VISHNU S (STM20ME020)

ABHINAND K 2 (STM20ME001)

SAYOOJ K M (STM20ME018)

This study presents the design and development of an innovative ventilator system incorporating a camshaft mechanism for enhanced respiratory support. Traditional ventilators rely on piston-driven or turbine-driven mechanisms, which may have limitations in terms of precision and adaptability to patient needs. The proposed ventilator leverages a camshaft system to provide precise control
over airflow, tidal volume, and respiratory rate. The camshaft-driven ventilator offers several
advantages, including customizable breathing patterns, precise control, portability etc.The design
incorporates sensors and algorithms for real-time monitoring of patient respiratory parameters.
The camshaft mechanism's mechanical simplicity and efficiency make it a promising candidate for
reliable ventilator systems. This research opens up new possibilities for innovative ventilator
designs that can potentially address critical respiratory care needs more effectively

In critical medical situations, the need for efficient and reliable ventilators is paramount to support
patients with respiratory distress. This abstract introduces a novel approach to ventilator design,
utilizing a Cam Shaft Mechanism to enhance functionality and address specific challenges in
traditional ventilator systems. The proposed ventilator integrates a precisely engineered cam shaft
to regulate the airflow and pressure, providing controlled breathing assistance to patients in a more
adaptive and responsive manner.

The Cam Shaft Mechanism offers several advantages over conventional designs, including
improved synchronization of breathing cycles, reduced mechanical complexity, and enhanced
flexibility in adjusting ventilation parameters. The cam profile is tailored to achieve precise control
over the inhalation and exhalation phases, optimizing respiratory support based on the patient's
unique needs.