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THE system engineering ANALYSIS - A STRUCTURED APPROACH FOR IMPROVING SHIP MAINTENANCE

NAVAL ENGINEERS JOURNAL 1982年第2期94卷 118-126页

作者： BEYERS, CP The authoris a member of the technical staff in the Ships Systems Program of ARINC Research Corporation's Ships and Ordnance Division. He is currently applying the System Engineering Analysis (SEA) methodology to systems installed on auxiliary class ships. He is the coauthor ofAmphibious Ship Engineering Operating Cycle (PEOC) Program Engineering Analysis Requirements which documents the SEA methodology. He has been instrumental in the development and improvement of the procedures and analytical techniques for the SEA methodology and the application of those procedures and techniques in the analyses of various ship systems and equipments. He has applied the SEA methodology to propulsion plant systems and equipments auxiliary systems and equipments and some electronic systems and equipments for the FF 1052 DDG 37 CG 16 CG 26 DD 963 AOE 1 AFS 1 and AOR 1 Classes. Prior to joining ARINC Research Mr. Beyers was responsible for test program development and data analysis for wind tunnel temperature testing of cars at Chrysler Corporation. He also solved mechanical and production problems with shock absorbers affecting car ride shock absorber life and parts costs. Mr. Beyers received his BS in Engineering from Oakland University (Rochester Michigan) in 1972.

This paper describes the system engineering Analysis (SEA), a methodology developed to objectively define and improve ship maintenance using Navy historical maintenance data. The methodology is based on the analysis of recurring failures and maintenance actions as exhibited in the maintenance data and the use of reliability-centered maintenance concepts for defining maintenance requirements. Failure modes and effects analyses (FMEAs) are limited to historically recurring failures; FMEAs are not conducted for all possible failure modes because of the likelihood of limited payback coupled with increased analysis cost. Results of a SEA provide (1) information for the Class Maintenance Plan, which defines the intermediate and depot-level maintenance requirements for a ship class, and (2) supporting information for the design review process and for improvements in the integrated logistics support of the selected system or equipment. The SEA also recommends design studies, design improvements, and maintenance strategy and support improvements.

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SYNTHETIC FUEL CONSIDERATIONS FOR NAVAL SHIPBOARD USE

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NAVAL ENGINEERS JOURNAL 1982年第2期94卷 286-295页

作者： FAIRBANKS, JW KENYON, CW Capt. John W. Fairbanks USNR:received his M.S. degree from the University of Santa Clara and his B.S. degrees from Stanford University and the Maine Maritime Academy. He taught at the Texas A&M University and the University of Maryland and from 1954 until 1957 served in the U.S. Navy in the Pacific. Subsequently he was a Research Engineer with Hiller Aircraft where he worked on the annular ejector and designed the High-Speed Bearing and Shaft Test Stand for XC-142A and later at Philco Ford worked on advanced space power systems. At NASA-Goddard in 1967 as a Power System Engineer he was employed on several space craft including the Orbiting Astronomical Observatory. From 1971 until 1977 he was employed by the Naval Ship Engineering Center (NAVSEC) as a Program Engineer for FT9 Marine Gas Turbine Development and the Ceramic Demonstrator Gas Turbine and also as Coordinator of Gas Turbine Material Development. In addition he organized the first two Gas Turbine Materials on Marine Environment Conferences and the U.S. participation in the U.S. Navy/Royal Navy Conference. Currently he is a Program Manager in Applied Heat Engine High Temperature Materials and Instrumentation at the Department of Energy (DOE) where he also served as Chairman Engineering Materials Coordinating Committee for DOE. A Naval Reserve Captain and Chairman of the ASME Washington Chapter he also is the former President of the Washington Chapter of the Maine Maritime Academy Alumni former Vice-President of the Stephen Decatur Chapter Naval Reserve Association and the outstanding 1975 Maine Maritime Academy Alumni. Capt. Fairbanks has authored over forty-five technical papers and in both 1974 and 1975 was the winner of the ASE Niedermair Award. Mr. Clarence W. Kenyon:graduated from the State University of New York Maritime College in 1960 and sailed on a Third Assistant Engineer's license with Isbrandtsen Steamship Company before accepting an engineering position with the Long Beach Naval Shipyard in 1961. In addition to his responsibilit

Synthetic fuels are assessed with respect to their potential use aboard Navy ships. The status of petroleum resources and the development of fuels from shale, coal, and biomass is summarized. A scenario of the projected availability of these fuels is presented which shows the sensitivity to funding and schedule. Diesel engine and gas turbine combustor tests with small quantities of coal derived and shale derived fuels are described and these tests results are evaluated for shipboard applications. Special shipboard modifications are discussed such as the replacement of rubber base seals, gaskets, and hoses with viton and teflon, and the use of stainless steel piping because of the fuel characteristics. Considerations for dual fuel systems using Diesel Fuel Marine for starting, stopping, and maneuvering are included based upon early test results. Consideration is given to the use of these fuels in the shipboard environment since they require special handling and adoption of personnel safety measures.

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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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DESIGN BUDGETING - A BOLD NEW SHIP ACQUISITION STRATEGY ... NOW A PROVEN CONCEPT

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NAVAL ENGINEERS JOURNAL 1981年第2期93卷 67-74页

作者： JARVIS, PS KAZAL, JD CAMPBELL, DB HAFF, MW Mr. Paul S. Jarvis:graduated from Virginia Polytechnic Institute from which he received his B.S. degree in Mechanical Engineering in 1962 and later he received his M.S. degree in Administration from The George Washington University in 1967. He has been in the AEGIS Shipbuilding Program since July 1971 and has served as Ship Systems Engineering Manager for CG 47 since 1977. Mr. Jarvis is a member of Tau Beta Pi and Pi Tau Sigma Engineering Fraternities and the Phi Kappa Phi National Scholastic Society. Mr. J. David Kazal:graduated from Colorado A&M from which he received his B.S. degree in Mechanical Engineering in 1951. Currently he is employed by the Ingalls Shipbuilding Division Litton Systems as a Project Engineer on the CG 47 Class Ship Program. During World War II he served in the U.S. Navy in Submarines. Mr. Kazal is a member of the American Society of Mechanical Engineers (ASME). Mr. Donald B. Campbell Jr.: received his B.S. degree in Electrical Engineering from North Carolina State University in 1961. He has over twenty-three years of professional experience in Ship Electronics System Engineering and was formerly a member of the Electrical Design Division at Newport News Shipbuilding. Additionally he was involved in quantification and evaluation of contractor shipbuilding claims against the U.S. Navy while he was employed by Booz-Allen Applied Research. Currently he is a Senior Member of the Engineering Staff at RCA providing program and engineering coordination for the AEGIS Program. Mr. Maurice W. Haff:received his B.S. degree in Electrical Engineering from Oklahoma State University in 1970. His advanced degrees which he received from The George Washington University are an M.S. degree in Management Engineering (1975) and an M.B.A. degree in International Business (1980). He has eleven years of engineering and management experience gained in a wide range of Navy Programs. While he was involved with “Design Budgeting” for the CG 47 from the beginning of the program as a Project Engineer Mr.

Traditional ship acquisition practices no longer support the requirements of today's shipbuilding programs. These practices require development of major combat and ship systems to be essentially complete prior to issuance by the government of the Request For Proposal (RFP) for ship detail design and construction. With the need for timely delivery of warships equipped with the most modern weapon systems possible, and maximum remaining years of functional effectiveness after delivery becoming increasingly important, new acquisition strategies are essential. “Design Budgeting,” an innovative new Navy acquisition and design strategy, is now a proven concept. Developed and implemented by the AEGIS Shipbuilding Project, it has been explored in depth with the Shipbuilding Industry as an alternative acquisition process that enables Combat system development and ship acquisition to proceed concurrently. Applied for the first time in the acquisition of Ticonderoga (CG-47), its use permitted development of major portions of the AEGIS Combat system (later to be Government Furnished Equipment to the shipbuilder) to continue well into ship detail design and construction without impact on overall schedules. Hundreds of changes to the ship engineering baseline which resulted from continued development and test of Combat system, were incorporated into the shipbuilding contract with no cost increase or delay and disruption of the shipbuilding schedule. Proven, adaptable, and available now, “Design Budgeting” is an acquisition and design strategy than can satisfy the requirements of current and future shipbuilding programs.

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THE AGE OF SAIL - IS IT OVER

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NAVAL ENGINEERS JOURNAL 1981年第2期93卷 145-153页

作者： MORISSEAU, KC THE AUTHOR:: graudated from the New York State Maritime College in 1956 receiving his B.S. degree in Marine Engineering. He then reported to the Navy's Bureau of Ships where he was assigned to the Hull Mechanical Section (Code 447) in the Hull Design Branch (Code 440). During this period he was involved in the contract design of various materials handling features of naval ships including vehicle and cargo handling for Amphibious Ships electronics equipment handling and replenishment at sea and in addition management of the Design Division's computer installation. In 1964 he became the Hull Project Coordinator for the AOR 1 Class AO(J) 51 Class and the AOE 3 Class ships and after completing their contract designs was transferred to the Auxiliary Type Desk and reassigned as AE 26 Class Project Engineer. From 1965 until 1974 he was the Program Manager for the FAST System and the Missile/Cargo STREAM System in the Underway Replenishment Project Office (PMS-390) Underway Replenishment Division (SHIPS-490) and its organizational predecessors. In April 1974 when SHIPS-490 and SHIPS-427 were merged he became Head of the Underway Replenishment Improvement Branch in the Amphibious and Combat Support Ship Logistics Division (SEA 941) Naval Sea Systems Command. In July 1979 he was transferred along with the management of the Underway Replenishment Improvement Program to the Deck and Replenishment Systems Division as Head of the Underway Replenishment Systems Branch (SEA 5124) the position he now holds in NA VSEA.

This paper explores the history, current trends and recent studies, experiments, and initiatives in the area of wind propulsion. The recent history of the development of sail as a means of ship propulsion is reviewed with regard to both sail and hull type. Studies and experiments are discussed such as evaluation for the U.S. Navy in 1956 of the use of ladder type hydrofoils with Marconi sails; a surface penetrating foil design, called an aerohydrofoil, developed in the early 1960s and recently successfully built and tested by its inventor; and the German Dynaship concept which uses an updated square rig sail configuration. Potential uses of sail for naval and commercial applications are presented, involving various sail forms such as air-foils, the Dynaship concept, the Flettner rotor, and Marconi rigs, and hull designs such as SWATH, Hydrofoil and Displacement. The paper also discusses some of the characteristics of wind over the world's oceans and their impact on the use of sail in naval and commercial service. The need for auxiliary fossil-fuel propulsion systems also is reviewed. An economic comparison of the cost of building and operating various sized sail-powered ships on selected routes is provided.

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CABLE BURIAL IN THE DEEP OCEAN-FLOOR

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NAVAL ENGINEERS JOURNAL 1980年第2期92卷 218-230页

作者： ROCKWELL, PK ENGEL, JH PIERCY, WB Mr. Philip K. Rockwell joined the Ocean Engineering Department at the Civil Engineering Laboratory (CEL) in 1969 after receiving his B.S. and M.S. degrees in Engineering from the University of California Los Angeles (UCLA) and in 1973 won the WEPCOSE Scholarship which took him to the University of Washington for postgraduate studies in Fluid Power Control Systems. Since joining CEL he has specialized in Underwater Manipulator and Diver Tool Systems has been the Project Engineer and Navy certified submersible operator for the manned submersible NEMO and has been responsible for the design test and evaluation of submersible fluid power and fluid power control systems. His most recent efforts have been on the Deep Ocean Cable Burial System for which he has been responsible for concept development program management validation testing. and coordination and planning for the total system design and fabrication. Mr. Rockwell is an Engineer-in-Training (EIT) in the state of California and in 1979 was awarded the Meritorious Civil Service Award for his outstanding performance. Mr. John H. Engel Jr. is a Mechanical Engineer in the Construction Systems Division Ocean Engineering Department. of the Civil Engineering Laboratory. He is a graduate of Oregon State University for which he received both his B.S. and M.S. degrees in Mechanical Engineering. Prior to joining CEL in 1975 he was involved with the design and development of remote oceanographic devices for the School of Oceanography at Oregon State University. At CEL he has worked in the areas of Underwater Gas Generation and Buoyant Lift Systems and at the present time is responsible for the mechanical design of the shallow water mooring for the initial ocean tests of the Current Measurement System. Mr. Engle also is a registered Engineer-in-Training in the state of Oregon. Mr. William Bruce Piercy at the present time is a student at the University of California at Berkeley where he is studying for his M.S. degree in Engineering having received his B.S. degr

Bottom fishing equipment employed by scallopers and trawlers routinely damage or break important Navy Oceanographic cables resulting in substantial repair coats and unacceptable system interruption. The Civil engineering Laboratory (CEL), sponsored by the Naval Facilities engineering Command (NAVFACENGCOM), has been developing and validating an engineering concept for a Deep Ocean Cable Burial (DOCB) system. This DOCB system will providethe Navy with an efficient, effective and reliable means of burying cables 3-feet deap in ocean mediments, at speeds not less than one knot, to water depths of 6,000 feet. The DOCB system b a remotely controlled machine which underruns and buries existing (previously laid) cables. It is powered and controlled from a surface ship via an electromechanical umbilica cable. The machine is self-propelled by ducted thrusters and supported on water lubricated skids. The excavation system computer an orbital vibrating plowshareand a vertical waterjet. Full-scale field testing at CEL baa keyed on three areas: •. Quantifying the reduction in drawbar force achieved by applying orbital vibration to an upward cutting plowshare. •. Evaluating a Vertically impinging jet nozzle for depth of a cut M a function of jet operating parameters. •. Demonstrating the effect on the soil drag of a flat-bottomed skid due to forcing a thin layer of water between the skid and the seafloor. The field teats of an orbital vibratory plow were performed in a 1 to 2 psi clay simllar to that found on the ocean floor. The results showed that a 70% reduction in drawbar force was achieved by applying an elliptical orbital vibration. It was also shown that the vibration feature would split or push aside buried rocks which would have stalled a conventional stationary plow. The water jet tests demonstrated that a 2 1/2-in. nozzle cuts 36-in. deep in 1 to 2 psi clay. The nozzle pressure was 75 psi and flow was 1,200 gpm. The water jet did not produce a clearly defined trench, b

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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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WHY NOT SAILS

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NAVAL ENGINEERS JOURNAL 1978年第5期90卷 57-62页

作者： MORISSEAU, KC The author graduated from the New York State Maritime College in 1956 receiving his BS degree in Marine Engineering. He then reported to the Navy's Bureau of Ships where after 18 months training he was assigned to the Hull Mechanical Section in the Hull Design Branch. During this period he was involved in the contract design of various materials handling features of naval ships including vehicle and cargo handling for Amphibious Ships electronics equipment handling and replenishment at sea and in addition also was charged with the management and operation of the Division's computer installation. In 1964 he became the Hull Project Coordinator for the AOR 1 Class AO(J) 51 Class and the AOE 3 Class ships and after completing their contract design was transferred to the Auxiliary Type Desk and reassigned as AE 26 Class Project Engineer. From 1965 until 1974 he was the Program Manager for the FAST System and the Missile/Cargo STREAM System in the Underway Replenishment Project Office (PMS–390)/Underway Replenishment Division (SHIPS–490) and its organizational predecessors. In April 1974 when SHIPS–490 and SHIPS–427 were merged he became Head of the Underway Replenishment Improvement Branch the position he now holds in the Naval Sea Systems Command.

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THE RESERVE MERCHANT SHIP DEFENSE system (RMSDS)

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Naval Engineers Journal 1977年第2期89卷 113-124页

作者： BASILE, NORMAN K. MASHIN, NORMAN P. Mr. Norman K. Basile received his MS degree in Mechanical Engineering from City University of New York in 1962. having been an Instructor of Marine Engineering and Training Officer at the New York State Maritime College. Fort Schuyler N. Y. from which he had received his BS degree in Marine Engineering in 1956. After working far various firms as a Marine Engineer he joined John J. McMullen Associates. Inc. (JJMA) as the Supervisor of Marine Engineering. In 1967 he was appointed Manager of Special Projects responsible for Chemical and LNG Transport Projects followed in 1969 by promotion to Vice President—Marine Engineering at which time he directed the company's efforts on the PF Program and the conceptual design of the AEGIS DG. Mr. Basile attained his present position as Executive Vice President. JJMA. in 1974 and in this capacity he now directs the efforts of the Technical Services Division and assists in establishing and implementing corporate management administrative. and fiscal policies. Mr. Norman P. Mashin received his MBA degree in Management for Engineers from Baruch College in 1971 and his BS degree in Nuclear Science from New York State Maritime College. Fort Schuyler. N. Y. in 1964. From 1964 until 1969 he was with Rosenblatt & Son Inc. in their Engineering Division where he went from Marine Engineer to Head of Machinery and Piping Preliminary Design Division and was responsible for all technical aspects of conceptual and preliminary design. Since 1970 he has been with John J. McMullen Associates. Inc. where he is presently Director. Programs Management responsible for the definition of technical requirements and deliverables work assignments and cost control. As Program Manager he directed all efforts for the Reserve Merchant Ship Defense System coordinating all aspects of design and construction effort both at JJMA and with the major subcontractors involved in the contract.

The prototype Reserve Merchant Ship Defense system (RMSDS) Facility will provide a base for naval helicopter operations on board a commercial Containership with minimal time and ship conversion effort. Basically, the design makes use of ISO dimensioned compatible modules to provide for living and operational support facilities for a Navy support detachment. Initially, the design has been developed to suit the LIGHTING Class of Containership and will support four SH—3H type helicopters and a naval detachment of sixty—five officers and men. This facility consist of four major elements, which are: Flight Deck, Accommodation Array, Hangar Array, and JP—5 Fuel system Storage and Service Array. Modular construction will be utilized to the maximum extent possible so as to aid in assembly, disassembly, and transportation of the RMSDS Facility. Interconnections between the various modules are all of the quick disconnect type, in keeping with the modular concept, thereby minimizing the potential for delays in assembly and disassembly. The RMSDS Facility is fully capable of sustaining and supporting SH—3 helicopter operations, including necessary command—and—control, maintenance/logistics support, integral personnel support facilities and provision of its own electric power for all uses within the complex. The services to be supplied by the host Containership are limited to fresh and salt water services as well as emergency electrical power (However, the RMSDS Facility DOES have additional back—up electrical power). Furthermore, to minimize development and fabrication costs of the RMSDS Facility, approved commercial marine equipment was utilized wherever possible. The logistic and tactical advantages, of the RMSDS/Intermodal Transportation system combination are explored and explained. Various alternative naval missions all utilizing various forms of VSTOL aircraft (SH—3, RH—53, CH—S3, AV—8A) are briefly described: Mine Counter Measures, Harbor Defense and Riverine Warfare, Ma

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Abstracts

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Environmental Management 1977年第1期1卷 67-96页

作者： Frankenfeld, John W. Schulz, Wolfgang McMurty, George J. Petersen, Gary W. May, G. A. Hering, F. S. Schwartz, J. I. Heywood, J. B. Chigier, N. A. Grohse, E. W. Walker, J. D. Colwell, R. R. Petrakis, L. Pergament, H. S. Thorpe, R. D. Schoepf, Richard W. Krzyczkowski, Roman Henneman, Suzanne S. Hudson, Charles L. Putnam, Evelyn S. Thiesen, Donna J. Parks, G. A. McCarty, Perry L. Leckie, J. O. Schrumpf, Barry J. Simonson, G. H. Paine, D. P. Lawrence, R. D. Pyott, W. T. Leh, M. Elders, W. Combs, J. Caplen, T. Harrison, F. L. Wong, K. M. Heft., R. E. Charnell, Robert L. Lehmann, Edward J. Mallon, Lawrence G. Hatfield, Cecile Adams, Gerald H. Johanning, James Talvitie, Antti Noll, Kenneth E. Miller, Terry Smiarowski, Joseph F. Willis, Cleve E. Foster, John H. Schlesinger, Benjamin Daetz, Douglas Lear, Donald U. Smith, Mona F. Hundemann, Audrey S. Crockett, Pernell W. Werner, Kirk G. Carroll, Thomas E. Maase, David L. Genco, Joseph E. Ifeadi, Christopher N. Lowman, F. G. Christensen, S. W. Van Winkle, W. Mattice, J. S. Harrison, Elizabeth A. Barker, James C. Chesness, Jerry L. Smith, Ralph E. Shaheeen, Donald G. Raney, R. Keith Borton, T. Wezernak, C. T. Raney, R. K. Sherwani, Jabbor K. Moreau, David H. Eisenberg, Norman A. Lynch, Cornelius J. Breeding, Roger J. Johnson, J. D. Foster, K. E. Mouat, D. A. Clark, R. Hyden, John William Owen, Wilfred Bayfield, Neil G. Barrow, Graham C. Stolz, Stephanie B. Wienckowski, Louis A. Brown, Betram S. Keyfitz, Nathan Wilson, W. L. Newman, Peter W. G. Bammi, Deepak Bammi, Dalip Goddard, James E. Chisholm, Tony Walsh, Cliff Brennan, Geoffrey Thompson, K. S. Richardson, R. Jensen, Clayton E. Brown, Dail W. Mirabito, John A. Cowing, Thomas G. Binghamton, Suny Siehl, George H. Albrecht, O. W. Alexander, Ariel Barde, Jean -Philippe Darby, William P. McMichael, Francis Clay Dunlap, Robert W. Muckleston, Keith W. Frankenhoff, Charles A. Giulini, Lorenzo T. Wyatt, T. Black, Peter E. Keating, William Thomas Leonard, M. E. Fisher, E. L. Brunelle, M. F. Dickinson, J. E. Pethig, Rudiger Clapham Exxon Research & Engineering Co. Linden Government Research Lab Coast Guard Washington D.C. Department of Transportation Washington D.C. Office For Remote Sensing of Earth Resources. NASA Earth Resources Survey Program Pennsylvania State University Washington D.C. Department of the Navy Washington D.C. Cambridge. Dept. of Mechanical Engineering Massachusetts Inst. of Technology USA Huntsville. School of Graduate Studies and Research Alabama Univ. USA Dept. of Microbiology. Office of Naval Research Maryland Univ. Arlington Research and Development Co. Pittsburgh AeroChem Research Labs. Inc. Princeton Dept. of the Interior Office of Library Services. Bibliographic Series (Final) Washington D.C. Interplan Corp. Santa Barbara Urban Mass Transportation Adm. Washington D.C. Naval Underwater Systems Center Newport Calif. Mercury Project. National Science Found Stanford Univ Washington D.C. Div. of Advanced Environmental Research & Tech. USA Corvallis. NASA Earth Resources Survey Program Oregon State Univ. Washington D.C. Riverside. Inst. of Geophysics and Planetary Physics National Science Foundation California Univ. Washington D.C. Livermore Lawrence Livermore Lab. California Univ. USA Atlantic Oceanographic and Meteorological Labs. National Oceanic and Atmospheric Administration Miami National Technical Information Service Springfield Miami Univ. Coral Gables School of Law National Oceanic and Atmospheric Administration Rockville National Academy of Sciences Office of Sea Grant Washington D. C. School of Law National Oceanic and Atmospheric Administration Office of Sea Grant. Rockville Norman. Dept. of Civil Engineering and Environmental Science. Urban Mass Transportation Administration Oklahoma Univ. Washington D. C. Knoxville.Dept. of Civil Engineering. Federal Highway Administration Tennessee Univ. Washington D. C. Amherst.Water Resources Research Center. Office of Water Research and Technology Massachusetts Univ. Washington D. C. Calif. Dept. of Industria

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