Eine Plattform für die Wissenschaft: Bauingenieurwesen, Architektur und Urbanistik
Eine Plattform für die Wissenschaft: Bauingenieurwesen, Architektur und Urbanistik
Study on mechanical properties of locked coil wire rope under and post fire
Highlights Carry out the static tensile test of the locked coil wire rope under and after high temperature. Obtain the mechanical properties and failure mode of locked coil wire rope under and post fire. The reduction law of locked coil wire ropes under and post fire is obtained. Compared with the existing research, the failure mechanism of cable is studied. The prediction method of temperature dependent mechanical properties is proposed.
Abstract As a new type of strand with excellent performance, a locked coil wire rope has been commonly used in all types of prestressed spatial structures. Owing to its unique section, it has a different temperature distribution, bearing mechanism, and failure mode from a traditional cable. In this study, static tensile tests of locked coil wire rope specimens were conducted under and after elevated-temperature treatments, and reduction laws of the mechanical properties of the strand were obtained. Based on the test results, a method for prediction of the mechanical properties of locked coil wire ropes under and after elevated-temperature exposure was developed. The research showed that the failure of a locked coil wire rope is ductile failure. Its ultimate strength begins to decrease when the heating temperature exceeds 200 °C. When the temperature reaches 400 °C, the strength of the strand is lower than 50 % of that at room temperature. The heat treatment process reduces the strength and ductility of the strand. When the heating temperature of a strand reaches 400 °C, it should be replaced in time after a fire. The research results provide a theoretical basis for fire resistance and post fire assessment of prestressed structures.
Study on mechanical properties of locked coil wire rope under and post fire
Highlights Carry out the static tensile test of the locked coil wire rope under and after high temperature. Obtain the mechanical properties and failure mode of locked coil wire rope under and post fire. The reduction law of locked coil wire ropes under and post fire is obtained. Compared with the existing research, the failure mechanism of cable is studied. The prediction method of temperature dependent mechanical properties is proposed.
Abstract As a new type of strand with excellent performance, a locked coil wire rope has been commonly used in all types of prestressed spatial structures. Owing to its unique section, it has a different temperature distribution, bearing mechanism, and failure mode from a traditional cable. In this study, static tensile tests of locked coil wire rope specimens were conducted under and after elevated-temperature treatments, and reduction laws of the mechanical properties of the strand were obtained. Based on the test results, a method for prediction of the mechanical properties of locked coil wire ropes under and after elevated-temperature exposure was developed. The research showed that the failure of a locked coil wire rope is ductile failure. Its ultimate strength begins to decrease when the heating temperature exceeds 200 °C. When the temperature reaches 400 °C, the strength of the strand is lower than 50 % of that at room temperature. The heat treatment process reduces the strength and ductility of the strand. When the heating temperature of a strand reaches 400 °C, it should be replaced in time after a fire. The research results provide a theoretical basis for fire resistance and post fire assessment of prestressed structures.
Study on mechanical properties of locked coil wire rope under and post fire
Guo, Liulu (Autor:in) / Chen, Zhihua (Autor:in) / Liu, Hongbo (Autor:in) / Meng, Yadan (Autor:in) / Zhang, Fan (Autor:in) / Wang, Longxuan (Autor:in)
14.08.2022
Aufsatz (Zeitschrift)
Elektronische Ressource
Englisch
Properties of and Applications with Full Locked Coil Rope Assemblies
| British Library Conference Proceedings | 2017