Cuttings Transport Models and Experimental Visualization of Underbalanced Horizontal Drilling

Wei, Na; Meng, YingFeng; Li, Gao; Wan, LiPing; Xu, ZhaoYang; Xu, XiaoFeng; Zhang, YuRui

doi:https://doi.org/10.1155/2013/764782

Mathematical Problems in Engineering

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Recent Advances on Methods and Applications of Nonlinear Differential Equations

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Research Article | Open Access

Volume 2013 | Article ID 764782 | https://doi.org/10.1155/2013/764782

Cuttings Transport Models and Experimental Visualization of Underbalanced Horizontal Drilling

Na Wei,¹YingFeng Meng,¹Gao Li,¹LiPing Wan,¹ZhaoYang Xu,¹XiaoFeng Xu,²and YuRui Zhang¹

Academic Editor: Guo-Cheng Wu

Received11 Apr 2013

Revised22 Jun 2013

Accepted25 Jun 2013

Published24 Jul 2013

Abstract

Aerated underbalanced horizontal drilling technology has become the focus of the drilling industry at home and abroad, and one of the engineering core issues is the horizontal borehole cleaning. Therefore, calculating the minimum injection volume of gas and liquid accurately is essential for the construction in aerated underbalanced horizontal drilling. This paper establishes a physical model of carrying cuttings and borehole cleaning in wellbore of horizontal well and a critical transport mathematical model according to gas-liquid-solid flow mechanism and large plane dunes particle transport theory.

1. Introduction

With the development of horizontal drilling oriented technology and thin formation of oil and gas reservoirs, aerated underbalanced horizontal drilling technology has become the focus of the drilling industry at home and abroad, and one of the engineering core issues is the horizontal borehole cleaning when gas-bearing mud exists [1–3]. Therefore, calculating the minimum injection volume of gas and liquid accurately is essential for the construction in aerated underbalanced horizontal drilling. To calculate the required minimum injection volume of gas and liquid accurately which can safely carry cuttings, it is necessary to carry out the researches of carrying cuttings theory and visualization experiment of particle motion in depth.

2. Transport Law Analysis of Cuttings in the Horizontal Wellbore

2.1. Particularity of Cuttings Transport in Horizontal Well

The cuttings’ distributions in horizontal section and vertical section are shown in Figures 1 and 2. When the rock is broken by bit, the large particle cuttings can transport smoothly at drill collar because of the high flow rate, but when they reach the drill collar and drill pipe junction large particle cuttings are accumulated due to the annulus area sudden increase. Contrasting vertical section and horizontal section [4, 5], we can find that in vertical section the larger cuttings will fall to the bottom of the well then be repeatedly broken, but in horizontal section once the large cuttings are produced which the fluid cannot carry, these cuttings will only stay at the lower side of the wall waiting for drill tool rolling until forming small particles to be carried by fluid to downstream.

2.2. Horizontal Well Cuttings Movement Form

In horizontal well cuttings transportation can be divided into suspension, rolling, and saltation.

2.2.1. Suspension

Suspension is an important way of cuttings movement. The form of the suspension is drift with drilling fluid. In suspension there are two kinds of force, one is gravity which makes cuttings settle down to the lower side of the wall and another kind is gas-liquid two-phase flow driving force which makes cuttings particle move to downstream along the wellbore. The speed of cuttings moving to downstream is related to the speed of gas-liquid two-phase flow, the transportation volume of cuttings can indirectly represent the speed of cuttings moving to downstream, and the greater the flow, the more it carried cuttings. In settling process suspended particles are brought back to the top by eddy current that makes the cuttings drift up and down. As a result, the settling velocity becomes slow. Suspension of cuttings schematic diagram is shown in Figure 3.

2.2.2. Rolling

When flow drag force is greater than particle resistance, the particles located in the surface outstanding position of cuttings bed begin to move in the form of slipping. Because of the rough wall surface, slipping often converts into rolling and the cuttings always keep contact with the lower side of the wall, the force as shown in Figure 4 and cuttings rolling schematic diagram as shown in Figure 5.

2.2.3. Saltation

When the jumping cuttings fall to the lower side of the wall, it will impact the cuttings bed, and the force is related to the jump height and drilling fluid velocity [6–8]. If the cuttings jump low, the momentum obtained from the fluid is small and they will stop jumping. If not, they will jump again. The jumping height is inversely proportional to the drilling fluid density. This special movement is called saltation, cuttings saltation force as shown in Figure 6.

3. Carrying Cuttings Model of Multiphase Flow in Horizontal Well Annulus

3.1. Cuttings Rolling

When cuttings are based on single particle rolling on the lower side of the wall, with the effect of the gas-liquid two-phase flow, they transport to the downstream [9].

3.1.1. Cuttings Particle Rolling Force Analysis

When the gas-liquid flow rate is small, the particles first roll in single in the wall, and the forces include: drag force produced by air current, friction force along the contact surface between the particle and the wall, gravity , buoyancy , and support on longitudinal, as shown in Figure 4.

3.1.2. Cuttings Particle Rolling Starting Condition

It is necessary to build a horizontal mathematical equation to determine the minimum gas liquid volume when single particle cuttings roll forward [10]: where is resistance coefficient, dimensionless; is fluid density, kg/m³; is fluid velocity, m/s; is cuttings particle diameter, m; is friction resistance coefficient, dimensionless; is cuttings particle gravity, N; is liquid phase flow rate, m³/s; is gas phase flow rate, m³/s; is flow area, m².

The minimum velocity can be derived from the different particle gravity and different materials friction resistance coefficient .

3.2. Cuttings Saltation

3.2.1. Cuttings Particle Rolling Force Analysis

When cuttings transport in the annulus, the forces mainly include gravity, resistance, the saffman lift force, buoyancy, basset force, pressure gradient force, added mass force and magnus effect force in underbalanced drilling [11, 12]; force analysis is as shown in Figure 7. In the horizontal section, cuttings gravity is the main force to constitute horizontal friction resistance, and the calculation formula is where is cuttings particle gravity, N; is cuttings particle density, kg/m³; is cuttings particle volume, m³; is gravity acceleration coefficient, m/s².

The driving force of the cuttings is mainly gas-liquid two-phase dragging force. The dragging force is influenced by many factors like the Reynolds number, cuttings size, cuttings shape, flow state, and fluid compressibility [13, 14]. Its direction is consistent with the speed of fluid relative to the particles, and the calculation formula is where is dragging force, N; is dragging coefficient, dimensionless; is fluid velocity, m/s; is cuttings particle transport velocity, m/s; is cuttings particle diameter, m.

3.2.2. Cuttings Particle Rolling Starting Condition

Cuttings particle group located in cuttings bed and flow boundary presents a state of bulk material accumulation [15]. The bulk materials limit equilibrium equation of cuttings particles can be signified as follows: where is the ultimate shear force making the particle moves, N; is internal force effecting on the particle, N; is internal friction coefficient of bulk material accumulation, dimensionless; is unit cohesion, N/m²; is flow area, m².

According to the force analysis of cuttings particles as shown in Figure 8, ignoring cohesive force and buoyancy [16], the accumulation particles limit force balance equation can be deformed into where , .

can be determined by experiment. In general, is a function of void fraction of particle group , given as where is void fraction of particle group, dimensionless; , is parameters related to cuttings accumulation degree, dimensionless; is internal friction coefficient of particles, dimensionless.

When saltation starts, force balance formula can be derived by combining formula (2), (3), and (6) as follows: where is fluid flow velocity under granular limit balance state; when continues to increase, the balance will be broken and cuttings will begin to transport, m/s.

4. The Visualization Experiment of Horizontal Section

This study establishes an annulus visualization organic glass experimental facility (total length 25 m, experimental annulus outer tube and inner diameter 140 mm, inner tube outer diameter 63 mm, inner tube inner diameter 55 mm), which uses compressed air and water as experiment flow and simulation cuttings (equivalent diameter 6 mm) as experiment medium, developing critical carrying cuttings in different liquid injections and tests the hydrodynamic parameters. Then we can get borehole cleaning critical carrying cuttings data in different experiment conditions.

4.1. Experiment Research Content

(1)Simulation of multiphase flow and carrying cuttings large bench in horizontal section (simulation of the rotating drill pipe in rotary drilling)(2)Simulation of multiphase flow and carrying cuttings large bench in horizontal section (simulation of the slide drilling and circulation after stopping drilling).

4.2. Experimental Facilities

Experimental facilities which simulate air flow condition at certain range of pressure and flow rate down the hole include experimental bench, air compressor, gas tank, water tank, liquid pump, and flow meter, as shown in Figure 8. Experiment testing part is monitoring and recording pipe section pressure, gas flow rate, liquid flow rate, image of the phenomenon, and so forth.

4.3. Experiment Process

The simulation cuttings are injected in different speeds at the bottom, maintaining a certain amount of gas injection and then increasing the liquid injection (liquid injection can be controlled from 0~5 L/s) until the cuttings are suspended in the experiment pipe section; at this time the gas flow rate is considered as the critical flow rate. The liquid flow rate was ratcheted up after injecting the liquid for 2 minutes steadily, and the experiment was stopped until the cuttings of the bottom are carried out completely. The test parameters include liquid injection, gas injection, liquid flow velocity, cuttings velocity, and cuttings concentration. Flow pressure is controlled from 0.1 MPa to 0.6 MPa throughout the experiment.

4.4. Experiment Phenomena

(1)When the drill string is rotating, experiment phenomena are shown in Figures 9 and 10.(2)When the drill is immovability, experiment phenomena are shown in Figures 11, 12, and 13.

Through the observation, comparing with the drill which is immovability, when the drill string is rotating it has a viscous impact on the surrounding drilling fluid due to its viscosity, and then cuttings on the cuttings bed are agitated, so the effect of carrying cuttings is better in conditions of injecting the same volume of gas. The way of cuttings transport is mainly saltation.

4.5. Experimental Data and Processing Results

(1)When the drill string is rotating, calculation results in different injecting volumes of gas and liquid (see Table 1).(2)When the drill is immovability, calculation results in different injecting volumes of gas and liquid (see Table 2).

Through the previous experimental data and phenomena, comparing with the drill which is immovability, the drill rotating can make the water acts as the simulation drilling fluid moving in spirals and the pressure of annular flow field distributing in fluctuation forms. At the same time, when the drill string is rotating it will have a viscous impact on the surrounding drilling fluid due to its viscosity, and then cuttings on the cuttings bed are agitated, so the effect of carrying cuttings is better in conditions that injecting the same volume of gas.

5. Model Modification

5.1. Critical Carrying Cuttings Mathematical Model Modification in Horizontal Well (Rotation)

From the result of experimental data, the real minimum continuous carrying cuttings comprehensive speed is the equal of 124% of saltation critical velocity as a modification model, given as where , stratified flow is , and turbulent (slug flow, agitation flow, and annular mist flow) is where is internal friction coefficient of particles, dimensionless; , are parameters related to cuttings accumulation degree, dimensionless; is gas-liquid interface friction coefficient, dimensionless; is stress between mixture and wall shear, Pa; is mixture real density, kg/m³; is gas-liquid mixing velocity, m/s; is drag coefficient, dimensionless, function of Re; is cuttings particle transport velocity, m/s; is cuttings particle diameter, m; is cuttings particle density, kg/m³; is the Reynolds number; is pipe diameter, m.

5.2. Critical Carrying Cuttings Mathematical Model Modification in Horizontal Well (Immovability)

From the result of experimental data, the real minimum continuous carrying cuttings comprehensive speed is the equal of 124% of saltation critical velocity as a modification model when the drill is rotating, namely, where , stratified flow is , and turbulent (slug flow, agitation flow, and annular mist flow) is

6. Conclusions

(1)Comparing vertical section and horizontal section, in vertical section the larger cuttings will fall to the bottom of the well repeatedly broken, but in horizontal section once the large particle cuttings are produced which the fluid cannot carry, these cuttings will only stay at the lower side of the wall waiting for drill tool rolling until forming small particles to be carried by fluid to downstream. (2)In horizontal section cuttings transport depending on gas-liquid comprehensive velocity and drilling fluid viscosity is mainly saltation, and the drill rotation benefits cuttings transport. In the condition of carrying cuttings smoothly, when the drill is immovability the comprehensive velocity is 1.18 times as big as when it is rotating. After processing the experimental data, the established mathematic model is modified.

Acknowledgments

The authors are grateful for the support of Open Fund of State Key Laboratory of Oil and Gas Geology and Exploration, Southwest Petroleum University (Transient flow behavior of the wellbore under condition of circulation cease in MPD, Grant no. PLN1309), National Natural Science Foundation of China (The wellbore flow model of liquid-based whole process underbalanced drilling, Grant no. 51204140, Formation evaluation theory research based on monitoring while underbalanced drilling, Grant no. 51104124 and Basic research on gas drilling, Grant no. 51134004), the Major State Science and Technology Special Project of China (Narrow density window of drilling technology and supporting equipment safety, Grant no. 2011ZX05021-003), National 973 Project of China (Safe and efficient drilling deep complex formation of basic research, Grant no. 2010CB226700), Sichuan Provincial Education Department Research (MPD stop cycle continuous flow of gas invasion transient wellbore, Grant no. 13ZB0189) and Features Leading Academic Discipline Project Funded Science Foundation Young Teacher (Whole process of underbalanced drilling wellbore flow model).

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Copyright © 2013 Na Wei et al. This is an open access article distributed under the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

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