HMROSS
Civil/Environmental
- Aug 12, 2003
- 11
I am using the method of relative rigities to distribute horizontal forces due to a rigid roof diaphram for a single story structure. The structure is comprised of rectangular boxes all of which are open on one end and closed on the other (earth covered-into hillside). I am looking at placing buttresses on both sides of the open-ends to move the center-of-rigidity towards the center-of-mass and reduce torsional effects.
Being that all the other wall rigidities are based on superposition of their solid pier(s)relative deflections, what is the best assumptions to make regarding a 45 degree sloped buttress wall from some height h. Examples (cantilever action):
A) h=8';L=8';h/L=1.0; d=0.7, R=1.4.
B) h=4';L=8';h/L=0.5; d=0.2; R=5.0
C) h=8';L=4';h/L=2.0; d=3.8; R=0.26
My objective is to model the rigidity as close as possible to the other relative rigidties. Noting that the method I am employing gives somewhat bigger overall values of rigidty than more advanced methods.
I am chosing to assume example B at this time and would like some feedback--shoot away at my ass---umption please.
Being that all the other wall rigidities are based on superposition of their solid pier(s)relative deflections, what is the best assumptions to make regarding a 45 degree sloped buttress wall from some height h. Examples (cantilever action):
A) h=8';L=8';h/L=1.0; d=0.7, R=1.4.
B) h=4';L=8';h/L=0.5; d=0.2; R=5.0
C) h=8';L=4';h/L=2.0; d=3.8; R=0.26
My objective is to model the rigidity as close as possible to the other relative rigidties. Noting that the method I am employing gives somewhat bigger overall values of rigidty than more advanced methods.
I am chosing to assume example B at this time and would like some feedback--shoot away at my ass---umption please.