An engineering team from the University of Johannesburg (UJ) has designed and developed a portable three-dimensional- (3D-) printed mechanical ventilator that has a customisable base plate to treat multiple patients.
The ventilator, named Aura Imprimere – meaning a breeze of air provided by printing – also allows off-grid operation for up to 1.5 hours should electricity supply be cut.
UJ Department of Mechanical Engineering Science head and project team leader Professor Tien-Chien Jen says the “unique 3D-printable ventilator” uses a microcontroller to control the operation of the two motors.
“By adjusting the speed and direction of rotation of the motors, it is possible to obtain a pressure-time profile that is suitable for the respiratory assistance of patients.
“Its components are also designed in such a way that it can be easily assembled on site in cities, rural areas or remote areas,” he adds.
The microcontroller monitors the pressure inside the ambu-bag by using a pressure sensor.
If the pressure sensor picks up irregularities in the pressure, the motor controller will intervene to correct these issues.
It is also important that the mechanical arms of the ventilator operate in unison, explains Jen.
“Sensors that monitor the position of the ventilator arms are used to enable the microcontroller to keep the mechanical arms of the ventilator in sync.”
The UJ-led team plans to distribute the active breathing circuit system on an open-source basis, making the software and designs freely available so that the ventilator can be produced anywhere in the world, provided that the producers own a 3D printer.
Aura Imprimere is based on a reciprocating engine piston and crank design.
The motors were extracted from locally bought electric screwdrivers.
The ventilator allows for electronic components, such as a control resistor, a variable resistor and a small programmable computer to be used.
The design is such that the friction between moving parts is minimised.
“The ambu-bag comes in different sizes, and the invention can be custom-changed with ease, on site, according to the patient age, condition, and breathing necessity,” notes Jen.
“This is due to the meshed base plates that allow the clamps, mechanism, electrical housing, and so forth, to be reorientated and placed as the consumer pleases – as inspired by Lego-type designs.”