Eine Plattform für die Wissenschaft: Bauingenieurwesen, Architektur und Urbanistik
Eine Plattform für die Wissenschaft: Bauingenieurwesen, Architektur und Urbanistik
Screwed connections in built-up cold-formed steel members at ambient and elevated temperatures
Abstract Screwed connections are commonly used in fabricating built-up cold-formed steel (CFS) members. However, the knowledge and understanding of their behaviour and design are limited. This research study investigated the shear behaviour and capacity of the screwed connections used in built-up CFS members. It included a series of shear tests of screwed connections between two single channel members as used in built-up back-to-back CFS members, failing by tilting and bearing. Tests were conducted at both ambient and elevated temperatures. Using the results from these tests and available literature, this study has shown that the design equations for the tilting and bearing capacity of screwed connections in the current CFS design standards are reliable for the screwed connections in built-up CFS members at ambient temperature. It has then shown that the same design equations can be used to predict the tilting and bearing capacity of these screwed connections at elevated temperatures if they are used in combination with the proposed reduction factor equations for elevated temperature capacities. Details of this research study, its results and findings are presented in this paper.
Graphical abstract Display Omitted
Highlights The shear behaviour of screwed connection in built-up CFS members was investigated. Curling of connected parts was minor because of the effect of edge flange elements. The accuracy of current design equations in predicting their capacities at ambient temperature was investigated. Equations were proposed for predicting the reduction of their capacity with increasing temperatures. Improved design guidelines were proposed for their capacities at elevated temperatures.
Screwed connections in built-up cold-formed steel members at ambient and elevated temperatures
Abstract Screwed connections are commonly used in fabricating built-up cold-formed steel (CFS) members. However, the knowledge and understanding of their behaviour and design are limited. This research study investigated the shear behaviour and capacity of the screwed connections used in built-up CFS members. It included a series of shear tests of screwed connections between two single channel members as used in built-up back-to-back CFS members, failing by tilting and bearing. Tests were conducted at both ambient and elevated temperatures. Using the results from these tests and available literature, this study has shown that the design equations for the tilting and bearing capacity of screwed connections in the current CFS design standards are reliable for the screwed connections in built-up CFS members at ambient temperature. It has then shown that the same design equations can be used to predict the tilting and bearing capacity of these screwed connections at elevated temperatures if they are used in combination with the proposed reduction factor equations for elevated temperature capacities. Details of this research study, its results and findings are presented in this paper.
Graphical abstract Display Omitted
Highlights The shear behaviour of screwed connection in built-up CFS members was investigated. Curling of connected parts was minor because of the effect of edge flange elements. The accuracy of current design equations in predicting their capacities at ambient temperature was investigated. Equations were proposed for predicting the reduction of their capacity with increasing temperatures. Improved design guidelines were proposed for their capacities at elevated temperatures.
Screwed connections in built-up cold-formed steel members at ambient and elevated temperatures
Vy, Son Tung (Autor:in) / Mahendran, Mahen (Autor:in)
28.02.2022
Aufsatz (Zeitschrift)
Elektronische Ressource
Englisch
| Emerald Group Publishing | 2021
| British Library Online Contents | 2018
| British Library Online Contents | 2018
| British Library Online Contents | 2018