The pursuit of sustainable polymeric materials has driven the development of epoxy systems derived from renewable sources, such as epoxidized soybean oil (ESO). Understanding their curing kinetics is essential for process control and optimisation of final properties. In this study, the curing behaviour of ESO/MTHPA/DEH 35 (epoxidized soybean oil/methyl tetrahydrophthalic anhydride/2,4,6-tris(dimethylaminomethyl) phenol) systems—with and without a tin-based catalyst (Tin) (Tin(II) 2-ethylhexanoate)—was evaluated using the isoconversional Friedman method. Samples were analysed via Differential Scanning Calorimetry (DSC) at heating rates of 5, 10, and 20 °C/min. Data were processed using the differential form of the conversion equation (α) to obtain the apparent activation energy (Ea) as a function of conversion. Model validation was achieved by comparing experimental and calculated conversion values (αexp vs αprev), and by linear regressions of ln(dα/dt) versus 1000/T. The Friedman model adequately described the kinetic behaviour of both systems. The Tin-containing formulation started curing at higher temperatures (~140–150 °C), indicating a greater initial energy barrier. The Ea(α) curve showed high values (~80 kJ/mol) for α < 0.2, attributed to the formation of high-energy catalytic complexes. For α > 0.2, a sharp decrease in Ea (< 20 kJ/mol) indicated the onset of autocatalytic propagation. In contrast, the system without Tin exhibited stable Ea values (~45–55 kJ/mol), suggesting a more homogeneous and thermally controlled process. Regression coefficients (R² > 0.98) and sigmoid fits (deviation < ±10%) confirmed the model’s validity. Overall, the Friedman method proved effective for describing the curing kinetics of these bio-based epoxy systems. The presence of Tin led to a multifaceted and accelerated curing mechanism, while its absence resulted in a simpler, thermally governed process with lower chemical complexity.