BES-5 reactor
BES-5 type reactor
GenerationExperimental
Reactor conceptUnknown
Status~29 units in earth orbit
Main parameters of the reactor core
Fuel (fissile material)235U
Fuel state37 solid cylinders
Neutron energy spectrumFast
Primary control methodsix rods, BC
2
with LiH inserts
Neutron reflectorBeryllium
Primary coolantNaK
Reactor usage
Primary useUS-A satellites
Power (thermal)100 kW
Power (electric)1.3–5 kW

BES-5, also known as Bouk or Buk (Russian: бук, lit.'beech'), was a Soviet thermoelectric generator that was used to power 31 satellites in the US-A (RORSAT) project. The heat source was a uranium 235 fast fission nuclear reactor (FNR).

Background

Spacecraft nuclear reactors are typically fast reactors for the following reasons. First, normal moderator materials (carbon, water) add bulk and mass which is not desirable in a spacecraft. Second, for reasons of nucleonics the fuel must be highly enriched to have a lightweight critical mass (similar to small reactor designs on nuclear submarines). Note that some of the 238U (which is fertile and not fissile) will be converted to 239Pu during operation, and this is taken into consideration during the design and while estimating the power output and design life expectancy.

Reactor design

The design of the BES-5 FNR is such that a sub-critical assembly exists into which a rod of fissile material is inserted. Feedback and monitoring of the power level will keep the reactor delayed critical and not prompt critical, which can be done by a mechanical control system.

The fuel core of the reactor was 0.24 m in diameter, 0.67 m long and weighed, as an assembly, 53 kg,[1][2] and contained 35–50 kg of enriched uranium. The entire reactor, including the radiation shielding, weighed 385 kg.

The uranium fuel was more than 90% enriched 235U [3] and generated 3 kW of electrical power[4] created by thermoelectric conversion of 100 kW of thermal output.

Use in space

The BES-5 reactor was used in more than 31 satellite missions to power the radar units of the US-A surveillance satellites. The reactor was designed to be boosted to a high orbit at the end of its operational life, to prevent the radioactive fuel from re-entering Earth's atmosphere.

There were several mishaps related to failures in the ejection system, most notably Kosmos 954, which scattered debris over Canada. Kosmos 1402 also re-entered the atmosphere, but burned up over the Atlantic Ocean, away from populated areas. Kosmos 1900 failed to reach its disposal orbit, and remains in low Earth orbit.

See also

References

  1. Special illustrated presentation by the delegation of the Russian Federation at the XXXIII session of the scientific and technical subcommittee of COPOUS on collisions of nuclear power sources with space debris, Vienna, February 16, 1996
  2. "The US-A program (Radar Ocean Reconnaissance Satellites)".
  3. G.M. Gryaznov, V.S. Nikolayev, V.I. Serbin, V.M. Tyugin, "Radiation safety of the space nuclear power systems and its realization on the satellite Cosmos-1900", Chapter 45 of the book Space Nuclear Power Systems 1989, Orbit Book Company, Malabar, Florida 1992,
  4. A.V Zrodnikov, V.Y Poupko, G.M. Gryaznov, "Experimental detection of neutron gas pressure on the control rods of a nuclear reactor under microgravity conditions", Proceedings of 11 th symposium on space nuclear power and propulsion, January 9–13, 1994, Albuquerque, American Institute of Physics, new York, 1994.
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