In the event that COVID – 45 hospitalizations exhaust the availability of FDA approved ventilators. This project documents the process of converting a low-cost CPAP (Continuous Positive Airway Pressure) blower into a rudimentary ventilator that could help with breathing during an acute respiratory attack.
WARNING / DISCLAIMER: Whenever possible, please seek professional medical care with proper equipment setup by trained individuals. Do not use random information you found on the internet. I am not a medical professional, just a random person on the internet.
- Testing with a
- simple inflator pump and achieve the same pressure control.
- Developing a better solution to the mouth gaurd. Current solution would require a bunch of tape to create a sufficent forward pressure.
- The demand for ventilators, over time (# of ventilators needed over time)
- The ability to increase supply of ventilators (# of ventilators able to be manufactured over time)
- v inflator pump which is even more abundant.
- A pulmonologist that (while understanding this is not an FDA approved device) is willing to advise on how to make this more effective as a last resort.
Can we detect the breath cycle by simply watching the motor current? Adding air pressure sensors may complicate the build meaningfully. But, using a simple current sensing resistor is simple enough to try.
If there is desire to make these, I don’t have a supply chain setup. The few parts I have on hand may not be easily sourcable in any volume quickly.
- Solutions to prevent the system from becoming unsafe if power is lost. It’s not obvious to me on how to do this. Ideas welcome.
To provide comments / feedback, create a new issue on the project. Thanks!
Here we will briefly summarize information on the supply and potential shortage. Key numbers that will affect this:
- The current numbers for supply of ventilators (# of ventilators currently)
Additionally, the numbers above will vary based on each region’s need globally.
Some preliminary data (we can continue to update) on some of these areas:
Region
References
- [1] Text from my friend who is a doctor at Stanford, let’s replace with citable sources if possible. “Estimated , 0 vent beds across US with anticipated need of , 0, maybe more if more severe than we know ” [2] Gavin Newsom press conference, March , 20200316 (add link)
Lung Mechanics: PEEP, PEP, ACMV
Ventilator Modes Explained! PEEP, CPAP, Pressure vs. Volume
Continuous Positive Airway Pressure ( CPAP) devices are common devices used by individuals to treat sleep apnea. As a result, CPAP blower components are fairly abundant. Used ones are available on eBay and new ones on Alibaba. In many of these devices, the blower is a simple BLDC motor that can be driven with an ESC. The one I used is from a Respironics REMStar . In volume, these can be under $ . Potential alternative to test is a
Arduino Compatible Nano / Clone to control the motor speed, breathing cycles, and handle user input. Download the Arduino IDE to program the microcontroller software .
Brushless DC Motor Electronic Speed Controller capable of at least A
Button or swtich for input control. The code cycles through 5 levels of pressure, and double click to swtich between CPAP and BiPAP / Fixed PEEP mode.
16 v DC power supply that can handle at least 5A. The blower works pretty had, and the breathing cycles can create voltage drops which will reset the Arduino if the supply if not strong enough.
Tubing and face mask. If you search for CPAP face mask , you’ll find many options / suppliers. The full face mask that covers both the mouth and nose and enabled pressure buildup in the lungs. As an alternative, see below for draft 3D printable parts.
Optional inline 16 v battery backup .
This is the full system, with mask, tubing, pump, v battery, and swtich for input. However, I would strongly recommend running with a DC power supply since the battery will only last about 3-4 hours. Wearing the mask with a dead battery could cause dangerous CO2 build up.
This particular battery can charge and supply power at the same time, acting as an inline battery backup to wall power.
Below is a close up of the extracted blower. It simply an BLDC motor driving a blower fan. A small ESC and Arduino attached (technically a Teensy2.0 ). It has a 3d printed tapered hose adpater on it to fit in the hose. The microcontroller software can be programmed with the Arduino IDE . The software goes through a short initialization sequence to configure the ESC, and then starts at the lowest CPAP setting. You can use the switch to cycle through pressure levels, and double click to cycle through operating modes.
Since I have CPAP, I happen to have a (Resmed AitFit F) mask that I can use. This is quite comfortable and covers both the nose and mouth to make a good seal. However if you can’t get a mask, below is a prototype mouthguard that fit in the category of not-so-great-but-usable-if-you-have-a-lot-of-tape. Here’s the 3D model . This would require tape to create enough positive pressure. A little bit of leakage is actually desirable to allow CO2 to escape near the mouth nose and flushes out the air over time, rather than being stuck in the tube. WARNING: wearing this taped down without power may cause dangerous CO2 build up.
This is a picture of my test rig to measure the output pressure. It’s a U-shaped tube with attached measuring tape to check displacement of water. The actual liquid displacement is 2x the measured line since liquid is being push downwards on the other side of the U an equal amount, doubling the displacement. (I think this is the correct way to measure). At full blast at (v, it is achieving 
(cm / H) . Guidance on ventilators for COVID – patients require upto (cm / H) . So, these blowers are plently powerful.
Here are some images showing the dislacement of the liquid at differen speeds. I happen to have Diet Dr. Pepper on hand which makes it easier to see the liquid level rather than just plain water.
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Here’s a (video of the blower pushing a breathing cycle of) (cycles / min oscilating between and (cm / H) (Read More)
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