Warehouse Slab on Grade Supporting Rack Post Loads
Warehouse Slab on Grade Supporting Rack Post Loads
(OP)
Anyone really experienced in design of slab on grade supporting rack post loads? If so, can you help with the following:
Is it more economical to use reinforced or unreinforced slab on grade?
Any good reference papers specifically addressing this?
If you use reinforced slab, how far apart do you place the constucution joints?
Do you use intermediate saw cuts?
What might be the typical reinforcement used?
Do you use SAFE to model it
In an unreinforced slab, where do you place the sawcuts - do you do one down the middle of the aisle where stresses are amximum?
Do you thicken the slab at edge conditions?
The post loads are about 18,000 pounds unfactored, the modulus of subgrade reaction is 100 pci. I was thinking of 30 MPa concrete (4350 psi)with a specified 28 day shrinkage not exceeding 0.035% as per CSA A23.1.
Very preliminary calculations indicate a 10" thick unreinforced slab would work. I suppose that an 8" slab with rebar with equivalent resisting moment to the plain concrete might also work.
Is it more economical to use reinforced or unreinforced slab on grade?
Any good reference papers specifically addressing this?
If you use reinforced slab, how far apart do you place the constucution joints?
Do you use intermediate saw cuts?
What might be the typical reinforcement used?
Do you use SAFE to model it
In an unreinforced slab, where do you place the sawcuts - do you do one down the middle of the aisle where stresses are amximum?
Do you thicken the slab at edge conditions?
The post loads are about 18,000 pounds unfactored, the modulus of subgrade reaction is 100 pci. I was thinking of 30 MPa concrete (4350 psi)with a specified 28 day shrinkage not exceeding 0.035% as per CSA A23.1.
Very preliminary calculations indicate a 10" thick unreinforced slab would work. I suppose that an 8" slab with rebar with equivalent resisting moment to the plain concrete might also work.






RE: Warehouse Slab on Grade Supporting Rack Post Loads
If you use reinforced slab, how far apart do you place the constucution joints?
>> This is up to the contractor, but I would suggest using diamond dowels to reinforce the joints. Especially if you have forklift traffic.
http://www.pna-inc.com/products/diamond_dowel/
Do you use intermediate saw cuts?
>> Absolutely, space depends on thickness, reinforcement, column location, geometry of the slab
What might be the typical reinforcement used?
>>Depends on what method you use and slab thickness, see below
Do you use SAFE to model it
>>I use a couple of different methods and compare the results, the WRI article below is a good place to start
In an unreinforced slab, where do you place the sawcuts - do you do one down the middle of the aisle where stresses are maximum?
>>If you can avoid aisles and rack posts, that is always nice
Do you thicken the slab at edge conditions?
>>Depends on where it is, forklift traffic, other loading conditions
I like the somewhat conservative confirmed capacity procedure for designing the reinforcement.
http
Good general article I just found:
http
Mathew Stuart's online class is a good primer:
http://www.pdhonline.org/courses/s132/s132.htm
Older free ACI 360 which has many of the different methods and charts:
http://civilwares.free.fr/ACI/MCP04/360r_92.pdf
This is a newer, alternative method... I have not heard too much from others on this method, but it seems like you get much more liberal and likely accurate/practical designs:
http
RE: Warehouse Slab on Grade Supporting Rack Post Loads
RE: Warehouse Slab on Grade Supporting Rack Post Loads
Design the slab for the forklift traffic and the rest essentially takes care of itself...for instance for larger racks and higher racks, you need a larger forklift, so you design for higher loads.
The static concentrated load at the rack legs usually results in a thickness controlled by shear. Agree again with a2...use plate dowels at joints and this won't be a big deal...but again, you're designing for the forklift!
RE: Warehouse Slab on Grade Supporting Rack Post Loads
Dik
RE: Warehouse Slab on Grade Supporting Rack Post Loads
RE: Warehouse Slab on Grade Supporting Rack Post Loads
RE: Warehouse Slab on Grade Supporting Rack Post Loads
thread507-264176: Super Flat Floors & Construction Joints
RE: Warehouse Slab on Grade Supporting Rack Post Loads
Dik
RE: Warehouse Slab on Grade Supporting Rack Post Loads
The State of Washington DOT has a series of programs that are free and easy to download. One of them, EverSTRESS, is an elastic layer analysis program based on the same algorithms as the older programs. They are pretty good, but a little quirky on the input data. Once you get the hang of it, not bad though. Check them out.
If you would like, I'll send you a copy of ELSYM5. It is a DOS based, public domain program, but it is very quirky on the monitor output...you have to make sure you can emulate ansi.sys in the command.com file in the root directory of the C: drive. That gets harder and harder with each successive iteration of Windows.
RE: Warehouse Slab on Grade Supporting Rack Post Loads
Dik
RE: Warehouse Slab on Grade Supporting Rack Post Loads
Also in your long strip scenario with no control joints, do you let it crack and then epoxy fill the cracks? Or try to provide longitudinal reinforcement to keep the cracks tight.
RE: Warehouse Slab on Grade Supporting Rack Post Loads
The joints are damaged by forklift wheels, and in some cases this is aggravated by curling. In external slabs subject to rainfall, joints also are where you get pumping of the subbase.
You can't stop cracking, but you can reinforce to keep the cracks tight. Filling is only required if for some reason a crack opens wider than expected.
RE: Warehouse Slab on Grade Supporting Rack Post Loads
So you are saying there is a movement in warehouse slab design with heavy forklift traffic to limit the joints by placing in long strips, or if possible to coordinate the rack placement with the joints so the joints are not exposed to wheel traffic? I have not heard of this before, any links to articles?
Funny how long concrete slabs have been around, and they seem so simple, and we are still tweaking how we design and build them...
I posted yet another driveway where the use of control joints has paid off, I could not find a crack... Of course, as you contend Hokie, this is not a good approach with warehouse slabs and would be pretty expensive.
RE: Warehouse Slab on Grade Supporting Rack Post Loads
RE: Warehouse Slab on Grade Supporting Rack Post Loads
A lot of the information available to date is somewhat proprietary, and some of it is just advertising. Jointless floor construction has not yet come of age as a "code" way of doing floors, but a lot of big industrial jobs are going that way. Most involve steel fibres. One UK company's website attached.
http:/
RE: Warehouse Slab on Grade Supporting Rack Post Loads
2. Do you use a dry shake floor hardener and if so, any particular type, product and rate of coverage?
2. What size base plates are used on the posts? Does the rack manufacturer determine that? Or should we as the structural engineers for the floor tell the rack manufacturer the size of base plate required so that the slab works for shear?
The warehouse is about 100,000 sq.feet and the racks are 4 levels of shelves, about 20 feet high, back-to-back racks.
RE: Warehouse Slab on Grade Supporting Rack Post Loads
2. No. Not a fan of dry shake hardeners. Use good quality concrete and make them put in what is specified without wetting it down. Flatness and finish are important.
3. Base plates are usually standard sizes on racks. Keep in mind they are sized by the manufacturers for anchorage and not bearing. They are usually the same size as the rack column, with a short tab extending inboard of the racking system to keep them out of the aisles and to provide unobstructed storage on the floor between the rack columns. They are anchored against lateral movement from loading/unloading and from overturning when loading/unloading onto upper shelves.
RE: Warehouse Slab on Grade Supporting Rack Post Loads
1. I am thinking of specifying the concrete sterngth at 90 days rather than at 30 days. Example 30 MPa at 90 days.
2. I would provide reinforcement as crack width control, based on frictional drag, using friction coefficient of 1.5 or maybe 2.0.
3. We normally pour the slab in 3 m (10 ft) widths and do transverse sawcuts at 40 times the slab thickness, using early entry saw. We use 40 mm (1.5") coarse aggregate and specify the concrete mix to be designed to achieve maximum bulk density. Also require Modulus of Rupture precosntruction tests.
4. Do you have any internet reference site that I could find the manufacturer's base plate size for a 9000 pound rack post load?
5. Is there any maximum distance between construction joints that you recommend?
6. Is there any reference for the diamond plate joint shear transfer dowels - how to specify them; their spacing, etc.
7. If the racks are 4 shelves high, with a post load of 40 kN (9 kips) and 80 kN for a pair of adjacent posts, would it be necessary to also check the slab for the forklift truck wheel loading?
RE: Warehouse Slab on Grade Supporting Rack Post Loads
You can spec any strength you want, as long as you are comfortable with what you get. If you have experience with 30 MPa at 90 days, and it will work properly, then spec it, else, spec 25 MPa at 28 days... it may be the same. I don't buy the longer time period, except for high fly-ash concrete where there is a slower strength gain. I sometimes look at the extended period of time for problems encountered during construction.
2
YOu can calculate the friction drag for rebar. It provides a bit of a quantified approach to providing rebar. Proper concrete and proper consolidation, sawcutting, curing, etc. will go a long way. I recently did a printing press slab that had 0.8% rebar because of the L/W and no joints permitted for the length.
3
Just be careful about the L/W ratios.
4
You can check it for confined bearing and will end up with a small pad. Check the small pad for punching shear and don't go too tight. Check the slab for flexural stress and provide a suitable safety factor. Check PCA Airport Slab publication for permissable tensile strength, in a pinch. Also use ACI guidelines. Check concrete tensile strength, not compressive, too. Beam tests or splitting cylinders.
5
Control joints should be 15' to 25' depending on the slab thickness. Critical is sawcutting time and curing.
6
I've not used diamond plates, but they should work well. Someone else can fill in the blanks... Smooth round dowels can be supplied in a 'rack' that can readily placed and they offer less perimeter for cracking.
7
Forklift loading can often be critical, depending on the front wheel load and tire construction and frequency of travel. Joints with forklift are often critical and I think I've done more floor investigations for damage caused by channelisation of forklift traffic and crossing joints than all others combined. Use a proper 'hard' or suitable joint filler to confine the concrete edge at the joint.
Others can expand or clarify the above.
Dik
RE: Warehouse Slab on Grade Supporting Rack Post Loads
Specifying 90-day strengths is fine for vertical work.
I still consider that the forklift loading on the slab will likely be more critical than the rack loading.
Agree with dik's comments, except I do not specify joint spacing greater than 15 feet unless absolutely necessary. Keep the L/W ratio at 1.2 or less.
RE: Warehouse Slab on Grade Supporting Rack Post Loads
Dik
RE: Warehouse Slab on Grade Supporting Rack Post Loads
Hard to see how 30 MPa at 28 days is going to be so much better than 30 MPa at 90 days with respect to durability. 30 MPa is 30 MPa. The strength gain is about 10% and that is negligible effect on durability. If you are thinking that there may be an abrasion issue, that goes more to the the quality of the aggregate. If it needs a hardener, then that is what should be applied, in my opinion, and not try to fenegle it through the concrete strength.
Although 15 foot centre joints is appropraite for the standard school or garage slab proportioned with 20 mm aggregate, I cannot agree with the advice to place the joints at 15 foot centres for a warehouse slab where the concrete has 40 mm aggregate and has been proportioned for maximum bulk density and minimum shrinkage starin as per CSA A23.1. We have successfully used 40 times slab thickness for many years. ACI 360 suggests 36 times and we succeeded in extending this by paying attention to the mix design and shrinkage, as noted above.
Hard to see how forklift can be more critical for the slab thickness design for the particular case I described, but thanks for the alert and we will check it out. I do agree that forklift effect on the joint is an issue.
RE: Warehouse Slab on Grade Supporting Rack Post Loads
You forgot to include, '...as long as you're happy with what you get'! Don't let my flippant response suggest that I would recommend specifying a 90 day strength... I have often spec'd a 56 day strength with 25% fly-ash, but never 90 days and never with only Portland cement. You are simply spec'ing an inferior 28 day strength...
With loaded, working, slabs, it is important to have a high strength slab. as I noted, for added shear and flexural strength and as Ron noted... for durability.
30 MPa concrete is more durable than 25 MPa at any time in the future history... I know that 30 MPa @ 28 days is more durable than 30 MPa @ 90 days because at 90 days, the 28 day strength concrete will have gained an additional 5 MPa... It will have an added 15% flexural and shear strength... These are important for loaded working slabs.
You can accommodate the shrinkage from the higher cement content by several means... reducing strength should not be considered. I generally spec a very stiff mix to start; contractors hate it. I spec a maximum slump... not a stipulated slump which gives the contractor an added inch or so latitude.
Regarding joint spacing, the bay spacing often determines the frequency... as noted, however, sawcutting time is critical. 20' is pushing a 6" slab, but it can work if the job is done properly.
I've included a copy of my normal notes for SOG construction:
SLAB ON GRADE
THE MODULUS OF SUB-GRADE REACTION IS ASSUMED TO BE 200 PCI. THE CONTRACTOR, THROUGH THE CLIENT IS RESPONSIBLE FOR OBTAINING A GEOTECHNICAL REPORT TO CONFIRM THIS DESIGN ASSUMPTIONS. THE [CONSULTANT | ENGINEER] ASSUMES NO LIABILITY FOR THESE DESIGN ASSUMPTIONS OR FOR ANY FOUNDATION REDESIGN NECESSITATED BY DIFFERING SOIL CONDITIONS
TEMPERATURE DIFFERENTIAL BETWEEN THE GRANULAR BASE AND THE TOP OF THE CONCRETE SLAB SHALL BE MINIMIZED
SLAB FINISHING SHALL BE DELAYED AS LONG AS POSSIBLE
THE SLAB IS DESIGNED FOR [LIGHT | MEDIUM | HEAVY] DUTY USE ONLY
THE EXPOSED SUB-GRADE FOR SLAB ON GRADE SHALL BE PROOF ROLLED. SOFT SPOTS SHALL BE EXCAVATED, BACK-FILLED WITH GRANULAR FILL AND COMPACTED TO 95% STANDARD PROCTOR. GRANULAR FILL AND COMPACTION METHODS TO BE APPROVED BY THE [CONSULTANT | ENGINEER]
THE COMPACTED GRANULAR FILL SHALL PROVIDE A UNIFORM SURFACE WITH NO ABRUPT CHANGES IN LEVEL. MAX DEVIATION IN LEVEL SHALL NOT EXCEED 0.5 INCHES
PROVIDE MIN [6 | 150] CMPT GRAN 'A' BASE COURSE BENEATH SLAB-ON-GRADE U/N. CMPT TO 95% [SPDD | MPDD] U/N
INSTALL 6 MIL PEVB MEMBRANE CONFORMING TO CAN3-51.33-M80 BTN SLAB AND FILL WITHIN THE AREA OF THE BUILDING
LAP PEVB JOINTS [12 | 300] MIN AND SEAL WITH MASTIC CEMENT
U/N REINF FOR SLAB-ON-GRADE SHALL BE:
DEPTH REINF
5 10M@16 TEW
LAP WELDED WIRE FABRIC, ONE FULL MESH AT SPLICES
REINF STEEL TO BE LOCATED [2 IN | 50 MM ] BELOW TOP OF FINISHED FLR SLAB
SUPPORT SLAB TOP REINF ON HIGH CHAIRS AND/OR 15M SUPPORT BARS WHERE REQUIRED. ALL BARS AND CHAIRS MUST BE SECURELY TIED TOGETHER
PROVIDE SUFFICIENT CHAIRS AND SUPPORT BARS TO MAINTAIN CONC PROTECTION AS SPECIFIED
CUTTING OF CONTROL JOINTS SHALL BEGIN AS SOON AS THE CONC SURFACE HAS HARDENED SUFFICIENTLY TO RESIST RAVELLING AS THE CUT IS MADE [.SAWCUTTING SHOULD COMMENCE APPROX 6 TO 8 HOURS AFTER FINISHING SLAB]
SAWCUT SLABS INTO PANELS NOT EXCEEDING 20' IN ANY DIRECTION. MAX CONTROL JOINT SPACING SHALL PREFERABLY NOT EXCEED 30 TIMES THE SLAB THICKNESS AND SHALL NOT EXCEED 36 TIMES THE SLAB THICKNESS. THE LENGTH TO WIDTH RATIO OF THE CONTROL JOINT PANELS SHALL NOT EXCEED 1.5. IF A SAWCUT INTERSECTS ANOTHER SAWCUT, THE SMALLER ANGLE OF INTERSECTION SHALL NOT BE LESS THAN 50 DEGREES
CONTRACTOR SHALL PROVIDE SHOPDRAWING SHOWING THE PROPOSED CUTTING PATTERN AND THE PROPOSED SAWCUTTING PROCEDURE WELL IN ADVANCE OF PLACING THE CONCRTE FOR THE SLAB ON GRADE
CONC SLAB-ON-GRADE HAS BEEN DESIGNED FOR THE FOLLOWING:
WHEEL LOAD XXXX POUNDS
INFLATION PRESSURE XXX PSI
DIM A XXX
DIM B XXX
DIM C XXX
LOAD REPETITIONS XXXXX THOUSAND
SAFETY FACTOR XXX
IF DIM A=0 THEN VEHICLE AXLE HAS SINGLE WHEELS
IF DIM B=0 THEN VEHICLE HAS SINGLE AXLE ONLY
These are edited as required depending on the project. The typical sawcut and filler material is specified on a typical detail.
Dik
RE: Warehouse Slab on Grade Supporting Rack Post Loads
While abrasion resistance is slightly related to the abrasion resistance of the coarse aggregateit is primarily a function of the cement paste integrity. The quality of the cement paste significantly affects abrasion resistance and that is directly related to w:c ratio and strength.
You state that you are greatly concerned about shrinkage cracking yet you take the spacing to an upper limit by anyone's stretch of the concept. Those are incompatible. Your experience might very well be anectdotal as compared to other applications. I see many problems with improperly spaced and untimely control joints, so 15 feet is the maximum for me.
ACI 360 only states that you can consider 60 or 90 day strengths to reduce slab thickness...it does not carry that consideration to durability. Further, it states that durability is directly related to strength and w:c ratio....which are contrary to using higher design-day requirements.
RE: Warehouse Slab on Grade Supporting Rack Post Loads
RE: Warehouse Slab on Grade Supporting Rack Post Loads
Just wondering how much concrete you guys have done lately that does not have SCM's in it (for which it is pretty common practice to specify 56 day strength or even 90 day strength), or are you recommending that SCM's not be used in warehouse slabs? The best slab I ever did had 50% slag cement.
Is it your standard practice to do warehouse slabs with joints at 15 foot centres? How many warehouse slabs have you done with joints at 15 fet centres and how are they performing with respect to curling and cracking when the forklift goes over them? Have you gone back to look after a year or 2?
Differential drying shrinkage causes the concrete at the joints to curl. For this reason, the less water in the concrete, the less curling there should be. That is why I am thinking to specify only the concrete strength needed to support the load and space the joints as far apart as possible, so there are fewer of them to cause problems. However, if you can point me to a reference publication that recommends for warehouse slabs that closer spacing of joints is better than greater spacing of joints, or that they should be spaced at 15 feet centres, then that will be interesting,
My slab is 8" thick warehouse slab. I have clearly said that we use 40 mm aggregate and do other things to reduce shrinkage. Ron - did you miss that or are you recommending larger than 40 mm aggregate?
Thanks again for the info.
RE: Warehouse Slab on Grade Supporting Rack Post Loads
Latest work has been in Sask. where concrete can be exposed to both chloride and sulphate attack; this requires a higher fly-ash content (some people use as high as 40% or more flyash, but I haven't gotten that far). Type 5, 50, HS cement is contraindicated for chloride attach, hence the use of fly-ash with Type 10, GU cement). 30 MPa @ 28 days is a good start.
You're on your way using 40 mm aggregate and also minimising the cement, hence the use of SCM's and not trying to achieve a extended term strength. I typically use a 3" maximum slump for flatwork and try to space rebar 12" (300) o/c min. so that they can walk through it, else they have to use foot boards. SCM's also have a role if reactive aggregate is available.
With an 8" slab, I would typically be looking at 20' sawcuts; 15' is better, but not always possible. The tricky part is arranging the sawcuts so that they work with isles and racking. I also provide the client with a 'Maintenance Manual' for slab upkeep. (I started doing that with parking garages nearly 40 years back.) You can extend the sawcut spacing a bit by increasing the amount of rebar. Timing of sawcutting and curing is absolutely critical. The use of a sofcut saw is really advised.
I use poly directly under the slab and not under the granular levelling course (this is contrary to some practices) and I've not had problems with curling. I suspect this is because of the sawcutting and curing. It may also be that I've not had a project done under the hot sun.
At pour joints (aka shrinkage/expansion joints), I typically use 20M or 25M smooth dowels (latter preferred) in a proper 'rack' and discontinue reinf at pour joints. Make sure that the dowels are parallel with no 'burrs' from shearing. I keep dowels 9" away from a pour joint at right angles (I don't want to get too close).
At sawcut joints in the floor I typically run rebar through sawcut locations, using 2" cover and 1-1/2" deep cuts. The cuts are 1/4" wide to permit filling. This provides support for the edge of the cut for wheel loads. Depending on the use, I use three different fillers. I generally show a typical sawcut pattern (this can be a challenge for irregular column locations and for architectural floor finishes), but, generally have the contractor provide a sawcut pattern for review. Timing for sawcutting is critical. I notice that for most highway work, with sawcutting, the rebar is discontinued and dowels are used.
There's probably a bunch of other stuff... but this is a start for discussion...
Dik
RE: Warehouse Slab on Grade Supporting Rack Post Loads
I'm not recommending against their use, I just haven't had time to look into this.
Dik
RE: Warehouse Slab on Grade Supporting Rack Post Loads
How old is it?
Have you gone back to see how it is performign after a year, or are you planning to? Be interesting to see if there are any any lessons to be learned.
Your comments are excellent and I agree fairly well with what you say, except I am a little concerned about poly directly under the floor because it promotes water rising to the surface which has undesirable effects on finishing and durability. The floor finishers in the Toronto area have told us not to do it and that seems to be supported by the literature. I assume that you have not had this problem. Generally we have stopped doing it for regular slabs on grade such as for schools, hospitals, etc. unless the geotechnical engineers says that it is required for moisture vapour permeation (or radon gas) reasons.
Regarding control joint spacing, about 20 years ago we were commissioned by a Canadian Governemnt Department to do a study to arrive at recommendations for their warehouse slabs. The people we assembled for that included one of the foremost experts in the field of concrete technology in Canada at the time and a foremr chiarman of CSA A23.1. I believe that one of the principle recommendations of that study was to space the control joints as far apart as justifiable having due regard to shrinkage and cracking, to minimize the number of joints, as they were one of the principle problem areas.
To achieve that, without causing undue cracking issues, the concrete technolgy expert came up with specific recommendations, not only about the size of course aggregate but also with respect to the proportioning for maximum bulk density and other aspects of the design of the mix, curing, etc. If you are not doing those rather special things that go well beyond just using the well known advice to use 40 mm coarse aggregate, then I can perhaps understand why you favour 15 or 20 foor joint spacings for an 8" slab.
Although I was not part of that study, I highly regard the people who researched and authored it. Now in their 80's they are still alive and I suppose I could consider going back to them and get their comments.
In my opinion, some of these things are trade-offs of one aspect of performance for another, so engineers' opinions can differ. It is interesting and useful information that, on balance, you have had better overall success with warehouse floors with rack storage and forklifts when you used control joints at closer spacing than greater spacing. Have you ever tried greater control joint spacing?
Regarding sawcuts and reinforcing, I suppose the reinforcing diminishes the effectiveness of the sawcuts, but overall I agree that it is not practical to stop the rebar at the sawcut control joints. In any event the reinfoecemnt to control crack width is in accordance with ACI.
Incidentally, in the Toronto area, we are quite near to a good source of high quality ground granulated blast furnace slag and far from fly ash source. With coal-generated electricity being phased out in Ontario, fly ash sources will have to be from the U.S. or Quebec, when it is no longer available from northern Ontario. Mostly it is slag as the SCM in the Toronto area, and I believe that little concrete is produced here that does not include slag. We do not generally have the sulphate issues that are prevalent on the prairies. Deicing chemicals (chlorides and other reactive ions) are a very big issue here for parking structures and the like, but this warehouse floor would not be subject to that and chloride in the soil has not been an issue here generally.
Some other questions, if you do not mind:
1. By "pour joints" do you mean the "constrcution joint" that would occur at the end of the day's pour?
2. Do you have any maximum limit on the length of slab placed in any one day? My concern would be opening of the construction joint to too wide a width if the length of pour is too long, particularly since the rebar thru the sawcut control joints may limit how much of the shrikage movement actually occurs at the sawcut joints and it may accumulate at the construction joint at the end of the pour. We had this issue with a topping placed on top of insulation (it was not a warehouse)
3. Do you provide "additional" local rebar in the slab at the construction joints to control cracking when the forklift vehicle goes over it when it is curled upward?
4. Do you normally use any hardener such a as a dry shake or a liquid hardener (such as Ashford formula) on the floors?
Best Regards
RE: Warehouse Slab on Grade Supporting Rack Post Loads
RE: Warehouse Slab on Grade Supporting Rack Post Loads
My experience and research affirms this, though you may get luck on 4-5" SOG with lots of control joints...
RE: Warehouse Slab on Grade Supporting Rack Post Loads
RE: Warehouse Slab on Grade Supporting Rack Post Loads
I haven't had any problems with the PEVB directly under the floor and I suspect this is due to curing and low slump. No problem with bleed water or finishing. Have always done it for moisture transmission.
I typically max my joints out as noted. Ron's spacing is a little less and it doesn't hurt... both of us are comfortable with what we do and if there are problems, it's likely due to other things. With pre-eng buildings and frames at 25' centres, with anything less than an 8" slab, I will put them in at 12.5'. For an 8" slab, they will go in at 25' and I'd likely use 0.25 rebar just to tighten up the cracking a tad.
I've not tried greater joint spacing because it works... for the same reason, likely, that Ron uses his spacing.
The increased aggregate size is good... often use 40mm... problem with concrete placement and pumping... Good supplier, good contractor, stiff mix, timely sawcutting, and proper curing are essential for good flatwork. In addition, it helps that there are a couple of excellent concrete finishers in your neighbourhood... and that helps a lot.
I've often found that forklift traffic is more critical than rack loading... and have done numerous reports for lawyers and insurance companies as a consequence.
Sawcutting weakens the slab and provides a location to crack, but it has to be done at the right time... else, you may as well wait for it to crack and route out the cracks and fill...
There are additional problems with the removal of mercury from flyash using a carbon process... this is causing problems with fly ash and may stop the useage of it.
Parkades and durability are a whole other area of discussion. You have a problem with the use of salt de-icers as well as numerous freeze-thaw cycles... here, in Winnipeg, it freezes in the winter and thaws in the summer <G> one cycle...
Pour joints are construction or cold joints...
I used to restrict the area of slab in one day, but this is a 'means and methods' for the Contractor... When I first started practicing, it was not uncommon for checkerboard pattern of slab placement. I have, however, had the Contractor sawcutting at 3:00 AM... and the first time this happens, they are really unhappy... Most projects are not of sufficient size and those that are big, are generally limited by what the Contractor can do.
Proper dowel design and placement accommodates forklift locations. Where dowels are not possible, the slab edge is thickened by 1/3.
I've not encountered curling with any of my work, but, I've seen it... Repair is pressure grouting under the slab and grinding flush.
I have used metallic hardeners on the occasional industrial slab, but for the most part don't use them... they and traprock can be problematic. I've not used a liquid hardener.
Dik
RE: Warehouse Slab on Grade Supporting Rack Post Loads
RE: Warehouse Slab on Grade Supporting Rack Post Loads
I did not notice your aggregate size in your post. That's critical to reducing shrinkage and your approach is good. I also noticed that you have an 8-inch thick slab. For that thickness I would go up to 18 to 20 feet between joints.
I'm a believer that fewer joints simply means wider joints, assuming no cracking in between. This is particularly true if you are using synthetic fibers.
Steel fibers are excellent for warehouse floor slabs. They solve a lot of problems...but they're expensive.
RE: Warehouse Slab on Grade Supporting Rack Post Loads
RE: Warehouse Slab on Grade Supporting Rack Post Loads
Dik
RE: Warehouse Slab on Grade Supporting Rack Post Loads
There is a slab in Central Florida that I designed almost 25 years ago. It is a pavement in an office park for a loading dock and dumpster traffic. Went by a while back and found good performance, no uncontrolled cracks, with only an occasional small rust stain from the fibers. On the same project, I designed an asphalt pavement with steel fiber in the asphalt. Over 20 years later, no overlay and not potholes.
I like steel fiber...just can't get clients to pay for it!
RE: Warehouse Slab on Grade Supporting Rack Post Loads
RE: Warehouse Slab on Grade Supporting Rack Post Loads
RE: Warehouse Slab on Grade Supporting Rack Post Loads
RE: Warehouse Slab on Grade Supporting Rack Post Loads
RE: Warehouse Slab on Grade Supporting Rack Post Loads
RE: Warehouse Slab on Grade Supporting Rack Post Loads
Dik
RE: Warehouse Slab on Grade Supporting Rack Post Loads
RE: Warehouse Slab on Grade Supporting Rack Post Loads
Dik
RE: Warehouse Slab on Grade Supporting Rack Post Loads
Had the opportunity to meet and speak with Bill Trow just before he retired (as I was being joined with the company).
They are and always have been a very professional and technically competent group. They have been led for many years now by Vlad Stritesky, who ran the roofing group during my affiliation. Vlad has done a good job with the company as one would expect from such a pro!
Ah....the memories!
RE: Warehouse Slab on Grade Supporting Rack Post Loads
Dik
RE: Warehouse Slab on Grade Supporting Rack Post Loads
RE: Warehouse Slab on Grade Supporting Rack Post Loads
My last project with Trow was the geotechnical investigation for a large Stevenson-Hluchan project in the Bahamas (1988/1989).
RE: Warehouse Slab on Grade Supporting Rack Post Loads
RE: Warehouse Slab on Grade Supporting Rack Post Loads
However for what it's worth, there is a Design guide:
Designing Floor Slabs on Grade by Boyd C. Ringo and Robert B. Anderson (we have the Second Edition)
EIT