Virtual Prototyping of the RM Active Grid®: a DEM-MBD Study

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Virtual Prototyping of the RM Active Grid®: a DEM-MBD Study. / Falkner, Philipp; Fimbinger, Eric; Flachberger, Helmut.
In: Berg- und hüttenmännische Monatshefte : BHM, Vol. 169.2024, No. 7, 05.08.2024, p. 400-411.

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@article{8c59f9c0067742579453c80d92620efd,
title = "Virtual Prototyping of the RM Active Grid{\textregistered}: a DEM-MBD Study",
abstract = "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{\textregistered} 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{\textregistered} system is loaded with particles in order to include the interaction effects of various bulk materials acting on the system{\textquoteright}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{\textregistered}, 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.",
keywords = "Discrete element method, DEM, multibody dynamics, MBD, multiphysics, virtual prototyping, Active Grid",
author = "Philipp Falkner and Eric Fimbinger and Helmut Flachberger",
year = "2024",
month = aug,
day = "5",
doi = "10.1007/s00501-024-01493-1",
language = "English",
volume = "169.2024",
pages = "400--411",
journal = "Berg- und h{\"u}ttenm{\"a}nnische Monatshefte : BHM",
issn = "1613-7531",
publisher = "Springer Wien",
number = "7",

}

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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 -