Corrosion inside the injection water pipe occurs from the Central Injection Facility Station to the wellhead. One way to reduce the rate of corrosion is to add inhibitors. This research is looking for the effect of variations in the concentration of the sodium chromate inhibitor (Na₂CrO₄) on the corrosion rate of API 5L grade B pipes used in the oil industry, especially in injection water fluids. For comparison, a corrosion rate test was carried out on a 3.5% NaCl solution. The study used an NPS 4 SCH 40 pipe with an outer diameter of 4.5 in (114.3 mm) with a thickness of 0.237in (6.02mm). The concentration parameter of the Sodium Chromate inhibitor used is 0.1; 0.3; 0.5; 0.7 and 0.9%. The study used a corrosion rate test using the potentiodynamic polarization method. The results showed the pipe corrosion rate in the injection water fluid was 0.3307 mpy, and the pipe corrosion rate in the 3.5% NaCl solution was 0.4960 mpy. The addition of chromate inhibitors succeeded in decreasing the corrosion rate. The maximum condition is achieved with the addition of 0.9% inhibitor. In this condition, the corrosion rate of the pipe in the injection water solution is 0.2175 mpy and the corrosion rate of the pipe in the 3.5% NaCl solution is 0.3218 mpy.

Annual book of ASTM Standards, ASTM G59-97 Standard Test Method for Conducting Potentiodynamic Polarization Resistance Measurement, ASTM International, 2014.

Annual book of ASTM Standards, ASTM G102 Standard Practice for Calculation of Corrosion Rates and Related Information from Electrochemical Measurement, ASTM International, 2015.

API Specification 5L, Specification for Line Pipe, 2012.

ASM Handbook, Laboratory testing, Volume 13, 1992, ASM International.

ASM Handbook, Aqueous Corrosion Reaction Mechanism, Volume 13A, 2003, ASM International.

ASM Handbook, Methods for Determining Aqueous Corrosion Reaction Rates, Volume 13A, 2003, ASM International.

ASM Handbook, Passivity, Volume 13A, 2003, ASM International.

Diaz, M.D, Aguilar, M.A.D., Tobon, A.C., and Dominguez, B.C., Corrosion Inhibition of pipeline steel X-70 in Sour Brine by an Imidazoline Derivative underflow assisted corrosion, International journal of electrochemical science, 12, 2017, 7481-7501.

Faraq, A. and El-din, M.R.N., The adsorption and corrosion inhibition of some nonionic surcfactants on API X65 steel surface in hydrochloric acid, Corrosion Science, 64, 2012, 174-183.

Finšgar, M., and Jackson, J., Application of corrosion inhibitors for steels in acidic media for the oil and gas industry: A review, Corrosion Science, 86, 2014, 17–41.

Gonzalez, J.A., Vazquez, A.E., Romo, M.R., Chavarin, J.U., and Pardave, M.P., Electrochemical evaluation of cephalotin as corrosion inhibitor for API 5L X52 steel immersed in an acidic medium, Arabian journal of Chemistry, 2015.

Joseph, O.O., Sivaprasad, S., and Fayomi, O.S.I., Comparative study on the effect of NaNO2 in corrosion inhibition of micro-alloyed and API 5L X65 steels in E20 simulated FGE, Energy Procedia, 119, 2017, 953-960.

Meresht, E.S., Farahani, T.S., and Neshati, J., 2-Butyne-1, 4 diol as a novel corrosion inhibitor for API X65 steel pipeline in carbonate/bicarbonate solution, Corrosion Science, 54, 2012, 36-44

Oliviera, L.A., Effect of silicate-based film on the corrosion behavior of the API 5L X80 pipeline steel, Corrosion Science, 139, 2018, 21-34.

Oliveira, M.C., Figueredo, R.M., and Acciari, H.A., Corrosion behavior of API 5L X65 steel subject to plastic deformation, Journal of materials research and technology, 2018.