Oil Compressibility Correlations

Overview

Oil compressibility ( $c_o$ ) is the isothermal change in oil volume per unit pressure change:

c_o = -\frac{1}{V} \left( \frac{\partial V}{\partial P} \right)_T = -\frac{1}{B_o} \left( \frac{\partial B_o}{\partial P} \right)_T

This property is essential for:

Material balance calculations — determines oil expansion above bubble point
Well testing interpretation — appears in diffusivity equation and total compressibility
Reservoir simulation — required input for undersaturated oil reservoirs
Production forecasting — affects primary recovery calculations

Physical Behavior

Oil compressibility behavior differs dramatically above and below the bubble point:

co
 │
 │                              
 │        ┌──── Undersaturated: Low co
 │       │      (single-phase liquid compression)
 │ ──────┘
 │        │
 │        │ ● Pb (discontinuity)
 │        │
 │        └────────────────── Saturated: High co
 │                             (gas evolution dominates)
 │                              
 └──────────────────────────────→ P
               Pb

Pressure Region	$c_o$ Magnitude	Physical Cause
$P > P_b$ (undersaturated)	$10^{-5}$ to $10^{-6}$ 1/psi	Liquid compression only
$P \le P_b$ (saturated)	$10^{-4}$ to $10^{-3}$ 1/psi	Gas evolution from solution

The effective or total oil compressibility below the bubble point includes gas evolution effects and is much larger than above $P_b$ .

Undersaturated Oil Compressibility

Vasquez and Beggs (1980)

For pressures above the bubble point ( $P > P_b$ ), oil behaves as a compressed liquid with relatively constant compressibility:

c_o = \frac{5 R_{sb} + 17.2 T - 1180 \gamma_g + 12.61 \gamma_{API} - 1433}{P \times 10^5}

Where:

$c_o$ = oil compressibility, 1/psi
$R_{sb}$ = solution gas-oil ratio at bubble point, scf/STB
$T$ = temperature, °F
$\gamma_g$ = gas specific gravity (air = 1.0)
$\gamma_{API}$ = oil API gravity, °API
$P$ = pressure, psia

Key Observations:

Compressibility decreases with increasing pressure (1/P term)
Higher temperature → higher compressibility
Higher GOR → higher compressibility
Lighter oil (higher API) → higher compressibility

Typical Values:

Oil Type	$R_{sb}$ (scf/STB)	$c_o$ × 10⁶ (1/psi)
Heavy, low GOR	100	5-10
Medium	500	10-20
Light, high GOR	1000+	15-30

Saturated Oil Compressibility

Villena-Lanzi (1985)

Below the bubble point ( $P \le P_b$ ), the effective compressibility includes the effect of gas evolving from solution:

c_o = \exp \left[ -0.664 - 1.430 \ln(P) - 0.395 \ln(P_b) + 0.39 \ln(T) + 0.455 \ln(R_{sb}) + 0.262 \ln(\gamma_{API}) \right]

Where:

$c_o$ = effective oil compressibility, 1/psi
$P$ = current pressure, psia
$P_b$ = bubble point pressure, psia
$T$ = temperature, °F
$R_{sb}$ = solution GOR at bubble point, scf/STB
$\gamma_{API}$ = oil API gravity, °API

Key Observations:

Compressibility increases rapidly as pressure drops below $P_b$
Strong dependence on both $P$ and $P_b$
Higher initial GOR → higher saturated compressibility

Physical Interpretation:

At saturated conditions, the "apparent" compressibility includes:

Liquid oil compression (small)
Gas liberation from solution (dominant)
Free gas expansion (after liberation)

Total Compressibility

In reservoir engineering, the total system compressibility combines all phases:

c_t = S_o c_o + S_w c_w + S_g c_g + c_f

Where:

$c_t$ = total compressibility, 1/psi
$S_o, S_w, S_g$ = oil, water, gas saturations
$c_o, c_w, c_g$ = phase compressibilities
$c_f$ = formation (pore) compressibility

Relative Magnitudes (typical):

Component	Compressibility (1/psi)	Contribution
Oil (undersaturated)	10-20 × 10⁻⁶	Moderate
Water	3-4 × 10⁻⁶	Small
Gas	100-500 × 10⁻⁶	Large
Formation	3-10 × 10⁻⁶	Small

For undersaturated oil reservoirs with no free gas, oil compressibility often dominates $c_t$ .

Functions Covered

The following functions implement these oil compressibility correlations. See each function page for detailed parameter definitions, Excel syntax, and usage examples.

Function	Condition	Correlation
CoUSatVasquezBeggs1980	$P > P_b$	Vasquez-Beggs (1980)
CoSatVillenaLanzi1985	$P \le P_b$	Villena-Lanzi (1985)

Calculation Workflow

For Undersaturated Reservoirs ( $P > P_b$ )

Use CoUSatVasquezBeggs1980 directly with reservoir conditions:

co = CoUSatVasquezBeggs1980(Rsob, SGgas, SGoilAPI, T, P)

For Saturated Reservoirs ( $P \le P_b$ )

Use CoSatVillenaLanzi1985 with current and bubble point pressures:

co = CoSatVillenaLanzi1985(P, Pb, T, Rsob, SGoilAPI)

Pressure Depletion Scenarios

As a reservoir depletes:

Initial pressure > Pb: Use Vasquez-Beggs
Pressure = Pb: Transition point (either correlation)
Pressure < Pb: Use Villena-Lanzi (compressibility jumps significantly)

Practical Considerations

Material Balance Applications

For undersaturated reservoirs, oil expansion above $P_b$ provides significant drive energy:

\Delta V = V_o \cdot c_o \cdot \Delta P

Example: 10 MMSTB of oil at $P = 4,000$ psia with $c_o = 15 \times 10^{-6}$ 1/psi:

If pressure drops to 3,000 psia ( $\Delta P = 1,000$ psi):

\Delta V = 10 \times 10^6 \times 15 \times 10^{-6} \times 1000 = 150,000 \text{ STB}

This expansion contributes to production before the bubble point is reached.

Well Testing

Total compressibility $c_t$ appears in the diffusivity equation:

\frac{\partial^2 p}{\partial r^2} + \frac{1}{r} \frac{\partial p}{\partial r} = \frac{\phi \mu c_t}{k} \frac{\partial p}{\partial t}

Accurate $c_o$ is critical for:

Calculating transmissibility from pressure buildup
Estimating drainage area from drawdown tests
Interpreting skin factor and wellbore storage

Bubble Point Pressure (Pb) — defines transition pressure
Oil Formation Volume Factor (Bo) — related to compressibility
Solution Gas-Oil Ratio (Rs) — affects saturated behavior
Dimensionless Variables — uses total compressibility

References

Vazquez, M. and Beggs, H.D. (1980). "Correlations for Fluid Physical Property Prediction." Journal of Petroleum Technology, 32(6), pp. 968-970.
Villena-Lanzi, M. (1985). "A Correlation for the Coefficient of Isothermal Compressibility of Black Oil at Pressures Below the Bubblepoint." M.S. Thesis, University of Tulsa.
McCain, W.D. Jr. (1990). The Properties of Petroleum Fluids, 2nd Edition. PennWell Books. Chapter 3: Isothermal Compressibility of Crude Oil.
Ahmed, T. (2019). Reservoir Engineering Handbook, 5th Edition. Gulf Professional Publishing. Chapter 2: Reservoir-Fluid Properties.

Oil Compressibility Correlations

Overview

Physical Behavior

Undersaturated Oil Compressibility

Vasquez and Beggs (1980)

Saturated Oil Compressibility

Villena-Lanzi (1985)

Total Compressibility

Functions Covered

Calculation Workflow

For Undersaturated Reservoirs (P>PbP > P_bP>Pb​)

For Saturated Reservoirs (P≤PbP \le P_bP≤Pb​)

Pressure Depletion Scenarios

Practical Considerations

Material Balance Applications

Well Testing

Related Documentation

References

Related Excel Functions

For Undersaturated Reservoirs ( $P > P_b$ )

For Saturated Reservoirs ( $P \le P_b$ )