Again, thank you very much for everyone's comments. I was concerned that my original post was too vague to get a substantial discussion going, but you've given me a lot of food for thought.
HotRod10 said:
If your model has the roof diaphragm rigidly attached to the beam, i.e. the connection is infinitely stiff (which is not the case in reality), whether continuously or at discrete points, it will act as a composite beam, will it not? I don't see how you get significant axial load into the beam otherwise. That being the case, unless the roof is modeled accurately with regard to stiffness, material strength, and restraint against buckling, then you could be significantly overestimating the capacity of the system. My experience with that type of software is limited, so I don't know whether the true buckling capacity of the roof can be modeled with a shell element, which would be perfectly flat and homogeneous (?), while the real roof is neither.
"...how would I go about accurately modeling that stiffness?"
The simple answer is that you wouldn't. You would ignore the roof in the structural model, other than assuming the beam is laterally braced at discrete points.
To your first point, you're right, the connection is infinitely stiff, and I now think this may be the issue. If I were to model it accurately, the rigid constraint should be replaced with some form of spring stiffness.
If I ignore the roof in the structural model, wouldn't there be a risk that I'm not adequately designing the beam? By virtue of connecting the roof to the steel, in reality there will be some load transfer through shear of the fasteners which in turn apply an axial load to the beam (albeit significantly smaller than the load calculated where I have the infinitely stiff connection between the two).
KootK,
Solid post. My comments are below:
KootK said:
Can you provide a bit more information with respect to the situation? Geometry and the load condition creating the axial forces?
The roof and beam are sloped, and the applied gravity loads are not perpendicular to its surface. So the applied reaction from the roof onto the beam would have one component that is normal to the surface of the roof and one that would be in-plane. However, as MrHershey correctly pointed out, when releasing the forces in the axial direction of the beam, the axial load went down significantly, so I was seeing an effect due to composite action.
KootK said:
My belief is that we should never base our work on the expectation that we know anything with any great degree of accuracy. That, because we really do not know anything with any great degree of accuracy. Rather, I think that it's a game of "somewhat intelligent general proportioning" rather than "knowing". It was a lot easier to see it that way back before software allowed us know things with considerably more precision than we once did.
That's precisely where I wanted to go with this thread and my own skills. Develop them further so that I can get a better sense of solving these problems, without having to over rely on the software, as its precision can be deceiving if the wrong assumptions are made.
KootK said:
Whenever this kind of thing comes up, you'll get some folks mentioning that often one kind of failure doesn't necessarily mean that your member is no longer fit to address another type of failure. Ductility and redistribution. Sometimes that's true but not always. If buckling is involved, that's usually non-ductile and the argument gets murky. In your case, one could see the beams possibly buckling torsionally under axial and then not being available to resist lateral loads. It's unlikely, and the beam may well unbuckle as you transition from one load case to another, but it's possible.
Adopting a "rough proportioning" mindset as a opposed to a "knowing" mindset has made the work a lot more enjoyable for me, truly. And I don't care if the codes do not explicitly allow this. The codes don't have to live with the vagaries and complexities of my work, I do.
So I guess, this is where the crux of this topic. How to determine whether I do get ductility and redistribution and ignore the axial loads to justify ignoring them.
KootK said:
My gut says that these axial loads can be ignored and probably should be for the sake of your own market competitiveness. If you're interested in taking this further, post some sketches and I'm sure that we can devise a plausible story for you to tell. That, right there, is the lion's share of what engineering management boils down to on the technical side. The plausible story that makes things easy and cheap.
One of the things my colleague and I discussed when reviewing the results, was specifically releasing the constraint in the axial direction of the beams. One possible justification we came up with was that since we know the roof material will fail in bearing long before shear failure of the fasteners, you would get excessive deformation in the hole, thus the axial load in the beam would never reach the values shown in the analysis.
MrHershey said:
You mention the beam is connected to the roof at a discrete point (I assume this is actually discrete points, plural) and things aren't modeled compositely. But if things are connected together without any force/moment releases then you'll get composite action whether you like it or not. Depending on how things are modeled, that may be where your axial is coming from.
Think of just a simply supported composite beam, steel wide flange with slab on deck. At midspan you'll have tension in the wide flange portion and compression in the slab. If you modeled things discretely and asked the program for the forces in just the beam, you'll get axial and it's real. But it's from composite action, it's not some global axial force. To check I'd turn shell stiffness parallel to the beams way, way down and see what you get. If axial goes away, that's your answer. You should also see your moments in the beam increase if composite action was the culprit.
Assuming that's your answer I'd tend to ignore the composite action (this assuming your diaphragm isn't concrete). That means either ditching the model or getting things modeled correct so you don't get composite action. While in real life you may get some composite action, it's not typically considered in design for lighter roofs. And to actually count on it you have to do way more than just look at beam axial. If you were in theory to consider this composite action, you would also need to design the actual diaphragm for its resultant axial force, ensure continuity of that axial force across any diaphragm joints or laps, and design the connectors from beam to diaphragm for horizontal shear transfer. One important thing in modeling is making sure you're consistent. If you're not discounting the composite action for the beam design, you need to follow through and not discount it for diaphragm and connection design either.
As mentioned in my response to KootK, doing as you suggested significantly reduced the axial loads, so this is an effect of composite action.
For your last paragraph, as you said typically for lighter roofs, composite action isn't considered because then you would need to design the roof for the resultant axial forces, continuity, joints etc., however in reality, the behaviour of that roof would be to act as a diaphragm and would see some of these forces. If the design doesn't take that into account, how is it that we don't see more roof failures because those forces were not taken into account in the design of the roof? I understand this concept when dealing purely with steel as we tend to limit the design to the yield strength of the material, so it has the capacity to go plastic and redistribute load etc.
