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Glossary of Technical Terms Used in Drilling & Well Completion: Turner Equation

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Turner Equation

Lifting the Load: Understanding the Turner Equation in Oil & Gas

In the world of oil and gas production, efficient extraction relies heavily on understanding the intricate interplay between fluids and well dynamics. One crucial aspect is the ability to lift liquids from the wellbore to the surface, a process often hindered by the weight of the liquid column. This is where the Turner Equation comes into play, a valuable tool for predicting the minimum gas flow required to effectively lift liquids in wells operating above 1000 psi flowing pressure.

The Turner Equation: A Formula for Flowing Success

The Turner Equation, developed by renowned oil and gas engineer Dr. Ray Turner, offers a practical way to calculate the minimum gas flow rate needed to overcome the hydrostatic pressure of the liquid column and initiate production. It is particularly useful for wells encountering high bottomhole pressures, typically above 1000 psi, which can significantly impede liquid flow.

The equation itself is presented as:

Qg = (0.025 * QL * (Pb - Pf) * (D * H)) / (P * M * T)

Where:

  • Qg: Minimum gas flow rate (scf/day)
  • QL: Liquid production rate (bbl/day)
  • Pb: Bottomhole pressure (psia)
  • Pf: Flowing pressure (psia)
  • D: Density of the liquid (lb/ft³)
  • H: Depth of the well (ft)
  • P: Atmospheric pressure (psia)
  • M: Molecular weight of gas (lb/lbmol)
  • T: Temperature (Rankine)

Decoding the Equation: Key Insights and Applications

The Turner Equation provides valuable insights into the dynamics of gas lift operations. It highlights the crucial role of several factors, including:

  • Liquid Production Rate (QL): Higher liquid production rates require increased gas flow to maintain lifting efficiency.
  • Pressure Differential (Pb - Pf): The difference between bottomhole and flowing pressures directly impacts the amount of gas required for lifting.
  • Well Depth (H): Deeper wells necessitate more gas flow to overcome the greater hydrostatic pressure.
  • Liquid Density (D): Heavier liquids (higher density) require more gas to overcome their weight.

This equation finds extensive application in:

  • Gas Lift Design: Determining the appropriate gas injection rate for new or existing wells.
  • Production Optimization: Adjusting gas injection rates based on changing well conditions or production targets.
  • Troubleshooting: Identifying potential issues with gas lift systems, such as insufficient gas injection or plugging in the wellbore.

Limitations and Considerations

While the Turner Equation serves as a valuable starting point for gas lift design, it's essential to acknowledge certain limitations:

  • Simplified Model: The equation is a simplified model that does not account for complex wellbore geometry, fluid properties, or gas-liquid interactions.
  • Assumptions: The equation assumes ideal gas behavior and relies on several assumptions about the wellbore and fluid properties.
  • Empirical Derivation: The equation is based on empirical observations and may not be universally applicable to all well conditions.

Despite these limitations, the Turner Equation remains a crucial tool for understanding gas lift principles and predicting minimum gas flow rates. By considering these limitations and integrating additional data and analysis, engineers can optimize gas lift systems for efficient and sustainable oil and gas production.

Test Your Knowledge

Quiz: Lifting the Load - Turner Equation in Oil & Gas

Instructions: Choose the best answer for each multiple-choice question.

1. What is the primary purpose of the Turner Equation?

a) To calculate the optimal pressure for gas injection in a well.

Answer

Incorrect. While pressure is a factor, the Turner Equation primarily focuses on gas flow rate.

b) To predict the minimum gas flow rate required for effective liquid lifting in wells.
Answer

Correct! The Turner Equation helps determine the minimum gas flow needed to overcome hydrostatic pressure and lift liquids.

c) To estimate the total gas reserves available in a reservoir.
Answer

Incorrect. The Turner Equation is not designed to assess gas reserves.

d) To analyze the composition of the gas used in gas lift operations.
Answer

Incorrect. While gas composition can influence lifting efficiency, the Turner Equation focuses on overall gas flow rate.

2. Which of the following factors is NOT directly considered in the Turner Equation?

a) Liquid production rate (QL)

Answer

Incorrect. Liquid production rate is a key factor in the equation.

b) Wellbore diameter
Answer

Correct! The Turner Equation does not explicitly account for wellbore diameter.

c) Depth of the well (H)
Answer

Incorrect. Well depth is directly related to hydrostatic pressure and is considered in the equation.

d) Density of the liquid (D)
Answer

Incorrect. Liquid density is a crucial factor influencing lifting requirements.

3. What is the primary application of the Turner Equation in the context of gas lift operations?

a) Predicting the exact amount of gas required for a specific well at any given time.

Answer

Incorrect. While the equation provides an estimate, it's not precise for dynamic conditions.

b) Providing a starting point for designing and optimizing gas lift systems.
Answer

Correct! The Turner Equation is a valuable tool for initial gas lift design and optimization.

c) Replacing more complex computer simulations for gas lift design.
Answer

Incorrect. The equation is a simplified model and often complements more complex simulations.

d) Accurately forecasting future gas lift requirements for long-term production plans.
Answer

Incorrect. The equation is more suited for immediate design and optimization, not long-term forecasting.

4. What is a key limitation of the Turner Equation?

a) It does not account for the impact of temperature on gas flow.

Answer

Incorrect. The equation includes temperature (T) as a variable.

b) It is only applicable to wells with very low bottomhole pressures.
Answer

Incorrect. The equation is particularly relevant for wells with high bottomhole pressures.

c) It assumes ideal gas behavior and does not fully consider complex wellbore geometries and fluid interactions.
Answer

Correct! The equation is a simplified model and makes certain assumptions about gas behavior and well conditions.

d) It does not account for the impact of well depth on lifting requirements.
Answer

Incorrect. Well depth is a key factor considered in the equation.

5. What is the significance of the pressure differential (Pb - Pf) in the Turner Equation?

a) It represents the total pressure loss experienced by the fluid as it flows to the surface.

Answer

Incorrect. The pressure differential represents the difference between bottomhole pressure and flowing pressure.

b) It indicates the amount of pressure required to overcome the hydrostatic pressure of the liquid column.
Answer

Correct! The pressure differential is directly related to the force needed to lift the liquid column.

c) It reflects the efficiency of the gas lift system in transferring energy to the fluid.
Answer

Incorrect. While efficiency is important, the pressure differential primarily reflects the pressure difference needed for lifting.

d) It is a measure of the gas's ability to expand as it flows up the wellbore.
Answer

Incorrect. Gas expansion is a factor, but the pressure differential directly relates to overcoming hydrostatic pressure.

Exercise: Lifting the Load - Applying the Turner Equation

Scenario:

You are working on a gas lift project for an oil well. The following data is available:

  • Liquid production rate (QL): 500 bbl/day
  • Bottomhole pressure (Pb): 2000 psia
  • Flowing pressure (Pf): 1000 psia
  • Density of the liquid (D): 50 lb/ft³
  • Depth of the well (H): 10,000 ft
  • Atmospheric pressure (P): 14.7 psia
  • Molecular weight of gas (M): 16 lb/lbmol
  • Temperature (T): 520 Rankine

Task:

Calculate the minimum gas flow rate (Qg) required for this well using the Turner Equation.

Equation: Qg = (0.025 * QL * (Pb - Pf) * (D * H)) / (P * M * T)

Show your calculations and interpret the results.

Exercice Correction

**Calculations:** Qg = (0.025 * 500 * (2000 - 1000) * (50 * 10000)) / (14.7 * 16 * 520) Qg ≈ 1,137,788 scf/day **Interpretation:** The minimum gas flow rate required for this well is approximately 1,137,788 scf/day. This means that at least this amount of gas needs to be injected into the well to overcome the hydrostatic pressure and effectively lift the oil to the surface. **Note:** This result is a starting point for gas lift design. Further analysis considering wellbore geometry, fluid properties, and other factors might be necessary for optimal gas lift system design.

Books

  • "Petroleum Production Engineering" by D.R. Matthews and J.P. Russell - A comprehensive text covering all aspects of oil and gas production, including gas lift theory and application.
  • "Gas Lift Design and Operations" by John P. Brill and Harold J. Beggs - A specialized text dedicated to gas lift technologies, including detailed explanations of the Turner Equation and its applications.
  • "Production Operations" by Tarek Ahmed - Covers a wide range of production operations, including gas lift, with a section dedicated to the Turner Equation and its relevance to production optimization.

Articles

  • "Gas Lift Design Using the Turner Equation" by Ray Turner - A seminal article by the developer of the equation, explaining its derivation and providing practical applications.
  • "The Turner Equation: A Simplified Approach to Gas Lift Design" by John P. Brill - A detailed analysis of the Turner Equation, highlighting its advantages and limitations.
  • "Optimizing Gas Lift Performance Using the Turner Equation" by Michael A. Wattenbarger - An article exploring how the Turner Equation can be used to improve gas lift efficiency.

Online Resources

  • "Gas Lift Design and Operation" by SPE - An online course offered by the Society of Petroleum Engineers covering various aspects of gas lift, including the Turner Equation and its practical use.
  • "Gas Lift Design and Optimization" by Schlumberger - A comprehensive online resource offering detailed information on gas lift design, including discussions about the Turner Equation and its applications.
  • "Gas Lift Calculations" by PetroWiki - A wiki dedicated to petroleum engineering, featuring a section on gas lift calculations, including the Turner Equation and its derivation.

Search Tips

  • Use specific keywords: "Turner equation," "gas lift design," "minimum gas flow rate," "oil and gas production."
  • Combine keywords with operators: "Turner equation AND gas lift" OR "Turner equation OR gas lift design."
  • Include relevant technical terms: "bottomhole pressure," "flowing pressure," "liquid production rate," "well depth."
  • Search within specific websites: "site:spe.org Turner equation" OR "site:schlumberger.com Turner equation."
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