Twenty-Third Symposium on Naval Hydrodynamics

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About this PDF file: This new digital representation of the original work has been recomposed from XML files created from the original paper book, not from the original typesetting files. Page breaks are true to the original; line lengths, word breaks, heading styles, and other typesetting-specific formatting, however, cannot be retained, and some typographic errors may have been accidentally inserted. Please use the print version of this publication as FOREWORD vii FOREWORD The Twenty-Third Symposium on Naval Hydrodynamics was held in Val de Reuil, France, from September 17–22, 2000. It coincided with the inauguration of the new model basin at the Bassin d'Essais des Carènes. This international symposium was organized jointly by the Office of Naval Research, the National Research Council (Naval Studies Board), and the Bassin d'Essais des Carènes. This biennial symposium promotes the technical exchange of naval research developments of common interest to all the countries of the world. The forum encourages both formal and informal discussion of presented papers, and the occasion provides an opportunity for direct communication between international peers. More than 140 participants, including students, from 25 countries attended the symposium. Sixty-three papers were presented in the ten topical areas covered by the symposium. Those topical areas are wave-induced motions and loads, hydrodynamics in ship design, propulsor hydrodynamics and hydroacoustics, CFD validation, viscous ship hydrodynamics, cavitation and bubbly flow, wave hydrodynamics, wake dynamics, shallow water hydrodynamics, and fluid dynamics in the naval context. These topical areas were chosen because they encompass recent scientific advances. For example, first-ever experimental results crucial for validating software for modeling unsteady turbulent flow were presented for a combatant in head waves. Another paper described the successful use of sophisticated large eddy simulation computations to predict the pressure recovery in a submarine launch way. A third discussed the use of experimentally validated large eddy simulations to understand the physics underlying nonstationary quantities for the hydrodynamic flow over a lifting surface. This brief list illustrates the quality and timeliness of the information presented in the symposium. Opening comments were delivered on the first morning by Ronald D.Taylor (Naval Studies Board), Admiral François Lefaudeux (Bassin d'Essais des Carènes), and RADM Jay M.Cohen, USN (Chief of Naval Research). The symposium featured invited lectures each morning. These lectures were presented by Robert Beck, Didier Frechou, Fred Stern, and Marshall Tulin and covered seakeeping computations, propulsor hydroacoustics, software verification and validation, and wave breaking. At mid-week, the Twenty-First Georg Weinblum Lecture was delivered by B.Molin, who spoke on the topic “Numerical and Physical Wavetanks: Making Them Fit” (not included in this proceedings). These lectures by prominent international experts set the pace for the technical sessions that followed throughout each day. The success of this symposium is the result of diligence on the part of many people. There was, of course, the Organizing and Paper Selection Committee consisting of myself and Dr. Patrick Purtell (Office of Naval Research), Mr. James Fein (Naval Sea Systems Command), Dr. Ronald Taylor (National Research Council), Dr. Stephane Cordier (Bassin d'Essais des Carènes), Dr. William Morgan (David Taylor Model Basin), Dr. Choung Lee (Pohang University of Science and Technology), and Prof. Robert Beck (Journal of Ship Research). The work of this committee was certainly the cornerstone for the success of the symposium. The administrative preparation and execution, and the production of this archival volume, were completed with the support of Susan Campbell and Mary Gordon of the Naval Studies Board, National Research Council. Special appreciation is extended to Jennifer McDonald and Diane McNeil, from my office, for handling the abstract collection and the preparation of the discussion sections. The staff of Bassin d'Essais des Carènes is to be congratulated for hosting this exemplary meeting. Their care for the well-being of the participants is greatly appreciated. Further appreciation is extended to Pulsar Developpment, which provided essential onsite administrative and organizational support. For this program officer, the symposium marked the end of a thirty-seven-year career in naval hydrodynamics. I am very proud of the reputation of this symposium series and of the associated proceedings, which are recognized internationally as the equivalent of a peer-reviewed journal and which for more than a half century have served as the document repository for leading-edge research in naval. hydrodynamics. I wish the best for the research community as it embraces the challenges of the 21st century. Edwin P.Rood Office of Naval Research the authoritative version for attribution.

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About this PDF file: This new digital representation of the original work has been recomposed from XML files created from the original paper book, not from the original typesetting files. Page breaks are true to the original; line lengths, word breaks, heading styles, and other typesetting-specific formatting, however, cannot be retained, and some typographic errors may have been accidentally inserted. Please use the print version of this publication as OPENING REMARKS—RADM JAY M.COHEN, USN CHIEF OF NAVAL RESEARCH viii OPENING REMARKS—RADM JAY M.COHEN, USN CHIEF OF NAVAL RESEARCH Admiral Lafaudeaux, first allow me to express what a personal honor it is for me to address this distinguished gathering. I am pleased that the Office of Naval Research, which I lead, has cosponsored this important symposium along with the National Research Council and the Bassin d'Essais des Carènes. The brochure for this twenty-third symposium invites us to “a week of exchange, debates, and sharing of experiences in the field of Naval hydrodynamics”—a worthy and necessary goal indeed! My personal experience started thirty-six years ago, when as a boy of seventeen I left home and entered the United States Naval Academy at Annapolis. I joined the Navy to see the world (places and people), to drive submarines at sea, and to design future ships when ashore. I did not realize at the time how fulfilling and challenging my choices would be. At Annapolis I studied naval architecture. I was enamored with the idea of placing a blank sheet of paper on a drafting table, using flexible plastic batons and lead-weighted ducks to hold the baton down in place while I used a pencil to draw a new hull form on the paper. What personal freedom of design and power: it was science, engineering, and art all in one. Computers of the day available to me couldn't compete with my mind, eye, and hand. The Naval Academy tow tank was small, simple, and reliable, and free to use if I helped the technical assistant with his chores. Models were pulled at consistent force by a cable and a weight that fell down a shaft equal to the length of the tank. Gravity was constant. The weights and models varied. None of my line drawings became actual ships and I didn't make any hydrodynamic breakthroughs as a result of my tow tank work, but I learned about ships, propulsion, seakeeping, and experimentation—and it was fun! Science should be fun. As a midshipman I spent two summers at sea. Once as a junior midshipman performing all the menial chores of a deck hand, cook, and engineer on the Coast Guard sail-training barque Eagle, I sailed from Connecticut, through the Panama Canal, and ended up after two weeks in Seattle. What an experience to run before a storm with all twenty-two sails straining and the lee sail awash as the Eagle moved smoothly through the water at her maximum hull speed. My second cruise was on a World War II vintage diesel electric submarine out of San Diego. The captain of that ship was experienced, confident, and a great officer and mariner. He allowed the five young midshipmen on board to drive his boat, learn by making or nearly making mistakes, and then learn some more. That submarine was my first experience with electric ship propulsion, but a far cry from the all-electric ships the United States Navy is designing today. Some of you know that submarine's commanding officer, then a lieutenant commander—he is Rear Admiral Brad Mooney, a retired former Chief of Naval Research. I would not be here if it were not for his inspiration. For those wondering when the “expressive” portion of this talk will end and begin to focus more on the specifics and challenges of hydrodynamics, just one more sea story. After two years at sea on a diesel submarine as an ensign in the Navy, I attended MIT and Woods Hole Oceanographic Institution. I studied naval architecture, marine engineering, and ocean engineering. It was 1970, and computers were just beginning to be used for seakeeping and computational fluid dynamics. Most of my textbooks were mimeographed copies of professors' class notes—professors, I might add, who came from all around the world, like the participants in this symposium. MIT has a sophisticated medium-sized tow tank that I used for my thesis work, the recovery of submersibles through the air-sea interface in a seaway. While computers were being used even then, tank testing remained essential for accurate validation of full-scale ship characteristics before ship production. One of the dangers of inviting an old naval officer to speak is that he has many more sea stories than a junior officer. I won't bore you any longer. It is most appropriate that this symposium is being held in France. Both the United States and the French Republic were born of revolution. Today we are experiencing a revolution in ship design, construction, and operation. And your efforts have made it possible, with enormous gains still ahead. Computers of incredible sophistication, power, and speed, available at affordable prices, have made into a worldwide reality what were previously only imagined hull forms, propulsors, materials, navigational accuracy, maintenance and performance monitoring and prediction, and sophisticated damage control in minimally manned, highly automated ships. I may be nostalgic for hand-drawn ship plans and sailing ships, but the reality and future possi-bilities are far more exciting and challenging. the authoritative version for attribution. We must rise to that challenge! There is still much to learn. People still program the computers, and despite our best efforts to model complex hydrodynamic effects such as turbulence, boundary-layer

Table of Contents

Front Matter R1-R19

Modern Seakeeping Computations for Ships 1-45

Forces, Moment and Wave Pattern for Naval Combatant in Regular Head Waves 46-65

New Green-Function Method to Predict Wave-Induced Ship Motions and Loads 66-81

Validation of Time-Domain Prediction of Motion, Sea Load, and Hull Pressure of a Frigate in Regular Waves 82-97

Ship motions and loads in large waves 98-111

Prediction of Vertical-Plane Wave Loading and Ship Responses in High Seas 112-125

Basic Studies of Water on Deck 126-142

Second Order Waves Generated by Ship Motions 143-156

Prediction of Nonlinear Motions of High-speed Vessels in Oblique Waves 157-170

Optimizing Turbulence Generation for Controlling Pressure Recovery in Submarine Launchways 171-180

HULL DESIGN by CAD/CFD SIMULATION 181-190

Steady-State Hydrodynamics of High-Speed Vessels with a Transom Stern 191-205

Practical CFD Applications to Design of a Wave Cancellation Multihull Ship 206-222

Simulation of Ship Maneuvers Using Recursive Neural Networks 223-242

Flow- and Wave-Field Optimization of Surface Combatants Using CFD-Based Optimization Methods 243-261

MARINE PROPULSOR NOISE INVESTIGATIONS IN THE HYDROACOUSTIC WATER TUNNEL "G.T.H." 262-283

Propulsor Design Using Clebsch Formulation 284-300

Unsteady Flow Quantities on Two-Dimensional Foils: Experimental and Numerical Results 301-313

Hydrofoil Turbulent Boundary Layer Separation at High Reynolds Numbers 314-329

Pressure Fluctuation on Finite Flat Plate above Wing in Sinusoidal Gust 330-341

Control of the Turbulent Wake of an Appended Streamlined Body 342-354

Investigation of Global and Local Flow Details by a Fully Three-dimensional Seakeeping Method 355-367

Prediction of Wave Pressure and Loads on Actual Ships by the Enhanced Unifed Theory 368-384

Frequency Domain Numerical and Experimental Investigation of Forward Speed Radiation by Ships 385-401

INTERNATIONAL COLLABORATION ON BENCHMARK CFD VALIDATION DATA FOR SURFACE COMBATANT DTMB MODEL 5415 402-422

Validation of High Reynolds Number, Unsteady Multi-Phase CFD Modeling for Naval Applications 423-440

Free Surface Viscous Flow Computation Around A Transom Stern Ship By Chimera Overlapping Scheme 441-456

ANTI-ROLL TANK SIMULATIONS WITH A VOLUME OF FLUID (VOF) BASED NAVIER-STOKES SOLVER 457-473

Validation of Tab Assisted Control Surface Computation 474-484

Experimental And Numerical Investigation Of The Flow Around The Appendices Of A Whitbread 60 Sailing Yacht 485-492

Propeller Wake Analysis by Means of PIV 493-510

Experimental and Numerical Investigation of the Unsteady Flow around a Propeller 511-526

Simulation of Incompressible Viscous Flow Around a Ducted Propeller Using a RANS Equation Solver 527-539

On Submerged Stagnation Points and Bow Vortices Generation 540-552

Numerical Prediction of Scale Effects in Ship Stern Flows with Eddy-Viscosity Turbulence Models 553-568

The Experimental and Numerical Study of Flow Structure and Water Noise Caused by Roughness of the Body 569-578

Large-Eddy Simulations of Turbulent Wake Flows 579-598

Instability of Partial Cavitation: A Numerical/Experimental Approach 599-615

An Unsteady Three-Dimensional Euler Solver Coupled with a Cavitating Propeller Analysis Method 616-638

On the Flow Structure, Tip Leakage Cavitation Inception and Associated Noise 639-653

An Experimental Investigation of Cavitation Inception and Development of Partial Sheet Cavities on Two - Dimensional 654-669

Modeling 3D unsteady sheet cavities using a coupled UnRANS-BEM code 670-686

Ship Wake Detectability in the Ocean Turbulent Environment 687-703

An Experimental and Computational Study of the Effects of Propulsion on the Free-Surface Flow Astern of Model 5415 704-712

Breaking Waves in the Ocean and around Ships 713-745

Numerical and Experimental Study of the Wave Breaking Generated by a Submerged Hydrofoil 746-761

The Numerical Simulation of Ship Waves Using Cartesian Grid Methods 762-779

Radiation Loads on a Cylinder Oscillating in Pycnocline 780-791

Wave Resistance Computations - A Comparison of Different Approaches 792-804

Computation of Nonlinear Turbulent Free Surface Flows Using the Parallel Uncle Code 805-819

Submarine manoeuvrability assessment using Computational Fluid Dynamic tools 820-832

Simulation of UUV Recovery Hydrodynamics 833-847

Reynolds-Averaged Modeling of High-Froude-Number Free-Surface Jets 848-862

On Roll Hydrodynamics of Cylinders Fitted with Bilge Keels 863-881

Combining Accuracy and Effciency with Robustness in Ship Stern Flow Computation 882-896

An Unstructured Multielement Solution Algorithm for Complex Geometry Hydrodynamic Simulations 897-909

Ship Stern Flow Calculations on Overlapping Composite Grids 910-926

Study on the Prediction of Flow Characteristics Around a Ship Hull 927-940

Analysis of Turbulence Free-Surface Flow around Hulls in Shallow Water Channel by a Level-set Method 941-956

A Design Tool for High Speed Ferries Washes 957-967

Flow Around Ships Sailing in Shallow Water - Experimental and Numerical Results 968-982

Ship Stability Study in the Coastal Region: New Coastal Wave Model Coupled with a Dynamic Stability Model 983-992

Waves and Forces Caused by Oscillation of a Floating Body Determined through a Unified Nonlinear Shallow-Water Theory 993-1005