Eine Plattform für die Wissenschaft: Bauingenieurwesen, Architektur und Urbanistik
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Effect of bolt clamping force on the fracture strength of mixed mode fracture in an edge crack with different sizes: Experimental and numerical investigations
Highlights ► Fracture strength of bolt clamped crack is greater than the edge crack for all crack sizes. ► The effective geometry factor is considerably reduced in bolt clamped cracked specimens. ► Ratio of effective geometry factor in clamped cracks to simple cracks is independent of the crack size. ► Ratio of fracture strength in clamped cracks to simple cracks is independent of the crack size.
Abstract To investigate the effect of bolt clamping force, resulting from torque tightening, on the mixed mode fracture (I and II) strength and effective geometry/loading factor of an edge crack with different lengths, experimental and numerical studies have been carried out. In the experimental part fracture tests were conducted on three batches of simple edge crack and bolt torque tightened with 3.5 and 7Nm edge crack at three different crack sizes of Poly methyl-methacrylate (PMMA) rectangular plate. The specimens’ fracture strength was obtained using a tensile test machine at different loading angles by employing a modified Arcan fixture. In numerical part, finite element simulations were employed to model the three test specimen batches at the three crack lengths to obtain their stress intensity geometry/loading factors. The results show that the bolt tightening torque significantly reduces the effective geometry/loading factor, and thus increases the joint fracture strength compared to bolt-less simple edge crack specimens. However, the bolt clamping effect on increasing the fracture strength was almost the same for different crack lengths.
Effect of bolt clamping force on the fracture strength of mixed mode fracture in an edge crack with different sizes: Experimental and numerical investigations
Highlights ► Fracture strength of bolt clamped crack is greater than the edge crack for all crack sizes. ► The effective geometry factor is considerably reduced in bolt clamped cracked specimens. ► Ratio of effective geometry factor in clamped cracks to simple cracks is independent of the crack size. ► Ratio of fracture strength in clamped cracks to simple cracks is independent of the crack size.
Abstract To investigate the effect of bolt clamping force, resulting from torque tightening, on the mixed mode fracture (I and II) strength and effective geometry/loading factor of an edge crack with different lengths, experimental and numerical studies have been carried out. In the experimental part fracture tests were conducted on three batches of simple edge crack and bolt torque tightened with 3.5 and 7Nm edge crack at three different crack sizes of Poly methyl-methacrylate (PMMA) rectangular plate. The specimens’ fracture strength was obtained using a tensile test machine at different loading angles by employing a modified Arcan fixture. In numerical part, finite element simulations were employed to model the three test specimen batches at the three crack lengths to obtain their stress intensity geometry/loading factors. The results show that the bolt tightening torque significantly reduces the effective geometry/loading factor, and thus increases the joint fracture strength compared to bolt-less simple edge crack specimens. However, the bolt clamping effect on increasing the fracture strength was almost the same for different crack lengths.
Effect of bolt clamping force on the fracture strength of mixed mode fracture in an edge crack with different sizes: Experimental and numerical investigations
Chakherlou, T.N. (Autor:in) / Maleki, H.N. (Autor:in) / Aghdam, A.B. (Autor:in) / Abazadeh, B. (Autor:in)
17.08.2012
10 pages
Aufsatz (Zeitschrift)
Elektronische Ressource
Englisch
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