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Air Lubricated and Air Cavity Ships

Development, Design, and Application

Authors: Gennadiy Alexeevitch Pavlov, Liang Yun, Alan Bliault, Shu-Long He

Publisher: Springer New York

Part of: Springer Professional "Wirtschaft+Technik" , Springer Professional "Technik"

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About this book

Air Lubrication and Air Cavity Technology is a major development that has emerged in recent years as a means to reduce resistance and powering for many types of ships, and an efficient design for high speed marine vessels. This book introduces the mechanisms for boundary layer drag reduction and concepts studied in early research work. Air bubble and sheet lubrication for displacement vessels is outlined and the key projects introduced. Generation of low volume flow air cavities under the hull of displacement, semi displacement and planing vessels are introduced together with theoretical and empirical analysis and design methods. Resistance reduction, power reduction and fuel efficiency are covered for both displacement and high speed vessels. Air layer and air cavity effects on vessel static and dynamic stability are covered, linked to regulatory requirements such as IMO. Seaway motions and reduced impact load of high speed craft in waves are discussed including model test results. Integration of propulsion systems for optimum powering is summarized. A design proposal for a wave piercing air cavity craft is included in an appendix. A comprehensive listing of document resources and internet locations is provided for further research.

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Table of Contents

Frontmatter

Chapter 1. Introduction

Abstract

Archimedes principle states that for a body to float it must displace a volume of water equal to its mass. If the body is driven forward, it must move aside that water volume. As the water flows around the surface of the body forces are generated, both by friction against the body surface and by inertial forces generated by acceleration around the body shape.

Gennadiy Alexeevitch Pavlov, Liang Yun, Alan Bliault, Shu-Long He

Chapter 2. Reducing Friction Resistance

Abstract

In this chapter we will work through the different methods that have been studied for surface friction resistance reduction, aimed at reducing, altering, or disconnecting the boundary layer from the hull surface. This gives a historical and technical background to understanding boundary layer flows.

Gennadiy Alexeevitch Pavlov, Liang Yun, Alan Bliault, Shu-Long He

Chapter 3. Air Lubrication and Air Cavity Analysis

Abstract

In this chapter we will use the acronym WFDR for water friction drag reduction to describe the general reduction of the frictional force of a hull wetted surface in water flow and air drag reduction (ADR) to describe achievement of reduction using air as a lubricant. If the local skin friction force on a surface in water flow is τ_w, then the local skin friction coefficient C_F can be defined as:where ρ is the water density and U₀ is the inflow velocity.

Gennadiy Alexeevitch Pavlov, Liang Yun, Alan Bliault, Shu-Long He

Chapter 4. Air Cavity Ship Concept Evaluation

Displacement and Semi-Displacement Types

Abstract

In this chapter we will take our review of air cavity mechanisms introduced in Chap. 3 a step further. We will look at applying a number of configurations for air cavity generation below the hull of displacement vessels and discuss initial design evaluation of a number of examples.

Gennadiy Alexeevitch Pavlov, Liang Yun, Alan Bliault, Shu-Long He

Chapter 5. Air Cavity Ships Concept Evaluation Planing Types

Abstract

A planing hull is supported almost entirely by dynamic forces and so its elevation and trim angle relative to still waterline vary uniquely with forward speed. In this chapter we will look at the influence of various hull parameters on the drag and trim of a planing hull and planing air cavity craft (ACC).

Gennadiy Alexeevitch Pavlov, Liang Yun, Alan Bliault, Shu-Long He

Chapter 6. ACC Stability and Seakeeping

Abstract

On stability we have two main subjects to address in this chapter; that of displacement vessel stability as affected by the presence of a thin air layer at the keel; and the stability of air cavity planing craft. An air cavity planing craft requires consideration of both stability at rest in displacement mode and when travelling at design speed when the principal forces are kinematic.

Gennadiy Alexeevitch Pavlov, Liang Yun, Alan Bliault, Shu-Long He

Chapter 7. ALS and ACC Propulsion

Abstract

There is a particular challenge with a propulsion system for a vessel using air lubrication (ALS) or an air cavity system (ACC). A displacement ship employing air lubrication has a stream of bubbles moving through the propeller stream tube which will affect its performance. A propeller located behind an air cavity will also be subjected to a vortex stream of air, vapour, and water as it flows past the stern ramp or closure of the cavity.

Gennadiy Alexeevitch Pavlov, Liang Yun, Alan Bliault, Shu-Long He

Chapter 8. Postscript

Abstract

This book has been a challenging task to complete, having been presented with the core material that was translated from Russian and Chinese by Professor Yun. The intent has been to connect the core work and projects carried out over nearly half a century in Russia described by Gennadiy Pavlov and the research in China collated by Liang Yun, with the recent research work and projects in other parts of the world so that a rounded presentation is available to the reader across the spectrum of ALS to ACS and ACC.

Gennadiy Alexeevitch Pavlov, Liang Yun, Alan Bliault, Shu-Long He

Backmatter

Title: Air Lubricated and Air Cavity Ships
Authors: Gennadiy Alexeevitch Pavlov
Liang Yun
Alan Bliault
Shu-Long He
Copyright Year: 2020
Publisher: Springer New York
Electronic ISBN: 978-1-0716-0425-0
Print ISBN: 978-1-0716-0423-6
DOI: https://doi.org/10.1007/978-1-0716-0425-0

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