- Title
- An experimental and theoretical study of the normal coefficient of restitution for marble spheres
- Creator
- Ye, Yang; Zeng, Yawu; Thoeni, Klaus; Giacomini, Anna
- Relation
- Rock Mechanics and Rock Engineering Vol. 52, p. 1705-1722
- Publisher Link
- http://dx.doi.org/10.1007/s00603-018-1709-5
- Publisher
- Springer
- Resource Type
- journal article
- Date
- 2019
- Description
- The normal coefficient of restitution (NCOR) is a useful index to quantify the energy dissipation during impact. This study presents experimental tests of marble spheres impacting a plate. The effects of the sphere diameter, elastic properties of the plate, impact velocity, and repeated impacts on the NCOR were investigated. Three fracture phases were observed: no macrocrack, macrocrack, and fragmentation. A clear influence of the propagation of the macrocracks on the NCOR was observed. Macrocracks also cause increased NCOR variability. The cumulative damage caused by macrocracks can affect the propagation of macrocracks and fragmentation. In the no macrocrack phase, the NCOR decreases with increasing velocity and with decreasing diameter, and the velocity effect of the NCOR is also related to the size of the marble sphere. The proposed average rate of contact stress correlates well with the NCOR and can describe fully the velocity and size effects of the NCOR, which provides a simple way to consider the complex velocity and size effects in rockfall simulations. The dissipation caused by microcracks and viscosity can be considered simultaneously through the average rate of contact stress. The marble sphere NCOR decreases with increasing elasticity modulus of the plate, and this conclusion is verified by the elastic-perfectly plastic contact theory. Finally, viscoelastic contact theory is used to describe the NCOR, which proves that the decrease in the NCOR with decreasing diameter is reasonable and can be used to predict a decrease in the NCOR with an increase in velocity.
- Subject
- impact; viscoelastic contact theroy; fracture phases; energy dissipation mechanism; fragmentation; size effect
- Identifier
- http://hdl.handle.net/1959.13/1414655
- Identifier
- uon:36792
- Identifier
- ISSN:0723-2632
- Language
- eng
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