High-Performance Stringer-Stiffened Composite Hull Structures under Slamming Loads: The Effects of Hydroelasticity and Non-Uniform Pressure Loads

Pearson, Connor and Battley, Mark and Souppez, Jean-Baptiste and Allen, Tom (2026) High-Performance Stringer-Stiffened Composite Hull Structures under Slamming Loads: The Effects of Hydroelasticity and Non-Uniform Pressure Loads. In: INNOV'sail 2026: International Conference on Innovation in High Performance Sailing Yachts and Wind-Assisted Ships, 3rd-5th June 2026, Gothenburg, Sweden.

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Abstract

Water impacts form a critical load for the outer hull panels of small high-speed marine craft. These result in highly localised non-uniform pressure pulse, which propagates along a hull panel as it is immersed. While slamming is multi-functional and stochastic, the severity of the impact is primarily a function of the vertical impact velocity, and angle between the panel and free surface, known as
the deadrise. Due to the complexities of water impacts, design standards —such as those defined in ISO-12215-5— recommend that hull panels are designed based on a static uniform pressure. However, these are unable to produce the same strain state as a water impact, leading to a disconnect between real-world and as-designed performance.
This study addresses this gap using hydroelastic simulations of the slamming of a stringer-stiffened panel typical of current generations of ocean-going racing yachts, and makes suggestions to improve the analysis of such structures during the design process. Results indicate that the structural response of such panels is dependent on the location of the pressure pulse and the effects of hydroelasticity,
which are not accounted for when using a uniform pressure. The Authors recommend that design processes may be improved by statically solving for key instants during the water impact using analytically derived non-uniform pressures. Such a method reduces the discrepancy between real-world and as-designed laminate strains to only 33.6%, compared to the 65.8% reported when using a uniform pressure load, representing a significant improvement over the current design standards.

Item Type: Conference or Workshop Item (Paper)
Dates:
Date
Event
3 June 2026
Published Online
Uncontrolled Keywords: Stringer-stiffened composite panels; Marine hull structures; Slamming loads; Constant velocity water impacts; Hat/Omega stringers.
Subjects: CAH10 - engineering and technology > CAH10-01 - engineering > CAH10-01-01 - engineering (non-specific)
Divisions: Architecture, Built Environment, Computing and Engineering > Engineering
Depositing User: Gemma Tonks
Date Deposited: 30 Jun 2026 10:26
Last Modified: 30 Jun 2026 10:26
URI: https://www.open-access.bcu.ac.uk/id/eprint/17090

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