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Simulating Bonnet Flutter - Unsteady Aerodynamics and Its Structural Response

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Non-members (tax incl.):¥6,600 Members (tax incl.):¥5,280
Paper/Info type
SAE Paper

No.2021-01-0946

Pages
1-7(Total 7 p)
Date of publication
Apr 2021
Publisher
SAE International
Language
English
Event
SAE WCX Digital Summit 2021

Detailed Information

Author(E)1) Adrian P. Gaylard, 2) Joaquin Gargoloff, 3) Jonathan Jilesen, 4) Jonathan Arata
Affiliation(E)1) Jaguar Land Rover, 2) Dassault Systemes, 3) Dassault Systemes, 4) Dassault Systemes SIMULIA
Abstract(E)Government regulations and consumer needs are driving automotive manufacturers to reduce vehicle energy consumption. However, this forms part of a complex landscape of regulation and customer needs. For instance, when reducing aerodynamic drag or vehicle weight for efficiency other important factors must be taken into account.
This is seen in vehicle bonnet design. The bonnet is a large unsupported structure that is exposed to very high and often fluctuating aerodynamic loads, due to travelling in the wake of other vehicles. When travelling at high speed and in close proximity to other vehicles this unsteady aerodynamic loading can force the bonnet structure to vibrate, so-called “bonnet flutter”. A bonnet which is stiff enough to not flutter may be either too heavy for efficiency or insufficiently compliant to meet pedestrian safety requirements. On the other hand, a bonnet which flutters may be structurally compromised or undermine customer perceptions of vehicle quality.
This work demonstrates a one-way coupled CFD to FEA analysis that is capable of predicting bonnet flutter during pre-prototype development, providing an approach which can allow engineers to balance the many demands made on this structure. This is accomplished using a combination of a Lattice-Boltzmann based Very Large Eddy flow simulation tool combined with finite element analysis. Both the unsteady surface pressures and subsequent structural response of the bonnet are compared to measurements made during track testing.
This demonstrates that by reproducing the real-world unsteady flow environment we can capture this effect, which raises the possibility of undertaking design actions to avoid this issue, while at the same time minimizing structural complexity and weight.

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