure drops when the horizontal well passing through two regions on a single side propagates faster. Figure 3 shows the production rate decline curves for the above three cases. As shown in Figure 3, the oil production rate of the horizontal well entirely in the inner region is basically lower than that of the other two scenarios. The reason for this is that the permeability of the inner region is lower than that of the outer region, whereas when a horizontal well is entirely in the inner region, the pressure drop propagation is more affected by the damage of the inner region and becomes slower.

FIGURE 2

FIGURE 3

Effects of Different Parameters

In this section, the effects that various reservoirs parameters have on the performance (transient pressure distribution and production rate decline performance) of a composite reservoir described mathematically in the previous section are discussed. The effects of damage radius, damage region permeability, and well position on oil production rate are discussed for the scenario when the horizontal well is entirely in the inner region (Figure 1A) and when the horizontal well passes through two regions (Figures 1B,C).

FIGURE 4

FIGURE 5

FIGURE 6

FIGURE 7

FIGURE 8

FIGURE 9

FIGURE 10

FIGURE 11

FIGURE 12

Conclusion

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