understanding stability and buoyancy in rovs
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Understanding Stability and Buoyancy in ROVs. Fred Donelson Bob Richards Jim Fannin. When you think about getting into a water craft, there are at least two major factors that you consider …. Most folks would like to ride in a craft that. Doesn’t tip over (is stable) - PowerPoint PPT PresentationTRANSCRIPT
Understanding Stability and Buoyancy in ROVs
Fred DonelsonBob Richards
Jim Fannin
When you think about getting into a water craft, there are at least two major factors that you consider …
Most folks would like to ride in a craft that
• Doesn’t tip over (is stable)• Doesn’t sink (is buoyant)
When designing and building an ROV, we want the same thing:
• A craft that is stable and doesn’t tip over
• A craft that is buoyant enough so that it can be maneuvered easily up or down without using too much energy
So a very simple but important question is:
How do we make things float?
to find out …
So at least two factors are important to consider for
buoyancy:
• Weight (mass x gravity)• Volume
So, based on these two factors …
Would a kayak float?
Click on the picture at right to
find out!
Yes … provided the conditions were
right!
Now when things are sinking, rotating or floating, that most likely means some physical forces are
involved!
So click the link below to find out the mathematical calculations
relating the forces of buoyancy and the forces of gravity
http://www.youtube.com/watch?v=woIct8d6j_8&feature=relmfu
Of course, watching someone else do these
calculations isn’t as good as actually playing with
them yourself!
Now go to this link Read the instructions, watch the demo, and then play with the simulation until you have a good understanding of how changing volume or changing mass affects the interaction of the forces of buoyancy and gravity!
Think you have it now?How much weight can your ROV
hold without sinking?
Watch this video demonstration using a plastic cup as a simulated ROV!
http://www.youtube.com/watch?v=HTMwM81J48M
Stability of an ROV is affected by the distance between the center of
gravity (Cg) and the center of buoyancy (Cb)
Could you build a simple craft and illustrate this principle like in
this clip?
Can you come up with a general “rule” that would ensure that your ROV would always remain stable
and not tip over?
(Hint: think relationship between Cb and Cg)
Think you have this buoyancy/stability thing down?
Take a few minutes and click on this guy to see!