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This is an assessment of Japanese High Speed Surface Transport (HSST) policy, vision, goals, and magnetic levitation development and commercialization strategy. It includes a status report for a test program now underway to demonstrate the safety, reliability and economic viability of the HSST-100 maglev train system. HSST-100 is one of three types of HSST maglev trains planned for implementation in Japan: HSST-100 for 100 km/h urban service, HSST-200 for 200 km/h medium range suburban service, and HSST 300 for the 300 km/h long range interurban application. For the HSST-100 program, included are detailed specifications for the vehicle, location of the Chubu (Central Japan) test site South of Nagoya, test site guideway specifications, guideway switching concept, test site facility description, major test activities, and test event schedule.

This is an assessment of Aerospace Technology in Japan, the national vision supporting it and the strategy underlies it's ultimate purpose. It includes a comparison of the organizations and missions of the two principle aerospace agencies: One, the Institute of Space and Astronautical Science (ISAS); and, two, the National Space Development Agency (NASDA). Included are the launch capabilities and deep space facilities of ISAS, at Kagoshima Space Center (KSC) in Uchinoura on Kyushu island; and the NASDA Tanegashima Space Center (TSC) on Tanegashima Island. Also included are the design and development history of domestic Nippon launch and space vehicles, beginning with the licensing of the United States Thor-Delta rocket technology and including the design of the domestic H-I second and third stages and the all domestic H-II vehicles.

This is an assessment of Japanese High Speed Surface Transit (HSST) policy, vision, goals, and magnetic levitation development and commercialization technology. It includes an illustrated historical review of past HSST magnetic levitation vehicle developments, a review of the present status of HSST trains, and an outline of future HSST conventional magnetic levitation trains with speeds of 300 km/h for interurban and transcontinental service. Also described are: the start of construction of a new test track which includes the track switching mechanism designed for the Las Vegas HSST route in the United States; test operation execution for the practicalization of HSST-100 by the newly formed Chubu (Central Japan) HSST Development Corporation of Nagoya Railroad Company and HSST Corporation. These magnetic levitation electric trains have been under development since 1974 and are now considered ready for introduction into commercial service.

This is an assessment of United States High Speed Guided Transit (HSGT) systems policy, vision, goals, and magnetic levitation development and commercialization technology. It includes a historical review of past magnetic levitation vehicle developments, a review of the present status of MagLev trains, and an outline of future conventional (EML) Electro Magnetic Levitation for speeds under 400 km/h; and, (SC) Super Conductive (EDL) Electro Dynamic Levitation for subsonic speeds approaching 900 km/h. Magnetic levitation transit technology has been under development in America since the United States Congress passed the 1965 High Speed Guided Transit Act (HSGT) which authorized the Department of Transportation to fund HSGT projects. Since this initial effort focused attention on the potential of the magnetic levitation concept for very high speed transit applications, this technology has been an ongoing development in Europe and Japan.

During the interval from 1985 to 1993, the major automotive manufacturers of Western Europe, America, and Japan introduced experimental and prototype battery electric vehicles (EV) to the public. These electric vehicle technical developments have demonstrated that the automotive industry is responsive and creative in proposing potential solutions to the key concerns which have constrained the widespread application of the EV in the past. While this technical assessment included: identification of the key concerns and innovative solutions to aerodynamic drag reduction, tire loss reduction, and compared acceleration performance, vehicle range, regenerative braking, batteiy developments, fast recharging, unique passenger compartment heating and cooling solutions, and low mass vehicle structural materials; the scope of this paper is limited to reporting the performance and vehicle range results.

As part of an electric vehicle state-of-the-art evaluation, General Motors built a fuel cell powered van, the Electrovan, to explore the potential and problems of the fuel cell powerplant. Fuel cells were considered because they offer the potential of high thermal efficiency and extended range compared with batteries. Although the Electrovan was successfully operated on the road, we concluded that much research and development work is still needed to solve the many major problems. The encouraging rate of progress and the advantages of fuel cells provide the stimulus to maintain a strong continuing effort in this field.

This is an assessment of electric propulsion and magnetic levitation of automotive size vehicles in Japan. It includes conventional battery electric vehicles with peak speeds up to 100 km/h in mixed traffic for urban and suburban applications and magnetic levitation guideway confined vehicles with peak speeds of 300 km/h for intercity trans-sportation. These electric vehicles have been under development since 1971 and some are considered ready for commercialization.

This is an assessment of Aerospace Technology in Japan, the national vision which supports it and the strategy which underlies it's ultimate purpose. It includes a comparison of the organizations and missions of the two principle aerospace agencies: One, the Institute of Space and Astronautical Science (ISAS); and, two, the National Space Development Agency (NASDA). Also included are the launch capabilities and deep space facilities of ISAS, at Kagoshima Space Center (KSC) in Uchinoura on Kyushu island; and, the Tanegashima Space Center (TSC) of NASDA located on Tanegashima Island. Also included are the design and development history of domestic Nippon launch and space vehicles, beginning with the licensing of the United States Thor-Delta rocket technology and including the design of the domestic H-I second and third stages and the all domestic H-H vehicles.

This is a comparative assessment of the three magnetic levitation high speed mass transportation systems currently under extensive development, and in the prototype vehicle demonstration stage, in the Federal Republic of Germany (FRG) and in Japan: One approach, which is promoted by Transrapid International (TRI) in FRG, is based on the electro magnetic levitation (EML) concept; a second approach, which is promoted by the High Speed Surface Transport Corporation (HSST), is based on the EML concept developed and licensed from Japan Air Lines (JAL); a third approach, which is promoted by the Railroad technology Research Institute (RTRI) (Sogo Tetsudo Gijutsu Kenkyusho), the developer of the Shinkansen train, is based on the super conductive electro dynamic levitation (EDL) concept.

This study identifies the ambient conditions under which a so-called empty-Boeing model 747-131 fixed wing jet center wing tank (CWT), containing a residual fuel loading of about 3 kg/m3, less than 60 gallons of aviation kerosene (JetA Athens refinery jet fuel), could form hazardous air/fuel mixtures. The issues are limited to explosion safety concerns relating to certificated fixed wing jet aircraft in scheduled passenger service. It is certain that combustible mixtures do not exist in a fuel tank containing JetA type fuel at ambient temperatures below 38°C (100°F), the lean limit flash point (LFP) for jet fuel at sea level. Never the less, the original study by Wyczalek and Suh (1997), identified six rational conditions which can occur and permit hazardous mixtures to exist in a fuel tank.

The specific mission was to determine the effect of driving schedules on the efficiency of battery powered electric vehicles (EV) and hybrid engine/electric vehicles (HEV). Efficiency was referenced to the hydrocarbon (HC) fuel source which provided the electrical energy. In the case of the battery powered pure electric vehicle, the HC source was referenced to the public utility HC fuels. While, in the case of hybrid electric vehicles, the HC source was carried on board the HEV in the vehicle fuel tank.

Battery electric propulsion presents opportunities to regeneratively recover vehicle kinetic energy and provide: unique integrated regenerative braking options singly and/or in combinations; to further improve vehicle energy economy by methods which are not inherently applicable to the conventional internal combustion powered automobile. There are three basic modes to be considered in the design of regenerative braking systems for battery electric vehicles: service braking, programmable deceleration, and emergency braking. Furthermore, the type of traction motor, the driving schedule, and charging characteristics of the associated battery pack are essential considerations involved in designing regenerative braking systems for optimal recovery of vehicle kinetic energy and optimizing battery pack life.

Battery electric propulsion presents opportunities to recover vehicle kinetic energy and provide: unique integrated regenerative braking options singly and/or in combinations; to further improve vehicle energy economy by methods which are not applicable to conventional internal combustion powered vehicles. There are three basic modes to be considered in the design of regenerative braking systems for battery electric vehicles: service braking, programmable deceleration, and emergency braking. Furthermore, the type of traction motor, the driving schedule, and charging characteristics of the battery pack are essential considerations involved in designing regenerative braking systems for optimal recovery of vehicle kinetic energy and optimal battery pack life.