medeek
Structural
- Mar 16, 2013
- 1,104
I've mucked around with wood truss analysis a bit in the last couple of years but until now have never had the opportunity to actually design one for a customer.
Recently I've been contacted by a client who would like to fabricate his own (wood gusset connected) trusses utilizing 2x4's, 8d nails (no glue) and 1/2" (15/32") plywood/osb plates for an out-to-out span of 20 ft with a 4:12 pitch.
They would like to utilize a king post truss (only one web) versus a fink or queen post truss in order to minimize construction time and labor. Hence the need to engineer the design since they feel they may be pushing their design a little with a king post type truss.
My algorithm for the analysis will go something like this:
1.) Determine design criteria of location (snow, wind, seismic) and geometry of the roof (out-to-out span, overhangs, pitch).
2.) Establish all pertinent load cases: Balanced snow, unbalanced snow, wind C&C, wind MWFRS, Dead Only, Construction Live Load etc...
3.) Calculate the tension/compression for each member for each load case.
4.) Calculate the panel point moments and mid panel moments as applicable for the top and bottom chords for each load case.
5.) Calculate the heel joint moment for each load case, (no top chord or bottom chord splices so no splice moments necessary).
6.) Calculate the reactions of the truss for each load case.
7.) Utilize the maximum tensions/compressions and moments of the previous calculations to design the members and the connector plates.
8.) The max. bearing will be used to check the bearing at the heel and the min. bearing will be given to the customer as the max. uplift to design for (ie. install H1 hurricane ties).
I will be using the ANSI TPI 1-2007 as a guide in running the different checks on the members and plates.
I think this should be relatively straight forward, however since I have never actually done a full truss analysis I thought it might be a good idea to throw this out there and see if anyone had any specific hints or suggestions.
A confused student is a good student.
Nathaniel P. Wilkerson, PE
Recently I've been contacted by a client who would like to fabricate his own (wood gusset connected) trusses utilizing 2x4's, 8d nails (no glue) and 1/2" (15/32") plywood/osb plates for an out-to-out span of 20 ft with a 4:12 pitch.
They would like to utilize a king post truss (only one web) versus a fink or queen post truss in order to minimize construction time and labor. Hence the need to engineer the design since they feel they may be pushing their design a little with a king post type truss.
My algorithm for the analysis will go something like this:
1.) Determine design criteria of location (snow, wind, seismic) and geometry of the roof (out-to-out span, overhangs, pitch).
2.) Establish all pertinent load cases: Balanced snow, unbalanced snow, wind C&C, wind MWFRS, Dead Only, Construction Live Load etc...
3.) Calculate the tension/compression for each member for each load case.
4.) Calculate the panel point moments and mid panel moments as applicable for the top and bottom chords for each load case.
5.) Calculate the heel joint moment for each load case, (no top chord or bottom chord splices so no splice moments necessary).
6.) Calculate the reactions of the truss for each load case.
7.) Utilize the maximum tensions/compressions and moments of the previous calculations to design the members and the connector plates.
8.) The max. bearing will be used to check the bearing at the heel and the min. bearing will be given to the customer as the max. uplift to design for (ie. install H1 hurricane ties).
I will be using the ANSI TPI 1-2007 as a guide in running the different checks on the members and plates.
I think this should be relatively straight forward, however since I have never actually done a full truss analysis I thought it might be a good idea to throw this out there and see if anyone had any specific hints or suggestions.
A confused student is a good student.
Nathaniel P. Wilkerson, PE
