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- Nodal analysis-based design for improving gas lift wells production
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- Nodal System Analysis of Oil and Gas Wells

You must log in to edit PetroWiki. Help with editing. Content of PetroWiki is intended for personal use only and to supplement, not replace, engineering judgment. SPE disclaims any and all liability for your use of such content. More information. Systems analysis has been used for many years to analyze the performance of systems composed of multiple interacting components. The objective of systems analysis is to combine the various components of the production system for an individual well to estimate production rates and optimize the components of the production system.

The flow of reservoir fluids from the subsurface reservoir to the stock tank or sales line requires an understanding of the principles of fluid flow through porous media and well tubulars. As the fluid moves through the production system, there will be an associated pressure drop to accompany the fluid flow. This pressure drop will be the sum of the pressure drops through the various components in the production system. Because of the compressible nature of the fluids produced in oil and gas operations, the pressure drop is dependent on the interaction between the various components in the system.

This occurs because the pressure drop in a particular component is not only dependent on the flow rate through the component, but also on the average pressure that exists in the component. As a result, the final design of a production system requires an integrated approach, since the system cannot be separated into a reservoir component or a piping component and handled independently.

The amount of oil and gas produced from the reservoir to the surface depends on the total pressure drop in the production system, and the pressure drop in the system depends on the amount of fluid flowing through the system.

Consequently, the entire production system must be analyzed as a unit or system. Depending on the terminal end of the production system, there is a total pressure drop from the reservoir pressure to the surface, as depicted in Fig. If the separator represents the end of the production system, the total pressure drop in the system is the difference between the average reservoir pressure and the separator pressure:.

This total pressure drop is then composed of individual pressure drops as the reservoir fluid flows to the surface. These pressure drops occur as the fluid flows through the reservoir and well completion, up the tubing, through the wellhead equipment and choke, and through the surface flowlines to the separator. Thus, the total pressure drop of Eq. These individual pressure drops can be divided into yet additional pressure drops to account for restrictions, subsurface safety valves, tubing accessories, etc.

Systems analysis is based on the concept of continuity. At any given point in the production system, there is a particular pressure and production rate associated with that point for a set of conditions. This concept allows the production system to be divided at a point of interest for evaluation of the two portions of the system.

This evaluation determines the conditions of continuity of pressure and production rate at the division point, which is the estimated producing condition for the system being evaluated.

The approach provides the flexibility to divide the production system at any point of interest within the system to evaluate a particular component of the system. The most common division points are at the wellhead or at the perforations, either at the reservoir sandface or inside the wellbore.

The terminal ends of the system will be the reservoir on the upstream end of the system and the separator at the downstream end of the system or the wellhead if a wellhead choke controls the well. The components upstream of the division point or node comprise the inflow section of the system, while the components downstream of the node represent the outflow section. Once the system is divided into inflow and outflow sections, relationships are written to describe the rate-pressure relationship within each section.

The flow rate through the system is determined once the conditions of continuity are satisfied:. After the division point is selected, pressure relationships are developed for the inflow and outflow sections of the system to estimate the node pressure.

The pressure in the inflow section of the system is determined from Eq. The pressure drop in any component, and thus in either the inflow or outflow section of the system, varies as a function of flow rate. As a result, a series of flow rates is used to calculate node pressures for each section of the system.

Then, plots of node pressure vs. The curve representing the inflow section is called the inflow curve, while the curve representing the outflow section is the outflow curve. The intersection of the two curves provides the point of continuity required by the systems analysis approach and indicates the anticipated production rate and pressure for the system being analyzed.

For outflow curve A, there is no intersection with the inflow performance curve. Because there is no intersection, there is no continuity in the system and the well will not be expected to flow with System A.

The inflow and outflow performance curves do intersect for System B. Thus this system satisfies continuity, and the well will be expected to produce at a rate and pressure indicated by the intersection of the inflow and outflow curves. System C also has an intersection and would be expected to produce at a higher rate and lower pressure than System B, as indicated by the graph. The outflow curve for System C has a rapidly decreasing pressure at low flow rates, reaches a minimum, and then begins to slowly increase with increasing rate.

This is typical for many outflow curves, which, in some cases, will yield two intersection points with the inflow curve; however, the intersection at the lower rate is not a stable solution and is meaningless.

The proper intersection of the inflow and outflow curves should be the intersection to the right of and several pressure units higher than the minimum pressure on the outflow curve.

The effect of changing any component of the system can be evaluated by recalculating the node pressure for the new characteristics of the system. If a change is made in an upstream component of the system, then the inflow curve will change and the outflow curve will remain unchanged. On the other hand, if a change in a downstream component is made, then the inflow curve will remain the same and the outflow curve will change.

Both the inflow and outflow curves will be shifted if either of the fixed pressures in the system is changed, which can occur when evaluating the effects of reservoir depletion or considering different separator conditions or wellhead pressures.

Systems analysis may be used for many purposes in analyzing and designing producing oil and gas wells. The approach is suited for evaluating both flowing wells and artificial lift applications. The technique provides powerful insight in the design of an initial completion. Even with limited data, various completion scenarios can be evaluated to yield a qualitative estimate of expected well behavior. This process is very useful in analyzing current producing wells by identifying flow restrictions or opportunities to enhance performance.

In addition, systems analysis can be used to evaluate multiwell producing systems. Systems analysis is a very robust and flexible method that can be used to design a well completion or improve the performance of a producing well.

Examples 1 and 2 demonstrate the systems analysis approach. Example 1 considers the effects of tubing size on gas well performance. Example 2 demonstrates the effects of reservoir depletion on the performance of an oil well. Greene, [4] Brown and Lea, [5]. Analyze a gas well to select an appropriate tubing size. The gas well under consideration is at 9, ft with a reservoir pressure of 4, psia.

Solution The first step in applying systems analysis is to select a node to divide the system. Initially, the node is selected to be at the perforations to isolate the inflow performance reservoir behavior from the flow behavior in the tubing. For this particular case, the well is flowing at critical flow conditions, and, consequently, the wellhead choke serves as a discontinuity in the system, which allows the use of the wellhead pressure as the terminal point for the outflow curve.

Once the node point is selected, the pressure relations for the inflow and outflow sections of the system are determined. For this example, Eqs. With these basic relationships, the flowing bottomhole pressure is calculated for different production rates for both the inflow and outflow sections.

Table 1 presents the inflow performance data while Table 2 presents the calculated pressures for three different tubing sizes using a constant wellhead pressure of 1, psia. These data are used to construct the inflow and outflow curves in Fig. The intersection of the outflow curves with the inflow curve dictates the estimated point of continuity and the anticipated producing conditions for the analyzed system. The same well could be analyzed with the wellhead as the system node. This allows the effect of changes in wellhead pressure on well performance to be determined.

The new inflow and outflow pressure relationships are. Table 2 shows the pressure-rate relationship for both the inflow and outflow curves. Because the wellhead is the node in this analysis, the outflow curve will be constant and equal to the anticipated flowing wellhead pressure.

The data are plotted in Fig. This is as expected because the choice of a division point or node does not affect the results for a given system. If the wellhead pressure is decreased to psia, the producing rate will change also. This effect is readily determined by constructing a constant wellhead pressure line of psia on the graph and selecting the points of intersection for each tubing size. Investigate the effects of reservoir depletion of an oil well to estimate producing conditions and consider the need for artificial lift.

The well under consideration is producing with a constant wellhead pressure of psia and is controlled by the choke. Solution Isolate the reservoir performance to visualize the effect of changing reservoir pressure.

The flowing bottomhole pressure at mid-perforations is selected as the node and, as the well is producing under critical flow conditions, the wellhead will serve as the terminal end of the system. The inflow and outflow rate-pressure data is generated with Eqs.

Table 3 provides the inflow performance data for average reservoir pressures of 2, psia and 2, psia. However, there is no intersection or point of continuity between the inflow and outflow performance curves when the reservoir pressure declines to 2, psia.

This indicates that the well will not flow under these reservoir conditions. On the basis of this analysis, the effects of lowering the wellhead pressure, reducing the tubing size, or installing artificial lift early in the life of the well to enhance its deliverability should be investigated. Use this section to list papers in OnePetro that a reader who wants to learn more should definitely read.

Use this section to provide links to relevant material on websites other than PetroWiki and OnePetro. Wellbore flow performance. Help with editing Content of PetroWiki is intended for personal use only and to supplement, not replace, engineering judgment.

Flowing and Gas-Lift Well Performance. Dallas, Texas: API. The Technology of Artificial Lift Methods, 4. Analyzing the Performance of Gas Wells. J Pet Technol 35 7 :

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Brown, Kermit E. Distinguished Author Series articles are general, descriptive representations that summarize the state of the art in an area of technology by describing recent developments for readers who are not specialists in the topics discussed. Written by individuals recognized as experts in the area, these articles provide key references to more definitive work and present specific details only to illustrate the technology. Purpose: to informthe general readership of recent advances in various areas of petroleum engineering. Nodal analysis, defined as a systems approach to the optimization of oil andgas wells, is used to evaluate thoroughly a complete producing system. Every component in a producing well or all wells in a producing system can beoptimized to achieve the producing system can be optimized to achieve theobjective flow rate most economically.

Lea, SPE. Kermit E. Brown is F. Stevenson Professor of Petroleum Engineering at the U. Since Brown has served as head of the Petroleum Engineering Dept. He has conducted many courses on gas lift, multiphase flow, and inflow performance and served as a Distinguished Lecturer during Brown served as the SPE faculty advisor for the U.

Nodal Systems Analysis of Oil and Gas Wells The objectives of nodal analysis are as follows. This content is only available via PDF.

It covers multiphase flow through flow lines, wells, chokes and the near-well reservoir. It teaches the development of mathematical models for those system elements, and how to implement these in computer code. It explains the underlying physics, starting from first principles whenever possible, and reverting to empirical correlations whenever necessary. It covers the essential concepts in nodal analysis of a well system and aims at providing the readers with enough knowledge to use commercial nodal analysis software for more complex systems, explore the literature in this field, and expand their knowledge. Supplementary items for this book can be downloaded here.

Skip to search form Skip to main content You are currently offline. Some features of the site may not work correctly. Aguilar and A. Rivas and J. In this work, a gas lift-based oil production wells improvement technique is presented.

You must log in to edit PetroWiki. Help with editing. Content of PetroWiki is intended for personal use only and to supplement, not replace, engineering judgment.

Nodal analysis, defined as a systems approach to the optimization of oil and gas wells, is used to evaluate thoroughly a complete producing system. For the systematicness easily ignored during the design of artificial lifting system, based on coordination principle of reservoir, wellbore and lifting equipment, the concept of well performance curves are proposed. With the well performance curves, a new nodal analysis method of artificial lifting system is obtained, which is more efficient. Upstream and downstream pressure of pump and pressure difference provided by pump are displayed in well performance curve, which reflects the property of the well itself.

Nodal Systems Analysis of X..? Kermit E. Brown is F. Stevenson Professor of Petroleum En9ineerin9 at the U. Since wh has served es head of the Petroleum Egineerhg Dept.

Awal, Mohammad Rafiqul, and Lloyd R. Mature fields lack the sparkle of a new play, and an operator typically will not invest capital for waterflooding, much less EOR. But prevailing higher oil prices can turn such a mature oil field more profitable by employing innovative production enhancement techniques. We propose the use of a simple, tapered tubing string completion using larger internal diameter ID tubing pipes in the upper sections that can be customized for specific reservoirs. Historically there are few instances of tapered ID tubing completion, which were basically necessitated by technical constraints liner, workover, etc. But our approach is focused on enhancing economic performance.

Optimum tubing size OTS selection was traditionally done by using nodal analysis to perform sensitivity analysis on the different tubing sizes.

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