1. Chapter 2 Pressure-Volume-Temperature for Oil
PVT analysis – PVT relationship

2. Three main oil PVT parameters
The three main parameters required to relate surface to reservoir volumes for an oil reservoir:
- Rs: The solution (or dissolved) gas-oil ratio
- Bo: The oil formation volume factor
- Bg: The gas formation volume factor

3. Definition of the basic oil PVT parameters
- Rs: The solution (or dissolved) gas-oil ratio
at reservoir P&T
- Bo: The oil formation volume factor
- Bg: The gas formation volume factor
Note : Standard Condition
For T = const.

4. Determination and Conversion of PVT Data
Determination of three main oil PVT parameters(RS, Bo, Bg)
-> PVT = f (P only) by routine laboratory analysis
Conversion of PVT data, as presented by the laboratory, to the form required in the field,
Laboratory - an absolute set of measurements
Field - depend up as the manner of surface
separation of the gas and oil

5. The complexity of Oil PVT
For gas, PVT relation
-- Simple relation
For oil, PVT relation > Complex;
PVT parameters must be measured by
laboratory analysis of crude oil samples.
>Relationship between surface and
reservoir hydrocarbon volumes.

6. The complexity of Oil PVT
The complexity in relating surface volumes of hydrocarbon production to their equivalent volumes in the reservoir can be appreciated by considering the following figures:
Undersaturated oil
saturated oil
gas saturated oil
+ free gas (or liberated solution gas)
They are traveling in reservoir at different velocity

7. How to divide the observed surface gas production into liberated and dissolved gas volumes in the reservoir?
Control in relating surface volumes of production to underground withdrawal is gained by knowing the three oil PVT parameters which can be measured by laboratory experiments performed on samples of the reservoir oil, plus its originally dissolved gas.

8. Oil Reservoir & Surface Volume – Above Bubble Point
Undersaturated oil

9. Oil Reservoir & Surface Volume – Below Bubble Point
Saturated oil
gas saturated oil
+ free gas (or liberated solution gas)
They are traveling in reservoir at different velocity

10. The instantaneous gas-oil ratio or producing gas-oil ratio

11. Bo as Function of Pressure

12. Rs as Function of Pressure

13. Bg and E as Function of Pressure

14. Producing Gas-oil Ratio (R) as Function of Pressure

15. Exercise 2.1 - Underground withdrawal
Given: measured at t during the
producing life
Calculate:
(1) Underground withdrawal rate expressed in terms of x & y
(2) Underground withdrawal rate
if pres = 2400 psia , qo =2500 STB/D , qg=2.125 MMscf/D and
PVT data in fig. 2.5(a)~(c) (p.51) or table 2.4 (P.65)
(3) Pressure gradient of oil =? if

16. (1) R = y/x = qg/qo [=] SCF/STB
p is known  Bo ; Rs ; Bg
Underground withdrawal

17. P = 2400 psia
from table 2.4  Bo =1.1822RB/STB
Rs = 352 SCF/STB
Bg = RB/SCF
x = qo = 2500 STB/D;
y = qg = MMSCF/D

18. (3)
To find , applying mass balance, such as
Mass of 1 STB of oil Mass of Bo RB of oil =
Rs scf dissolved gas at dissolved gas in the standard condition reservoir condition