# Multistage Static and Dynamic Optimization Framework for Composite Laminates in Lightweight Urban Rail Vehicle Car Bodies

**Authors:** Alessio Cascino, Francesco Distaso, Enrico Meli, Andrea Rindi

PMC · DOI: 10.3390/ma19030531 · Materials · 2026-01-29

## TL;DR

This paper introduces a multistage optimization framework for designing lightweight rail vehicle bodies using composite laminates, achieving significant thickness reduction while maintaining structural performance.

## Contribution

A novel sequential optimization approach for composite laminates in low-floor rail vehicles, balancing static and dynamic requirements while reducing material use.

## Key findings

- A 66% reduction in laminate thickness was achieved compared to the baseline design.
- The fundamental natural frequency was maintained at approximately 16 Hz, preserving dynamic integrity.
- Failure index increased by 22.5% and 23.3% for symmetric and asymmetric laminates, maximizing material efficiency.

## Abstract

This paper presents a robust multistage optimization framework for the integration of composite laminates into the car body shell of a low-floor light rail vehicle (LRV). While structural design in low-floor vehicles is typically complex, this methodology successfully balances both static and dynamic requirements through a sequential optimization process. Developed in strict accordance with reference European standards, the methodology addresses the structural challenges inherent in low-floor architectures, where complex load paths and redistributed equipment masses require targeted reinforcement. The proposed approach sequentially addresses dynamic and static requirements through a structural optimization process. Two distinct 10-ply laminate configurations, one symmetric and one asymmetric, were investigated. The results demonstrate that the multistage optimization successfully converged to a highly mass-efficient solution, achieving a 66% reduction in laminate thickness compared to the baseline design. This significant result was accomplished while maintaining full regulatory compliance; the failure index increased by approximately 22.5% and 23.3% for the two composite laminate configurations, respectively, effectively maximizing material utilization. A key finding of this study is the preservation of structural dynamic integrity; the fundamental natural frequency was maintained at approximately 16 Hz, with a high correlation across the first ten vibration modes, confirming that the global dynamic behaviour remains unaffected. These observations provide critical insights into the synergy between hybridization and structural constraints, suggesting a systematic pathway for designers to achieve an optimal trade-off between manufacturing costs, weight reduction, and performance in advanced urban transit platforms.

## Full text

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## Figures

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## References

50 references — full list in the complete paper: https://tomesphere.com/paper/PMC12897840/full.md

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Source: https://tomesphere.com/paper/PMC12897840