TY - JOUR
T1 - Experimental testing and analysis of the axial behaviour of intermeshed steel connections
AU - McGetrick, Patrick J.
AU - Robinson, Desmond
AU - Matis, Pantelis
AU - Martin, Tony
AU - Laefer, Debra F.
AU - Al-Sabah, Salam
AU - Truong-Hong, Linh
AU - Huynh, Minh Phuoc
AU - Schultz, Arturo E.
AU - Le, Jia Liang
AU - Shemshadian, Mohammad E.
AU - Labbane, Ramzi
PY - 2021
Y1 - 2021
N2 - This paper presents the work carried out on a collaborative tripartite project between the USA, Republic of Ireland and Northern Ireland to create and investigate the design, development and testing of a new class of intermeshed steel connections (ISCs) that do not rely on field welding and minimise bolting, thus targeting the facilitation of fast disassembly of steel structures and material reuse. This research took advantage of fully automated, precise, advanced manufacturing cutting technologies (e.g. laser, waterjet and high-definition plasma cutting) to achieve a connection method in steel that previously was only possible in materials such as timber, with the potential to revolutionise the steel construction industry. The paper outlines the ongoing research work by the collaborative team, focusing on the design, fabrication, finite-element analysis (FEA) and scaled experimental testing of side ISCs for the flanges of open sections, which included the use of state-of-the-art digital image correlation technology for non-contact measurements. A simplified connection design procedure is presented based on yielding of the side plates. This design procedure is refined based on the results of experimental testing and FEA of the local axial behaviour of the flange connection, addressing stress concentrations in the flange, fabrication tolerances and material overstrength.
AB - This paper presents the work carried out on a collaborative tripartite project between the USA, Republic of Ireland and Northern Ireland to create and investigate the design, development and testing of a new class of intermeshed steel connections (ISCs) that do not rely on field welding and minimise bolting, thus targeting the facilitation of fast disassembly of steel structures and material reuse. This research took advantage of fully automated, precise, advanced manufacturing cutting technologies (e.g. laser, waterjet and high-definition plasma cutting) to achieve a connection method in steel that previously was only possible in materials such as timber, with the potential to revolutionise the steel construction industry. The paper outlines the ongoing research work by the collaborative team, focusing on the design, fabrication, finite-element analysis (FEA) and scaled experimental testing of side ISCs for the flanges of open sections, which included the use of state-of-the-art digital image correlation technology for non-contact measurements. A simplified connection design procedure is presented based on yielding of the side plates. This design procedure is refined based on the results of experimental testing and FEA of the local axial behaviour of the flange connection, addressing stress concentrations in the flange, fabrication tolerances and material overstrength.
KW - Buildings, structures & design
KW - Recycling & reuse of materials
KW - Steel structures
UR - http://www.scopus.com/inward/record.url?scp=85103990437&partnerID=8YFLogxK
U2 - 10.1680/jstbu.19.00181
DO - 10.1680/jstbu.19.00181
M3 - Article
AN - SCOPUS:85103990437
VL - 175
SP - 153
EP - 173
JO - Proceedings of the Institution of Civil Engineers - Structures and Buildings
JF - Proceedings of the Institution of Civil Engineers - Structures and Buildings
SN - 0965-0911
IS - 2
ER -