Specific type of Production Analysis (PA) workflow based on correlation between multi-well production/injection history and permanent downhole gauges (PDG) data records.
The key simulation engine of MRT is pressure convolution which is based on Unit-rate Transient Responses (UTR) retrieved from Production rates / PDG data history by means of pressure deconvolution.
It does not require new data acquisition at well site and makes use of historical dynamic data records, usually few months or longer.
Motivation
The ultimate purpose of MRT is to extract maximum information from correlation between the long-term (few months or longer) flowrate and BHP history.
This information is further related to well flow performance and cross-well connectivity.
Goals & Objectives
- Create short-term prediction model on production response to various multi-well production regimes
- Compare the well dynamics and and cross-well connectivity with expectations and identify the candidates for drilling, workover or additional well surveillance
- Assess dynamic reservoir properties
Inputs
Primary Inputs | |
---|---|
PVT model | |
Production/injection history for all wells in a test | |
Bottom-hole pressure (BHP) history for at least one well | |
Additional Inputs | |
Well location | |
Well schematics | |
Well tests | |
Initial formation pressure at drilling (DST/WFT) | |
Production Logging Reports | |
Pressure Transient Survey reports | |
Workover history |
Outputs
Production History | |
---|---|
Simulated total subsurface flowrate history | |
Simulated Bottom-hole pressure (BHP) history | |
Simulated formation pressure history | |
Simulated Productivity Index history | |
Simulated cross-well interference history | |
Production Forecast | |
Rate forecast under Pressure Control regime | |
BHP forecast under Liquid Control regime | |
Formation pressure forecast under Liquid Control regime | |
Diagnostic Metrics | |
Cross-well interference map | |
Unit-rate Transient Response Matrix (UTRM) | |
Unit-rate Transient Response Spider (UTRS) | |
Inflow Performance Relationship (IPR) | |
Cumulative Productivity Plot (Hall Plot) | |
J-plots | |
Potential drainage volume | |
Dynamic drainage volume | |
WOR diagnostics | |
GOR diagnostics | |
Apparent transmissibility | |
Apparent skin-factor | |
Fracture half-length |
Applications
Production forecasts | |
---|---|
Predict formation pressure without shutting wells down and avoiding production deferment | |
Short-term production forecasts for different multi-well production scenarios | |
Selecting well-intervention candidates | |
Identify well-intervention candidates with possible thief production/injection | |
Identify well-intervention candidates with possibly inefficient reservoir flow profile | |
Identify well-intervention candidates for Rate Optimization | |
Identify well-intervention candidates for producer ↔ injector conversion | |
Dynamic Model Calibration | |
Adjusting historical production allocation | |
Adjusting the potential reservoir volume extension at different directions | |
Adjusting faults / channels / compartmentalization | |
Adjusting fracture model |
Workflow
Examples
See Also
Petroleum Industry / Upstream / Production / Subsurface Production / Field Study & Modelling / Production Analysis
[ MRT @sample ] [ MRT @workflow ]
[ Material Balance Analysis ] [ Capacitance Resistance Model (CRM) ] [ Pressure convolution] [ Pressure deconvolution ] [ Pressure Transient Analysis (PTA) ]
[ MDCV ]
[ RDCV ][ RDCV @model ][ RDCV @sample ]
[ XDCV ][ XDCV @model ][ XDCV @sample ]