Thanks for your feedback
I note the following:
I tend to agree that using purlins for this purpose is problematic because of the slotted holes, but only from a serviceability point of view. In regards to the ultimate capacity the structure cannot fail (if it is designed properly) as it only takes a small movement to have the bolts engage. This movement however occurs in each bay, and the cumulative effect on the serviceability performance of the structure seems very problematic to me.
Having said that though, I know of several large projects by very reputable and knowledgable engineering consultancies (in Australia) that have produced this type of design over many years (20+), and have been exposed to this type of design myself, but did not understand how it works from a serviceability point of view. I was wanting to hear feedback from others - which you provided - so thanks, again. If you have any further feedback please add that.
In regards to the ultimate capacity of the purlins in compression, the "battened purlins" only are designed to take the roof bracing forces, not the other purlins. The "battened purlins" consist of two purlins nominally 300mm apart bolted to each other to create a little verendeel truss (in plan view), and the buckling capacity of these "battened purlins" is then dictated by their major axis capacity.
In regards to the connection capacity to cleats at the main rafters, the ultimate capacity per bolt is about 30kN for an M12 bolt, and 4 bolts for each pair of purlins gives more than enough capacity.
In regards to eccentricities, yes this has to be catered for. The typical detail at the "battened purlin" connection to the rafter involves having a fly brace, so the top and bottom flanges are held (albeit by purlin members with slotted holes!). With rod bracing (typically 16mm rods, grade 250MPa), the tension force is not that large and the web of the roof beam can be justified through yield line design approach.
So, the only aspect I am uncertain about is the performance under service loads. I agree it is problematic. I have asked about this with some colleagues who were presenting these designs to clients and having them built. I was offered some advice but did not find it useful. It is the case of those with "special" knowledge not fully passing it on. I am talking about senior people with 40 years experience who are renowned experts in their fields. But, it doesn't mean they are necessarily correct! The opposite side of that coin though is that they have produced this deign for buildings with large gantry cranes and slewing jib cranes that regularly impart large horizontal forces, and to date there has not been a problem in their structures due to this type of detail.
Another point I would make is that purlin companies promote in their engineering brochures what the compression capacities are for purlins of certain lengths - obviously implying they are used to take these loads.
Finally - in modelling "large" industrial buildings in 3D - there are significant movements of "braced members" that occur regardless - through the extension of tension members for example. defining a building as "braced" can be a bit arbitrary in some cases. It might the case that the additional movements at "battened purlins" - which in theory is +/- 3mm for a 16mm bolt in a 22mm hole (assuming M16 bolts are used at "battened purlins"), may not be too difficult to accomodate within the allowable deflection limits? I have not tried to model for these movements however - and they are only +/- 3mm on average. Some may be +0/-6 or vice versa. I dont think it is something that can be designed for, except perhaps conservatively at +/-6mm?
Cheers
