Oil wells drilling in adverse environments requires specialists dedicated to study the drilling process to ensure a quickly, safely and quality performance. In this context, experimental and numerical studies can be find in technical literature that evaluate the cutting action done by a single cutter aiming to quantify the contact forces, proposing solutions to increase its useful life time and its rate of penetration, and to understand the cutting mechanism. Following this line of research, this Thesis aims to provide a better understanding regarding the rock / polycrystalline diamond compact cutter interaction during the halite deposits and carbonate reservoirs drilling. The study was approached through numerical modeling of the single cutter test and through numerical modeling of the cutting action by multiple cutters using the discrete element method. Experimental results were used to calibrate the synthetic sample and the rock cutting numerical models. A parametric numerical study of the single cutter test was done aiming to identify parameters that control the cutting action. Then, an analytical equation was developed that quantifies the global mechanical specific energy resulting from the cutting action of multiple cutters, in order to understand and quantify the contribution of each cutter to overall efficiency. The equation was applied using the results of numerical modeling of multiple cutters developed in this work. It was verified that the good agreement between numerical predictions and experimental results validated the use of the discrete element method to model the cutting process in different rock types. The numerical modeling developed in this study can be considered a useful tool for design and optimizing the performance of drill bits.