Biodiesel is a biofuel typically produced from transesterification and/or esterification of vegetable oils (eg soy and palm oil) which is made up of different types of fatty acids such as, for example, oleic, linoleic, linolenic acid in different compositions. However, among the articles found in the literature that address simulations and intensification of industrial processes in the production of biodiesel, the chemical composition of the oil is simplified, reducing it to the highest concentration triglyceride. In order to analyze the intensification of the process of obtaining biodiesel from soybean oil, using reactive distillation, initially, a comparison of the properties of biodiesel, such as density, viscosity and composition, produced via homogeneous and heterogeneous catalysis was performed, considering - the total chemical composition of soybean oil and considering only the major triglyceride, composed of one molecule of oleic acid and two of linoleic acid. The analysis confirmed that there is no significant change in the results in replacing the biodiesel composition with a single fraction of triglycerides, due to the proximity of physicochemical properties. In view of this, the development of simulation and process intensification was developed from the major component in soybean oil. Considering the lack of complete information relating composition studies, reactive distillation, energy integration and economic evaluation, the thesis complements a methodology to simulate the production of biodiesel via homogeneous and heterogeneous catalysis, using reactive distillation (DR), energy integration and considering the financial feasibility of all studied flowcharts. The simulations developed resulted in a better use of the energy present in the available hot currents, thus reducing the investment in utilities. It was concluded that when using reactive distillation, for homogeneous and heterogeneous catalysis, there is energy to be saved, around 30 to 48 percent, that is, there is availability of modification in the process so that there is a better use and energy saving. From this, energy integration was used, using the energy reuse system, obtaining a better scenario for the energy study, providing savings of 70 percent and 65.8 percent of energy in homogeneous and heterogeneous processes, respectively. As for the economic feasibility, it was considered the capacity of the process with a useful life of 15 years and the simulations indicated positive yields and are suggested to be economically viable. However, by employing reactive distillation with process intensification, the reduction of energy and financial costs with the heterogeneous catalyst proved to be the best option energetically and economically. Comparing the system with expenses, the initial homogeneous, with the economic, mentioned above, the energy savings of the utilities was around 80 percent and the difference in the net present value (NPV) of 744,089.84 dollars. The result showed that the investment in more process current heat exchangers, added to the reduction of equipment in the heterogeneous catalysis path, allowed to reach a more attractive alternative cost ratio than the traditional process via homogeneous catalysis, even though the cost of the catalyst is higher in the heterogeneous case.