Virtual Prototyping of the RM Active Grid®: a DEM-MBD Study
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In: Berg- und hüttenmännische Monatshefte : BHM, Vol. 169.2024, No. 7, 05.08.2024, p. 400-411.
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TY - JOUR
T1 - Virtual Prototyping of the RM Active Grid®: a DEM-MBD Study
AU - Falkner, Philipp
AU - Fimbinger, Eric
AU - Flachberger, Helmut
PY - 2024/8/5
Y1 - 2024/8/5
N2 - Numerical simulation is an established tool to improve knowledge of complex systems and to accelerate the development of new prototypes. In this contribution, the patented Active Grid® made by the company RM RUBBLE MASTER HMH GmbH is examined.In an initial step, representative system parameters (spring properties) are found via a multibody dynamic simulation; at this point, without particles acting on the system components. After that, the virtually defined Active Grid® system is loaded with particles in order to include the interaction effects of various bulk materials acting on the system’s mechanical components. For this purpose, a DEM-MBD co-simulation, extending the discrete element method (DEM) towards multibody dynamics (MBD) simulation, is performed, accounting for the bulk materials via DEM and the interacting system components via MBD. This bi-directional co-simulation enables the consideration of interactions between the bulk materials (the particles) and the driven spring-damper system (the moving system components).With this virtual prototype of the Active Grid®, performance benefits and characteristics in terms of screening efficiency for different material types and varying drive speeds are analysed. The overall aim is to achieve a scalable DEM-MBD model that allows virtual prototyping and, especially, optimisation for future system developments.
AB - Numerical simulation is an established tool to improve knowledge of complex systems and to accelerate the development of new prototypes. In this contribution, the patented Active Grid® made by the company RM RUBBLE MASTER HMH GmbH is examined.In an initial step, representative system parameters (spring properties) are found via a multibody dynamic simulation; at this point, without particles acting on the system components. After that, the virtually defined Active Grid® system is loaded with particles in order to include the interaction effects of various bulk materials acting on the system’s mechanical components. For this purpose, a DEM-MBD co-simulation, extending the discrete element method (DEM) towards multibody dynamics (MBD) simulation, is performed, accounting for the bulk materials via DEM and the interacting system components via MBD. This bi-directional co-simulation enables the consideration of interactions between the bulk materials (the particles) and the driven spring-damper system (the moving system components).With this virtual prototype of the Active Grid®, performance benefits and characteristics in terms of screening efficiency for different material types and varying drive speeds are analysed. The overall aim is to achieve a scalable DEM-MBD model that allows virtual prototyping and, especially, optimisation for future system developments.
KW - Discrete element method
KW - DEM
KW - multibody dynamics
KW - MBD
KW - multiphysics
KW - virtual prototyping
KW - Active Grid
U2 - 10.1007/s00501-024-01493-1
DO - 10.1007/s00501-024-01493-1
M3 - Article
VL - 169.2024
SP - 400
EP - 411
JO - Berg- und hüttenmännische Monatshefte : BHM
JF - Berg- und hüttenmännische Monatshefte : BHM
SN - 1613-7531
IS - 7
ER -