Michele Martelli scite author profile

This article focuses on the mathematical model of the pitch control mechanism for a marine controllable pitch propeller, with the aim of describing the dynamic behaviour of this kind of system and its influence on ship performance. Too great a load on the blades can result in high pressures in the actuating system, response delays and control system problems, which are ultimately responsible for most mechanism failures. The behaviour of the controllable pitch propeller actuating mechanism is considered in terms of blade position, oil pressures inside the controllable pitch propeller hub and magnitudes of the forces acting on the blades. In the proposed mathematical model, the forces acting on the propeller blade are evaluated taking into account the yaw motion of the ship, the propeller speed (including shaft accelerations and decelerations) and the turning of the blade during the pitch change. On the basis of the introduced procedure, a controllable pitch propeller numerical model as part of an overall propulsion and manoeuvrability simulator representing the dynamic behaviour of a twin-screw fast vessel is developed. The aim of this work is to represent the ship propulsion dynamics through time-domain simulation, based on which the designers can develop and test several design options, in order to avoid possible machinery overloads with their consequent failures and to obtain the best possible ship performances. In this aspect, the controllable pitch propeller model is an essential design tool.

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System control design of autopilot and speed pilot for a patrol vessel by using LMIs

Alessandri¹,

Donnarumma²,

Vignolo³

et al. 2015

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Heading and speed control for a patrol vessel is addressed by using simple PID regulators. The selection of the PID parameters for both controllers is accomplished by using decoupled linearized model of the original motion equations and LMIs as a design tool. The effectiveness of the resulting controllers is validated on the original dynamic equations and with the presence of external disturbances such as wind, waves, and current.

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Design and Validation of Dynamic Positioning for Marine Systems: A Case Study

Donnarumma

Figari

Martelli

et al. 2018

IEEE J. Oceanic Eng.

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The design of a dynamic positioning (DP) system is a challenging task with several technical fields involved in the problem solution. Numerical simulation is a powerful tool to aid the designer during the system development and to speed up the design process. This paper presents the simulation methodology adopted to design and test the DP system for a vessel with a standard propulsion configuration. Simulation results and sea trial measurements are compared to illustrate the reliability of the proposed simulation platform.

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A collision avoidance algorithm for ship guidance applications

Zaccone

Martelli

2019

Journal of Marine Engineering & Technology

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A COLREG-Compliant Ship Collision Avoidance Algorithm

Zaccone

Martelli

Figari

2019

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