Diluted polymeric solutions can be used in Oil & Gas industry for reservoir injection as mobility control agents in enhanced oil recovery technics, which goal is to increase the oil field recovery factor and postpone the high water production rates. However, the macroscopic expected phenomena, increase of the areal sweep, is directly influenced by microscopic factors that occurs at the pore scale. Due to their huge molecular chains, by advancing through the porous media, high molecular weight polymer solutions hinder the water flow changing the water/oil mobility ratio. Nevertheless, the comprehension of polymeric solutions flow is still a great challenge due to the Non-Newtonian behavior of the flow rate x pressure gradient relation and the sensibility to several variables such as: type of polymer used, concentration, viscosity ratio, temperature, salinity and shear rate. The present work analyzes the implementation of two constitutive models, Oldroyd-B and FENE-CR, coupled with the Finite Element method using the Galerkin weighted residual formulation to model the flow of diluted polymeric solutions through constricted capillaries and understand the viscous and elastic phenomena involved. The obtained results provide a more detailed portrait of the constitutive models and the flow of diluted polymeric solutions through pore throats.