Slab Depressions in Double Tee Floor Systems
Slab Depressions in Double Tee Floor Systems
(OP)
See the somewhat fictionalized rendition of my project below. Originally, it was desired to use hollow core precast plank for this second floor transfer slab. Somewhere along the line, before it landed on my desk, it was concluded that the spans were too long for 12" HC and that a double tee system would be better. As things have progressed, the question has arisen "how do we handle slab depressions?". Without egregiously sacrificing the economy of the TT's, it seems to me that they really cannot be handled.
Before I throw in the towel on this scheme and try to steer things in another direction, does anybody know of any tricks for making a go of it with the TT's? While I haven't done a TT transfer slab before, I know that it definitely has been done before. I'd think that this would be a common problem in need of solution. The only simple idea that I can come up with is to do it all in the topping. But, then, that gets heavy, expensive, thick, and generally ridiculous.
Before I throw in the towel on this scheme and try to steer things in another direction, does anybody know of any tricks for making a go of it with the TT's? While I haven't done a TT transfer slab before, I know that it definitely has been done before. I'd think that this would be a common problem in need of solution. The only simple idea that I can come up with is to do it all in the topping. But, then, that gets heavy, expensive, thick, and generally ridiculous.
I like to debate structural engineering theory -- a lot. If I challenge you on something, know that I'm doing so because I respect your opinion enough to either change it or adopt it.






RE: Slab Depressions in Double Tee Floor Systems
RE: Slab Depressions in Double Tee Floor Systems
I like to debate structural engineering theory -- a lot. If I challenge you on something, know that I'm doing so because I respect your opinion enough to either change it or adopt it.
RE: Slab Depressions in Double Tee Floor Systems
RE: Slab Depressions in Double Tee Floor Systems
What's the loading on the floor? 42' is well in the ballpark of 12" HC for most uses.
Brian C Potter, PE
Simple Supports - Back at it again with the engineering blog.
RE: Slab Depressions in Double Tee Floor Systems
I'll ask it. Somewhat oddly, I'm sometimes a precast engineering. What I know of my clients' fabrication techniques leads me to believe that this would be quite difficult. I'd think that one would have to block out the flange and the tops of the stems and then come back and add the fold after the fact.
The usual business where the interior and exterior walking surfaces are at nearly the same elevation but the exterior has a bunch of building envelope stuff piled up on top of it.
A common permutation of this is to run hollow core in in other direction, drop the edge planks has needed, and smooth out the odd bits with topping. It make sense when you've got a high aspect ration building with all of the depressions on the long sides, which is normal.
It carries three floors of wood residential structure coming down as line loads parallel to the plank. Parallel, at least, for now.
I like to debate structural engineering theory -- a lot. If I challenge you on something, know that I'm doing so because I respect your opinion enough to either change it or adopt it.
RE: Slab Depressions in Double Tee Floor Systems
1) Cast on a flange at the correct height after the double tee has been poured, prior to erection (it would have to be post-pour as I'm not aware of any double-tee forms that can accommodate a jog in height like you're showing). This would be kind of a hassle (read: $$$), and you'd likely get some gnarly stress concentrations at the edge of the depression where you have a discontinuity, but your span is low enough and your section deep enough that you could probably make it work.
3) Frame the whole thing with light gauge after the tees have been erected. The issue now is that your "tee" is spanning 12 or so feet with 12" of missing depth and no top flange, but again, it's possible this is workable with the span and tee size numbers you're working with. You could also look into combining this solution with a deeper tee at this section (you'd have to ask around for a precaster that has the forms for them), though then you run into headroom issues.
You also might look into framing this area with single tees - you run into the same problem, but single tees tend to be able to handle a lot more capacity, so might work better.
Brian C Potter, PE
Simple Supports - Back at it again with the engineering blog.
RE: Slab Depressions in Double Tee Floor Systems
Our set down was only 3" from memory, yours is a lot more savage at 8-12".
I'd look at ways of reducing the set down, it's a case of the architecture needing to follow the practical engineering realities. We do our best but sometimes the architecture needs to pull its head in. Perhaps a cutoff drain at the threshold can allow for a much smaller set down for example, or a fall away from the building to allow less set down.
Lastly might just need to throw through additional beams to frame out the lower portion, or turn the floor system 90 degrees locally and span the other way if it worked for your wall loads. You could have ribs at closer centres if it was an issue.
RE: Slab Depressions in Double Tee Floor Systems
RE: Slab Depressions in Double Tee Floor Systems
RE: Slab Depressions in Double Tee Floor Systems
Simplifying my building has not simplified my thread it seems. That's what I get for trying to game the system.
I like to debate structural engineering theory -- a lot. If I challenge you on something, know that I'm doing so because I respect your opinion enough to either change it or adopt it.
RE: Slab Depressions in Double Tee Floor Systems
Slab depressions on double tees just seem like a super scary proposition.
Is it possible the other depressions are less onerous than this one?
RE: Slab Depressions in Double Tee Floor Systems
I like to debate structural engineering theory -- a lot. If I challenge you on something, know that I'm doing so because I respect your opinion enough to either change it or adopt it.
RE: Slab Depressions in Double Tee Floor Systems
You could say it's too hard, but I'd say it's just too unique. Precast plants operate best when we can churn out the same sections over and over. Allows us to keep a steady shop schedule, bid projects easier, and keep the money train flowing steadily. As soon as you do really unique custom pieces you now need extra time to setup the forms and fabricate the atypical rebar. You need to ensure it can be lifted and handled without cracking (often with offset centers of gravity). The QA/QC folks need to spend a lot more time making sure all the unique details are accounted for. Then the estimators pricing the job out need to account for all the extra hours and unique materials. Then the production managers need to make sure they account for the extra time this empty form has to sit in the shop while the custom rebar is installed and the bonded out areas are made. Often times the unique pieces will have the plant engineer (me) have to design and/or stamp something for submittal to the EOR. And so on. All this then needs to be done at a low enough cost to keep the contractor happy. Finally, 90% of the time, if you screw up a job it's going to be on a unique piece and not a "stock piece"; so the risk on these jobs goes up.
Overall it's just far easier money to avoid the more difficult projects. Many times we will pass on a job bid just because we'd rather save the shop space and churn out septic tanks or manholes, because in the long run we'll make the same amount of money for less risk. That said, if you can get us a unique job at a slow time in our year we'll be all over that. The difficulty isn't the issue, it's just what makes us the most consistent money in the long run. It's good to find a precaster to work with early on so that they can guide you away from any details that makes the job too risky or time consuming to be feasible. Often times it can be little things, like making all the stirrups the same spacing or what not. Definitely a case where "least weight" does not equal "least cost". Remember that precasters are more concerned with getting concrete into and out of forms ASAP and then getting the forms out of the shop to make way for new forms. Anything that gets in the way of that costs money.
A little bit of a tangent, sorry KootK. I'll get a proper response to your question in a minute.
Professional Engineer (ME, NH, MA) Structural Engineer (IL)
American Concrete Industries
https://www.facebook.com/AmericanConcrete/
RE: Slab Depressions in Double Tee Floor Systems
Professional Engineer (ME, NH, MA) Structural Engineer (IL)
American Concrete Industries
https://www.facebook.com/AmericanConcrete/
RE: Slab Depressions in Double Tee Floor Systems
I don't have the numbers at hand but I'd say the cost of a 3 to 4" slab on foam will be easily mitigated by a flat, repetitive, precast system.
RE: Slab Depressions in Double Tee Floor Systems
Never. That's kind of voodoo that I recommend for other folks but would never have the balls to execute myself. I'm not sure that I could go on living knowing that three stories of building is depending on that weld plate in tension not ripping out. Curious, would you be willing to do it? As a precast specialist, I weight your opinion quite heavily in these matters. As a solution, it's clever and innovative, no doubt.
Thanks for sharing your perspective DETstru. I'll mull it over. Part of what's bothering me here is how deep this floor system is getting. 32" tee + 3" topping + 8" build up = ...43"? I get that precast goes up fast but at what point do we say enough's enough and switch to a 14" post-tensioned slab with a fold in it?
I like to debate structural engineering theory -- a lot. If I challenge you on something, know that I'm doing so because I respect your opinion enough to either change it or adopt it.
RE: Slab Depressions in Double Tee Floor Systems
I've done a fair share of tees, and I don't think fabrication will really be your issue here. Contra TME, I think casting these would actually be fairly trivial. As you say, all they have to do is block out the flange and a chunk of the stems, which (shouldn't) be a problem. All they'll do is put a bit of styrofoam in the forms, no goofy splicing required. It's not the prettiest thing in the world, but I'd be willing to bet your precaster has done uglier pieces.
Your issue is going to be what kind of capacity you're left with in just the two reduced-height stems, but that should be a fairly easy check (and these tees are deep enough that it's not obviously a no-go).
Brian C Potter, PE
Simple Supports - Back at it again with the engineering blog.
RE: Slab Depressions in Double Tee Floor Systems
I like to debate structural engineering theory -- a lot. If I challenge you on something, know that I'm doing so because I respect your opinion enough to either change it or adopt it.
RE: Slab Depressions in Double Tee Floor Systems
Casting the low slab in the field is, once again, a pain, but it doesn't seem like an obvious dealbreaker (especially since you'll have a contractor there already pouring concrete for the topping).
I think if the capacity is there, this could all be ironed out, and this would be the "weird portion of the building" that all precast jobs seem to have.
Brian C Potter, PE
Simple Supports - Back at it again with the engineering blog.
RE: Slab Depressions in Double Tee Floor Systems
Not unless I could overbuild the hell out of it and have a quality welder. I'd also want 4 weld plates per stem for redundancy.
Now that I've slept on it I've decided I don't like my own detail as it could have a big issue if any corrosion occurred and would be difficult to repair. Maybe it could be improved if the dropped area was a secondary pour with rebar extending continuously from the double tee into the dropped area?
Anyway, scratch my idea. I'm sure it could work but cheaper and likely better to just have a blocked out area of a double tee and go from there.
Oh, I agree that the forming and casting would be trivial. In my previous comment I was more discussing generally what the rational Agent666s precasters may have for giving push-back on custom elements; mostly that it could be the precaster was just too busy to want to do a more complicated custom piece. For KootK in particular I expect the only pushback will be on the extra reinforcement required at the notch and perhaps the prestressing calculations to ensure no cracking occurs at transfer. Also, whoever is responsible for designing the beams strength will have fun working out the capacity with the secondary slab being effectively a non-presstressed topping. None of these would be show stoppers in my book, simply difficulties to overcome.
This wouldn't be too bad. If I had to do it we could have 180° rebar hoops extend from the blocked out web area of the double tee, flip the double tee over and form up a secondary pour on a raised platform in the shop and cast the low slab. Flip back over and ship. This would probably double the cost of the double tee but wouldn't be a terribly difficult pour.
Thirded for typical double tees. The precaster could cast a grouted shear key profile in the flanges and this would get you some decent load sharing in my mind but obviously isn't typical outside of bridge construction. If it's typical double tee construction with just a thin topping slab then I'd only count on minor load sharing and nothing like full shear transfer.
I'm more just throwing ideas out to see what sticks so this may work just as well as my weld plate idea; but what about a hybrid composite steel beam mixed with the typical double tee framing?
Don't have time to sketch it up but use a steel beam that matches the higher and lower profile you have. Have the beam cast into either a precast slab section or a cast-in-place slab to get the profile you need and give composite action for the beam. Design the beam to have similar deflection response as the double tees (matching the camber of the double tees will be interesting). Install adjacent to the typical double tees an go from there.
No idea if this will be something that meets the project goals/cost/etc. Like I said, just throwing out ideas.
Professional Engineer (ME, NH, MA) Structural Engineer (IL)
American Concrete Industries
https://www.facebook.com/AmericanConcrete/
RE: Slab Depressions in Double Tee Floor Systems
Dik
RE: Slab Depressions in Double Tee Floor Systems
Right now!
RE: Slab Depressions in Double Tee Floor Systems
The success of a welded stub would depend on a lot of things in my mind. Rust would be a concern for sure, but with proper details it could be protected. Something along a cazaly hanger might work if it could be concealed well. It is easy to be very conservative with something like that since you can spec a lot of extra weld and use much larger bars without adding much cost. The weld quality issue is likely not a huge concern since the welding would likely be done in the shop by the plant welders.
Blocking out the TT top is also not outside the realm of possibility either if you have a plant that does a lot of insulated wall panels. Any company that does a lot of insulated panels works with crazy ideas all the time and forming odd things with foam is pretty routine.