Gaia Rosch KPP.

Buoyancy kw Machines

I am opening this thread for Parts work on Buoyancy Generators

it is for believers to post parts 3d files and sourcing to aid those who know what they are doing

First Part we look for is air fittings  Here are some pictures
all assistance to find such supplier part number is welcomed.

Dan 

 in this video and picture you can see a  mechanical air on off lever operated by a cog on main shaft
all can be draw or suggested here  as a 3d print

https://youtu.be/ftp49tEQ0-o?si=p3l7p9MeIq7_zdGk

other options

Best Medium is Mineral oil
best bearing air bearing
best rotary tanks shape is oval
best tank tank is inverted cone
best Bubble maker voltrolysis
best chain is a belt
best materials are  light weight
Expanded Polystyrene (EPS):

EPS foam is extremely lightweight and buoyant.
It is commonly used in flotation devices and buoyancy applications.
EPS can be shaped easily and provides good insulation.
Polyethylene (PE):

Polyethylene is a versatile plastic known for its strength and low density.
High-density polyethylene (HDPE) is particularly strong and buoyant.
It is resistant to water and chemicals, making it suitable for marine applications.
Polypropylene (PP):

Polypropylene is lightweight and has good buoyancy characteristics.
It is resistant to moisture, chemicals, and UV radiation.
PP is often used in marine and aquatic applications.
Acrylonitrile Butadiene Styrene (ABS):

ABS is a lightweight, rigid plastic that combines good strength with buoyancy.
It is resistant to impact and can withstand submersion in water.
Polyurethane (PU):

Polyurethane foam can be used for buoyancy, especially in applications where flexibility is needed.
It can be molded into various shapes and densities.
Polyvinyl Chloride (PVC):

PVC foam boards can provide buoyancy and are relatively lightweight.
They are also resistant to water and chemicals.
When selecting a plastic for your float tanks, consider factors such as the specific buoyancy requirements, structural integrity, and any additional features you need (e.g., resistance to chemicals, UV resistance). It's important to calculate the required buoyancy force and design the tank accordingly to ensure it can support the desired weight while remaining buoyant.

Additionally, the design and construction of the tanks, such as the use of reinforcement materials and the overall geometry, will play a crucial role in achieving both buoyancy and structural strength. Consulting with a materials engineer or a plastics expert can help you choose the most suitable material and design for your specific application.