The movement of air from the environment to the alveoli is a vital and complex phenomenon that occurs due to variations in intrathoracic and airway pressures in relation to the atmosphere. The construction of didactic prototypes can minimize the abstraction required in these in vivo phenomena. In this study, we automated a didactic prototype of pulmonary ventilation already described in literature to simulate and exhibit variations in intrathoracic pressure during diaphragmatic function. A pulmonary ventilation (PV) prototype was produced with recyclable materials, and automated by adapting a pressure sensor in the system to generate pressure curves as a function of time during the simulation of diaphragmatic function. The automated plunger’s downward traction induced by the servomotor (such as diaphragmatic) reduced the pressure inside the bottle (intrathoracic), and this variation can be observed graphically on a computer interface while the balloon was expanded, and atmospheric air invaded its interior. Conclusion: The incorporation of technology into a simple PV prototype allowed a safe and simulated demonstration of how the diaphragm induces the variation of the intrathoracic pressure in relation to the atmosphere concomitantly with the pulmonary deformation that occurs during inspiration and exhalation.