Dynamic Modeling and Safety Analysis of Whole Three-Winch Traction System of Shipboard Aircraft

Dynamic Modeling and Safety Analysis of Whole Three-Winch Traction System of Shipboard Aircraft

The winch traction system for shipboard aircraft, when operating in a marine environment, is subjected to additional forces and moments due to the complex motion of the hull. These loads pose significant threats to the safety of the aircraft during the traction process. To address the safety issues...

Full description

Saved in:
Bibliographic Details
Main Authors: Guofang Nan, Ying Wang, Yihui Zhou, Haoyu Wang, Yao Li
Format: Article
Language:English
Published: MDPI AG 2025-06-01
Series:Aerospace
Subjects:
shipboard aircraft
three-winch traction
trajectory
sea condition level
wind scale
Online Access:https://www.mdpi.com/2226-4310/12/7/579
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:The winch traction system for shipboard aircraft, when operating in a marine environment, is subjected to additional forces and moments due to the complex motion of the hull. These loads pose significant threats to the safety of the aircraft during the traction process. To address the safety issues under complex sea conditions, this paper adopts harmonic functions to describe the rolling, pitching, and heaving motions of the hull. A theoretical analytical model of the three-winch traction system, considering the intricate coupling motions of the ship, is established. Unlike previous studies that often simplify ship motion or focus on single-component modeling, this work develops a complete, whole-system dynamic model integrating the winch system, rope, aircraft structure, and ship interaction. The dynamic characteristics of the small-deck winch traction system are investigated, with particular focus on the influence of the rear winch position, driving trajectory, and ship motion on the system’s dynamics and safety. This research is innovative in systematically exploring the dynamic safety behavior of a three-winch traction system operating under small-deck conditions and complex sea states. The results show that as the distance between the two rear winches increases, the lateral force on the tire decreases. Additionally, as the aircraft’s turning angle increases, the front winch rope force also increases. Moreover, with higher sea condition levels and wind scales, the maximum lateral force on the tires increases, leading to a significant reduction in the stability and safety of the winch traction system. This is particularly critical when the sea condition level exceeds 3 and the wind scale exceeds 6, as it increases the risk of tire sideslip or off-ground events. This research has substantial value for enhancing the safety and stability of winch traction systems on small decks, and also provides a theoretical basis for traction path design, winch position optimization, and the extension of the service life of key system components, demonstrating strong engineering applicability.
ISSN:2226-4310

Similar Items