Hello lemgineers!
I’m working on designing a claw that can be operated underwater. The plan is to use a linear actuator in a waterproof housing. The main issue is allowing the shaft to slide through without causing a leak. What’s the best way to go about this?
If you have an air line to the surface, then running the enclosure at positive pressure to negate the force of water pressure at depth might be a starting point.
I would also reconsider whether a linear actuator is the right approach. A hydraulic piston external to the housing where your motor resides reduces the complexity of any waterproofing, and might be a better approach if you’re dealing with significant depths/pressures.
If the travel distance of the rod is fairly limited, you can use a corrugated boot.
Otherwise, maybe a gland seal with positive air pressure on the dry side?
Would depend on how deep underwater and the pressure and so forth, but maybe look at how steam engine piston rods are sealed - an o-ring or a wiper seal would probably do the job
Look at the gland end of any hydraulic cylinder.
If you need a shaft to slide through the wall of your housing, Google “shaft seal” or “oil seal.” The seal usually presses into a hole in your housing, so you will want the housing to be metal rather than plastic.
https://www.mcmaster.com/products/shaft-seals/
A dynamic seal like this is going to be difficult to implement. The shaft will need to be very smooth and carefully aligned to the housing. Some small amount of water is likely to get past the seal.
I’m with @[email protected]. Consider other ways to actuate your claw that don’t require moving a part through the housing wall. I’m addition to pneumatic or hydraulic actuators outaide your housing, here’s an idea using magnets and screws:
https://org.osu.edu/osu-uwrt/2022/04/11/underwater-claw-development/
Consider a hydraulic actuator that already works underwater?
I’m late to the party, but I’m not sure why nobody mentioned the keyword “stuffing box”. That’s what this exact part is called in maritime operations, and as the name suggests it was traditionally a box packed with something to slow down the movement of water. You still have to bail on the other end, though, because it’s not perfect.
However, since it’s just a linear actuator it’d be simpler to go with an accordion-type covering. At shallow depths you could use a normal plastic one, if it needs to go deep metal ones exist. That’s much simpler to deal with than an actual sliding bearing.
Sorry I’m just now seeing this, and late to the party is just fine 😍 I’m looking at redesigning it this year anyways!
I’m not sure if this is similar to what you meant by an accordion covering, but what we did was design a mold that we 3D printed and poured silicone into to create a seal/cover that will stretch as the piston of the linear actuator slides in and out.
I meant with the pleats, similar to what you see on an actual accordion, or in a bendy straw. It’s how they did the joints on the Apollo space suits, for a vaguely similar application. The shape is sometimes called “bellows”, but that’s pretty confusing when it also refers to an air blowing technology that may or may not involve a diaphragm of any kind.
If you got enough range of movement with just a straight elastomer cylinder, that works, but if the pressure is pretty modest a variety of stretchy ducts made for HVAC or other home purposes are sold. I have some for draining rainwater, but they seem to break in stiff wind, so YMMV. You could also mold your own again.
We actually did start out with an accordion/bellows design, but found that the flexibility of the material alone was more than sufficient to handle the required distance of travel on the actuator piston!
Thanks for all your responses! I should have mentioned that pneumatics and hydraulics are off the table at this time.
Right now we’re thinking of manufacturing a flexible seal that can travel with the rod while maintaining a seal with the housing. That might be over engineering a bit, but we’ll be doing some testing this week to see how it goes!