Difference between revisions of "Oil Flowing Material Balance"
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# Upload the data required | # Upload the data required | ||
# Open the [[Oil Flowing Material Balance]] tool [https://ep.pengtools.com/matbal/flowing-material-balance/oil here] | # Open the [[Oil Flowing Material Balance]] tool [https://ep.pengtools.com/matbal/flowing-material-balance/oil here] | ||
− | # Estimate the '''N''' | + | # Estimate the '''N''' (red line) |
# Calculate the average reservoir pressure <math> \bar{P}</math> based on '''N''', known production data and using [[Oil Material Balance]] equation | # Calculate the average reservoir pressure <math> \bar{P}</math> based on '''N''', known production data and using [[Oil Material Balance]] equation | ||
# Calculate the <math> {J_D}_{norm}</math> | # Calculate the <math> {J_D}_{norm}</math> | ||
# Calculate the <math> {N_p}_{norm}</math> | # Calculate the <math> {N_p}_{norm}</math> | ||
# Plot the <math> {J_D}_{norm}</math> vs <math> {N_p}_{norm}</math> plot (orange line): | # Plot the <math> {J_D}_{norm}</math> vs <math> {N_p}_{norm}</math> plot (orange line): | ||
− | + | # Change the '''N''' to match the orange line with the red one | |
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− | # Change the | ||
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# Change the flat [[JD]] gray line to match the changing [[JD]] gray line | # Change the flat [[JD]] gray line to match the changing [[JD]] gray line | ||
− | # Save the [[ | + | # Save the [[Oil Flowing Material Balance]] model |
# Move to the next well | # Move to the next well | ||
=== Data required === | === Data required === |
Revision as of 07:27, 10 April 2018
Contents
Brief
Oil Flowing Material Balance (Oil FMB) is the advanced engineering technique published in 2005 by Louis Mattar and David Anderson [1].
Oil Flowing Material Balance is applied to determine:
- Reservoirs STOIIP & EUR
- Well's EUR and JD
Oil Flowing Material Balance uses readily available Well flowing data: production rate and bottomhole pressure.
The interpretation technique is fitting the data points with the straight lines to estimate STOIIP and JD.
Math & Physics
The total pressure drop at the wellbore is:
Where
- , is pressure drop due to depletion defined by the Oil Material Balance
- , is pressure drop due to Darcy's law
In terms of oil pseudo pressure the total pressure drop is:
Where
Finally, the Oil Flowing Material Balance equation:
Or
Where
Discussion
Oil Flowing Material Balance can be applied to:
- single well
- multiple wells producing from the same Reservoir.
The X axis on the Oil Flowing Material Balance Plot can be selected as:
Note what Oil Flowing Material Balance accounts for the changing PVT properties of the oil.
Example 1. Multiple wells producing from the same Reservoir. X axis - Wells cumulative Example 2. Multiple wells producing from the same Reservoir. X axis - Reservoir cumulative Example 3. Shifted Model Start (to account for gas injection)
Workflow
- Upload the data required
- Open the Oil Flowing Material Balance tool here
- Estimate the N (red line)
- Calculate the average reservoir pressure based on N, known production data and using Oil Material Balance equation
- Calculate the
- Calculate the
- Plot the vs plot (orange line):
- Change the N to match the orange line with the red one
- Change the flat JD gray line to match the changing JD gray line
- Save the Oil Flowing Material Balance model
- Move to the next well
Data required
- Create Field here
- Create or Upload Reservoirs here
- Input the Reservoirs GIIP and STOIIP here
- Create or Upload PVT (SG, Pi, Ti) here
- Upload Wells
- Create or Upload Wells Perforations here
- Create or Upload kh and JD here
- Upload Daily Measures
In case you need to calculate the flowing bottomhole pressure from the wellhead pressure:
- Calculate the flowing bottomhole pressures using BHP Calculator
- Export flowing bottomhole pressures to Daily Measures here
In case you want to add the static reservoir pressures on the FMB Plot:
- Create or Upload the static reservoir pressures, here
- Calculate Monthly Measures from the Daily Measures using Monthly Data Calculator
Nomenclature
- = reservoir constant, inverse to productivity index, psia2/cP/MMscfd
- = compressibility, psia-1
- = gas initially in place, MMscf
- = cumulative gas produced, MMscf
- = gas productivity index, MMscfd/(psia2/cP)
- = dimensionless productivity index, dimensionless
- = permeability times thickness, md*m
- = pressure, psia
- = average reservoir pressure, psia
- = pseudopressure, psia2/cP
- = gas rate, MMscfd
- = time, day
- = material balance pseudotime for gas, day
- = temperature, °R
- = gas compressibility factor, dimensionless
Greek symbols
- = viscosity, cp
Subscripts
- g = gas
- i = initial
- R = °R
- wf = well flowing
References
- ↑ 1.0 1.1 Mattar, L.; Anderson, D (2005). "Dynamic Material Balance (Oil or Gas-In-Place Without Shut-Ins)" (PDF). CIPC.
- ↑ 2.0 2.1 Stalgorova, Louis; Mattar, Ekaterina (2016). "Analytical Methods for Single-Phase Oil Flow: Accounting for Changing Liquid and Rock Properties". Society of Petroleum Engineers.