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Developments of America's first heavy lift space rocket Saturn I, the Saturn IB and Saturn V propelled America's space program during the Apollo and Skylab eras. First launched in 1966, Saturn IB replaced the Saturn I's S-IV second stage with the more powerful S-IVB. It could carry a partially fueled Apollo Command / Service Module or fully fueled Lunar Module into low Earth orbit, allowing critical testing of these systems to be conducted long before the Saturn V was ready. It also flew one orbital mission without a payload, with the extra fuel used to demonstrate that the S-IVB's J-2 engine could be restarted in zero gravity - a critical operation for translunar injection. The Saturn IB produced thrust equivalent to 1.6 million pounds force, and could carry 46,000 pounds of payload to low Earth orbit. Saturn IB flew nine times, including three Skylab missions and for the Apollo-Soyuz Test Project. Saturn V was simply the heaviest, tallest, and most powerful rocket ever built, and capable of carrying the heaviest payload. First launched in 1967, the rocket consisted of three stages, with the S-IVB serving as its third stage. Taller than the Statue of Liberty, Saturn V had a mass of 3000 metric tons and five F-1 engines capable of producing thrust thrust of 7.6 million pounds-force. It could take payloads up to 100,000 pounds beyond Earth orbit or 262,000 pounds into low Earth orbit. It flew thirteen times, including eight times to the moon and (in a two-stage version) on the Skylab I mission. Originally prepared by the Missile and Space Systems Division of NASA contractor Douglas Aircraft, this book was created to acquaint payload planners with the capabilities of the Saturn IB and Saturn V rockets. It shows methods by which Saturn vehicles can accommodate payloads of various weights and volumes for different missions, and methods by which they might be modified to allow even greater performance. It's a wonderful reference for the museum docent, researcher, or anyone who ever wondered how these mighty rockets were designed and built.
Developments of America's first heavy lift space rocket Saturn I, the Saturn IB and Saturn V propelled America's space program during the Apollo and Skylab eras. First launched in 1966, Saturn IB replaced the Saturn I's S-IV second stage with the more powerful S-IVB. It could carry a partially fueled Apollo Command / Service Module or fully fueled Lunar Module into low Earth orbit, allowing critical testing of these systems to be conducted long before the Saturn V was ready. It also flew one orbital mission without a payload, with the extra fuel used to demonstrate that the S-IVB's J-2 engine could be restarted in zero gravity - a critical operation for translunar injection. The Saturn IB produced thrust equivalent to 1.6 million pounds force, and could carry 46,000 pounds of payload to low Earth orbit. Saturn IB flew nine times, including three Skylab missions and for the Apollo-Soyuz Test Project. Saturn V was simply the heaviest, tallest, and most powerful rocket ever built, and capable of carrying the heaviest payload. First launched in 1967, the rocket consisted of three stages, with the S-IVB serving as its third stage. Taller than the Statue of Liberty, Saturn V had a mass of 3000 metric tons and five F-1 engines capable of producing thrust thrust of 7.6 million pounds-force. It could take payloads up to 100,000 pounds beyond Earth orbit or 262,000 pounds into low Earth orbit. It flew thirteen times, including eight times to the moon and (in a two-stage version) on the Skylab I mission. Originally prepared by the Missile and Space Systems Division of NASA contractor Douglas Aircraft, this book was created to acquaint payload planners with the capabilities of the Saturn IB and Saturn V rockets. It shows methods by which Saturn vehicles can accommodate payloads of various weights and volumes for different missions, and methods by which they might be modified to allow even greater performance. It's a wonderful reference for the museum docent, researcher, or anyone who ever wondered how these mighty rockets were designed and built.
Designed by Wernher von Braun and Arthur Rudolph at NASA's Marshall Space Flight Center, the Saturn V rocket represents the pinnacle of 20th Century technological achievement. The only launch vehicle in history to transport astronauts beyond Low Earth Orbit, the Saturn V delivered 24 men to the moon. To this day it holds records as the tallest (363 feet), heaviest (nearly 7 million lbs.) and most powerful (over 7.6 million pounds-force of thrust) launch vehicle ever produced. It also remains one of the most reliable, achieving 12 successful launches with one partial failure - the unmanned Apollo 6 which suffered vibration damage on lift-off, resulting in a sub-standard orbit. The Saturn series of rockets resulted from Von Braun's work on the German V-2 and Jupiter series rockets. The Saturn I, a 2-stage liquid-fueled rocket, flew ten times between 1961 and 1965. A uprated version the 1B carried the first crewed Apollo flight into orbit in 1968. The Saturn V, which first flew in 1967, was a three-stage rocket. The first stage, which burned RP-1 and LOX, consisted of five F-1 engines. The second stage used five J-2 engines which burned LOX and liquid hydrogen (LH2). The third stage, based on the second stage of the Saturn 1B, carried a single J-2. The Saturn V could carry up to 262,000 pounds to Low Earth Orbit and more critically, 100,000 pounds to the Moon. Created by NASA as a single-source reference as to the characteristics and functions of the Saturn V, this manual was standard issue to the astronauts of the Apollo and Skylab eras. It contains information about the Saturn V system, range safety and instrumentation, monitoring and control, prelaunch events, and pogo oscillations. It provides a fascinating overview of the rocket that made "one giant leap for mankind" possible.
In January 2004 NASA was given a new policy direction known as the Vision for Space Exploration. That plan, now renamed the United States Space Exploration Policy, called for sending human and robotic missions to the Moon, Mars, and beyond. In 2005 NASA outlined how to conduct the first steps in implementing this policy and began the development of a new human-carrying spacecraft known as Orion, the lunar lander known as Altair, and the launch vehicles Ares I and Ares V. Collectively, these are called the Constellation System. In November 2007 NASA asked the National Research Council (NRC) to evaluate the potential for new science opportunities enabled by the Constellation System of rockets and spacecraft. The NRC committee evaluated a total of 17 mission concepts for future space science missions. Of those, the committee determined that 12 would benefit from the Constellation System and five would not. This book presents the committee's findings and recommendations, including cost estimates, a review of the technical feasibility of each mission, and identification of the missions most deserving of future study.
This illustrated history by a trio of experts is the definitive reference on the Apollo spacecraft and lunar modules. It traces the vehicles' design, development, and operation in space. More than 100 photographs and illustrations.
Embark on an exhilarating adventure in science fiction with "Edison's Conquest of Mars" by Garrett Putman Serviss. In this groundbreaking novel, the brilliant inventor Thomas Edison leads an audacious expedition to the Red Planet, blending the realms of science and imagination in an epic tale of exploration and innovation. Set in the early 20th century, Serviss’s narrative captures the spirit of discovery and the quest for knowledge that defined an era. Join Edison and his team as they navigate the challenges of interplanetary travel, encountering alien civilizations, mysterious landscapes, and thrilling challenges that test their ingenuity and resolve. Through a captivating blend of adventure, technology, and philosophical exploration, this novel not only entertains but also sparks the imagination, reflecting the hopes and dreams of a society on the brink of a new age of discovery. Serviss's visionary work serves as a tribute to Edison's legacy and the power of human innovation. As the characters confront the unknown, readers will be drawn into a world where the limits of science are pushed, and the possibilities of the universe are explored. With rich descriptions and engaging dialogue, Serviss invites you to ponder the implications of progress and the future of humanity. Are you ready to join Edison on his quest for knowledge and adventure among the stars? Don’t miss the chance to experience "Edison's Conquest of Mars" and explore the wonders of the universe through the eyes of one of history's greatest inventors. Order your copy today and get ready for an unforgettable journey!
The official record of America's first space station, this book from the NASA History Series chronicles the Skylab program from its planning during the 1960s through its 1973 launch and 1979 conclusion. Definitive accounts examine the project's achievements as well as its use of discoveries and technology developed during the Apollo program. 1983 edition.
Thousands of workers labored at Kennedy Space Center around the clock, seven days a week, for half a year to prepare a mission for the liftoff of Apollo 11. This is the story of what went on during those hectic six months. Countdown to a Moon Launch provides an in-depth look at the carefully choreographed workflow for an Apollo mission at KSC. Using the Apollo 11 mission as an example, readers will learn what went on day by day to transform partially completed stages and crates of parts into a ready-to-fly Saturn V. Firsthand accounts of launch pad accidents, near misses, suspected sabotage, and last-minute changes to hardware are told by more than 70 NASA employees and its contractors. A companion to Rocket Ranch, it includes many diagrams and photographs, some never before published, to illustrate all aspects of the process. NASA’s groundbreaking use of computers for testing and advanced management techniques are also covered in detail. This book will demystify the question of how NASA could build and launch Apollo missions using 1960s technology. You’ll discover that there was no magic involved – just an abundance of discipline, willpower, and creativity.