2026-04-17T02:27:08Zhttps://recercat.cat/oai/request

oai:recercat.cat:10256/229572024-06-14T08:54:04Zcom_2072_452955com_2072_2054col_2072_453061

00925njm 22002777a 4500 dc Meulman, Edwin author Renart Canalias, Jordi author Carreras Blasco, Laura author Zurbitu González, Javier author 2023-04-28 Understanding the performance of a bonded joint over time is essential for the design of durable bonded joints and maintenance protocols. Viscoelastic creep crack growth and how it affects the mechanical behaviours of an adhesive is relevant information for a durable design. For this purpose, a method to obtain the average crack growth rate ( ) as a function of the energy release rate ( ) was developed. The proposed roller wedge driven (RWD) creep crack growth methodology can provide creep crack growth rate curves for a constant applied energy release rate. The RWD test setup was designed by the authors to test mode I DCB-like specimens by using a roller wedge. An advantage of using a moving wedge is that, on average, the crack growth rate equals the displacement rate of the wedge. By changing for different specimens, a vs curve can be obtained for the methacrylate adhesive Araldite 2021–1. The power law regression line of the vs curve provides a Pariś law-like equation. Data have shown that applying an energy release rate that is relatively low compared to the fracture toughness of Araldite 2021–1, found by quasi-static testing, will result in creep crack growth. Furthermore, a transition from cohesive to adhesive failure has been observed when the applied energy release rate is lowered. For durability design of bonded joints it must be considered that only using data from quasi-static testing will very likely overestimate the durability of the bonded joint The authors would like to acknowledge the support of the Spanish Government through the Ministerio de Ciencia, Innovación y Universidades under the contract PID2021-127879OB-C21 and Grant RYC2021-032171-I funded by MCIN/AEI/ 10.13039/501100011033 and by “European Union NextGenerationEU/PRTR. The first author would also like to acknowledge the support received from the Universitat de Girona and Banco Santander through the fellowship grant IFUdG2021-AE, co-funded by the AMADE research group (GRCT0064). The work in this research has been made possible by patent 300352094, PCT/ES2020/070074 made available by IKERLAN, S.COOP. (IKER018) and the Universitat de Girona. Furthermore, the authors like to acknowledge the support from the AMADE research group testing laboratory. Open Access funding provided thanks to the CRUE-CSIC agreement with Elsevier. http://hdl.handle.net/10256/22957 Assaigs de materials Materials -- Testing Mecànica de fractura Fracture mechanics A methodology for the experimental characterization of energy release rate-controlled creep crack growth under mode I loading