- #1
resjsu
- 12
- 0
Hello,
See attached PDF for basic depiction of an issue I am currently working on.
If lid starts off with angle = 0 (closed) and I fling it open until it hits the "stop" (interferes with bottom causing it to stop), how fast must lid being traveling to tip over entire assembly? From this I want to see how much force I must apply to get lid traveling at specified speed.
My approach was to use conservation of angular momentum and find the lid angular momentum at the instant it reach the max opening and then insert this momentum into the momentum equation for the assembly, which would give me the velocity the assembly would experience correct?
But I cannot make the connection of how to then equate if the assembly will actually tip because in the static diagram I know the moment the weight of the assembly (counter balance) is exerting and it is in ft-lbs. But, when I calculate for angular momentum the assembly experiences it is in (lb-ft^2)/s
Any guidance at all would help.
Thank you
See attached PDF for basic depiction of an issue I am currently working on.
If lid starts off with angle = 0 (closed) and I fling it open until it hits the "stop" (interferes with bottom causing it to stop), how fast must lid being traveling to tip over entire assembly? From this I want to see how much force I must apply to get lid traveling at specified speed.
My approach was to use conservation of angular momentum and find the lid angular momentum at the instant it reach the max opening and then insert this momentum into the momentum equation for the assembly, which would give me the velocity the assembly would experience correct?
But I cannot make the connection of how to then equate if the assembly will actually tip because in the static diagram I know the moment the weight of the assembly (counter balance) is exerting and it is in ft-lbs. But, when I calculate for angular momentum the assembly experiences it is in (lb-ft^2)/s
Any guidance at all would help.
Thank you