Influence of the design constraints on the thickness optimization of glass panes to achieve lightweight insulating glass units in cruise ships
Journal article, 2023

The increasing complexity and size in cruise ships demands for lightweight structures and practical but accurate design methods. Conventionally, the focus has been on the steel parts of the ship, as they make most of its weight. However, the proportions of other materials are increasing. Therefore, this study attempts to provide better understanding how one could reach the lightweight designs of insulating glass units (IGUs) in ships. These are windows where at least two glass panes are separated by a hermetically sealed cavity. They are thin-walled structures that benefit not only from the geometrically nonlinear behavior, but also from the load sharing. Considering these effects, their behavior is studied using the nonlinear Finite Element Method and Particle Swarm Optimization. Different design criteria are imposed on the thickness determination of the glass panes with different shapes. Rectangular, triangular, and circular shapes are considered. The results show that the triangular shapes have the least weight for a given area when the deflection criterion is the dominating one. When maximum principal stress is the thickness defining criterion, the shapes perform almost equally well. The ratio between the pane thicknesses had the most influence on the behavior of the IGU. As it increases, i.e., one pane is significantly thicker than the other, the load sharing percentage drops, but it provides the most lightweight solution. Closer it is to 1, more equally the structural stresses are divided between the panes, i.e., redundancy is achieved. Finally, it is possible to establish a simple but effective method for the thickness determination of these IGUs using the results of this study. However, more work is required, including numerical analysis and experimental testing.

Insulating glass unit

Nonlinear finite element analysis

Particle swarm optimization

Classification

Load sharing

Cruise ship design

Author

Janne Heiskari

Aalto University

Jani Romanoff

Aalto University

A. Laakso

Meyer Turku Oy

Jonas Ringsberg

Chalmers, Mechanics and Maritime Sciences (M2), Marine Technology

Marine Structures

0951-8339 (ISSN)

Vol. 89 103409

Driving Forces

Sustainable development

Innovation and entrepreneurship

Subject Categories

Materials Engineering

Applied Mechanics

Vehicle Engineering

Areas of Advance

Transport

Production

Materials Science

Roots

Basic sciences

DOI

10.1016/j.marstruc.2023.103409

More information

Latest update

3/16/2023