In this research, p-PANI was prepared in a solution containing 0.15 M aniline and 0.20 M phosphoric acid (pH = 2.19) on a low carbon steel (SAE 1018) substrate by a 2.00 V DC power source in order to study the anti-corrosion effect of the electropolymerized film. Comparing the corrosion potential of p-PANI/steel with the bare steel by the Tafel plot (scanning rate, 1 mV/s; potential range, -0.9 V to -0.1 V), the former is 111 mV higher than the latter. The blue p-PANI had two XRD peaks at 2θ = 20.35° and 25.48°. They are probably due to the long range ordering of the quinoid and benzenoid rings. The rings have a length near 4.39 Å and the parallel packed polymers have a van der Waal distance of 3.51 Å. FT-IR spectra of the p-PANI show absorption bands at 1578 cm-1 and 1490 cm-1 corresponding to the quinoid (C=N) and benzenoid (C=C) rings, respectively. The p-PANI/steel film has a porous morphology observed under SEM. Dissolving the p-PANI in DMF, the 618 nm absorption corresponding to the π-π＊transition is found in the UV-Vis spectra that is a characteristic peak of emeraldine base. Adding a PPDT, poly(2-N-phenylamino-4,6-dimercapto-S-triazine), layer between PANI and steel. PPDT is strongly adsorbed on the surface of steel and allows low permeability of water and oxygen. As a consequence, the corrosion potential of p-PANI/PPDT/steel is further increased, 200 mV higher than the bare steel. Hence, the p-PANI/PPDT bilayer material has a better anti-corrosion effect.