Abstract
Polymer flooding is an established enhanced oil recovery (EOR) method; still, many aspects of polymer flooding are not well understood. This study investigates the influence of mechanical degradation on flow properties of polymers in porous media. Mechanical degradation due to high shear forces may occur in the injection well and at the entrance to the porous media. The polymers that give high viscosity yields at a sustainable economic cost are typically large, MW > 10 MDa, and have wide molecular weight distributions. Both MW and the distributions are altered by mechanical degradation, leading to changes in the flow rheology of the polymer. The polymer solutions were subjected to different degrees of pre-shearing and pre-filtering before injected into Bentheimer outcrop sandstone cores. Rheology studies of injected and produced polymer solutions were performed and interpreted together with in situ rheology data. The core floods showed a predominant shear thickening behavior at high flow velocities, which is due to successive contraction/expansion flow in pores. When pre-sheared, shear thickening was reduced but with no significant reduction in in situ viscosity at lower flow rates. This may be explained by reduction in the extensional viscosity. Furthermore, the results show that successive degradation occurred which suggests that the assumption of the highest point of shear that determines mechanical degradation in a porous media does not hold for all field relevant conditions.
Highlights
Among several processes which are applied to increase oil recovery, polymer flooding has been widely implemented as a mobility control technique in tertiary enhanced oil recovery (EOR) [1].The most basic method of recovering oil from a reservoir is by pressure depletion [2]
The results show that successive degradation occurred which suggests that the assumption of the highest point of shear that determines mechanical degradation in a porous media does not hold for all field relevant conditions
The influence of mechanical degradationand and filtration rheology hashas beenbeen investigated for two polymers with different molecular weights
Summary
The most basic method of recovering oil from a reservoir is by pressure depletion [2]. The pressure difference between the oil reservoir and the surface will lead to production of oil until the reservoir pressure becomes too low for production. Typically 95%–80% of the oil remains in the ground, and the energy costs of demobilizing the oil field and remobilizing at a new site is relatively high. The energy recovery is improved by injecting water or gas into the reservoir to maintain pressure. This reduces the remaining oil to 80%–40%. In most cases, there is more oil left in the reservoir than produced at the end of the economic lifetime of the oil field
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
