Download Free Nuclear Power From Underseas To Outer Space Book in PDF and EPUB Free Download. You can read online Nuclear Power From Underseas To Outer Space and write the review.

John Simpson, former president of Westinghouse Power Systems Company and past president of the American Nuclear Society, provides a vibrant account of the events associated with the birth of the nuclear industry. Simpson's account of his career and the many turns it took is formidable. Sixteen chapters provide the reader with a historical perspective portrayed by a person whose role, energy, and contributions to the development of fission power are significant. Simpson takes you through the building and operation of the first submarine, nuclear propulsion units, Shippingport, the astronuclear years, and early commercial power. Written largely in narrative and anecdotal form, the technical story is also provided. The final chapter provides a summary and the author's thought-provoking view of the future of nuclear power.
Provides details of a variety of radioisotope power systems, shows in what circumstances they surpass other power systems, and provides the history of the space missions in which they have been employed. The book also summarizes the use of on-board reactors and the testing done on reactor rocket thrusters.
"Space Nuclear Propulsion and Power: Principles, Systems, and Applications" is a comprehensive exploration into the science and technology of nuclear systems designed for space missions. This book offers an in-depth analysis of nuclear propulsion and power generation, focusing on the principles and mechanisms that drive these systems, as well as their practical applications in space exploration. The book begins with a detailed overview of the fundamental principles of nuclear physics and reactor design, providing the necessary background for understanding how nuclear energy can be harnessed for space applications. It delves into the various types of nuclear propulsion systems, including Nuclear Thermal Propulsion (NTP) and Nuclear Electric Propulsion (NEP), explaining the operational mechanisms, benefits, and challenges of each. A significant portion of the book is dedicated to the engineering and technological aspects of these systems. It covers the design, development, and testing of nuclear reactors and propulsion units, emphasizing the importance of safety, reliability, and efficiency. The book also discusses the critical role of materials science in addressing the unique challenges posed by the space environment, such as extreme temperatures, radiation exposure, and the need for long-term durability. In addition to propulsion, the book explores nuclear power generation for spacecraft, including systems that provide electricity for onboard instruments, life support, and communication. It examines the integration of nuclear power systems with other spacecraft components, highlighting how these technologies enable long-duration missions to distant planets and beyond. "Space Nuclear Propulsion and Power" also considers the future of space exploration, discussing emerging technologies and potential advancements in nuclear systems that could further expand humanity's reach into the cosmos. It addresses the economic, environmental, and regulatory challenges associated with deploying nuclear technology in space, offering insights into how these obstacles might be overcome. This book is an essential resource for engineers, scientists, and students interested in the cutting-edge field of space nuclear technology, offering a thorough understanding of both current systems and future possibilities in space exploration.
Space Nuclear Propulsion and Power: Principles, Systems, and Applications Unlock the Future of Space Exploration Space Nuclear Propulsion and Power: Principles, Systems, and Applications is a vital text for students, practitioners, and industry professionals, offering a deep exploration of space nuclear propulsion and power systems. This extensive guide provides essential knowledge for understanding and advancing technologies that will propel humanity into space. In-depth Coverage of Cutting-Edge Technologies This book examines various propulsion systems, including chemical and nuclear thermal propulsion. It details the fundamentals of rocket propulsion, combustion dynamics, nozzle design, and critical calculations. Readers gain insights into practical considerations, such as high-speed exhaust gas generation and efficiency optimization. Advanced Mathematical Formulations and Real-World Examples To ensure practical application, the book includes real-world examples and detailed mathematical formulations, such as the Tsiolkovsky rocket equation, nuclear fission, radioactivity, and neutronics. These examples help readers understand and apply principles to their studies in space nuclear systems. The structured approach, combining theory with practical examples, makes complex concepts accessible and engaging. Innovative Power Solutions for Space Missions Beyond propulsion, the book explores radioisotope thermoelectric generators (RTGs) and nuclear reactors for powering spacecraft and lunar bases. RTGs, converting heat from radioisotope decay into electricity, have powered missions like Voyager, Cassini, and New Horizons. Nuclear reactors offer high power levels for propulsion and power generation, with detailed coverage of Nuclear Thermal Propulsion (NTP) and Nuclear Electric Propulsion (NEP). NTP systems use a nuclear reactor to heat hydrogen, producing thrust, while NEP systems generate electricity to power electric thrusters, ideal for deep space missions. Powering Lunar Bases and Mars Missions Nuclear technologies extend beyond space travel to lunar and Mars missions. Nuclear reactors provide robust power sources for habitats, scientific experiments, and resource extraction on the Moon and Mars. These environments make solar power less viable, especially for long-duration missions. Nuclear power supports life support systems, communication, and mobility, offering sustainable energy where sunlight is insufficient. Inspiration for Future Innovators Space Nuclear Propulsion and Power is more than a textbook; it challenges readers to think critically about the future of space exploration and the role of nuclear technology. Emphasizing theory and practice integration, the book inspires curiosity and innovation, encouraging contributions to ongoing design and development in this fascinating field. Join the Journey to the Stars Whether you are a student or a seasoned professional, Space Nuclear Propulsion and Power offers valuable insights and guidance. Engage with the material, challenge presented concepts, and join the community advancing technologies that will shape space exploration's future and our understanding of the universe. Embrace the journey into the unknown and unlock the potential of space nuclear propulsion and power with this definitive text. Welcome to an exploration of technologies propelling humanity to the stars.
From submarines to the suburbs—the remaking of Pittsburgh during the Cold War During the early Cold War, research facilities became ubiquitous features of suburbs across the United States. Pittsburgh’s eastern and southern suburbs hosted a constellation of such facilities that became the world’s leading center for the development of nuclear reactors for naval vessels and power plants. The segregated communities that surrounded these laboratories housed one of the largest concentrations of nuclear engineers and scientists on earth. In Nuclear Suburbs, Patrick Vitale uncovers how the suburbs shaped the everyday lives of these technology workers. Using oral histories, Vitale follows nuclear engineers and scientists throughout and beyond the Pittsburgh region to understand how the politics of technoscience and the Cold War were embedded in daily life. At the same time that research facilities moved to Pittsburgh’s suburbs, a coalition of business and political elites began an aggressive effort, called the Pittsburgh Renaissance, to renew the region. For Pittsburgh’s elite, laboratories and researchers became important symbols of the new Pittsburgh and its postindustrial economy. Nuclear Suburbs exposes how this coalition enrolled technology workers as allies in their remaking of the city. Offering lessons for the present day, Nuclear Suburbs shows how race, class, gender, and the production of urban and suburban space are fundamental to technoscientific networks, and explains how the “renewal” of industrial regions into centers of the tech economy is rooted in violence and injustice.
The Atomic Space Age has been and continues to be an engine for future wealth creation. Humanity stands on the verge of becoming an interplanetary species. We know we are made of star-stuff precisely because many of the isotopes in our bodies originated in the death throes of dying suns. With the discovery of nuclear fission in 1938, mankind was for the first time able to glimpse both our distant past and our possible future. As with the discovery of fire and agriculture thousands of years ago, wind power hundreds of years ago, and steam power and electricity in the nineteenth century, we must now learn to tame this powerful new force locked within the heart of the atom. Buckminster Fuller once observed that wealth is nothing more than energy compounded by ingenuity. Since (mass-)energy can never decrease, and ingenuity will only increase, there is no limit to the quantity of wealth that our species can and will create using nuclear space propulsion.
The advantages of space nuclear fission power systems can be summarized as: compact size; low to moderate mass; long operating lifetimes; the ability to operate in extremely hostile environments; operation independent of the distance from the Sun or of the orientation to the Sun; and high system reliability and autonomy. In fact, as power requirements approach the tens of kilowatts and megawatts, fission nuclear energy appears to be the only realistic power option. The building blocks for space nuclear fission electric power systems include the reactor as the heat source, power generation equipment to convert the thermal energy to electrical power, waste heat rejection radiators and shielding to protect the spacecraft payload. The power generation equipment can take the form of either static electrical conversion elements that have no moving parts (e.g., thermoelectric or thermionic) or dynamic conversion components (e.g., the Rankine, Brayton or Stirling cycle). The U.S. has only demonstrated in space, or even in full systems in a simulated ground environment, uranium-zirconium-hydride reactor power plants. These power plants were designed for a limited lifetime of one year and the mass of scaled up power plants would probably be unacceptable to meet future mission needs. Extensive development was performed on the liquid-metal cooled SP-100 power systems and components were well on their way to being tested in a relevant environment. A generic flight system design was completed for a seven year operating lifetime power plant, but not built or tested. The former USSR made extensive use of space reactors as a power source for radar ocean reconnaissance satellites. They launched some 31 missions using reactors with thermoelectric power conversion systems and two with thermionic converters. Current activities are centered on Fission Surface Power for lunar applications. Activities are concentrating on demonstrating component readiness. This book will discuss the components that make up a nuclear fission power system, the principal requirements and safety issues, various development programs, status of developments, and development issues.
At a time when no other country enjoys the advantages that the United States currently reaps from space, some U.S. officials argue that U.S. space defenses will be needed to protect access to critical military and civilian assets in orbit. Others argue that space should be a valuable "sanctuary" from deployed weapons and military conflict. To inform this debate—and develop meaningful guidelines for the future—Clay Moltz has undertaken the only comprehensive study of the first 50 years of space security, highlighting the main trends in military space developments, their underlying causes, and the factors that are likely to influence their future course. What emerges is a picture of surprising military restraint shown by the United States and the Soviet Union in space, and the inescapable conclusion that the only way forward is through a multilateral commitment to interdependent, environmentally focused space security.