Proton (satellite program)

*Proton 1*,2,3,and4
	A Proton satellite
Mission type	Astronomy
Operator	Soviet Union
COSPAR ID	1965-054A (Proton 1); 1965-087A (Proton 2); 1966-060A (Proton 3); 1968-103A (Proton 4);
Spacecraft properties
Manufacturer	OKB-52
Launch mass	12,200 kg (26,900 lb) (Proton 1); 12,200 kg (26,900 lb) (Proton 2); 12,200 kg (26,900 lb) (Proton 3); 17,000 kg (37,000 lb) (Proton 4);
Start of mission
Launch date	Proton 1:16 July 1965 11:16UTC; Proton 2:2 November 1965 12:28UTC; Proton 3:6 July 1966 12:57UTC; Proton 4:16 November 1968 11:40UTC;
Rocket	UR-500(1–3),Proton-K(4)
Launch site	Baikonur Cosmodrome Site 81/23(1–3),Baikonur Cosmodrome Site 81/24(4)
End of mission
Disposal	De-orbited
Decay date	Proton 1:11 October 1965; Proton 2:6 February 1966; Proton 3:6 September 1966; Proton 4:24 July 1969;
Orbital parameters
Reference system	Geocentric
Eccentricity	.030 (1–3),.017 (4)
Perigee altitude	Proton 1:183 kilometres (114 mi); Proton 2:189 kilometres (117 mi); Proton 3:185 kilometres (115 mi); Proton 4:248 kilometres (154 mi);
Apogee altitude	Proton 1:589 kilometres (366 mi); Proton 2:608 kilometres (378 mi); Proton 3:585 kilometres (364 mi); Proton 4:477 kilometres (296 mi);
Inclination	63.5° (1–3), 31.5° (4)
Period	~92 minutes (1–4)

Proton(Russian:протон) ('proton') was a Soviet series of four cosmic ray and elementary particle detecting satellites. Orbited 1965–68, three on test flights of theUR-500 ICBMand one on aProton-Krocket, all four satellites completed their missions successfully, the last reentering the Earth's atmosphere in 1969.

Background

The Proton satellites were heavy automated laboratories launched 1965–68 to study high energy particles and cosmic rays.^[5]These satellites were built to utilize the test launches of theUR-500,a heavy two-stageICBMdesigned byVladimir Chelomey's OKB-52to carry a 100-megaton nuclear payload. Each Proton was housed in a purpose-built third stage added to the UR-500 stack.^[6]

Spacecraft design

Protons 1–3 were largely identical craft massing 12,200 kg (26,900 lb), with scientific packages developed under the supervision of Academician Sergey Nikolayevich Vernov ofMoscow State University's Scientific-Research Institute of Nuclear Physics.^[6]Experiments included agamma-raytelescope, ascintillator telescope,andproportional counters.^[7]The counters were able to determine the total energy of each super-high energy cosmic particle individually, a capability no prior satellite had possessed. Though the equipment had been developed eight years earlier (by Professor N. L. Grigorov), the UR-500 was the first booster powerful enough to orbit a satellite carrying the sensitive particle counter.^[8]The counters could measure cosmic rays with energy levels up to 100 millioneV.^[9]

Proton 3 also was equipped with agas-Cerenkov-scintillatortelescope^[10]to attempt to detect the newly postulated fundamental particle, thequark.The entire experiment package massed 4,000 kg (8,800 lb) and was composed of metal, plastic, and paraffin blocks.^[9]

Telemetrywas relayed via a 19.910MHzbeacon. Four solar panels powered the crafts, which were cooled by heat exchangers. The Protons were spin-stabilized, theirattitudecontrolled by jet and an on-board dampener. Satellite systems were controlled by an internal computer.^[7]

Proton 4 was considerably more massive at 17,000 kg (37,000 lb). Its primary instrument was an ionization calorimeter composed of steel bars and plastic scintillators. A measuring device comprising one lump of carbon and another of polyethylene^[9]provided data on cosmic rays and the energy spectrum in orbit, the possible collisions of cosmic ray particles with atmospheric nuclei of hydrogen, carbon, and iron, and continued the search for the quark.^[4]

Missions

Proton 1

Proton 1 was launched into Earth orbit 16 July 1965 11:16 UTC fromBaikonur Cosmodrome Site 81/23,^[11]though the launch was threatened by a leak in the oxidizer pipeline resulting in nitrogen tetroxide spilling on electrical wires. Early in the flight, launch specialists only received signals indicating that the satellite was functioning. Eventually, however, Proton 1 performed normally, returning physics data on ultra-high-energy cosmic particles. Its mission lasted 45 days,^[5]and the satellite reentered Earth's atmosphere 11 October 1965.^[12]

Proton 2

The virtually identical Proton 2 was launched 2 November 1965 12:28 UTC, also from Baikonur Cosmodrome Site 81/23.^[11]It reentered Earth's atmosphere on 6 February 1966.^[12]At the time of their launch, American experts believed the first Protons were experimental space station components due to their weight and the Soviet use of the word "station" in describing the observatory satellites.^[13]^[14]

Proton 3

After an unsuccessful launch of the third test UR-500 on 24 March 1966 14:39 UTC, Proton 3 was successfully launched into Earth orbit from Baikonur Cosmodrome Site 81/23 on 6 July 1966 12:57 UTC^[11]on the fourth and final UR-500 test flight^[5]and began searching for quarks and other elementary particles of fractional electron charge.^[9]The satellite returned data for most, if not all, of its short time in orbit,^[16]reentering Earth's atmosphere on 16 September 1966.^[12]Shortly before reentry, Proton 3 was observed tumbling once per second over theIndian Oceanby the crew ofGemini 11.^[17]

Proton 4

After the end of the run of UR-500 test launches, the rocket (now designated Proton) and its successors were largely employed in the launch of theZondlunar spacecraft. However, on 16 November 1968 11:40 UTC, the final and much larger Proton 4 was launched into orbit viaProton-Krocket fromBaikonur Cosmodrome Site 81/24to continue the search for the quark and supplement the earlier Proton satellites' cosmic ray measurements.^[9]This final Proton reentered Earth's atmosphere on 24 July 1969.^[12]

Legacy

The Proton satellites were heralded by Soviet media as the start of a new stage in Soviet space exploration.^[18]The success of Proton afforded Chelomey a status in the Soviet rocket industry equal to that ofSergei KorolevofOKB-1(developer ofSputnik,Vostok,andVoskhod) andMikhail YangelofOKB-456(an important designer of military missiles). The UR-500, originally named "Gerkules" (Russian:Геркулес) ('Hercules'), was renamed "Proton" when news reports conflated the launcher and its payload. Though the Proton was never used in the ICBM role it had been built for, the rocket became an extraordinarily successful booster for commercial satellites, serving well into the 1990s.^[18]

References

^"Proton 1".NASA Space Science Data Coordinated Archive.Retrieved23 October2020.
^"Proton 2".NASA Space Science Data Coordinated Archive.Retrieved23 October2020.
^"Proton 3".NASA Space Science Data Coordinated Archive.Retrieved23 October2020.
^^a ^b"Proton 4".NASA Space Science Data Coordinated Archive.Retrieved23 October2020.
^^a ^b ^cWade, Mark."UR-500".Archived fromthe originalon 26 October 2020.Retrieved23 October2020.
^^a ^bChertok, Boris (2011).Rockets and People. Volume IV, The Moon Race.Washington D.C.: NASA. p. 21.OCLC 775599532.
^^a ^bWilliam R. Corliss (1967).Scientific Satellites.Washington D.C.: Science and Technical Information Division, Office of Technology Utilization, National Aeronautics and Space Administration. pp. 779–780.
^"Aeronautics and Astronautics, 1965"(PDF).NASA. p. 342.Retrieved24 April2020.
^^a ^b ^c ^d ^eHart, Douglas M. (1987).The Encyclopedia of Soviet Spacecraft.New York: Exeter Books. pp. 82–83.OCLC 17249881.
^Akimov, V. V.; Grigorov, N. L.; Nesterov, V. E.; Rapoport, I. D.; Savenko, I. A.; Skuridin, G. A.; Titenkov, A. F. (1970)."Measurements of the primary cosmic ray spectra in the 1011-1014 eV energy range from Proton-1, 2, 3 satellites".Proceedings of the 11th International Conference on Cosmic Rays, held in Budapest, 25 August – 4 September 1969.1:517–520.Bibcode:1970ICRC....1..517A.
^^a ^b ^cMcDowell, Jonathan."Launch Log".Jonathon's Space Report.Retrieved30 December2018.
^^a ^b ^c ^dMcDowell, Jonathan."Satellite Catalog".Jonathon's Space Report.Retrieved23 October2020.
^"News Digest (Soviets launched)".Aviation Week and Space Technology.New York: McGraw Hill Publishing Company. 8 November 1965.Retrieved23 October2020.
^"Aeronautics and Astronautics, 1965"(PDF).NASA. p. 333.Retrieved24 April2020.
^Bruce S. Maccabee (August 2000)."Gemini 11 UFO".
^"Aeronautics and Astronautics, 1966"(PDF).NASA. p. 285.Retrieved26 August2021.
^"Gemini 11 Demonstrates Pilot Capabilities".Aviation Week and Space Technology.New York: McGraw Hill Publishing Company. 19 September 1966. p. 27.Retrieved25 August2021.
^^a ^bAsif A. Siddiqi.Challenge to Apollo: The Soviet Union and the Space Race, 1945–1974(PDF).Washington D.C.: NASA. p. 339-440, 967, 971.OCLC 1001823253.

External links

The history of "NPO Mashinostroyenia"
The INCA Project,Ionization-Neutron CAlorimeter – a modern continuation of Proton experiment project atInstitute for Nuclear ResearchofRussian Academy of Scienceswebsite^{[dead link]}

[nssdc1-1] "Proton 1".NASA Space Science Data Coordinated Archive.Retrieved23 October2020.

[nssdc2-2] "Proton 2".NASA Space Science Data Coordinated Archive.Retrieved23 October2020.

[nssdc3-3] "Proton 3".NASA Space Science Data Coordinated Archive.Retrieved23 October2020.

[nssdc4-4] "Proton 4".NASA Space Science Data Coordinated Archive.Retrieved23 October2020.

[astro-5] Wade, Mark."UR-500".Archived fromthe originalon 26 October 2020.Retrieved23 October2020.

[rop-6] Chertok, Boris (2011).Rockets and People. Volume IV, The Moon Race.Washington D.C.: NASA. p. 21.OCLC 775599532.

[SP-133-7] William R. Corliss (1967).Scientific Satellites.Washington D.C.: Science and Technical Information Division, Office of Technology Utilization, National Aeronautics and Space Administration. pp. 779–780.

[aa1965-8] "Aeronautics and Astronautics, 1965"(PDF).NASA. p. 342.Retrieved24 April2020.

[sov-9] Hart, Douglas M. (1987).The Encyclopedia of Soviet Spacecraft.New York: Exeter Books. pp. 82–83.OCLC 17249881.

[meas-10] Akimov, V. V.; Grigorov, N. L.; Nesterov, V. E.; Rapoport, I. D.; Savenko, I. A.; Skuridin, G. A.; Titenkov, A. F. (1970)."Measurements of the primary cosmic ray spectra in the 1011-1014 eV energy range from Proton-1, 2, 3 satellites".Proceedings of the 11th International Conference on Cosmic Rays, held in Budapest, 25 August – 4 September 1969.1:517–520.Bibcode:1970ICRC....1..517A.

[log-11] McDowell, Jonathan."Launch Log".Jonathon's Space Report.Retrieved30 December2018.

[cat-12] McDowell, Jonathan."Satellite Catalog".Jonathon's Space Report.Retrieved23 October2020.

[avweek1965d-13] "News Digest (Soviets launched)".Aviation Week and Space Technology.New York: McGraw Hill Publishing Company. 8 November 1965.Retrieved23 October2020.

[aa1965a-14] "Aeronautics and Astronautics, 1965"(PDF).NASA. p. 333.Retrieved24 April2020.

[macc-15] Bruce S. Maccabee (August 2000)."Gemini 11 UFO".

[aa1966-16] "Aeronautics and Astronautics, 1966"(PDF).NASA. p. 285.Retrieved26 August2021.

[avweek1966-17] "Gemini 11 Demonstrates Pilot Capabilities".Aviation Week and Space Technology.New York: McGraw Hill Publishing Company. 19 September 1966. p. 27.Retrieved25 August2021.

[challenge-18] Asif A. Siddiqi.Challenge to Apollo: The Soviet Union and the Space Race, 1945–1974(PDF).Washington D.C.: NASA. p. 339-440, 967, 971.OCLC 1001823253.

[1]

[2]

[3]

[4]

[5]

[6]

[7]

[8]

[9]

[10]

[11]

[12]

[13]

[14]

[15]

[16]

[17]

[18]

v t e ← 1965 Orbital launches in1966 1967 →
January	Kosmos 104 OPS 2394 OPS 7253 OPS 3179 Kosmos 105 Kosmos 106 OPS 1593 Luna 9
February	OPS 7291 ESSA-1 OPS 1439 Kosmos 107 Kosmos 108 OPS 1184 OPS 3011 OPS 3031 Dipason Kosmos 109 DS-K-40 No.2 Kosmos 110 ESSA-2
March	Kosmos 111 OPS 3488 GATV-5003 Gemini VIII Kosmos 112 OPS 0879 OPS 0974 Kosmos 113 N-4 No.3 OPS 1117 Molniya-1 No.5 OV1-4 OV1-5 OPS 0340 Luna 10
April	Kosmos 114 OPS 1612 Surveyor SD-3 OAO-1 OPS 0910 Kosmos 115 OV3-1 Molniya 1-03 Kosmos 116
May	OPS 1508 Kosmos 117 Kosmos 118 OPS 1950 OPS 6785 Nimbus 2 Zenit-4 GATV-5004 OPS 0082 OPS 1788 Kosmos 119 Explorer 32 Surveyor 1
June	ATDA Gemini IX-A OPS 1577 OPS 1856 OGO-3 Kosmos 120 OV3-4 FTV-1351 Secor 6 ERS-16 OPS 9311 OPS 9312 OPS 9313 OPS 9314 OPS 9315 OPS 9316 OPS 9317 GGTS Kosmos 121 OPS 1599 PAGEOS Kosmos 122
July	Explorer 33 AS-203 Proton 3 Kosmos 123 OPS 1850 OV1-7 OV1-8 Kosmos 124 GATV-5005 Gemini X Kosmos 125 Kosmos 126 OPS 3014
August	OV3-3 Kosmos 127 OPS 1545 Lunar Orbiter 1 OPS 1832 OPS 6810 Pioneer 7 OPS 2366 FTV-1352 Secor 7 ERS-15 Luna 11 IDSCP 1 IDSCP 2 IDSCP 3 IDSCP 4 IDSCP 5 IDSCP 6 IDSCP 7 GGTS Kosmos 128
September	GATV-5006 Gemini XI OPS 6026 OPS 1686 OPS 6874 Zenit-2 No.40 OPS 6026 OPS 1686 OPS 6874 OGCh No.05L Surveyor 2 OPS 1703 Ōsumi 1 OPS 4096
October	ESSA-3 FTV-1583 Secor 8 OPS 2055 OPS 5345 Kosmos 129 Molniya 1-04 Kosmos 130 Luna 12 Surveyor SM-3 Intelsat II F-1 OV3-2
November	OGCh No.06L OPS 2070 OPS 5424 OPS 0855 OV4-1R OV4-1T OV1-6 Lunar Orbiter 2 OPS 1866 GATV-5001A Gemini XII Kosmos 131 Strela-2 No.1 Kosmos 132 Kosmos 133
December	Kosmos 134 OPS 1890 ATS-1 OV1-9 OV1-10 Kosmos 135 Soyuz 7K-OK No.1 OPS 8968 Biosatellite 1 Kosmos 136 Ōsumi 2 Kosmos 137 Luna 13 OPS 1584
Launches are separated by dots ( • ), payloads by commas (, ), multiple names for the same satellite by slashes ( / ). Crewed flightsare underlined. Launch failures are marked with the † sign. Payloads deployed from other spacecraft are (enclosed in parentheses).