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16-IN GUN BLAST AND THE BATTLESHIP REACTIVATION program

NAVAL ENGINEERS JOURNAL 1987年第3期99卷 227-238页

作者： YAGLA, JJ The authorreceived his B. A. degree in science (physics) from the State College of Iowa in 1965. He received his M. S. degree in engineering mechanics in 1968 and his Ph.D in aerospace engineering and engineering science in 1981 from Arizona State University. He has done analytical and experimental research in the field of weapons blast since 1965 at the Naval Surface Weapons Center in Dahlgren Virginia. As a supervisory research mechanical engineer he was previously head of the Physical Response Analysis Branch Blast Effects Branch and Ship Engineering Branch. Dr. Yagla is the test development agent and was test conductor for the gun and missile structural test firings in USS Iowa class battleships. He is a consultant to the Naval Sea Systems Command battleship combat system engineer and the Naval Air Systems Command Cruise Missile Project for blast and structural response. He is presently analyzing shock and vibration problems for the Standard Missile Program Office.

Reactivated and modernized USS Iowa class battleships employ many new systems, none of which were designed to withstand blast from 16-inch guns. Placement of the new equipment was driven by the need to impose the smallest possible restrictions on the guns. The design problem was complicated by two factors: first, the blast overpressure field surrounding the gun had not been accurately measured with modern instruments. Second, the blast overpressure tolerance of several important systems was unknown. The problem was solved through judicious placement of the equipment so that work could begin on the ship. Meanwhile the pressure surrounding a 16-inch gun was measured at the Dahlgren Laboratory. Mathematical functions describing the blast field were then used to design shipboard experiments in which the guns were fired at progressively more severe angles of train and elevation, while the equipment performance was carefully monitored. Four sets of shipboard experiments were required. Limiting values for the firing arcs have been determined, and the consequences of exceeding the recommended limits are now known.

关键词： WARSHIPS

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ELECTROMAGNETIC ENVIRONMENT engineering - A SOLUTION TO THE EMI PANDEMIC

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NAVAL ENGINEERS JOURNAL 1987年第3期99卷 202-209页

作者： GRICH, RJ BRUNINGA, RE RAdm. Richard J. Grich USN:was commissioned from Officers Candidate School in May 1953 after receiving a B. S. in electrical engineering from Catholic University and a masters degree from Columbia University in New York. He has served as engineering officer USS Paul Revere (APA-248) as ship superintendent at the New York Naval Shipyard and as assistant material officer on the staff of Commander Naval Air Force Atlantic Fleet. He has a distinguished background as an engineering duty officer in engineering electronics. He has served as the head of the Operations Department on the IN-SURV Board and was assigned as head Logistics Branch Navy Division Defense Attache's Office Saigon Vietnam. For six years he was project manager for the Nimitz class carrier acquisition program PMS-392 at the Naval Sea Systems Command. During this tour he was responsible for the construction and delivery of USS Nimitz (CVN-68) and USS Dwight D. Eisenhower (CVN-69) and the construction through launching of USS Carl Vinson (CVN-70). He also consolidated the VSTOL support ship project into PMS-392 and developed the Service Life Extension Program for USS Saratoga (CV-60). During his subsequent tour he was supervisor of shipbuilding converson and repair in Pascagoula MS. He is presently serving as the assistant commander for acquisition and logistic planning at the Space and Naval Warfare Systems Command. He is a member of ASNE. Cdr. Robert E. Bruninga USN: was graduated from the Georgia Institute of Technology in 1970 with a B. S. degree in electrical engineering. After attending the United States Naval Postgraduate School Monterey where he received his M. S. degree in electrical engineering he was assigned as the assistant weapons instrumentation officer on USS Observation Island (AG-154). Later while serving on the Commander Service Group Three staff in Sasebo Japan he was selected as an engineering duty officer (ED). He has served at the Supervisor of Shipbuilding Conversion and Repair Brooklyn as ship superintendent

There are severe electromagnetic interference (EMI) problems which are pandemic throughout the fleet with both known and unknown impact on the operational performance of ships. This paper suggests that the key solution to the EMI pandemic is to develop an engineering discipline in electromagnetics (EM) comparable to the stature of naval architecture and marine engineering to embed EM design considerations and tradeoffs throughout the ship and equipment design processes. Such an engineering discipline to electromagnetics, and a Navy management commitment to its implementation, would prevent EMI by allowing the use of engineering budgets, allocations, and margins based on predicted EM fields in optimization and design toward well defined performance requirements. The EM engineering discipline would rely on gathering existing resources, developing new approaches where needed, and implementing new steps in the ship design process to accomplish these objectives: (1) use of improved techniques for EM environment prediction, (2) identification of quantifiable performance measures, (3) developing the body of knowledge and traceability between performance and EM effects, (4) selection of ship and equipment design features based on EM considerations, and (5) iteration of the ship design based on EM results.

关键词： ELECTRONIC EQUIPMENT

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U. S. NAVAL ACADEMY'S NEW YARD PATROL CRAFT: FROM CONCEPT TO DELIVERY.

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Naval Engineers Journal 1987年第1期99卷 37-58页

作者： Compton, Roger H. Chatterton, Howard A. Hatchell, Gordon McGrath, Frank K. Roger H:. Compton is a Webb graduate who since 1966 has been a part of the naval architecture faculty at the U.S. Naval Academy. Since accepting the appointment to the Academy he has been instrumental in establishing the ABET accredited major program in naval architecture in the conceptual design and operation of the Naval Academy Hydromechanics Laboratory and in the conceptual design of the 108-ft yard patrol craft. Besides his Naval Academy involvement he serves as an adjunct professor with Virginia Polytechnic Institute in its NAVSEA Institute graduate program at Crystal City. He is an active member of both ASNE and SNAME and has published technical papers with both societies. Howard A. Chatterton:began his career as a Navy coop student at the Boston Naval Shipyard in 1960. He received his bachelor's degree in naval architecture and marine engineering from Massachusetts Institute of Technology in 1966 and his master's degree in 1968. He was employed by the Preliminary Design Division of BuShips in the submarine design and hydrofoil design groups until 1972 when he joined the Coast Guard's Naval Engineering Division. He remained with the Design Branch until 1981 when he accepted a faculty position at the U.S. Naval Academy as the research director for the Academy's hydromechanics laboratory. He has recently returned to Coast Guard Headquarters as the assistant chief Naval Architecture Branch Office of Merchant Marine Safety. Gordon Hatchell:is a naval architect at the Naval Sea Combat Systems Engineering Station Norfolk Virginia in the Combatant Craft Engineering Department. He served as lead-ship YP project engineer from its inception to delivery and continues to serve as project coordinator on follow-up ship procurements. He has worked on other boat procurements as well as serving as weight and stability coordinator. Mr. Hatchell began his engineering career in the Design Division at the Norfolk Naval Shipyard in Portsmouth Virginia after receiving a BS in civil engineering from Virginia Polytec

The design of the new 108-ft yard patrol craft (YPs) for the U. S. Naval Academy is described from its beginnings as a senior midshipman design project, through its preliminary and contract design development at the U. S. Navy's small craft design team headquarters, Naval Sea Combat systems engineering Station, Norfolk, Virginia (NAVSEACOMBAT-SYSENGSTA-Norfolk). During preliminary and contract design the Naval Academy Hydromechanics Laboratory (NAHL) provided experimental data to support NAVSEA-COMBATSYSENGSTA-Norfolk's design analyses in powering, seakeeping, and maneuvering. Several tradeoff studies of interest to patrol craft designers are presented. Major events in the detail design and construction of the first boat are described from both the designer's and the shipbuilder's points of view. The launching, builder's and sea trials of the first boat are described.

关键词： NAVAL VESSELS

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The Effect of Task Difficulty on the Steady State Visual Evoked Response

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Proceedings of the Human Factors and Ergonomics Society Annual Meeting 1986年第13期30卷 1254 - 1258页

作者： Andrew M. Junker Kevin M. Kenner David F. Ingle Harry G. Armstrong Aerospace Medical Research Laboratory Wright-Patterson Air Force Base Ohio Human Engineering Program Ofc. Systems Research Labs Inc. Dayton Ohio Human Engineering Program Ofc. Systems Research Labs Inc. Dayton Ohio

Steady State Visual Evoked Responses to sum-of-sine wave modulated light were measured for subjects as they performed a decision making task. Describing function phase values demonstrated a positive shift under task conditions. For those subjects classified as Alpha producers (peak response in the 8 to 12 Hz region) there was an attenuation of gain with increasing task difficulty. In the beta range (above 12 Hz) a resistance to gain attenuation with increasing task difficulty, even to the point of gain increase, was observed.

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COMBAT SYSTEM INDUSTRIAL-TESTING - MEASUREMENT OF SUCCESS

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NAVAL ENGINEERS JOURNAL 1986年第5期98卷 47-57页

作者： TRESSLER, DL HART, JB Dennis L. Tresseler is currently combat system test team leader for the combat systems test and evaluation branch of the Naval Sea Systems Command (SEA 61 × 11). Mr. Tresseler graduated in 1972 with a degree in mechanical engineering technology. He began his career at Newport News Shipbuilding in 1972 where he was a test director responsible for weapon system installation alignment and testing in CGN-36 thru 40 and CVN-68 and 69. In 1977 he came to the Washington area and worked for various contractors in technical and managerial positions before coming to NA VSEA in 1981. He is a member of the Naval Institute and his paper on “FF-1041 Class Modernization” has been accepted for publication in the Proceedings. J.B. Hart is currently the senior program manager combat systems for VSE Corporation headquartered in Alexandria Virginia. He is the program manager for VSE's master ordnance repair (MOR) team. His previous position was with COMPTEK Research Inc. Virginia Beach as senior combat systems engineer. Mr. Hart earned his BS degree from the University of New York in general engineering. He retired as chief ordnance control warrant officer after 22 years of service in 1982. While on active duty he served in various combat systems capacities since 1968 the most noteworthy of which were as ship's combat systems test officer/fire control officer on USS Belknap (CG-26) bringing her back into commission through major reconstruction and as combat system chief onboard USS Albany (CG-10) assisting in test and delivery of the first NTDS model 4.0 software program as well as numerous control systems updates both software and hardware.

This is an overview of the combat system test and certification (CST&C) program as a subset of the total ship test program (TSTP) for active fleet surface ships. The paper will discuss how the T&C program measures not only the suitability of repairs and modifications done during a ship's combat system industrial availability in a public or private yard period, but also the impact that successful program conduct has on the materiel effectiveness throughout a ship's operational cycle. The CST&C management organization and responsibilities, including NAVSEA's master ordnance repair program as well as combat system code 190's relationship to the CST&C program and the impact of pre- and post-industrial testing requirements on the actual conduct of industrial testing will be addressed.

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MASTER ORDNANCE REPAIR APPLIED - STANDARD ITEM 009-67

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NAVAL ENGINEERS JOURNAL 1986年第3期98卷 35-42页

作者： STIMSON, WA MARSH, MT UTTICH, RM William A. Stimsonreceived his B.S. degree in mathematics from the University of Texas at El Paso in 1964 and his M.S. degree in engineering from the University of Santa Clara in 1971. He served in the U.S. Army Artillery during the Korean Conflict and subsequently was employed at IBM Huntsville Alabama until 1968 where he worked in the design of automatic control systems of the Saturn vehicle. From 1968 until 1971 he was employed at Ames Research Center Moffett Field in the design of nonlinear control systems for sounding rockets and pencil-shaped spacecraft. Following this Mr. Stimson worked at Hewlett Packard Sunnyvale California as a test engineer in automatic test systems. Since 1973 Mr. Stimson has been employed at the Naval Ship Weapon Systems Engineering Station Port Hueneme. He was a ship qualification trials project supervisor for many years and is now serving as master ordnance repair deputy program manager. Mr. Stimson is a member of the American Society of Naval Engineers and is program chairman of the Channel Islands Section. Cdr. Michael T. Marsh USNreceived a B.S. in mathematics from the University of Nebraska and was commissioned via the NESEP program in 1970. He holds an M.S. in computer science from the U.S. Navy Postgraduate School and an MBA from the State University of New York. Cdr. Marsh has served in the weapons department of USSFrancis Hammond (FF-1067) and of USSJohn S. McCain (DDG-36). He was weapons officer aboard USSSampson (DDG-10). As an engineering duty officer Cdr. Marsh was the technical design officer for PMS-399 at the FFG-7 Class Combat System Test Center from 1978 to 1982. He is presently combat system officer at SupShip Jacksonville and has been active in the MOR program since its inception. Cdr. Marsh is also the vice chairman of the Jacksonville Section of ASNE. LCdr. Richard M. Uttich USNholds B.S. and M.S. degrees in mechanical engineering from Stanford University. He enlisted in the Navy in 1965 serving as an electronics technician aboard USSNereus (A

The 600-ship United States Navy offers private shipyards an unprecedented opportunity for overhaul of surface combatants with complex combat systems. Recognizing the new challenge associated with the overhaul of high technology combat systems in the private sector, the Navy in 1983 established the master ordnance repair (MOR) program. This program, a joint effort of the Naval Sea systems Command (NAVSEA) and the Shipbuilders Council of America (SCA), was designed to identify and qualify those companies and private shipyards technically capable of managing combat systems work and conducting combat system testing. Standard Item 009–67 describes the role of the MOR company in combat system overhaul. It defines terms that are important to understanding the item itself, and imposes upon the prime contractor an obligation to utilize the MOR subcontractor in a managerial capacity. Specific tasks are assigned to the MOR company in planning, production, and testing. Finally, this standard item describes to the Navy planner how to estimate the size of the MOR team appropriate to the work package, a feature that will ensure that combat system bids are tailored to a specific availability.

关键词： WARSHIPS

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WARSHIPS AND COST CONSTRAINTS

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NAVAL ENGINEERS JOURNAL 1986年第2期98卷 41-52页

作者： HOPE, JP STORTZ, VE Jan Paul Hope a native of Northern Virginia received his bachelor of science degree in mechanical engineering from the University of Virginia in 1969. Upon graduation he began his career in the Department of the Navy with the Naval Ship Systems Command in the acquisition of patrol craft mine sweepers and submarine rescue ships. In January 1971 he transferred to the ship arrangements branch of the Naval Ship Engineering Center. He was selected for the long-term training program at George Washington University in 1974 and completed the program in February 1976 with the degree of master of engineering administration. While at the Naval Ship Engineering Center Mr. Hope was general arrangement task leader on the AO-177 CG-47 CSGN CSGN (VSTOL) CGN-9 (Aegis) and CGN-42 and he also assisted in the landmark Naval Sea Systems Command civilian professional community study. In 1978 he was selected as acting head of the damage control section and subsequently was selected as acting head of the surface ship hydrodynamic section. In February 1980 he was promoted to head of the surface combatant arrangements design section. Mr. Hope was selected for the first class of the NA VSEA commander's development program. While on the program he served in the DDGX combat systems engineering division and the DDGX project office of NA VSEA was the assistant director for ship design in the office of the Assistant Secretary of the Navy for shipbuilding and logistics and was the director of weight engineering and the director of systems engineering for the DDG-51 project in NA VSEA. Upon completion of the program Mr. Hope was assigned as the deputy director of the boiler engineering division to create a new division as a major fleet support initiative by NA VSEA. In June 1985 he joined the staff of the Assistant Secretary of the Navy for shipbuilding and logistics. Mr. Hope was presented the Department of the Navy meritorious civilian service medal in June 1983 for his service with the Office of the Assistant Secretary of the

This paper discusses the need and processes for designing warships to meet cost constraints and for managing warship acquisition programs during the design phase to assure effective adherence to production cost constraints by the design team. The resource control methodology used during the contract design of the Arleigh Burke class destroyer, DDG-51, is examined as a potential model for controlling the cost while maintaining the combat effectiveness of warships. The paper begins with a summary of the basic issue — the relationship among unit cost, unit capability, force level numbers, and force capability — showing recent trends in destroyer costs and force levels. This introduction also includes a discussion of the cost constraint for the DDG-51 in relation to historical trends and ship construction funding allocation. The resource control methodology used to reduce and control costs of the DDG-51 is discussed with a summary of the approach, key concepts and tools, chronology of key events, examples, and results achieved. A number of observations on this methodology are then made which are followed by comments on life cycle costs. The paper concludes with remarks on the future application of the resource control methodology and areas for further work to improve future resource control efforts.

关键词： WARSHIPS

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SYSTEM-75 - COMMUNICATIONS AND CONTROL ARCHITECTURE

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AT&T TECHNICAL JOURNAL 1985年第1期64卷 153-173页

作者： BAXTER, LA BERKOWITZ, PR BUZZARD, CA HORENKAMP, JJ WYATT, FE AT&T Information Systems Laboratories an entity of AT&T Information Systems Inc. Donn Baker: M.E. (Engineering) 1953 Stevens Institute of Technology Bell Laboratories Communications Development Training Program 1956 Bell Laboratories 1953–1982 AT&T Information Systems Laboratories 1983—. Howard D. Frisch: B.S.M.E. M.M.E. M.B.A. (Finance/Operations) Cornell University in 1979 1980 and 1981 respectively Bell Laboratories 1981–1983 AT&T Information Systems Laboratories present affiliation Bell Communications Research Inc. C. R. Lindemulder: B.S.M.E. 1960 New Mexico State University M.M.E. 1963 New York University Bell Laboratories 1960–1982 Albert S. Loverde: B.S. (Mechanical Engineering) 1961 Purdue University M. S. (Engineering Mechanics) 1963 New York University Bell Laboratories Communications Development Training Program 1964 Bell Laboratories 1961–1982

The System 75 office communication system uses a unique communications and control architecture that provides great flexibility and a minimum of overhead for small configurations while growing smoothly to larger line sizes. A distributed communication network provides 64 kb/s connectivity for both voice and data. It consists of a pair of time division multiplexed buses and intelligent port circuits. Flexible conferencing and gain adjustment are supported as an integral part of the network. The control complex supports an operating-system-based software structure.

关键词： DIGITAL COMMUNICATION systems

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LIGHTWEIGHT BROAD-BAND HF COMMUNICATIONS ANTENNA (LWCA)

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NAVAL ENGINEERS JOURNAL 1985年第4期97卷 279-286页

作者： BIONDI, RJ PRIDE, RW MURRAY, HD WHEELER, PK Roy J. Biondi:received his B.S.E.E. degree from the University of Illinois and has since taken additional graduate studies at the George Washington University. Currently he is head of the Communication Systems Application Branch code PDE 110–14 within the NAVELEXSYSCOM. Prior to his present appointment he served in the Combat Systems Division Naval Sea Systems Command and served as radar branch head in the former Naval Ship Engineering Center (NAVSEC). He was responsible for development and production of shipboard radars such as the AN/SPS-48 AN/SPS-49 AN/SPS-52 and AN/SPS-55. His primary Navy radar and combat system experience was attained during his earlier career in the Navy's Bureau of Ships where he was the AN/SPS-48 radar project engineer. In addition to ASNE which he joined in 1977 he is a member of IEEE and ASE and has had several technical papers published on radar radar antennas radar processing and transmission lines. Mr. Biondi has a total of 25 years naval experience in radar combat systems and communications. Richard W. Pride:received his B.S.E.E. from the University of Maine in 1959. Currently he is head of the Combatant Ship Section code PDE 110–143 in the Communications Systems Application Branch within the NAVELEXSYSCOM. Prior to joining the Naval Electronic Systems Command in 1974 he was the head of the Communication Antenna Design Section of the former Naval Ship Engineering Center. Harold D. Murray:received his B.S.E.E. from Vanderbilt University. Currently he is an EXCOMM program manager code PDE 110–1433 in the Combatant Ship Section of NAVELEXSYSCOM. As an EXCOMM program manager Mr. Murray is responsible for the external communications system design for the CG-47 (Aegis) class cruisers. Mr. Murray's previous government service includes 14 years at the Naval Research Laboratory (NRL) and 5 years at Naval Air Systems Command. Major areas of responsibility included shipboard RF distribution systems and aircraft intercommunication systems and control. Paul K. Wheeler:is pre

External communications is a critical element in the U.S. Navy design and utilization of a ship's combat system. The communications antenna system is a key factor in attainment of reliable circuit performance and reduction of electromagnetic interference (EMI). To maintain pace with improved ship manufacturing techniques and construction materials, along with design efforts to reduce topside generated EMI/RFI effects, an improved antenna design must also evolve. With the ever increasing complexity in the integration of the topside environment, the RF aspects of the antenna designs must be augmented by detailed analysis of the operating environment and the mechanical design if the goals of reliability and quality performance are to be achieved. The Naval Electronic systems Command has developed a new “Broadband HF Communications Antenna.” This paper traces the design evolution and describes the processes in determining current design deficiencies, the design objectives to correct these deficiencies and the results obtained.

关键词： ANTENNAS

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MARINE APPLICATION OF MAGNUS EFFECT DEVICES

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NAVAL ENGINEERS JOURNAL 1985年第1期97卷 51-57页

作者： MORISSEAU, KC The authorgraduated from the New York State Maritime College in 1956 with a degree in marine engineering. He then reported to the Navy's Bureau of Ships where he was involved in the contract design of various materials handling features of naval ships. In 1964 he was the Hull Project Coordinator for the AOR-1 class AO(J)-51 class and the AOE-3 class ships. 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. In April 1974 he became head of the Underway Replenishment Improvement Branch in the Amphibious and Combat Support Ship Logistics Division. In July 1979 he was transferred to the Deck and Replenishment Systems Division as head of the Underway Replenishment Systems Branch the position he now holds in the Naval Sea Systems Command. In addition he has been active in sailing ship research and the promotion of sail assist for Navy ships. He is a member of the Society of Naval Architects and Marine Engineers and the Association of Scientists and Engineers.

The Magnus effect is an induced, very high lift phenomenon that has been used for wind propulsion of ships as early as 1924. More recently, this unique lift principle has been used for steering towboats. Recent research has indicated that Magnus effect roll stabilizers, water propellers, and air and water generators may be both feasible and have greater efficiency than traditional designs. The paper explains the Magnus effect, reviews the history of the Magnus effect, reviews current marine applications including the work of investigators in Germany, France, Sweden and Russia, discusses in detail Magnus effect rotor design, and proposes auxiliary wind propulsion Magnus effect devices for single screw oilers.

关键词： SHIP PROPULSION

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