Gambrel Roof with a Stick Built Moment Frame
Gambrel Roof with a Stick Built Moment Frame
(OP)
This one is looking to be an interesting project. The client wants to stick build the roof in a similar fashion to the method detailed by Andrew DiGiammo in the Journal of Light Construction: http://www.jlconline.com/projects/design-gambrel-r...
The method is similar to a site built truss in a lot of ways using 3/4" plywood as gusset plates as shown below:


I haven't got into all of the details yet but just poking around the internet I've found some interesting articles etc...
I will provide further structural details as I progress but for now I'm just wondering if anyone else has looked at this type of system before?
I will probably put this into Risa3D to determine my moments, axial and shear of the members at the joints. This is a very similar problem to analyzing a site built truss. Here are some basic assumptions and initial thoughts:
1.) The floor joist will be loaded in tension, preventing the frame from speading its legs, in essence the bottom chord of the truss. Check this member for combined tension and bending due to floor loading.
2.) The connection at the floor joist (I Joist) and the bottom of the frame will be assumed to be pin jointed with attention to the uplift and tension at this joint. I'm thinking a sill plate that the 2x12 or 2x10 lower rafter is notched into might provide a nice positive connection for the outward thrust of the roof. I'm still thinking about uplift and what ties to use at this location.
3.) 3/4" plywood gusset plates will be at three locations. Tension and Moments at these locations will control the design of the gusset plates and fasteners. The debate of single shear vs. double shear nailing continues. The large gusset plates will create rigid joints at these locations.
4.) Check the the upper and lower rafters in combined compression and bending.
5.) The client will probably install a knee wall and a collar tie, how does this affect the analysis.
6.) The floor joist will be supported at approx. mid span by a bearing wall on the first floor.
7.) Need to look into wind loads on gambrel shaped roofs, this one is new for me.
Just a few things to get started with, I'm sure there will be other questions, assumptions and issues with this design.
A confused student is a good student.
Nathaniel P. Wilkerson, PE
www.medeek.com
The method is similar to a site built truss in a lot of ways using 3/4" plywood as gusset plates as shown below:


I haven't got into all of the details yet but just poking around the internet I've found some interesting articles etc...
I will provide further structural details as I progress but for now I'm just wondering if anyone else has looked at this type of system before?
I will probably put this into Risa3D to determine my moments, axial and shear of the members at the joints. This is a very similar problem to analyzing a site built truss. Here are some basic assumptions and initial thoughts:
1.) The floor joist will be loaded in tension, preventing the frame from speading its legs, in essence the bottom chord of the truss. Check this member for combined tension and bending due to floor loading.
2.) The connection at the floor joist (I Joist) and the bottom of the frame will be assumed to be pin jointed with attention to the uplift and tension at this joint. I'm thinking a sill plate that the 2x12 or 2x10 lower rafter is notched into might provide a nice positive connection for the outward thrust of the roof. I'm still thinking about uplift and what ties to use at this location.
3.) 3/4" plywood gusset plates will be at three locations. Tension and Moments at these locations will control the design of the gusset plates and fasteners. The debate of single shear vs. double shear nailing continues. The large gusset plates will create rigid joints at these locations.
4.) Check the the upper and lower rafters in combined compression and bending.
5.) The client will probably install a knee wall and a collar tie, how does this affect the analysis.
6.) The floor joist will be supported at approx. mid span by a bearing wall on the first floor.
7.) Need to look into wind loads on gambrel shaped roofs, this one is new for me.
Just a few things to get started with, I'm sure there will be other questions, assumptions and issues with this design.
A confused student is a good student.
Nathaniel P. Wilkerson, PE
www.medeek.com






RE: Gambrel Roof with a Stick Built Moment Frame
Check out Eng-Tips Forum's Policies here:
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RE: Gambrel Roof with a Stick Built Moment Frame
It is curious how part of a post shows up, then the rest. Don't know if it is a site glitch or if the OP did it, but I have seen it recently in another thread.
RE: Gambrel Roof with a Stick Built Moment Frame
Just for comparison purposes it would be interesting to model the frame with and without the collar tie to see how it affects the loading at the joints and the bending in the members, which of two will be more conservative? With the plywood gusset plates large enough can the collar tie be omitted entirely?
A confused student is a good student.
Nathaniel P. Wilkerson, PE
www.medeek.com
RE: Gambrel Roof with a Stick Built Moment Frame
Check out Eng-Tips Forum's Policies here:
FAQ731-376: Eng-Tips.com Forum Policies
RE: Gambrel Roof with a Stick Built Moment Frame
RE: Gambrel Roof with a Stick Built Moment Frame
I would agree with this assessment provided that there is a continuous chord (ie. double top plate) framed in at the pitch change of the gambrel roof. If you look at framing texts that show how to frame a gambrel roof, the old school method typically has knee-wall coming up to the pitch change and then rafters (upper and lower) supported on this knee-wall.
With the alternative method I've shown there is no continuous top plate (chord) at the pitch change. My theory is that each "truss" bay will act like a moment frame similar to a moment frame steel building design. The lateral load from these moment frames will then be transferred into the floor diaphragm below which will then be picked up by the first floor shearwalls. Therefore each frame will need to be able to resist the lateral loads being applied to it.
There will be certain amount of redundancy since the gable walls will provide some shear wall capacity in my opinion, but without the diaphragm chord at the pitch break I'm not sure I can rely fully on the gable end shear walls to take all of the lateral load (transverse).
The problem with the old school method of framing a gambrel roof is the way in which the vertical loads of the roof are transfered into the kneewall and then into the floor joists below. Since the knee-wall in inset from the exterior wall it imparts significant bending into the floor joist below.
The method shown above should more successively transmit those vertical loads directly into the perimeter walls below.
A confused student is a good student.
Nathaniel P. Wilkerson, PE
www.medeek.com
RE: Gambrel Roof with a Stick Built Moment Frame
With wind loads in the longitudinal direction (parallel to ridge) the steep lower pitch will act similar to a shear wall in preventing racking.
A confused student is a good student.
Nathaniel P. Wilkerson, PE
www.medeek.com
RE: Gambrel Roof with a Stick Built Moment Frame
RE: Gambrel Roof with a Stick Built Moment Frame
RE: Gambrel Roof with a Stick Built Moment Frame
I will then be able to determine my worst case moment loads on the gusset plates. From there one needs to check the fastener withdrawal (shear) due to the moment (and possibly combined tension load if there is a significant load reversal from the wind loads). One also needs to check the potential failure of the gusset plate itself along the scarf line. Both of these items I have discussed in some detail in this previous thread:
http://www.eng-tips.com/viewthread.cfm?qid=401659
If one ignores the compression load (assuming load is transferred through contact of 2x rafters) then my previous equation for the applied stress on the gusset plate reduces to: 6M/bd2 which must be less than the Ft' of the plywood.
I'm not saying this is my final algorithm, I've yet to give it more thought but I think I'm fairly close.
With regard to the shear check of the fasteners of a splice plate that is in both (tension/compression) and bending the approach would be similar to the method used in this thread for portal frames:
http://www.eng-tips.com/viewthread.cfm?qid=374730
When I dig into it in a couple of days I will probably try to create a tidy little spreadsheet where you can enter in the results from the various load cases and the logic which determine which one will govern and control the stress analysis.
A confused student is a good student.
Nathaniel P. Wilkerson, PE
www.medeek.com
RE: Gambrel Roof with a Stick Built Moment Frame
Also I realize the "traditional" approach does not provide as wide a space as you are showing. Maybe that sketch was from some other source and did not have the mid-span support as part of it.
Also seems like there would be ways to reduce the moment in the gussets if lateral stability could be achieved with a well positioned cross wall (perpendicular to the ridge) and using the roof diaphragm.
Just some thoughts. I'll be interested in your results.
RE: Gambrel Roof with a Stick Built Moment Frame
http://www.eng-tips.com/viewthread.cfm?qid=232119
It seems that there is no clear direction on this within the ASCE 7-10, but I may have somehow missed it.
A confused student is a good student.
Nathaniel P. Wilkerson, PE
www.medeek.com
RE: Gambrel Roof with a Stick Built Moment Frame
You may need more space for insulation than will fit in the required rafter depth, so increasing the rafter size would allow for wider gussets.
You could also consider steel gusset plates or talk to a truss manufacturer and so what they have to say. What you have is a frame, not a truss. When truss manufacturers build attic storage trusses (which are really frames) they tend to use large gusset plates, so truss plates may not be an option. I was thinking of thicker steel plates with bolted or screwed connections.
Double shear connections can be helpful because you do not have a lot of width to work with.