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Finding equilibrium position
Hi!
Sometimes I have to evaluate the load inclination (see figure) and if it's acceptable without changing primary suspension slings (from the hook to the spreader beam).
Analitically is not complicated if secondary suspension are vertical (as in the figure) but if they are inclinated inward or outward and beam mass are taken into account is not simple
So I ask what type of analisisys is better for finding equilibrium position and where could be appropriare to apply friction and damping
I started with a simple model where the beam is composed by 2D elements and the load with 3D brick elements. Also slings are considered ad 2D elements (beam elements) because we are sure that there will be no compression
Thanks in advance
Sometimes I have to evaluate the load inclination (see figure) and if it's acceptable without changing primary suspension slings (from the hook to the spreader beam).
Analitically is not complicated if secondary suspension are vertical (as in the figure) but if they are inclinated inward or outward and beam mass are taken into account is not simple
So I ask what type of analisisys is better for finding equilibrium position and where could be appropriare to apply friction and damping
I started with a simple model where the beam is composed by 2D elements and the load with 3D brick elements. Also slings are considered ad 2D elements (beam elements) because we are sure that there will be no compression
Thanks in advance
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Comments
For greater inclination is necessary to change the length of the primary suspension
I started from the attached model (is like a simple pendulum) where I know what is the equilibrium position
Note: I noticed that increasing the elastic modulus of the beam the solution converge more slowly
Attached two runs, the second is wit Raleigh damping, alpha =0 and beta = 1s
As I understand with damping the system will finish in the equilibrium position.
Seocond step is to build a model with the load and for this case solution doesn't converge. I will attach another test
Solution seems to be right....the problem was related to the slings (beam elements) rotations
I guess your nonlinear static attempts could be failing because of rigid body motions.(It has happened to me).
Some hints:
1-I’m considering an only compression support for the base to capture the real lifting process.
2-I’m using only tension nonlinear springs for the slings.
3-If I were only interested in the final slope, I would consider spreader beam can only fail in the connection area with the slings or buckling. (truss). Slings can’t transfer bending moment.
4-Operators typically attach a rope to control the whole system under horizontal rotation.
5-The piece is considered suspended when reaction force on the last point in contact with the base is zero.
Compression only and nonlinear only tension springs require nonlinearity.
Quasistatic because I'm lifting the system linearly. Why?. Because only 3-legged tables do not limp. Better to check the lifting process when one corner is on the ground. I'm sure the slings are all in tension once suspended but it's not so clear to me how they split the load during the lifting maneuver.
In my understanding the dynamic option simulates the act of releasing the load and letting it hang without touching the ground (and damping coeffcients doesn´t matter as we look for the stabilized position), while the static option simulates lifting the load from the ground. I'm going to try to simulate some of my skids to see the feasibility in real life models with both options.