Impact of Gas Lift Design in Unconventional Wells - A Delaware Basin Operator's Perspective

As a common occurrence in production operations, liquid-rich horizontal gas (and gassy oil) wells in unconventional plays develop severe instabilities at different stages of their well life. In this novel work, we first quantify the three-phase gas-oil-water multiphase flow behavior leading up to the characteristic severe loading signatures in order to better understand the dynamic heel-dominant liquids loading. Then, we demonstrate how a simple analytical diameter-and-inclination-dependent critical gas velocity equation can be used to determine the onset of the severe loading instabilities in a variety of artificial lift/liquid loading mitigation strategies, namely end-of-tubing landing (EOT), tubing/casing sizing, gas lift variations and tail pipe/dip tube. Actual high frequency bottom hole pressure data along with measured surface conditions will be used to evaluate the slugging behavior and recreate using analytical multiphase flow simulator. The flow conditions will be extrapolated to the heel/near lateral section of the well and simulated for various lift strategies.

Understanding Heel Dominant Liquid Loading in Unconventional Horizontal Wells

Kannan¹,

Nagoo²,

Lea³

2019

Intelligent Gas Lift Compressor Adjust Injection With Dynamic Conditions

Munding¹,

Hudson²,

Karami

2020

Approximately 40% of unconventional wells in the United States with artificial lift are using gas lift. One of the blessings of gas lift is that it is very forgiving and rarely fails. This has led some operators to the conclusion that gas lift doesn’t require a proper control and optimization scheme. The objective of this study is to use field data and show the importance and benefit of a controlled and optimized gas lift compressor to aid production. The intelligent gas lift compressor utilizes a heavy computational process of taking a composite Vogel reservoir inflow model coupled with a Hagedorn & Brown outflow model that informs the Guo model to solve for a minimum critical rate to lift liquid droplets out of the wellbore. First, an empirical range of injection rates is used to find the rate with maximum unloading as indicated by a drop in casing injection pressure. Once this rate is found, reservoir inflow performance relationship (IPR) parameters are estimated to meet that condition. These parameters are held constant for a time period and injection rate needed is calculated based on production rate and pressure coming into the programmable logic controller (PLC) via digital connections. This approach is tested on a well and the production is monitored over a 3-month period. The collected data are used to analyze the benefits of an intelligent gas lift compressor control. The data from a well with this intelligent gas lift system is monitored over a 3-month period. This includes a 20-day period of the compressor searching for an injection rate that shows to be the most efficient. Then the compressor control is set up with a critical rate control mode. This calculation is performed with an edge server that runs the intense calculations every minute to instruct the compressor what volume of injection it needs to achieve manipulation of an automated suction control valve and speed control of the engine driver. The surface casing pressure data shows a very stable unloading behavior profile, which is confirmed with very stable oil and gas production data over the observation period. An estimate of gained production during the periods of high line pressure along with stable unloading is given as the justification for outfitting the well site with the intelligent compressor controls. Despite gas lift’s importance as a lift technique, its control and optimization are still not properly addressed within the industry. This work’s proposed intelligent gas lift scheme can be a potentially valuable solution to unstable unloading of liquids, and benefit the operators significantly in production and revenues.

Will Gas Lifting in the Heel and Lateral Sections of Horizontal Wells Improve Lift Performance? The Multiphase Flow View

Nagoo¹,

Vangolen

2020

The purpose of this paper is to highlight the results of a comprehensive investigative study that quantifies the multiphase flow-related differences in multiphase hydrostatic pressure gradient, oil holdup and gas velocities as the gas injection depth is lowered from vertical to higher angles along the heel and into the lateral sections of horizontal wells. The results of this work enable a deeper understanding of gas slippage under gas lift operation at high angle sections of horizontal wells. When used for optimizing horizontal well liquids unloading, gas lift valves are placed as low in the well as operationally allowable. But what happens if gas lift is applied along the bend or lateral? To help address this important question, we first leverage the vast knowledge gained from the inclined multiphase flow literature. The scientific knowledge base for up/down inclined multiphase flows reveals why such behaviors in laterals are so complex, namely, the extreme slip effects that exist. In this work, we start with selecting published lab experiments in this area, and then simulate their flow behaviors using an advanced, cutting-edge analytical multiphase flow simulator. Next, we extend our validation to the field-scale using actual horizontal well gas lift field datasets sourced from different unconventional shale oil plays. With this detailed flow modeling substantiated, we then conduct the principal investigation of this work by quantifying the horizontal well gas lift performance at various representative inclinations (0, 30, 60, 88, 90 and 92 degrees from vertical) to better understand how changes in four major sensitivity variables, namely, diameter, gas injection rate, total liquids rate and water cut, impact the effectiveness of the gas lift process. Then, for each of these sensitivities and at each inclination, we analyze and compare the difference in value (value before gas lift - value after gas lift) of the multiphase hydrostatic pressure gradient, oil holdup, wellbore gas velocity and critical gas velocity. A new learning from this work is that the prior vertical well experience and basis for gas lift being more effective at deeper depths does not translate to horizontal wells. The experience-driven industry viewpoint that gas lift is unaffected by inclination is not supported by both controlled inclined flow loop lab data and horizontal well field data. From the multiphase view, gas lift optimization is governed by the slip behaviors and it is demonstrated in this work that the multiphase hydrostatic pressure gradient reduction will be much lower at horizontal well inclinations of greater than 45 degrees from vertical, meaning the gas lift technique becomes less effective at these higher inclinations deep in the heel and lateral regions. Our results show that in this latter scenario, most of the gas will slip past the liquids, and increasingly so at higher angles (the pipe acts as a separator at these higher angles) and the effectiveness of the gas lift significantly lowers as the flow starts to undergo slugging and other high-slip transitional flow patterns. This has a significant practical impact to operators trying to optimize end-of-tubing (EOT) placement in conjunction with the gas lift lowest valve placement. Summarily, the results from our detailed modeling are used to demonstrate what is and what is not possible in terms of liquids evacuation from horizontal wellbores using gas-assisted lift at up/down inclined angles - and specifically - how gas injection rates affect hydrostatic pressure gradients, oil holdups, wellbore gas velocities and critical unloading gas velocities along the bend and lateral.