Predicting wellbore and cement slurry temperatures is a fundamental aspect of designing plug cementing jobs, yet the calculations involved can be complex. Temperature fluctuations impact cement setting times, fluid dynamics, and overall job success. Without accurate modeling, engineers risk ineffective cement placement and long-term well integrity issues.
A numerical model specifically for well temperature prediction during mud displacement and pull-out-of-the-hole (POOH) operations could address these challenges. This kind of model considers transient heat transfer between wellbore fluids, the work string, and the surrounding formation across all well depths—both during and after the cementing job. Unlike traditional 2D models that assume a stationary pipe string fixed at total depth (TD), this model provides a more comprehensive and dynamic approach.
Why Temperature Simulation Matters in Plug Cementing
Accurate temperature modeling helps engineers predict cement slurry behavior, optimize fluid selection, and minimize wellbore integrity risks. Understanding heat transfer dynamics ensures better cement placement and long-term performance, ultimately leading to safer and more efficient operations.
Temperature Profiles during Pull-Out-of-Hole (POOH) Operations
A simulation study was conducted to evaluate the temperature variations during cement plug jobs, focusing on pull-out-of-hole (POOH) operations. Temperature sensor loggers placed at key well points provided real-time data to compare against simulation models.
Key Findings:
- Accurate simulation results: The simulations closely matched field data, with only minor temperature differences during POOH.
- Pipe diameter effects: Larger pipe diameters showed higher bottom-hole temperatures due to slower fluid displacement.
- Impact of slurry movement: The fluid temperature near the bottom was higher during POOH, with substantial temperature recovery after pipe removal.
- Fluid level behavior: The use of balanced plugs minimized fluid loss and created air sections at the top of the pipe, influencing temperature changes.
For full insights, read the complete technical paper here.
A Solution to Accurate Temperature Prediction in Plug Cementing Operations
Accurate temperature prediction is essential for designing effective plug cementing jobs, yet the calculations involved can be complex. To address this, an advanced numerical model has been developed to simulate temperature changes during mud displacement and pull-out operations. Unlike traditional 2D models that assume a stationary pipe at total depth (TD), this model accounts for transient heat transfer across all well depths, providing a more precise representation of wellbore conditions during and after cementing.
By using this model, engineers can:
- Accurately predict temperature variations during the cement job.
- Optimize fluid selection and pump schedules based on well-specific conditions.
- Minimize risks related to cement placement and improve operational outcomes.
- Ensure better long-term well integrity and cement bond quality.
Through detailed case studies, the model examines how different factors—such as pipe diameter, fluid viscosity, well inclination, pulling velocity, and operation types (balanced plug vs. “pump and pull”)—impact cement temperatures, offering insights for optimizing plug cementing strategies. leveraging well-calibrated modeling software, cementing professionals can improve well integrity and operational efficiency.
Explore PlugPRO and its impact on plug cementing operations. Contact our team to learn more.