A seemingly simple question but in fact very difficult?
A seemingly simple question but in fact very difficult?
(OP)
Please see attached file.
The base plate is adequate. the 300 kips-in overturn moment can be in any direction.
Required: What is the maximum tension (kips) in anchor bolt.
Note: only left hand drawing is in original question. The right hand drawing is based on my analysis, it may not be correct. You can ignor it.
The base plate is adequate. the 300 kips-in overturn moment can be in any direction.
Required: What is the maximum tension (kips) in anchor bolt.
Note: only left hand drawing is in original question. The right hand drawing is based on my analysis, it may not be correct. You can ignor it.






RE: A seemingly simple question but in fact very difficult?
& 45 degrees (1 bolt and concrete triangular dist)
RE: A seemingly simple question but in fact very difficult?
1. What is the requirement for stiffness? I.e. do you have a maximum assumed rotation?
2. Do you have an uplift force?
3. What grade bolt are you using?
4. Base plate thickness?
You may ask why do i want to know all this additional information, and the reason is in semi-rigid design there are a few methods for design, I personally like for the base plate design the component method by Wald F et al. And these inputs allow you to select you plate mode. Ie prying ect.
When in doubt, just take the next small step.
RE: A seemingly simple question but in fact very difficult?
RE: A seemingly simple question but in fact very difficult?
RE: A seemingly simple question but in fact very difficult?
RE: A seemingly simple question but in fact very difficult?
One problem is that people want to over-analyze it. The appoach used in the tank codes is to assume that stress distribution in the tank/stack is Mc/I, and then assume that anchor loading must be distributed similarly, so the anchors are just treated as a ring of metal of equivalent area. And this seems to be carried to its logical conclusion in the large transmission towers that are supported by the bolts, with no contact between the base plate and concrete.
The alternate approach is to take a section immediately below the surface of the concrete, and analyze it as a composite steel-concrete section, and derive the anchor distribution from that assumption. The flaw is that anchor loading immediately above the concrete must be the same as immediately below the concrete, so making assumptions that give you different numbers above and below doesn't really gain anything other than complication.
In the case of your right-hand sketch, I think the flaw is that you have no rational basis to determine that triangular loading. In fact, the base plate is flexible and 2-dimensional, and contact stresses would very across the face, not just linearly along an axis. There is also going to be SOME amount of bolt pretension, and that unknown amount of pretension will also result in a distribution of contact stresses across the bolt area. So you can make one assumption and calculate bolt loads simply. You can make a different assumption and work through a bunch of math and come up with a bolt load, but it's still based on your assumptions. It's not immediately clear if you've gained anything by the complication in that case.
Two solutions come to mind. One is to refer to standards governing the type of construction, and see if there is a codified approach. This won't necessarily be more accurate than whatever solution you derive on your own, but using a method and an allowable stress that have proven to be satisfactory is an acceptable approach, even if the theory leaves something to be desired. The second solution is to support the base plate on the bolts, which simplifies the problem. There are many cases where it is easier to change the geometry to fit the math than the other way around.
RE: A seemingly simple question but in fact very difficult?
but would you allow the baseplate to crease along edge of the compression field ? are you looking for the ultimate strength (plasticity) or a near enough approximation, in which case plane sections remain plane would be reasonable.
how do you take bolt preload into account ... on the tension side it's reasonably easy (gapping, physical extension of the bolts, rotation of the baseplate) ... on the compression side ?
RE: A seemingly simple question but in fact very difficult?
RE: A seemingly simple question but in fact very difficult?
It is common practice to assume the base plate is rigid. Additionally, you can only count on an equivalent area of steel for the anchor rods if there is some mechanchism by which the rods can take compression. This may be common for transmission towers/lightpoles with nuts under the plate, but is not common for the large % of baseplates.
I used the LRFD approach and assumed a rectangular pressure distribution (not triangular) with the magnitude = phi*(0.85)*f'c. The compression area was so large (8.5" - even with 8ksi concrete) that only one anchor was in tension. Technically, it would have had (3) in tension, but two are so close to the NA that it is reasonable to neglect them.
RE: A seemingly simple question but in fact very difficult?
If you assume that the bending moment in the base plate is negligible, then you can immediately calculate the anchor force, which will be the same as if the column were supported on the bolts. If you assume that the bending moment in the base plate IS significant, then the assumption of a rigid base plate would appear to be questionable. Or you could assume that bending in the base plate is negligible, and assume that bending stresses in the column do not follow the Mc/I distribution, but then you're left without a column analysis. So it seems to me you can work this different ways, but it is not obvious which is actually better- all involve rather gross approximations.
Note also that for the example shown, with pure moment, if the compressive loading turns out to have its centroid out beyond the far bolts, then you get a less conservative approach than assuming the load on the bolts only.
RE: A seemingly simple question but in fact very difficult?
No downward force or base shear.
Is this a free-standing post with an outrigger supporting a load that can swivel 360 degrees around the base or is this a free-standing sign under storm wind loads or is this a column that is part of a moment frame.
Is this an actual assembly or a theoretical assembly. The question asks for what is the MAXIMUM tension in the anchor BOLT. I remember a similar question on the PE exam way back when. To me maximum would mean worst case most conservative solution which would occur using one bolt with the minimum resisting moment arm of 7.07in or 42.4kips.
RE: A seemingly simple question but in fact very difficult?
This is a very common design issue in real world. Actually, I, myself often have to estimate this kind of anchor tension in my daily design work. If it is similar to your past PE exam question, it is totally an accidental coincidence.
Come back to this question, I have to acknowledge your answer gives me a shock. I have never thought such kind of solution as correct answer. But, well, You are probably right, I mean your answer might be academically wrong but politically correct.
RE: A seemingly simple question but in fact very difficult?
Sorry if I came off a little harsh on that post...
You're right I won't score any points on a doctoral discertation with that answer, but I would arrive at a safe design (actually I would probably increase the plate size and fastener spacing).
I asked if this was a theoretical problem because you are only providing pure moment without any additional forces. Moments caused by eccentric loading always deliver a vertical or horizontal load which can either aid or hinder the design of the anchor (i.e., a downward force will conteract some of the tension in the fasteners, the addition of shear will also reduce the anchor capacity)
I don't think there is enough information to posit a more refined solution (i.e., anchor size, plate thickness, pretension in bolts, grout under base plate will create some adhesion, etc.)
In practice I don't know if a more refined solution is of much help, but, it is a nice challenge... And I am all for a good challenge.
RE: A seemingly simple question but in fact very difficult?
RE: A seemingly simple question but in fact very difficult?
Lets look at it another way, its understood that the contact area directly below the tube wall is much much stiffer than the base plate. Therefore I hypothesize that the bearing distribution will follow a semicircular pattern following the line of the tube. The bearing plate will feather out the load onto the concrete footing below so perhaps you have a bearing area of 3π" x 3" = 9π = 28.27in2 x 1,500 psi = 42.4k.
The center of pressure of this distribution will be between 0 and 3" from the C.L. of the assembly. Lets say 1" (using simplified triangular distribution in plan)... This would give you a resisting moment arm of 7.07" + 1" or 8.07". Ignoring the two anchors at the C.L. of the assembly for now would give you a tension of 300/8.07 = 37.2 kips.
You could refine the analysis a little more but I think the overall results and the effort involved aren't going to result in a big payoff from the result using the 7.07" resisting moment arm.
I hope everyone can follow my logic.
RE: A seemingly simple question but in fact very difficult?
Really, when one problem of this thing is stated I would usually assume this is the intent, except the question makes clear it wants other thing and why, for otherwise I would be expecting as above expected more input data parameters.
RE: A seemingly simple question but in fact very difficult?
RE: A seemingly simple question but in fact very difficult?
In design of buildings typically there will be a significant downward force that will counteract much of the uplift, also when reviewing W-Shapes most of the force will be in the flanges which typically lands the loads very close to the line of anchors (also the W-Shape is essentially rectangular and matches the shape of the base plate geometrically).
I haven't reviewed the AISC DG on base plates in a while but I don't know if it specifically addresses round columns, or cases without any significant gravity loads.
But, either way the codes leave it up to the designer to evaluate if said procedure will yield the proper results. You have to watch when applying black box solutions, remember, you have to watch out for GIGO (Garbage In Garbage Out).
I think this is where engineering is a little bit of an art form, you have to understand the mechanisms at work and then try to simplify them so that you can model them to arrive at a reasonable (and safe answer). You also have to know when over simplification may not be appropriate. We have to watch out and not just become technicians who input values into a computer and then paste the results into their designs, or just punch numbers into equations without understanding if the are valid or not.
RE: A seemingly simple question but in fact very difficult?
I was only pointing that for just such data and question that kind of answer is what I think is proper, not that I would design such way any baseplate.
RE: A seemingly simple question but in fact very difficult?
And took a look at AISC Design Guide 1, Column Base Plates. I have a copy of the Third Printing 2003.
What was interesting in the Appendix A "Research Review" is the following note:
"DeWolf and Sarisley (1978b, 1980, 1982) conducted
tests of base plates with moments and compared the
results to the present design methods. Their variables
included the plate thickness, the anchor bolt size and the
eccentricity for the equivalent axial load. They found that
the behavior at failure was not always consistent with the
assumption used in present design approaches."
RE: A seemingly simple question but in fact very difficult?
http://w