Log-Inject-Log

Test Your Knowledge

Log-Inject-Log Quiz

Instructions: Choose the best answer for each question.

1. What are the three main steps involved in a Log-Inject-Log (LIL) procedure?

a) Logging, Injection, Repeating b) Logging, Sampling, Analyzing c) Injection, Monitoring, Repeating d) Sampling, Injection, Logging

2. What is the primary purpose of fluid injection during a LIL process?

a) To remove oil from the reservoir. b) To increase reservoir pressure and improve production. c) To identify the location of oil deposits. d) To measure the temperature of the formation.

3. Which of the following parameters can be measured by logging tools during a LIL procedure?

a) Oil Saturation (So) b) Reservoir Temperature c) Water Saturation (Sw) d) All of the above

4. How does LIL help optimize waterflood operations?

a) By identifying the location of water injection points. b) By measuring the effectiveness of water injection in displacing oil. c) By determining the optimal water injection rates. d) All of the above

5. What is one of the main benefits of comparing the initial and repeat logging data in LIL?

a) Identifying areas where the injected fluid has been successfully distributed. b) Determining the volume of oil extracted from the reservoir. c) Measuring the efficiency of the drilling process. d) Analyzing the composition of the injected fluid.

Log-Inject-Log Exercise

Scenario: An oil company is planning to implement a waterflood operation in a new reservoir. They have conducted initial logging and determined the following:

• Oil Saturation (So): 35%
• Water Saturation (Sw): 65%
• Reservoir Temperature: 120°F

After injecting water into the reservoir, they repeat the logging and observe the following changes:

• Oil Saturation (So): 25%
• Water Saturation (Sw): 75%
• Reservoir Temperature: 115°F

Task:

Based on the changes in logging data, analyze the effectiveness of the waterflood operation. Discuss the following aspects:

1. Sweep Efficiency: How effectively did the injected water displace the oil?
2. Formation Response: What does the change in temperature indicate about the reservoir's response to the water injection?
3. Potential Issues: Are there any potential issues or concerns based on the observed changes?

Techniques

Log-Inject-Log: A Comprehensive Guide

Chapter 1: Techniques

This chapter details the various techniques employed within the Log-Inject-Log (LIL) process. The core of LIL involves pre- and post-injection logging, but the specific techniques used are highly dependent on the reservoir characteristics and the objectives of the injection.

1.1 Logging Techniques:

The initial and repeat logging typically utilize a suite of wireline logging tools. These might include:

• Resistivity Logs: Measure the electrical conductivity of the formation, which is inversely proportional to resistivity. Changes in resistivity after injection can indicate the movement of conductive fluids (e.g., water) into the reservoir. Different resistivity tools (e.g., induction, laterolog) provide varying depth of investigation.

• Porosity Logs: Determine the pore space within the rock. Neutron porosity and density porosity logs are commonly used. Changes in porosity (though less common than resistivity changes) can be indicative of significant formation alteration.

• Nuclear Magnetic Resonance (NMR) Logs: Provide information on pore size distribution and fluid type. This is crucial for understanding how the injected fluid interacts with the reservoir fluids. Pre- and post-injection NMR logs can show changes in pore saturation and fluid mobility.

• Temperature Logs: Measure the temperature profile of the formation. Injection of fluids, particularly at different temperatures than the formation, will create temperature anomalies which can track fluid movement.

• Pressure Logs: Measure the pressure within the wellbore and formation. These are essential to monitor the pressure changes caused by injection and to assess the effectiveness of pressure support or fracturing operations.

1.2 Injection Techniques:

The injection phase itself can be conducted using various methods:

• Water Injection: The most common method, used for pressure maintenance, enhanced oil recovery (EOR), and waterflooding.

• Gas Injection: Used in gas injection projects for EOR or pressure maintenance.

• Chemical Injection: Involves injecting specialized chemicals to improve sweep efficiency or alter reservoir properties (e.g., polymer flooding, surfactant flooding).

• Hydraulic Fracturing: Creates fractures in the reservoir to increase permeability and improve production. LIL is particularly valuable in evaluating the success of hydraulic fracturing.

The selection of the injection technique is based on reservoir characteristics, project goals, and economic considerations. Careful design of the injection program is crucial for maximizing the effectiveness of LIL.

Chapter 2: Models

Interpreting LIL data requires the use of appropriate reservoir models. These models help quantify the changes observed in the logging data and translate them into meaningful reservoir parameters.

2.1 Saturation Models:

These models relate changes in resistivity logs to changes in water saturation. Archie's law is a commonly used empirical model, but more sophisticated models may be required to account for complex reservoir heterogeneity.

2.2 Fluid Flow Models:

These models simulate fluid movement within the reservoir based on reservoir properties such as permeability, porosity, and fluid viscosities. They help predict the spatial distribution of injected fluids and validate interpretations of LIL data. Numerical simulators are often employed.

2.3 Geomechanical Models:

These models are especially important when hydraulic fracturing is involved. They simulate the stress state of the reservoir and predict fracture propagation and geometry. This information can be used to interpret the extent of fracture growth observed in LIL data.

2.4 Integration of Models:

Effective use of LIL data often involves integrating multiple models. For instance, a geomechanical model might predict fracture growth, which is then compared with the saturation changes observed in the resistivity logs to assess fracture conductivity. This integrated approach provides a more comprehensive understanding of the reservoir behavior.

Chapter 3: Software

Specialized software packages are necessary to process and interpret LIL data. These tools provide functionalities for:

• Data Loading and Preprocessing: Handling and cleaning the large datasets obtained from logging tools.

• Data Visualization: Generating various plots and images to visualize the spatial distribution of injected fluids and changes in reservoir properties.

• Model Calibration and Inversion: Adjusting model parameters to match the observed data and estimating reservoir parameters.

• Reservoir Simulation: Running numerical simulations to predict fluid flow and reservoir behavior.

Examples of relevant software packages include Petrel (Schlumberger), Eclipse (Schlumberger), and CMG (Computer Modelling Group). These packages often include specialized modules for handling and interpreting logging data, including LIL data. Other specialized software may be employed for specific tasks, such as fracture characterization or geomechanical modelling.

Chapter 4: Best Practices

The success of LIL relies heavily on proper planning and execution. Best practices include:

• Careful Well Selection: Choosing wells with suitable reservoir properties and access for logging and injection operations.

• Detailed Pre-injection Assessment: Thorough characterization of the reservoir using core analysis, well tests, and existing well logs.

• Optimized Injection Design: Carefully designing the injection program to ensure adequate coverage and minimize interference with other wells.

• Precise Logging Procedures: Following strict logging procedures to maintain data quality and consistency.

• Rigorous Data Processing and Quality Control: Implementing strict quality control measures to identify and correct errors in the data.

• Integrated Interpretation: Combining different data sources and models for a more comprehensive interpretation.

• Documentation: Meticulous recording of all procedures, data, and interpretations.

Chapter 5: Case Studies

This chapter will present several case studies illustrating the application of LIL in various reservoir scenarios. Specific examples could include:

• Case Study 1: Hydraulic Fracturing Evaluation: Demonstrating how LIL can be used to evaluate the effectiveness of a hydraulic fracturing treatment by mapping the extent of the created fractures.

• Case Study 2: Waterflood Optimization: Showing how LIL can be used to optimize water injection rates and locations to maximize oil recovery.

• Case Study 3: Enhanced Oil Recovery (EOR) Monitoring: Illustrating the use of LIL to track the movement of injected chemicals and assess the effectiveness of an EOR project.

Each case study would include details of the reservoir characteristics, the injection strategy employed, the logging data obtained, the modeling techniques used, and the key findings. These examples will highlight the diverse applications and the valuable insights that LIL can provide.