The production and the use of DRI (Direct Reduction Iron) are increasing today in developed countries, mainly by reducing the price of natural gas and the success of shale gas extraction technology. In addition, the lower level of contaminants in DRI than in metal scraps, led it to be considered a good alternative as metallic charge for the Electric Arc Furnace (EAF) and the process in LD / BOF converter. This work was one part of the cooperation program between Samarco Mining Company and Steel Group of the Pontifical Catholic University of Rio de Janeiro / PUC-Rio, which specifically dealt with the kinetic model for the metallization and carburization simultaneous in RD shaft furnaces. Under this purpose the reactor was divided into three zones: Reduction, Transition and Cooling. There were also three concentric regions considered: peripheral, media and center. Based on the results from experiments covering different types of pellets, using gas mixtures similar to those present in the industrial processes and obeying their corresponding fluid dynamic similarities, it developed a software called METCARB, which included in its preparation all kinetic equations and models developed experimentally in the three reactor zones of RD. The experimental part was therefore a major part of this work, together with the design of computational model and its industrial validations. With METCARB predictions about the simultaneous metallization and carburization in any internal region of the furnaces, it became possible, using as inputs the dimensions of the furnace, temperature measurements, compositions of gases, etc. The results of metallization and carburization also in graphic format are generated by the computer system, and the chronometric curves and results tables. Studies on two real cases were performed in order to validate the developed computational tool. It was found that the carburization always occurs simultaneously with the reduction of iron oxides and, depending on the temperature and composition of the gases; precipitation of fine carbon may occur. The simulations with METCARB model showed that the periphery of the ZR generated more DRI metallized than the center area. A contrary phenomenon has been verified with the carburization; With the experimental conditions used in this study, averages values obtained for the metallization and carburization in the final ZR vary between 0.4 - 0.7 percent C and 92 percent - 97 percent, respectively; It was not found that the progress of reduction degree occurred in the transition (ZT) and cooling (ZA) regions, in other words, it remained along these zones of the metallization values obtained at the bottom of ZR; The influence of water vapor in the carburization process in the case studies (0 - 4.25 percent H 2 O) takes a smaller percentage of carburization (2.7 percent C - 2.35).