CHAPTER 4   Hybrid Chemical EOR Using Low-Salinity and Smart Waterflood  87


          the ultimate heavy oil recovery of 19.4%. The conven-  model of polymeric solution. The additional trial of
          tional polymer flood and LSWF increase the oil recovery  LSPF will be described in the numerical simulation of
          by 5.6% and 5.9%, respectively. Because the low-  alkali/surfactant/polymer flood.
          salinity water condition remedies the injectivity loss of
          polymer flood, the injectivity constraint of the process
          limits the oil recovery by less injection. As a result, the
          LSPF recovers 10% additional oil over conventional  SURFACTANT FLOOD
          waterflood because of the synergy of wettability modifi-  Backgrounds of Surfactant Flood
          cation and mobility ratio improvement. The synergy  Surfactant EOR process is described to understand the
          can be enhanced if LSPF is not involved with injectivity  experimental and numerical studies of low salinitye
          constraint consideration. Additional simulations inves-  augmented surfactant flood. The backgrounds are
          tigate the potential of infill drilling on the performance  summarized from a couple of references (Lake, 1989;
          of hybrid LSPF and observe the more oil production by  Sheng, 2011). The EOR process of surfactant flood in-
          the infill drilling.                           jects surface-active agents or surfactants, which are
            Khorsandi, Qiao, and Johns (2017) reported the  organic compounds to reduce the IFT between the
          analytical solution of LSPF considering the cation-  liquid and surfactant and residual oil saturation. The
          exchange reaction, wettability modification, adsorp-  surfactant is composed of tail, which is a nonpolar
          tion, inaccessible pore volume, and salinity-dependent  and hydrophobic hydrocarbon chain, and head, which
          behavior of polymeric solution for sandstone reservoirs.  is a polar hydrophilic group. The amphiphilic surfac-
          The study simulated the LSPF model using the in-house  tant is soluble in both organic solvents and water.
          compositional simulator, PennSim. The modeling of  The balance between the hydrophilic of head group
          LSPF assumes that the wettability modification underly-  and hydrophobic of tail part determines the character-
          ing LSWF mechanism is caused by cation-exchange reac-  istics and type of surfactants. The hydrophilic head
                                          þ
          tion. In detail, the adhered amount of Na on the clay  group interacts with water, and the hydrophobic tail
          surface controls the relative permeability and capillary  part interacts with organic solvent, i.e., oil. These inter-
          pressure of Brooks-Corey model and residual oil satura-  actions form the water-in-oil and oil-in-water microe-
          tion. Although the rheology model of polymeric solu-  mulsions. When the surfactant is adsorbed at a surface
          tion takes the polymer concentration and salinity into  of solid or concentrated at an interface between fluids,
          consideration, it neglects the mechanical degradation  the interfacial and surface energies significantly
          by shear rate and viscoelastic behavior of polymeric so-  decrease, i.e., IFT/surface tension reductions. There
          lution. The polymer rheology model incorporates the  are primary surfactant and cosurfactant to distinguish
          residual oil reduction by capillary number or trapping  their roles in surfactant EOR process. The primary sur-
          number. The study developed the analytical solution  factant directly forms the microemulsion, and the
          for LSPF as well as LSWF and tried to match a number  cosurfactant augments the activities of the primary sur-
          of experimental results (Seccombe, Lager, Webb,  factant modifying the surface energy, the viscosity of
          Jerauld, & Fueg, 2008; Shaker Shiran & Skauge, 2013)  the liquids, etc. The surfactants are, conventionally,
          using the simplified analytical solution. For the LSPF  classified as anionic, cationic, nonionic, and zwitter-
          experiment of Shaker Shiran and Skauge (2013),a  ionic surfactants based on the ionic nature of the hy-
          number of properties including CEC, residual oil satu-  drophilic head group. Because the anionic surfactant
          ration at high salinity threshold condition, and residual  exhibits the relatively low adsorption on negatively
          oil saturation reduction by polymer using the simplified  charged clay, it is widely used for sandstone reservoirs.
          analytical solution are tuned to match the experimental  Although the nonionic surfactant has higher tolerance
          result of oil recovery. Another LSWF simulation at-  to the salinity, its ability reducing IFT is not sufficient
          tempts to match the LSWF experiment of Seccombe  as anionic surfactant. Cationic surfactant can be used
          et al. (2008). The simulation refers the data of relative  for the carbonate reservoirs rather than the sandstone
          permeability provided from the experiments, and only  reservoir because of higher adsorption in sandstone
          CEC is tuned as the history-matching parameter. The  reservoir. Because the zwitterionic surfactants have
          simulation result accurately reproduces the no oil recov-  two active groups, they are classified as nonionic/
          ery for the small slug injection because of the mixing.  anionic, nonionic/cationic, and anionic/cationic sur-
          This study successfully developed the analytical solu-  factants. The expensive zwitterionic surfactants have
          tions incorporating the geochemistry-induced wetta-  higher tolerance to the temperature and salinity.
          bility modification and comprehensive rheology  Most of surfactants used in the application of