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Soviet R-7 Semiorka (Little Seven)

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Title: Soviet R-7 Semiorka (Little Seven)


1
Soviet R-7 Semiorka (Little Seven)
2
Soviet R-7
  • Background
  • Early Soviet missile development programs
    included the first long-range surface-to-air
    missile, and the increased range and later
    submarine-launched R-11
  • The first nuclear warhead missile, the R-5 also
    evolved directly from the R-1 / V-2
  • All were incapable of reaching other continents
    or reaching orbit

3
Soviet R-7
  • Background
  • Korolev' knew what capabilities were needed for
    both an ICBM and reaching orbit and requested
    permission to build the first intercontinental
    ballistic missile (ICBM)
  • The ICBM request was approved in 1952 by Stalins
    decree
  • The new R-7 missile was a new-generation,
    heavy-lift booster that was the first large
    rocket not derived from Germany's V-2

4
R-7 Design
5
Soviet R-7
  • Following the government decree of February 13,
    1953, the design bureaus under Korolev's OBK-1
    began a preliminary design of the two-stage
    long-range missile
  • Early specifications for the R-7 launcher were
    for a nuclear warhead payload capacity carried
    over intercontinental distances
  • 170 ton vehicle mass
  • 3,000 kg payload
  • Range of 8,000 km

6
Soviet R-7
  • Korolevs initial design for the R-7 had two
    stages ignited at the same time
  • Four external booster segments comprised the
    first stage (Stage B)
  • Stage A was the second stage called the core
    stage
  • The booster and core design was based on several
    models of Helmut Grottrup, a German engineer
    brought to Russia with the V-2s

7
Soviet R-7
  • The R-7's engines also used a German design for
    the combustion chambers
  • R-7s core and booster stages employed a
    four-engine cluster designed by Glushko
  • Originally the engines for core and booster were
    specified as a single engine rated at 65 ton
    thrust
  • Designated RD-105/106

8
Soviet R-7
  • Because of combustion instabilities in the large
    thruster design, Glushko configured four 25 ton
    thrusters in the RD-107/108 clusters
  • A single turbopump was designed to feed fuel and
    oxidizer to all four engines
  • Simplified the propellant feed, but the multiple
    chambers and a single pump shaft was a potential
    problem for reliable engine operation

9
Soviet R-7
  • Korolev also felt that the four-engine unit
    required steering thrusters to achieve the needed
    warhead impact accuracy
  • Improved guidance during the thrust phase
  • Improved impact accuracy by steering the missile
    after booster cutoff

10
Soviet R-7
  • RD-108
  • RD-108 core engine contained four 25 ton engines
    with four smaller vernier outboard engines for
    impact guidance

11
Soviet R-7
  • Photo of the assembly line for the R-7 at the
    Baikonor facility. The core module and RD-108
    engine is on the right, a single booster with a
    RD-107 engine is on the left

12
Soviet R-7
  • RD-107/8
  • Four RD-107 booster units and a single RD-108
    core engine are shown on a recent Soyuz booster,
    an almost identical design of Korolevs R-7 ICBM

13
Soviet R-7
  • In the completed design, both the RD-107 and
    RD-108 had vernier guidance thrusters
  • Four for the core RD-108 module
  • Two for the RD-107 used on each of the four
    booster modules

14
Soviet R-7
  • The RD-107 and 108 engines had a two-phase
    startup and operation cycle
  • Began with the main thruster starting with simple
    gravity feed for the fuel and oxidizer injection
    into the combustion chamber
  • As the propellant flow increased, the turbopump
    accelerated and forced hydrogen peroxide liquid
    into a gas generator for even greater pressure
    that drove the turbopump faster
  • After reaching operating speed, the engines
    sustained the normal thrust levels for liftoff
    and ascent

15
Soviet R-7
  • Supporting trusses on the launch pad held the
    rocket down until full take-off thrust was
    developed, about 10 seconds after ignition
  • During flight, a special system synchronized the
    fuel consumption of the four strap-on boosters to
    keep the rocket's weight in balance
  • Radio guidance sensors and control commands were
    used for testing and guidance of the missile
    during early flight

16
Soviet R-7
  • Glushko's quad cluster design provided 100 tons
    of thrust in addition to the guidance thrusters
    that were also fed by the same turbopump unit
  • Regenerative cooling of the exhaust nozzle was
    accomplished by circulating kerosene before its
    injection into the combustion chamber

17
Soviet R-7
  • Fuel and oxidizer for the R-7 was LOX and
    kerosene which had a 250 sec specific impulse
  • Glushko felt strongly that rocket fuels should be
    used that could be stored at ambient temperatures
    instead of at cryogenic temperatures
  • This disagreement persisted throughout Gluskkos
    personal conflict with Korolev

18
Soviet R-7
  • The RD-107 weighed only 25 percent more than the
    V-2 engine but developed over three times as much
    thrust
  • The outer wall of the RD-107/8 engine was steel
    and the inner wall was a chromium bronze alloy 6
    mm thick
  • 5 mm deep channels were milled into the chamber
    to conduct a flow of kerosene for regenerative
    cooling

19
Soviet R-7
  • The 3.8 ton-thrust verniers were designed by
    Mikhail Malnikov which later evolved into small
    upper stage engines for their lunar and manned
    vehicles (Mitchell)
  • The four combustion chambers shared a 3,800 kW
    (5,000 HP) steam-powered turbopump
  • A common drive shaft turned pumps for kerosene,
    liquid oxygen, hydrogen peroxide (for steam
    generation), liquid nitrogen (for tank
    pressurization) and pumps for the vernier engines

20
Soviet R-7 Specs
  • Design (overall) S. Korolev OKB-1 Bureau
  • Engine design V. Glushko OKB-456 Bureau
  • Control system N. Pilugin NI-885 Bureau
  • Vehicle length 28 m (without upper stage)
  • Weight 280 metric tons (wet) 27 tons
    empty
  • Fuel Refined kerosene (T-1)
  • Oxidizer Liquid oxygen (LOX)
  • Stage 1 4 strap-on (external) boosters, each
    with a 4 engine cluster RD-107 2 steering
    engines
  • Stage 2 Core (center) module - 4 engine
    cluster RD-108 4-steering engines
  • Range 8,500-8,800 km
  • Stage 1 burn 104-130 sec
  • Stage 2 burn 285-320 sec

21
R-7 Testing and Qualification
22
Soviet R-7
  • The first launch of the R-7 was on May 15, 1957,
    two months after delivery to the pre-launch
    processing facilities in March 1957
  • The flight was successful until a strap-on
    booster separated at T98 seconds, creating
    instability and producing a complete breakup
  • A second launch test was made on 11 June, 1957,
    with a failure due to a Stage A propellant
    pressurization problem

23
Soviet R-7
  • The third test launch was made on 12 July, 1957,
    but failed 33 seconds after liftoff due to a
    control circuit error
  • A fourth launch was made on 21 August, 1957 with
    Nakita Kruschev present
  • Although the launch was called a success, a
    complication with the warhead separation led to
    an impact with the vehicle
  • This first launch of the R-7 was immediately
    announced as a successful launch of the world's
    first ICBM

24
Soviet R-7
  • U.S. military planners and the Eisenhower
    administration realized they were far behind the
    Russians with their Atlas ICBM program
  • This was the birth of the missile gap that,
    while political and not supported by missile and
    warhead count, led to rapid weapons buildup on
    both sides

25
Soviet R-7
  • R-7 ICBM
  • A second verification test of the ICBM was made
    on 7 September, 1957 to qualify the R-7 for the
    Sputnik satellite launch
  • The qualification testing for the Soviet's ICBM
    role continued until acceptance and deployment in
    1960
  • Even after the R-7 systems were refined for use
    as a reliable, accurate ICBM weapon, the missile
    was never deployed in significant numbers

26
Soviet R-7
  • R-7 telemetric warhead used for development and
    testing of the ICBM

27
Soviet R-7
  • Soviet thermonuclear warhead used on the R-7 ICBM

28
Soviet R-7
  • ICBM (cont.)
  • Fueling was time consuming and a tanking would be
    useful for only 24 hours after which it would
    have to be drained, re-eximined, and if necessary
    refurbished, and then cycled which took another
    36 hours
  • This tripled the number of R-7s that had to be
    online for nuclear weapons strategic deployment
  • In addition, the R-7 required above-ground launch
    facilities made it vulnerable to attack or even
    sabotage

29
Soviet R-7 ICBM
  • ICBM (cont.)
  • By August of 1961, there were only four R-7
    ICBM's in operational service
  • This included two missiles in storage the two
    operational launch pads at Plesetsk
  • The R-7 was removed from service as an ICBM in
    1967, but continued on in space launch
    applications and are still used today

30
R-7 Conversions
31
Soviet R-7
  • Korolev's R-7 has had unmatched success as a
    launcher, from the early ICBMs to today's Soyuz
    and Molinya boosters
  • Between 1957 and 2000, over 1,628 R-7s were
    launched with a success rate of 97.5 for
    production models
  • The R-7 was also adapted for use in the first
    Russian manned flights with a larger third stage
    added for boost into orbit

32
Soviet R-7
  • The Vostok booster configuration, also called the
    Vostok, had a payload capacity of 5 tons
  • An even larger third stage booster increased the
    payload to 6 tons to accommodate the Voshkod and
    later the Soyuz manned vehicles
  • As of 2010, every manned Russian or Soviet
    spaceflight has been launched by an R-7
    derivative

33
Soviet R-7
  • Launch test of the Vostok capsule and Vostok
    launch vehicle, one of the many R-7 derivatives

34
Soviet R-7
  • A Soyuz launch vehicle and mated Soyuz capsule is
    shown being transported from the Baikonour plant
    to the launch pad

35
Soviet R-7
36
Soviet R-7
  • A Soyuz launch vehicle and mated Soyuz capsule is
    shown being transported from the Baikonour plant
    to the launch site stand

37
Soviet R-7
  • The original design of the R-7 core and four
    strap-on booster was adapted as a lunar and
    interplanetary launcher by adding a third and
    fourth stage
  • Later manned launchers also included a third
    stage to produce the Vostok launch vehicles that
    had a payload capacity of 5 metric tons

38
Soviet R-7
  • An even larger third stage was used for the
    Voskhod and Soyuz crew vehicles, with a payload
    over 6 tons
  • A fourth stage was used for the Molniya booster
    to place communications satellites into
    high-inclination, high-altitude, eccentric orbits

39
Soviet R-7
  • R-7 ICBM
  • Called the R-7 and R-7A Semyorka
  • Classified by Western intelligence as SS-6
    Sapwood
  • Launch system variants
  • Sputnik, Polyot, Voskhod, Soyuz/Vostok, Vostok,
    Luna, Vostok-L Vostok-K Vostok-2, Vostok-2M,
    Molniya, Molniya-M, Soyuz, Soyuz-L, Soyuz-M,
    Soyuz-U, Soyuz-U2, Soyuz-FG, Soyuz-2

40
  • References and Resources
  • Mitchel, Don P., The R-7 Missile
  • http//www.mentallandscape.com/S_R7.htm

41
The End
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