Nuclear propulsion

Nuclear propulsion includes a wide variety of propulsion methods that fulfill the promise of the Atomic Age by using some form of nuclear reaction as their primary power source. The idea of using nuclear material for propulsion dates back to the beginning of the 20th century. In 1903 it was hypothesised that radioactive material, radium, might be a suitable fuel for engines to propel cars, boats, and planes.[1] H. G. Wells picked up this idea in his 1914 fiction work The World Set Free.[2]

Pressurised water reactors are the most common reactors used in ships and submarines. The pictorial diagram shows the operating principles. Primary coolant is in orange and the secondary coolant (steam and later feedwater) is in blue.

Surface ships, submarines, and torpedos

Nuclear-powered vessels are mainly military submarines, and aircraft carriers. Russia is the only country that currently has nuclear-powered civilian surface ships, most are icebreakers but one is a container ship. They use nuclear reactors as their power plants. For more detailed articles see:

Nuclear-powered submarine.

Civilian maritime use

Military maritime use

Torpedo

Russia's Channel One Television news broadcast a picture and details of a nuclear powered torpedo called Status-6 on about 12 November 2015. The torpedo was stated as having a range of up to 10,000 km, a cruising speed of 100 knots, and operational depth of up to 1000 metres below the surface. The torpedo carried a 100 megaton nuclear warhead.[3]

Aircraft and missiles

A picture of an Aircraft Nuclear Propulsion system, known as HTRE-3(Heat Transfer Reactor Experiment no. 3). The central EBR-1 based reactor, took the place of chemical fuel combustion to heat the air. The reactor rapidly raised the temperature via an air heat exchanger and powered the dual J47 engines in a number of ground tests.[4]

Research into nuclear-powered aircraft was pursued during the Cold War by the United States and the Soviet Union as they would presumably allow a country to keep nuclear bombers in the air for extremely long periods of time, a useful tactic for nuclear deterrence. Neither country created any operational nuclear aircraft. One design problem, never adequately solved, was the need for heavy shielding to protect the crew from radiation sickness. Since the advent of ICBMs in the 1960s the tactical advantage of such aircraft was greatly diminished and respective projects were cancelled. Because the technology was inherently dangerous it was not considered in non-military contexts.

Nuclear-powered missiles were also researched and discounted during the same period.

Spacecraft

Many types of nuclear propulsion have been proposed, and some of them (e.g. NERVA) tested for spacecraft applications.

Nuclear pulse propulsion

Nuclear thermal rocket

Bimodal Nuclear Thermal Rockets - conduct nuclear fission reactions similar to those employed at nuclear power plants including submarines. The energy is used to heat the liquid hydrogen propellant. The vehicle depicted is the "Copernicus" an upper stage assembly being designed for the Space Launch System (2010).

Ramjet

Direct nuclear

Nuclear electric

Russian Federal Space Agency development

Anatolij Perminov, head of the Russian Federal Space Agency, announced that it is going to develop a nuclear-powered spacecraft for deep space travel. Preliminary design was done by 2013, and 9 more years are planned for development (in space assembly). The price is set at 17 billion rubles (600 million dollars).[6] The nuclear propulsion would have mega-watt class,[7][8] provided necessary funding, Roscosmos Head stated.

This system would consist of a space nuclear power and the matrix of ion engines. "...Hot inert gas temperature of 1500 °C from the reactor turns turbines. The turbine turns the generator and compressor, which circulates the working fluid in a closed circuit. The working fluid is cooled in the radiator. The generator produces electricity for the same ion (plasma) engine..." [9]

According to him, the propulsion will be able to support human mission to Mars, with cosmonauts staying on the Red planet for 30 days. This journey to Mars with nuclear propulsion and a steady acceleration would take six weeks, instead of eight months by using chemical propulsion – assuming thrust of 300 times higher than that of chemical propulsion.[10][11]

Vehicles

Cars

The idea of making cars that used radioactive material, radium, for fuel dates back to at least 1903. Analysis of the concept in 1937 indicated that the driver of such a vehicle might need a 50 ton lead barrier to shield them from radiation.[12]

In 1941 Dr R M Langer, a CalTech physicist, espoused the idea of a car powered by uranium-235 in the January edition of Popular Mechanics. He was followed by William Bushnell Stout, designer of the Stout Scarab and former Society of Engineers president, on 7 August 1945 in the New York Times. The problem of shielding the reactor continued to render the idea impractical.[13] In December 1945, a John Wilson of London, announced he had created an atomic car. This created considerable interest. The Minister of Fuel and Power along with a large press contingent turned out to view it. The car did not show and Wilson claimed that it had been sabotaged. A later court case found that he was a fraud and there was no nuclear-powered car.[14][15]

Despite the shielding problem, through the late 1940s and early 1950s debate continued around the possibility of nuclear-powered cars. The development of nuclear-powered submarines and ships, and experiments to develop a nuclear-powered aircraft at that time kept the idea alive.[16] Russian papers in the mid-1950s reported the development of a nuclear-powered car by Professor V P Romadin, but again shielding proved to be a problem.[17] It was claimed that its laboratories had overcome the shielding problem with a new alloy that absorbed the rays.[18]

In 1958 at the height of the 1950s American automobile culture there were at least four theoretical nuclear-powered concept cars proposed, the American Ford Nucleon and Studebaker Packard Astral, as well as the French Simca Fulgur designed by Robert Opron[19][20] and the Arbel Symetric. Apart from these concept models, none were built and no automotive nuclear power plants ever made. Chrysler engineer C R Lewis had discounted the idea in 1957 because of estimates that an 80,000 lb (36,000 kg) engine would be required by a 3,000 lb (1,400 kg) car. His view was that an efficient means of storing energy was required for nuclear power to be practical.[21] Despite this, Chrysler's stylists in 1958 drew up some possible designs.

In 1959 it was reported that Goodyear Tire and Rubber Company had developed a new rubber compound that was light and absorbed radiation, obviating the need for heavy shielding. A reporter at the time considered it might make nuclear-powered cars and aircraft a possibility.[22]

Ford made another potentially nuclear-powered model in 1962 for the Seattle World's Fair, the Ford Seattle-ite XXI.[23][24] This also never went beyond the initial concept.

In 2009, for the hundredth anniversary of General Motors' acquisition of Cadillac, Loren Kulesus created concept art depicting a car powered by thorium.[25]

Other

The Chrysler TV-8 was an experimental concept tank designed by Chrysler in the 1950s. The tank was intended to be a nuclear-powered medium tank capable of land and amphibious warfare. The design was never mass-produced.[26] The Mars rover Curiosity is powered by a radioisotope thermoelectric generator (RTG), like the successful Viking 1 and Viking 2 Mars landers in 1976.[27][28]

See also

References

  1. Some practical uses of radium rays, The Republic, Sunday, September 13, 1903
  2. The new source of energy, The World Set Free, H G Wells, Collins, London and Glasgow, 1956 edition, page 55
  3. Russia reveals giant nuclear torpedo in state TV 'leak', BBC news, 12 November 2015 - retrieved 27 November 2015
  4. Thornton, G; Blumbeg, B. (January 1961). "Aircraft Nuclear Propulsion Heat Transfer Reactor Experiments Fulfill Test Goals". Nucleonics (McGraw-Hill) 19 (1). ISSN 0096-6207.
  5. Contact: Gynelle.C.Steele (July 15, 2005). "F-22 Raptor Stealth". NASA Glenn's Research & Technology. Retrieved 2009-07-08.
  6. Russians to ride a nuclear-powered spacecraft to Mars // 2009
  7. Page, Lewis (5 April 2011). "Russia, NASA to hold talks on nuclear-powered spacecraft. Muscovites have the balls but not the money". The Register. Retrieved 26 December 2013.
  8. "Interview: Academician Anatoly Koroteyev An Inside Look at Russia’s Nuclear Power Propulsion System" (PDF). 21st CENTURY. Fall/Winter 2012-2013. Retrieved 26 December 2013. Check date values in: |date= (help)
  9. (Russian) Academician Anatoly Koroteev: "Nuclear power can provide a qualitative leap in the development of space"
  10. Space Propulsion for Martian Mission may be Developed in 6-9 Years
  11. Russia Leads Nuclear Space Race After U.S. Drops Out
  12. The Science Review, Issues 1-12, University of Melbourne Science Club, Melbourne University, 1937, page 22
  13. Automobile Quarterly, Volume 31 Number 1, 1992, pages 14-29
  14. First Atomic Car "sabotaged", Townsville Daily Bulletin, Queensland, Australia, Monday 3 December 1945 page 2
  15. "Atomic Car" hoax - Elderly inventor gets goal sentence, Cairns Post, Queensland Australia, Monday 22 July 1946, page 3
  16. "Benson Ford poses challenge on atomic powered automobiles". The Brooklyn Daily Eagle. October 2, 1951. p. 3. Retrieved June 4, 2015 via Newspapers.com.
  17. Reading Eagle, Sunday, February 20, 1955, page 8
  18. Atom-powered Automobile Claimed Russian, The victoria Advocate, Victoria, Texas, Sunday, January 30, 1955, page 7
  19. "Radioactive cars of the twentieth century". Retrieved 26 April 2012.
  20. "Une anticipation Simca : la "fulgur"" (in French). Retrieved 26 April 2012.
  21. The Atom powered car, Popular Mechanics, April 1957, page 141
  22. Advent of Atom Powered Plane Speeded, Ray Cromley, The Victoria Advocate, Victoria, Texas, Wednesday, June 24, 1959, page 4
  23. Hanlon, Mike. "Ford Seattle-ite: one of history's most significant concept cars". Gizmag.com. Retrieved 26 April 2012.
  24. "1962 Ford Seattle-ite XXI". Retrieved 26 April 2012.
  25. WTF? Cadillac World Thorium Fuel Concept?
  26. Hunnicutt 1990, p. 36.
  27. "Multi-Mission Radioisotope Thermoelectric Generator" (PDF). NASA/JPL. January 1, 2008. Retrieved August 6, 2012.
  28. "Mars Exploration: Radioisotope Power and Heating for Mars Surface Exploration" (PDF). NASA/JPL. April 18, 2006. Retrieved September 7, 2009.

Further reading

External links

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