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THE SURFACE EFFECT CATAMARAN - PROGRESS IN CONCEPT ASSESSMENT

naval ENGINEERS JOURNAL 1983年第3期95卷 301-311页

作者： WILSON, FW VIARS, PR ADAMS, JD Fred W. Wilson:received his B.A. degree from the Virginia Polytechnic Institute and State University in 1967 and his M.A. degree from the University of Tennessee in 1971. Mr. Wilson has been involved with air-supported vehicle technology at the Aviation and Surface Effects Department of the David Taylor Naval Ship Research and Development Center since 1967. Until 1979 Mr. Wilson was with the Surface Effect Ship Division and participated in early SES development the SES-100A and -100B trials and in the 3000-ton SES program. Since 1979 Mr. Wilson has been in the Program Development Office participating in aircraft programs as well as the current twin-cushion surface effect ship (Surface Effect Catamaran) program. Philip R. Viars:graduated from the University of Cincinnati with a B.S. in Aerospace Engineering in 1974. He received his M.S. in Ocean and Marine Engineering from George Washington University in 1980. Since 1972 Mr. Viars has worked in the Aviation and Surface Effects Department at the David Taylor Naval Ship Research and Development Center (DTNSRDC). While at DTNSRDC Mr. Viars has participated in model and full-scale experimental programs focused on simulation. Mr. Viars is recognized as the Center expert in SES stability and performance having participated in most of the manned Navy SES testcraft evaluations. Since 1981 Mr. Viars has been in the Program Development Office where he has worked on the twin-cushion surface effect ship (SECAT) and other programs. John D. Adams:received his B.S.E. in 1972 from the University of Michigan School of Naval Architecture and Marine Engineering. He has spent seven years in Marine engineering research Marine systems design and development and dynamic tow tank testing and data analysis. Mr. Adams is currently responsible for the Maritime Dynamics Inc. field operation at the U.S. NavySES Test Facility (SESTF) Patuxent River Maryland. On-site responsibility has been the design development and manned testing of active ride control systems for the U.S. NavyXR-

The surface effect catamaran incorporates twin high length-to-beam cushions to support a low length-to-beam platform. The performance characteristics of the resulting vehicle, i.e., the resistance and head sea motions, are equivalent to a higher length-to-beam surface effect ship. The high lateral stability which results from the widely spaced hulls and cushions of the surface effect catamaran provides several advantages not inherent in conventional surface effect ship configurations. These advantages are manifested by high cross-structure height and reduced structural loads without reduction in static or dynamic roll stability. For an 800-ton ship the widely spaced cushions provide a capability of controlling off-head sea types of motions and the virtual elimination of green water over the deck up through Sea State 6. Model tests have validated cushionborne and hullborne resistance computer prediction programs. Head sea motions tests have justified the use of high cross-structure height to minimize high slam types of structural loads. Preliminary design and model tests indicate the potential for the surface effect catamaran to operate as an open ocean ship in smaller sizes than heretofore thought possible. In addition, its planform and large volume provides pay-load capabilities of much larger ships.

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PUTTING AN OIL-SPILL CLEANUP COMPUTER-MODEL TO WORK FOR THE NAVY

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naval ENGINEERS JOURNAL 1983年第3期95卷 165-172页

作者： NYHART, JD PSARAFTIS, HN YAROSCHAK, PJ Mr. J. D. Nyhart:is professor of management at the Sloan School of Management and the Department of Ocean Engineering at the Massachusetts Institute of Technology. His current research and writing focus on the use of scientific and technical material in formal judicial and administrative proceedings as well as the development of economic and regulatory models appropriate for deep ocean mining and oil-spill control. Harilaos N. Psaraftis:is Assistant Professor of Marine Systems at the Department of Ocean Engineering at the Operations Research Center at M.I.T. Professor Psaraftis received two M.Sc. degrees in 1977 (in Naval Architecture and Marine Engineering and in Shipping and Shipbuilding Management) and a Ph.D. in 1979 (in Ocean Systems Operations Research) all from M.I.T. Professor Psaraftis has been conducting research in problem areas such as the probabilistic modeling of underwater detection and optimal sensor allocation (project sponsored by ONR) the optimization of oil spill cleanup operations (project sponsored by a consortium of government and industry organizations) the development of routing and scheduling algorithms in transportation problems (project sponsored by DOT) and the analysis and solution algorithms of sealift routing and scheduling problems (project sponsored by ONR and the Military Sealift Command). Professor Psaraftis has published in various journals and is currently the Chairman of the Ocean Systems Management Program at M.I.T. Mr. Paul J. Yaroschak:received his Bachelors Degree in Civil Engineering from Villanova University and his Masters Degree in Environmental Engineering from Northeastern University. He has served in the Civil Engineer Corps U.S. Navy in Public Works and Construction Management and as a Project Engineer for Navy-wide Water and Wastewater Treatment Projects for the Naval Facilities Engineering Command. He is currently Head of the Environmental Engineering Branch of the Naval Facilities Engineering Command. Mr. Yaroschak is a Registered Professional Engineer i

A research group at the Massachusetts Institute of Technology has completed the first phase of the development of a computer assisted model for analyzing complex decisions and policies regarding oil spill cleanup. The model is the product of an ongoing MIT Sea Grant project, sponsored by a consortium of government and industry organizations, including the National oceanic and Atmospheric Administration, the U.S. C oast G uard , the U.S. N avy , the Commonwealth of Massachusetts, the Spill Control Association of America, JFB Scientific Corporation, the Doherty Foundation, Petro-Canada and Texaco. The model can be used, among other things, in strategic planning for the long-term oil spill response needs of a region, in assisting On Scene Coordinators in responding to a specific spill (tactical/operational setting), in evaluating the environmental and economic damages of a spill versus the cost of cleanup, in simulation and training, and in the analysis of various policy and regulatory issues such as the effects of delays, the use of dispersants and the investigation of liability and compensation issues. The paper describes the model in detail, focuses on its potential uses and presents experience with its application in conjunction with pollution control efforts of the U.S. Navy. Specifically, we outline the application of the model in the Port of Charleston, South Carolina, an ongoing project sponsored by the naval Facilities engineering Command. The difficulty of gathering data for such an application is discussed.

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THE STRUCTURAL SYNTHESIS DESIGN program - ITS IMPACT ON THE FLEET

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naval ENGINEERS JOURNAL 1983年第3期95卷 87-99页

作者： WIERNICKI, CJ GOODING, TG NAPPI, NS Mr. Christopher J. Wiernicki:graduated from Vanderbilt University in 1980 with a B.E. degree in Structural Engineering. Upon graduation he began his professional career at the David Taylor Naval Ship Research and Development Center. As a structural engineer in the Surface Ship Structures Division Mr. Wiernicki was responsible for developing improved methods and procedures for designing and evaluating structural systems for surf ace combatants. Specific projects included design for producibility development and evaluation of automated ship structural design methods and participation in the structural design of the CG 49 Cruiser and the current DDG 51 Destroyer. In 1982 Mr. Wiernicki received his M.S. degree in Ocean Engineering from George Washington University. Mr. Wiernicki is a recipient of the SNAME 1982-82 Graduate Scholarship and is currently doing post graduate work in Naval Architecture at Massachusetts Institute of Technology he is a member of ASNE SNAME ASCE and Chi Epsilon. Mr. Thomas G. Gooding:graduated in 1975 from the University of Michigan with B.S. degrees in Oceanography and Naval Architecture. After graduation he began his professional career at the Naval Ship Engineering Center (NA VSEC) as a structural engineer. From 1975 till 1978 Mr. Gooding worked in the area of ship dry docking and was the structural task leader on the complex overhaul ofUSS Long Beach (CGN-9). Mr. Gooding returned to the University of Michigan to receive a M.S. in Naval Architecture in 1979. Currently Mr. Gooding is the structural task leader on the DDGX/DDG 51 program at the Naval Sea Systems Command (NAVSEA). Mr. Gooding is a member of SNAME and the Naval Institute. Mr. Natale S. Nappi:graduated from City College of New York in 1954 with a Bachelor of Civil Engineering and received his M.S. in Civil Engineering from Polytechnic Institute of Brooklyn in 1959. He began his professional career in 1964 at the New York Naval Shipyard as a Naval Architect (Structure) performing detail structural design and fabrication s

The structural design of a ship's section is a complicated, repetitive and time consuming task. With the advent of new technology, high speed computers have enabled the ship designer to accomplish in a matter of seconds what would formerly take days to accomplish by hand. The Structural Synthesis Design program (SSDP) is a N avy developed computer-aided design tool which is used to design (or to analyze) the longitudinal scantlings for a variety of ship cross sections, consisting of any practical combinations of decks, platforms, bulkheads and materials, i.e., various steel and aluminum alloys. The final hull section design will have the lowest practical weight for the chosen geometric configuration, structural arrangements, and imposed loadings. The scantling developed by the program will satisfy all U.S. N avy ship structural design criteria. An explanation of the objective and design elements of N avy ship structures is included. The rationale behind the SSDP design philosophy is developed along with the significant program capabilities. In an attempt to highlight the influence of automated design procedures on the current naval ship design process, the effect of the SSDP on the DDG 51 destroyer structural development is addressed.

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U.S. AND FOREIGN HULL FORM, MACHINERY AND STRUCTURAL DESIGN PRACTICES

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naval Engineers Journal 1983年第6期95卷 36-53页

作者： KEHOE, JAMES W. BROWER, KENNETH S. MEIER, HERBERT A. RUNNERSTROM, CDR. ERIC James W. Kehoe Jr. is well known for his work in conducting comparative naval architecture studies of U.S. and foreign warship design practices for which he received the ASNE Gold Medal for 1981 and the Legion of Merit. He is currently a partner in Spectrum Associates Incorporated Arlington Virginia where he is engaged in the feasibility and concept design of naval ships and in continuing his comparative engineering analyses of U.S. and foreign warships. Prior to his retirement from the U.S. Navy as a Captain in 1982 his naval career involved sea duty aboard three destroyers and three aircraft carriers including command of the USS John R. Pierce (DD-753) and engineer officer of the USS Wasp (CVS-18). Ashore he had duty at the Naval Sea Systems Command where he directed the Comparative Naval Architecture Program as an instructor in project management in the Polaris missile project and as a nuclear weapons officer. He holds a B.S. in mathematics from Stonehill College Massachusetts (1952) and an MA in education from San Diego State College (1959). A frequent contributor to the Naval Engineers Journal U.S. Naval Institute Proceedings and the International Defense Review he has published a number of articles on U.S. Soviet and other foreign warship design practices and the effects of design practices on ship size and cost. Kenneth S. Brower is a partner in Spectrum Associates Incorporated Arlington Virginia which he founded in June 1978. He graduated from the University of Michigan in 1965 with a Bachelor's Degree in Naval Architecture. Mr. Brower has contributed to the design and construction of numerous merchant ships and warships the latter of which include the CG-47 project Arapaho the FDL and DX projects the new NATO Frigates Replacement for the ‘90's DDGX and FFX projects as well as several frigate developed for Foreign Military Sales. Since 1972 he has actively supported the Naval Sea Systems Command's Comparative Naval Architecture Program. During this period Mr. Brower has contribute

There are two principal benefits to conducting comparative engineering analyses of U.S. and foreign ship design practices and criteria: 1) they offer an opportunity to identify clever ideas from which the U.S. can benefit, and 2) they cause us to assess U.S. design practices critically that we may have been taking for granted or may have been accepting as inviolable. The results of a comparative analysis of U.S. and foreign hull form, machinery, and structural design practices are reported in this paper. Numerous studies of U.S. and foreign warships have shown that the hull form, machinery, and structural design practices of various navies differ considerably. Although most large navies operate their ships in generally similar environments, each country has developed its own unique style of hull form. Based on an assessment of foreign hull form design practices, the U.S. Navy has recently developed a style of hull form that offers improved stability and seakeeping performance and which facilitates the arrangement of internal functions. Foreign ships generally have a tighter machinery arrangement than comparable U.S. ships. However, this is not necessarily achieved by accepting less subsystem performance or by sacrificing redundancy. The tightness of foreign machinery plants seems to be achieved by tighter management control over the ship design and acquisition process. In addition, foreign navies appear to be more flexible in adjusting to a new technology such as that which occurred during the change from steam to gas turbine propulsion. U.S. ships appear to be constructed to more rigorous structural detail design standards than foreign ships. The structural configuration of foreign ships, including the integration of web frames, longitudinal girders, and stanchions also differs from U.S. practice. The configuration of ship structure and the value of rigorous U.S. structural design practices are worthy of additional research. The results of the study reported in thi

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THE INTRODUCTION OF HEAT RECOVERABLE COUPLINGS TO SHIP REPAIR AND MAINTENANCE

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naval ENGINEERS JOURNAL 1982年第6期94卷 63-71页

作者： LIBERATORE, DJ BASKERVILLE, JE LCdr. Donald J. Liberatore USN: began his career in the U.S. Navy in 1965. He has had many diverse assignments involving surface ships and submarines during the past seventeen years. During his tour at Naval Shipyard Portsmouth (N.H.) he was Assistant Design Superintendent and responsible for the introduction of Heat Recoverable Coupling technology into the shipyard. Presently he is assigned to the Naval Sea Systems Command (NAVSEA) in the Sonar Dome Office. Prior assignments within NAVSEA have been as Assistant Ship Systems Design Manager for the SSNX and FA-SSN preliminary designs in the Submarine Propulsion Analysis Branch in the Submarine Hydrodynamics Branch and in the Gear Coupling and Clutch Branch. He received his Bachelor of Engineering degree from Vanderbilt University in 1971 and in 1977 graduated from Massachusetts Institute of Technology with his M.S. degree in Naval Architecture and Marine Engineering and his Professional degree of Ocean Engineer. A member of ASNE since 1975 LCdr. Liberatore also is a member of IEEE SNAME the Naval Institute and Sigma Xi. Cdr. James E. Baskerville USN: is presently assigned to NAVSEA as the Ship Manager for the DDG 51 the Navy's next generation surface combatant. In a previous tour at Naval Shipyard Pearl Harbor he was the Navy's Program Manager for Heat Recoverable Coupling introduction in ship repair and maintenance. A graduate of the U.S. Naval Academy Class of 1969 he is a qualified Surface Warfare Officer and a designated Engineering Duty Officer (ED). He received his M.S. degree in Mechanical Engineering and his Professional degree of Ocean Engineer from Massachusetts Institute of Technology and also holds a patent right on an Electronic Control and Response System. His naval assignments have included tours in the USS Ramey (FFG-2) as Aide and Flag Lieutenant to the Commander Naval Electronic Systems Command and as Ship Superintendent Surface Type Desk Officer and Assistant Design Superintendent at Naval Shipyard Pearl Harbor. Cdr. Baskervi

Although Heat Recoverable Couplings (HRCs), used to join pipe, may be labeled innovative “state-of-the-art” technology for U.S. naval Shipyards, they have been in use in foreign ships and high technology industries for over a decade. HRCs provide a permanent leak-proof pipe joint in specified applications without the use of high temperature and the inherent hazards of an open flame. Manufactured from NITINOL, a nickel-titanium alloy developed by the U.S. Navy, the couplings exhibit a “shape memory” characteristic. That is, they return (shrink) to a specified shape (pipe diameter) thus forming a mechanical seal when the expanded coupling is removed from a cryogenic environment and warmed above approximately —130°C. This paper provides background information into the development of NITINOL, technical explanation of shape memory metallurgy, and a summary of results, with specific examples, describing the trial use of HRCs at Pearl Harbor and Norfolk naval Shipyards. Limited return cost data and recommendations for future use are presented. Then, using the HRC program as a basis, the Authors discuss the conservative nature of the ship repair and maintenance environment. This environment, in the Authors' opinion, couples with complex contractual constraints and requirements which serve to restrict the introduction of new ideas. An analogy is made to Russian tenacity of recent years which promotes “exploring and doing” while we in the U.S. Navy are frequently content to study.

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SEAKEEPING PERFORMANCE COMPARISON OF AIR CAPABLE SHIPS

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naval ENGINEERS JOURNAL 1982年第2期94卷 101-117页

作者： COMSTOCK, EN BALES, SL GENTILE, DM Mr. Edward N. Comstock:is currently Head of the Hull Form Design and Performance Branch (SEA 3213) of the Naval Sea Systems Command. He received his B.S.E. degree in Naval Architecture and Marine Engineering in 1970 and his M.S.E. degree in Ship Hydrodynamics in 1974 both from the University of Michigan. Mr. Comstock began his career with theU.S. Navyin 1974 as a Seakeeping Specialist in the Hull Form and Fluid Dynamics Branch of the former Naval Ship Engineering Center. Achieving his present position in January 1982 Mr. Comstock was previously Head of the Surface Ship Hydrodynamics Section of SEA 3213 being responsible for recent hull form designs including DDG-51 MCM-1 and ARS-50. Before obtaining that position in 1979 Mr. Comstock's efforts were primarily aimed at developing and establishing seakeeping performance assessment and design practices. Prior to his employment by the Navy Mr. Comstock worked in the Structural and Hydrodynamics Group of General Dynamics' Electric Boat Division. A member of ASNE he is also a member of ASE and SNAME and has been active in supporting the efforts of the SNAME H-7 (Seakeeping) Panel SNAME HS-12 (Hull Instrumentation) Panel the National Science Foundation (NSF) and the NATO Armaments Group IEG6/Sub-Group 5 (Seakeeping). Ms. Susan L. Bales:has been associated with the David W. Taylor Naval Ship R&D Center (DTNSRDC) and its predecessor organizations throughout her professional career. She is currently Head of the Ocean Environment Group of the DTNSRDC Surface Ship Dynamics Branch (1561) and also serves as the DTNSRDC Program Manager of the Navy's Exploratory Development Program on Surface Waves. Her work documented by more than fifty technical publications has been directed primarily to ship seakeeping ocean environment and ship performance assessment problems. An internationally recognized authority in her field she is also active in several professional societies as well as the SNAME H-7 (Seakeeping) Panel the National Science Foundation (NSF) and the NA

The on-going debate regarding the merits of large versus small aircraft carriers raises several issues concerning the ability of various ship configurations to support sea based air operations. One such issue is the question of the relative seakeeping performance of ship alternatives. In an effort to shed some light on the matter, a comparative seakeeping assessment of nine air capable ships covering a wide range of size and hull form was performed. An evaluation of the impact of aircraft and ship motion limitations on sea based air operations and a comparison of the relative ability of the ships to conduct air operations while in a seaway are presented. The specific air operations considered are launch, recovery, and support of aircraft. The ships evaluated are CVN-71, CVA-67 (MR), CVV, LHA-1, VSS-D, DDV-2, DDV-1D, DD-963, and SWATH-6. These ships have the combined capability to operate Vertical Takeoff and Landing (VTOL), Conventional Takeoff and Landing (CTOL), Short Takeoff and Arrested Landing (STOAL), and Short Takeoff and Vertical Landing (STOVL) type aircraft. Results indicate that seakeeping performance generally degrades with decreasing displacement, that SWATH-6 performance is the least degraded, that elevator wetness can be an important degrader for ships with lower freeboards, that roll motion can be an important degrader for ships under 60,000 tons, and that percent time of operation is strongly dependent on the prevailing wave and wind environment.

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A SUBMARINE CONTROL-SYSTEM TEST VEHICLE

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naval ENGINEERS JOURNAL 1980年第2期92卷 148-155页

作者： SEJD, JJ WATKINSON, KW HILL, WF Mr. James J. Sejd received his B.S. degree in Civil Engineering from Case Western Reserve University and has since undergone considerable graduate study at both The George Washington and American Universities. He served almost four years in the U.S. Navy as a Naval Aviator and enjoys the unique distinction of being qualified in both Heavier- and Lighter-than-Air aircraft. Early in his career he was employed at the Navy's Bureau of Ships in the capacity of a Structural Designer and Structural Research Monitor. In 1966 he joined the Staff of the Center for Naval Analyses where he was involved in the mathematical modeling of ships and aircraft and in economic “trade-off‘ analysis. In 1970. he went to the Naval Ship Engineering Center as an Operations Research Analyst in the Ship Design and Development Division. At the present time he is employed as a Program Manager for the Naval Sea Systems Command Ship Design Research and Development Office. A member of ASNE since 1973 he also is a member of the Association of Scientists and Engineers at NAVSEA the Operations Research Society of America and the Lighter-Than-Air Society. Mr. Kenneth W. Watkinson received both is B.S. and M.S. degrees in Engineering Science from Florida State University in 1970 and 1971 respectively. Since graduation he has been employed at the Naval Coastal Systems Center (NCSC). Panama City. Fla. where he is primarily involved in the investigation of the stability and control of underwater vehicles. For the past four years he has been the Task Leader and Principal Investigator for the NCSC portion of the Advanced Submarine Control Program involved in developing control design methods and the instrumentation system for the Submarine Control System Test Vehicle. Mr. William F. Hill is currently the ASCOP Program Manager at Lockheed Missiles & Space Company (LMSC) Inc. where he has the overall responsibility for design and construction of the Control System Test Vehicle (CSTV). He entered the aircraft industry in England as an Apprentice w

As part of the Advanced Submarine Control program (ASCOP), the naval Sea Systems Command has developed an open water Submarine Control System Test Vehicle (CSTV). This vehicle is a 1/12 scale model of an SSN 688 Class Submarine, with provisions for easy geometric changes. Such changes include alternate Sail size and location, the addition of parallel middle-bodies, alternative tail sections, and alternative control configurations. A self-contained instrumentation and control system provides the capability for “on-board” recording of all relevant Submarine-state variables, over the entire speed and depth range, to a degree of data accuracy exceeding any known system. With the means thus available to correlate measured vehicle hydrodynamics with selected maneuvers, conditions, and changes in hull geometry and control surface configuration, modern mathematical techniques for improving submarine equations of motion can be employed to permit dramatic design enhancements in both safety and performance. This paper provides the rationale and history of the development of this vehicle, a description of the instrumentation and control package, and a description of the vehicle itself.

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NAVY REPAIR SHIP DESIGN - FEASIBILITY DISCUSSION OF NEW REPAIR CONCEPTS AND TECHNOLOGY

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naval ENGINEERS JOURNAL 1978年第4期90卷 51-63页

作者： WILKINS, JR The Authorwas employed by Wheeler Industries Inc. during the summer of 1976. During this time he was involved with feasibility studies for a new Navy Repair Ship to be designated the ARX. In the Spring of 1977 he graduated from the University of Michigan College of Engineering Department of Naval Architecture and Marine Engineering. While at the University he was a Midshipman in the NROTC. He plans to continue his education at the University of Michigan and to receive his Masters degree in Ocean Engineering with immediate commissioning as an officer in the U.S. Navy upon the completion of his graduate program. A recent letter indicates he has completed his studies and is presently residing in Chula Vista Calif.

Feasibility studies hate been conducted for a new surface Repair Ship for the U.S. Navy. Improvements in material handling, management information systems, maintenance facilities, production techniques, platform design, and repair methods, as discussed, will increase the operational efficiency of this new generation of Repair Ships over existing ships. The improvements discussed are suggested by industry, research, engineers, and by men currently on board Fleet Tenders and Repair Ships.

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STRUCTURAL ANALYSIS AND DESIGN OF A CATAMARAN CROSS‐STRUCTURE BY THE FINITE ELEMENT METHOD

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naval Engineers Journal 1973年第1期85卷 33-42页

作者： MANSOUR, DR.A. FENTON, LCDR. PAUL H. Dr. A. Mansour an Associate Professor in the Department of Ocean Engineering at Massachusetts Institute of Technology received his Bachelor of Science degree in Mechanical Engineering from the University of Cairo in 1958 and his M.E. and Ph.D. degrees in Naval Architecture and Marine Engineering from the University of California at Berkeley in 1962 and 1966 respectively. He has had field experience and design responsibilities for about six years in the Suez Canal Authority John J. McMullen Associates Inc. and M. Rosenblatt and Son Inc. and has been with the Massachusetts Institute of Technology for the past four years. During this period he contributed several technical papers and reports in the areas of structural mechanics sea loads finite element analysis of marine structures and probabilistic structural mechanics. He has been a consultant for several companies and organizations is a member of Sigma Xi and SNAME currently serving as a member of the latter's Stress Analysis and Strength of Structural Elements Panel. USN Lieutenant Commander Paul H. Fenton USN a 1964 graduate of the U.S. Naval Academy recently completed a graduate education program at M.I.T. in the field of Naval Construction and Engineering earning two degrees: Ocean Engineer and Master of Science in Naval Architecture and Marine Engineering. He is presently assigned to the Charleston Naval Shipyard Charleston South Carolina and has had previous duty in the U.S.S. STICKELL (DD 888) and with the Naval Support Activity Saigon.

One of the problems encountered during the design of the ASR‐21 Catamaran is the determination of the effectiveness of the cross‐structure deck plating. In this paper, this problem is examined using the Finite Element Method. The behavior of a multicell box girder representing a catamaran cross‐structure is studied. Because of the relatively low length‐to‐breadth ratio of a typical catamaran cross‐structure, the deck plating effectiveness is found to be rather small. Parametric studies are performed, and curves of the effectiveness as a function of the relevant geometric and loading parameters are presented. These curves may be helpful in the early stages of new designs. © 1973 by the American Society of naval Engineers

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THE DEVELOPMENT OF MANNED, DEEP‐DIVING SUBMERSIBLES

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naval Engineers Journal 1969年第5期81卷 35-42页

作者： RAMSAY, RAYMOND THE AUTHOR: completed a British apprenticeship with Furness Shipbuilding Company and studied for the Higher National Certificate (Naval Architecture) in 1952. He emigrated to Canada in 1956 after serving with the Royal Army Educational Corps in England and Singapore. Before appointment as a Senior Naval Architect in the Ship Concept Design Division of the U.S. Naval Ship Engineering Center he performed naval architectural duties for the Davie Shipbuilding Company (Quebec Canada) also the Great Lakes Engineering Works and General Dynamics /Electric Boat Division in the United States. During the period January to November 1968 he participated in the NAVSEC element of the Deep Ocean Technology Program associated with the development of submersible vehicles and was a member of the DSSV technical evaluation team. Recently he transferred to NAVSHIPS Code 425 with promotion to Program Manager PERA(SS)—Planning and Engineering for Repairs and Alterations (Submarines). Mr. Ramsay is an Associate Member of the North East Coast Institution of Engineers and Shipbuilders (England) a Full Member of The Society of Naval Architects and Marine Engineers Civil Member of The American Society of Naval Engineers and Full Member of The Association of Senior Engineers.

The need for maintaining technological leadership in the deep submergence field is given recognition, with particular reference to manned submersibles. A design sequence is outlined to illustrate how operating crew requirements must be satisfied very early in the design process to insure maximum overallmission effectiveness. The necessity for more technologists and “totally immersed” projects to manage future vehicle technology efforts is also addressed. © 1969 by the American Society of naval Engineers, Inc.

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