kestlerhawk
Mechanical
- Mar 22, 2011
- 1
Hello all,
sorry for the trouble, but i am completely trumped by this at the moment.
if i consider a rope hanging from two points under its own weight, i can calculate the deflection using a catenary function.
however, consider a circular cutout on the top of a box. if a sheet of my mylar is laid over that hole loosely, i can reproduce the deflection using a catenary curve, however, if i apply a vacuum in that box that sucks down on the mylar membrane, will the curve remain catanary?
i'm under the impression it will be more parabolic approaching spherical, and for our application the spherical assumption was used leading to errors i'm trying to fix right now.
i'm still under the impression the curve will be a modified catanary equation (similar towed line in water.)
i cannot find any academic material of this matter and any help would be greatly appreciated.
thank you in advance for your help.
regards,
sorry for the trouble, but i am completely trumped by this at the moment.
if i consider a rope hanging from two points under its own weight, i can calculate the deflection using a catenary function.
however, consider a circular cutout on the top of a box. if a sheet of my mylar is laid over that hole loosely, i can reproduce the deflection using a catenary curve, however, if i apply a vacuum in that box that sucks down on the mylar membrane, will the curve remain catanary?
i'm under the impression it will be more parabolic approaching spherical, and for our application the spherical assumption was used leading to errors i'm trying to fix right now.
i'm still under the impression the curve will be a modified catanary equation (similar towed line in water.)
i cannot find any academic material of this matter and any help would be greatly appreciated.
thank you in advance for your help.
regards,
