- Title
- An Experimental Setup to Study the Fragmentation of Rocks Upon Impact
- Creator
- Guccione, Davide E.; Thoeni, Klaus; Fityus, Stephen; Nader, Francois; Giacomini, Anna; Buzzi, Olivier
- Relation
- ARC.DP160103140 http://purl.org/au-research/grants/arc/DP160103140
- Relation
- Rock Mechanics and Rock Engineering Vol. 54, Issue 8, p. 4201-4223
- Publisher Link
- http://dx.doi.org/10.1007/s00603-021-02501-3
- Publisher
- Springer
- Resource Type
- journal article
- Date
- 2021
- Description
- Rockfall is a natural hazard that needs to be rigorously managed along all the major road and railways transport networks by identifying the most appropriate mitigation measures. There has been significant progress in rockfall modelling and rockfall protection systems in recent years but there remains one aspect that is not very well understood and quite challenging to account for in the design of rockfall protection structures, namely the fragmentation of falling blocks upon impact. Rocks often break up upon impact, which leads to a change in size, shape and energy of falling blocks, parameters that affect the design of the protective structures. Before being able to incorporate fragmentation into predictive trajectory models, it is required to better understand the fragmentation process and its likely outcome (number, volume of fragments and their trajectories). To that aim, an innovative experimental setup was developed at the University of Newcastle (Australia) to study rock fragmentation upon impact. The setup was designed to perform controlled vertical drop tests and record the following impact parameters: impact force, impulse, impact duration, velocities (of the block before impact and its fragment after impact) and all components of energy, pre and post impact. Six views (four high-speed cameras and two mirrors) are used for an accurate reconstruction of the 3D trajectory of blocks and fragments, in translation and rotation. This paper presents the validation of the setup via two series of drop tests using mortar spheres. Attention was focused on the evaluation of impact force and impulse from load cells placed under the impacted surface, tracking of translational and rotational velocity and the computation of total kinetic energy (before and after impact) and all components of energy dissipation. The results confirm that the experimental setup and the approach developed can be used to obtain impact force, impulse and to compute the energy balance during the impact and fragmentation and conduct advanced fragmentation testing.
- Subject
- impact; trajectory; tracking; energy balance; fragmentation; rockfall; SDG 11; Sustainable Development Goals
- Identifier
- http://hdl.handle.net/1959.13/1472091
- Identifier
- uon:48766
- Identifier
- ISSN:0723-2632
- Language
- eng
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