Model Aircraft Styled Air Engine, Experimental




Introduction: Model Aircraft Styled Air Engine, Experimental

About: The more mistakes I make, the more knowledge I gain.

The first in my model aircraft compressed air powered engine series, "Model Aircraft Styled Air Engine, Experimental" was the result of yet another challenge; build a single cylinder compressed air engine using the fewest number of parts, and all 100% 3D printed.

Weighing in at a mere .8 ounces (25 grams), this engine requires only 8 3D printed parts (only one more than my "3D Printed "Wobbler" Style Air Engine" design), no purchased parts, and incorporates a rotary valve (as I used before in my "Four Cylinder Air Engine, Experimental" design) with a difference. The rotary valve used in this design was inspired by the 1933 work of Joseph S. Ott (and no, I wasn't around then to see it) which utilizes the propeller axle as both an axle and a valve. The valve timing is determined by the angular offset between the flat surfaces on the axle and the pin on the journal. As an added bonus, the design provides a fairly decent exhaust system.

I learned quite a lot during the design of this engine, and used that knowledge in subsequent engine designs for model aircraft use. While this early version will not necessarily propel an aircraft, it does make quite a conversation piece around my workshop. It will indeed test your 3D printer capabilities.

You will need a 1/4" threaded compressor adapter and compressor to operate this model. If you do not wish to 3D print the propeller, a 6 by 5.5 E propeller with a 6.2mm center hole will work.

As is usual, I probably forgot a file or two or who knows what else, so if you have any questions, please do not hesitate to ask as I do make mistakes in plenty.

Designed using Autodesk Fusion 360, sliced using Cura 3.0.4 and printed in PLA and PVA on an Ultimaker 2+ Extended and an Ultimaker 3 Extended.

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Step 1: Print the Parts.

Print one each of the parts. I printed "Axle Propeller.stl", "Propeller 3 Blade.stl" and "Spinner.stl" with 100% infill and a .15mm layer height. I printed the remaining parts at 20% infill and .15mm layer height.

"Block.stl", "Propeller 3 Blade.stl" and "Spinner.stl" must be printed with supports.

I printed my block using red PLA with natural PVA for support using a Cura 3.0.4 support overhang angle setting of 40. At this setting, Cura 3.0.4 also places PVA support material inside the air passageways which, after printing, will dissolve in a water bath. When not using PVA (or dual extrusion), make sure the slicer does not place support material in the air passageways as it will not be accessible for removal after the print is completed, thus the engine will not work.

I printed my propeller and spinner with a Cura 3.0.4 support overhang angle setting of 60. Check your slicer for the best settings for your printer.

Prior to assembly, test fit and trim, file, sand, etc. all parts as necessary for smooth movement of moving surfaces, and tight fit for non moving surfaces. Depending on the colors you chose and your printer settings, more or less trimming, filing and/or sanding may be required. Carefully file all edges that contacted the build plate to make absolutely sure that all build plate "ooze" is removed and that all edges are smooth. I used small jewelers files and plenty of patience to perform this step. "Piston.stl" and "Axle Propeller.stl" must slide / rotate respectively smoothly but not "loose". If these two parts are too tight, the engine will not operate, and if too loose, excess bypass air will escape and degrade engine performance.

This design uses threaded assembly, thus a 6mm by 1 tap and die may be needed to clean the threads.

Step 2: Assembly.

Place the small end of "Rod Piston.stl" into "Piston.stl", then secure the rod in place using "Pin Piston.stl" as shown.

Thread "Axle Propeller.stl" into "Journal.stl", carefully noting the final orientation of the axle in regard to the pin on the journal as shown. This is important as it controls the timing of pressurized air into the cylinder as well as the exhaust air from the cylinder.

Slide the piston assembly into position in "Block.stl" as shown.

While carefully flexing the piston rod to the side, slide the axle assembly into the block, then place the large end of the axle over the pin on the journal as shown.

Place "Spinner.stl" into "Propeller 3 Blade.stl" then thread it into the axle as shown.

Thread the 1/4" compressor adapter into "Adapter Compressor.stl" as shown, then thread this assembly into the block as shown.

Step 3: Operation.

Always wear appropriate safety equipment (safety glasses, face shield, etc.) when operating this model.

Connect the model to a compressor using a quick disconnect.

Set the compressor air pressure to around 5PSI

Spin the propeller counter clockwise (as viewed from the front of the model) as shown in the video. If the model doesn't start, slightly increase the pressure and try again.

Hope you like it!

To be continued...

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    3 Discussions


    2 years ago

    Hi, nice work! Saw your projects a while ago and find them interesting. Thanks for sharing. Just in case you weren't aware, Tom Stanton has been working on a similar project: and


    Reply 2 years ago

    Thanks, glad you liked it!

    I have seen those links and communicated briefly with Tom, very nice work.

    After some testing, I chose to not use the Air Hog style valving as it is quite inefficient as compressed air is introduced into the cylinder before the piston reaches top dead center. This design, and my newer ones, allows the valve timing to be adjusted such that compressed air is introduced into the cylinder after the piston passes top dead center.

    Thanks again!



    Reply 2 years ago

    Interesting, thanks for elaborating. Looking forward to seeing where you take this next.