Predicting shear strength of CFS channels with slotted webs by machine learning models

Abstract: Staggered rectangular perforations (slots) are provided in the webs of cold-formed steel (CFS) beams and columns to reduce their thermal conductivity and improve the energy efficiency of CFS buildings. The perforations adversely affect the structural characteristics of the members, especially those governed by the web parameters, such as the shear strength and shear buckling. This paper presents machine learning (ML) models to predict the elastic shear buckling load and the ultimate shear strength of CFS chann… Show more

“…Many publications described ML models considered in this study for predicting properties of concrete and reinforced concrete structures . Fewer papers have been published on ML applications to steel structures, including buckling analysis of beam-columns [66], cold-formed steel (CFS) space structure optimization [67], web crippling strength prediction [68], elastic distortional buckling stress determination [69,70], rotation capacity prediction [71], strength prediction of concrete-filled steel tubular columns [72], failure mode identification of column base plate connection [73], capacity prediction of cold-formed stainless steel tubular columns [74], seismic drift demand estimation for steel moment frame buildings [75], and shear strength of CFS channels with staggered perforated webs [76][77][78][79]. ML techniques were previously applied to steel cellular beams.…”

Buckling and ultimate load prediction models for perforated steel beams using machine learning algorithms

“…Many publications described ML models considered in this study for predicting properties of concrete and reinforced concrete structures . Fewer papers have been published on ML applications to steel structures, including buckling analysis of beam-columns [66], cold-formed steel (CFS) space structure optimization [67], web crippling strength prediction [68], elastic distortional buckling stress determination [69,70], rotation capacity prediction [71], strength prediction of concrete-filled steel tubular columns [72], failure mode identification of column base plate connection [73], capacity prediction of cold-formed stainless steel tubular columns [74], seismic drift demand estimation for steel moment frame buildings [75], and shear strength of CFS channels with staggered perforated webs [76][77][78][79]. ML techniques were previously applied to steel cellular beams.…”

Buckling and ultimate load prediction models for perforated steel beams using machine learning algorithms

“…Many publications described ML models considered in this study for predicting properties of concrete and reinforced concrete structures . Fewer papers have been published on ML applications to steel structures, including buckling analysis of beam-columns [66], cold-formed steel (CFS) space structure optimization [67], web crippling strength prediction [68], elastic distortional buckling stress determination [69,70], rotation capacity prediction [71], strength prediction of concrete-filled steel tubular columns [72], failure mode identification of column base plate connection [73], capacity prediction of cold-formed stainless steel tubular columns [74], seismic drift demand estimation for steel moment frame buildings [75], and shear strength of CFS channels with staggered perforated webs [76][77][78][79]. ML techniques were previously applied to steel cellular beams.…”

Buckling and ultimate load prediction models for perforated steel beams using machine learning algorithms

Application of machine learning in cold-formed steel