Credit: Khrunichev. 14,138 bytes. 351 x 190 pixels.
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| Buran missile - M-42 and M-44 Buran trisonic ramjet missiles were considered in both manned and unmanned versions. Credit: Khrunichev. 14,138 bytes. 351 x 190 pixels. |
A government decree on 20 May 1954 authorised the Myasishchev aircraft design bureau to proceed with full-scale development of the Buran trisonic intercontinental cruise missile. The competing Burya design of Lavochkin was launched in July 1957, but the development of unstoppable ICBM's had made intercontinntal cruise missiles oboslete. The equivalent American Navaho project was cancelled ten days later. Korolev's R-7 ICBM completed its first successful test flight in August. Buran was being prepared for its first flight when Myasishchev's project was cancelled on November 1957.
A final government decree on 20 May 1954 authorised the Lavochkin and Myasishchev aircraft design bureaux to proceed in parallel with full-scale development of trisonic intercontinental cruise missiles. Both missiles would use ramjet engines by Bondaryuk, astronavigation systems by R Chachikyan, inertial navigation systems by G Tolstoysov, and aerodynamics developed by TsAGI (Central Hydrodynamics Institute). Myasishchev's Buran would use rocket booster engines built by Glushko. While both missiles were to deliver a nuclear warhead over an 8,500 km range, rhe warhead design specified for the Myasishchev missile had a total mass of 3,500 kg, two thirds heavier than that specified for the Lavochkin.
The TsAGI configuration for the cruise stage was of conventional layout, with a thin profile 70 degree swept arrow wing mounted at mid-fuselage. The fuselage itself was cylindrical and area-ruled, with the classic ramjet shock cone in a nose intake. The astronavigation and guidance systems were mounted in a dorsal fairing. The star scanners of the system looked out through quartz windows.
Myasishchev had began work in April 1953, before the official authorisation, on his RSS-40 (RSS= rocket-aircraft system), code-named Buran (snowstorm). The RSS-40 would consist of two stages, a four-rocket boost stage (the M-41) and a ramjet cruise stage (the M-42). The RSS-40 would be launched vertically from an ingenious transporter-launcher, designed by V K Karrask. The RSS-40 was 24 m long, had an 11.6 m wingspan, a total mass of 125 tonnes, and cruised at 3000 to 3200 km/hr. The ramjet intake cone was canted 3 degrees downward, which represented the pitch angle of the missile in cruise.
Several variants of the Myasishchev M-42 cruise stage were studied. Some were related to improving the missile guidance, including an auxiliary communications package for providing en-route navigation and targeting updates, as was planned for the competing Burya. Another laid out a piloted version, with a cockpit installed in the cruise stage. The pilot would eject and be recovered by parachute at the conclusion of the mission. Myasishchev planned several manned flights to explore the psychology of human flight on the edge of space.
 | Buran missile Credit: © Mark Wade. 2,517 bytes. 183 x 376 pixels. |
Liftoff Thrust: 219,850 kgf. Total Mass: 125,000 kg. Core Diameter: 2.4 m. Total Length: 28.0 m.
German aerodynamicist Albring designed the G-3 missile for the Russians. This would use a rocket-powered Groettrup-designed G-1 as the first stage. The cruise stage would have an aerodynamic layout like that of the Saenger-Bredt rocket-powered antipodal bomber of World War II. Cruising at 13 km altitude, the supersonic missile would carry a 3000 kg warhead to a range of 2900 km. This was an alternate approach to Ustinov's 3000 kg over 3000 km range missile requirement of April 1949. This design would be elaborated at Korolev's bureau into the EKR ramjet design of 1953.
 | Navaho vs Burya Credit: © Mark Wade. 10,772 bytes. 530 x 475 pixels. |
The NTS (Scientific-Technical Soviet) of NII-88 met in plenary session and subjected Korolev's proposal to withering criticism. The G-4 was found to be superior. After heated discussion, the Soviet approved further development of technology for the R-3, but not the missile itself. The decisions were: an R-3A technology demonstrator would be built and flown under Project N-1 (probably to prove G-4 concepts). Under Project N-2 both the RD-110 and D-2 engines would proceed into development test in order to prove Lox/Kerosene propellant technology. Packet rocket and lightweight structure research for use in an ICBM would continue under project N-3 / T-1. Winged intercontinental cruise missile studies would continue under project N-3 / T-2. Neither the G-4 or R-3 ended up in production, but the design concepts of the G-4 led directly to Korolev's R-7 ICBM (essentially a cluster of G-4's or R-3A's) and the N1 superbooster. Work on the G-4 continued through 1952.
In parallel with the R-5 Korolev OKB NII-88 begins design of 8,000 km range winged missile.
Council of Soviet Ministers (SM) Decree 'On themes N1, N2, and N3 in the ballistic missile program.' was issued.
Myasishchev was tasked with building an intercontinental jet-powered bomber, something veteran aircraft designer Tupolev said was impossible. Myasishchev managed to complete the first prototype 103M (called M-4 Bear in the West) bomber ten months after go-ahead. Myasishchev would later play a key role in Soviet spaceplane development.
 | Buran Missile 2 view Credit: © Mark Wade. 4,428 bytes. 326 x 384 pixels. |
In 1951 to 1953 Korolev's design bureau had prepared an experimental trisonic ramjet design, the EKR.The expert commission ifelt that there were still many technical problems to be solved, most of which were better handled by an aircraft designer rather than Korolev. Further, Korolev had to place the highest priority on development of the R-7 ICBM. Therefore a final government decree on 20 May 1954 authorised the Lavochkin and Myasishchev aircraft design bureaux to proceed in parallel with full-scale development of trisonic intercontinental cruise missiles.
Informal go-ahead was given for Korolev to start design work on the R-7. In parallel, Myasishchev OKB-23 and Lavochkin OKB-301 began design of intercontinental ramjet cruise missiles.
Council of Soviet Ministers (SM) Decree 'On selection of launch area for the R-7, 40 Buran, and 350 Burya' was issued.
Council of Soviet Ministers (SM) Decree 957-409 'On transfer of intercontinental cruise missile work to the Ministry of Aviation Industry' was issued. Korolev had to place the highest priority on development of the R-7 ICBM. Therefore the final government decree authorised the Lavochkin and Myasishchev aircraft design bureaux to proceed in parallel with full-scale development of trisonic intercontinental cruise missiles. Both missiles would use ramjet engines by Bondaryuk, astronavigation systems by R Chachikyan, inertial navigation systems by G Tolstoysov, and aerodynamics developed by TsAGI (Central Hydrodynamics Institute). Lavochkin's Burya would use rocket booster engines built by Glushko, while Myasishchev's Buran would use Isayev engines. Both missiles were to deliver a nuclear warhead over an 8,500 km range. But the warhead design specified for the Lavochkin missile had a total mass of 2,100 kg, while that for the Myasishchev missile weighed 3,500 kg.
Myasishchev was just completing project design of his Buran design, while Lavochkin was already completing construction of the first Burya.
Council of Soviet Ministers (SM) Decree 'On termination of work on the 40 Buran intercontinental cruise missile' was issued. Buran was being prepared for its first flight when Myasishchev's project was cancelled. After successful flight tests of Lavochkin�s Burya missile, the Soviet leadership did not see any need for continued development of a parallel ramjet design. Following the cancellation, Myasishchev sought approval for test of an air-launched version.