Mir Hardware Heritage/Part 1 - Soyuz

1.1 General Description

The following description of Soyuz is excerpted from an article in the Soviet newspaper Pravda (November 17, 1968).^[1] It describes the Original Soyuz, the earliest flown version of Soyuz, yet fits the current Soyuz derivative, the Soyuz-TM, in most particulars.

The Soyuz consists of the following main modules: the orbital module . . . a descent capsule [descent module], intended for putting crews into orbit and returning them to Earth; and the service module, which houses the . . . engines.

The orbital module is in the fore part of the ship and is connected with the descent capsule. The service module is placed behind the descent capsule.

When the ship is being placed into orbit, it is protected against aerodynamic and thermal overloads by a nose faring, which is jettisoned after the passage through the dense layers of the atmosphere.

The cosmonaut’s cabin [descent module] . . . is covered on the outside by a . . . heat-resistant covering to protect it from intensive aerodynamic heating during descent to Earth.

After the vehicle has been slowed down by the atmosphere in its descent from orbit, the braking parachute opens . . . then the main parachute which is used for landing opens. Directly before landing— at a height of about 1 meter above the Earth—the solid-fuel braking engines of the soft-landing system are switched on.

[In the] service module . . . a hermetically-sealed . . . container

The pick-ups [sensors] for the orientation system are located outside the service module. Mounted on . . . the service module are the solar batteries [arrays]. To ensure that the solar batteries are constantly illuminated, they are oriented towards the Sun by rotating the ship.

The . . . spaceship is equipped with an automatic docking system. The on-board systems of the ship may be controlled either by the cosmonaut from the control panel, or automatically.

1.2 Historical Overview

Figure 1-1 is a Soyuz family tree depicting the evolutionary relationships described in this section.

1.2.1 First Prospectus for Circumlunar Travel (1962)

On March 10, 1962, Sergei P. Korolev, Chief Designer of the Soviet space program and head of Special Design Bureau-1 (Russian acronym OKB-1), ancestor of today’s RKK Energia (until recently, NPO Energia), approved a prospectus titled, “Complex for the Assembly of Space Vehicles in Artificial Satellite Orbit (the Soyuz).” The prospectus described the L1, a threeman spacecraft broadly resembling Soyuz as built. It had four modules. In order from fore to aft, these were an attitude control module, a living module, a reentry/command module,

Figure 1-2. L1 Soyuz manned circumlunar concept (1962). Should not be confused with the L1 (Zond) spacecraft (figure 1-9). The cone at the front (right) of the L1 Soyuz is an attitude control module; behind it are cylindrical orbital and descent modules, and a frustum-shaped service module. The round appendage (right) is a solar array, and the dish, a high-gain antenna. At the rear of the L1 are three booster modules.

The same prospectus described a manned spacecraft called Siber (or Sever) (“north”). This was a threeperson vehicle meant to deliver crews to a space station.^[2]

1.2.2 Second Prospectus for Circumlunar Travel (1963)

On May 10, 1963, Korolev approved a second prospectus, “Assembly of Vehicles in Earth Satellite Orbit.” In this prospectus, the “Soyuz complex” consisted of spacecraft designated A, B, and C. Soyuz-A (figure 1-4) corresponded to the L1 vehicle of the 1962 prospectus. Soyuz-B was an unmanned propulsion module launched dry with a detachable fueled rendezvous

unmanned tanker for fueling the propulsion module in orbit. Only Soyuz-A was to be manned.

The Soyuz complex (figure 1-5) required five or six launches of the Vostok launch vehicle to carry out a circumlunar mission. The Soyuz-B booster, with an attached rendezvous propulsion unit, was launched first. Up to four Soyuz-C tankers were then launched to fuel the booster. Soyuz-A, with three cosmonauts aboard, then docked nose-to-nose with the booster. The Soyuz-B rendezvous propulsion unit was discarded, and the booster fired to push Soyuz-A around the Moon on a free-return trajectory.

The Soyuz A-B-C complex had a total mass of about 18,000 kg. The Soyuz-A manned spacecraft accounted for 5800 kg of that mass (Soyuz-TM masses about 7070 kg). Total length of the complex was about 15 m. The Soyuz-A was 7.7 m long (compared to 6.98 m for Soyuz-TM).^[3][4]

The Soviet lunar effort thus became a two-pronged enterprise. Both prongs depended heavily on the Original Soyuz spacecraft. It was patterned after the Soyuz-A component of the 1963 prospectus. It carried a simple docking system which permitted crew transfer only by extravehicular activity (EVA). The Original Soyuz served the same role as the Gemini spacecraft did in U.S. lunar plans, and more besides. Like Gemini, the Original Soyuz was an interim vehicle, filling the gap between the earliest manned programs and the lunar program. Like Gemini, the Original Soyuz provided the means for preparing men, machines, and procedures in space for the lunar program. Unlike Gemini, the Original Soyuz provided the structural basis for the lunar spacecraft.

By the end of 1965, the Soviet manned lunar program included three vehicles, all based to a greater or lesser degree on the Original Soyuz. They were

• The L1, a stripped-down version of the Original Soyuz known as Zond (“probe”) meant for circumlunar flights
• The L2, a beefed-up version of the Original Soyuz called the Lunar Orbit Module—the Soviet counterpart to the U.S. Apollo command and service module (CSM)
• The L3, the lunar lander

The Soviet lunar program was hobbled by underfunding and more than its share of misfortune. In January 1966, Korolev died from complications during surgery. The Soyuz 1 disaster, in April 1967, set back the lunar landing schedule by 18 mo. Bitter personal rivalries between leaders in the Soviet space program also interfered with the goal of landing a cosmonaut on the Moon.

1.2.3 Polyot 1 and 2 (1963-1964)

The mysterious Polyot 1 (November 1963) and Polyot 2 (April 1964) maneuverable satellite flights were once thought to have been tests of Korolev’s Soyuz-B component. In 1992, however, a Russian book stated that the Polyots were antisatellite (ASAT) weapon test vehicles developed by V. N. Chelomei’s OKB-52 organization (ancestor of today’s NPO Mashinostroyeniye). A Russian article published the same year stated that the Polyots were tests of the propulsion systems for OKB-52’s Almaz military space stations. Another account had the Polyots testing engines to be used in Chelomei’s reusable space plane program. It is possible that the Polyots tested engines to be used in all three programs. In any case, the Polyots were not directly related to the Soyuz program.^[5][6]

1.2.4 Manned Lunar Program (1964-1976)

Soviet Communist Party Central Committee Command 655-268 officially established the Soviet manned circumlunar and lunar landing programs on August 3, 1964. The preliminary plan for the Soviet manned lunar landing program was approved by Korolev on December 25, 1964. The N-1/L3 program, as it was called, would have landed a single cosmonaut on the Moon in 1967-68. The mission plan assumed successful development of a large rocket called the N-1. Studies leading to the N-1 had begun in 1956, and work began in earnest in 1960.^[7][8]

The circumlunar program was retained. By late 1965, however, relying on multiple launches of components and extensive use of Earth-orbit rendezvous to assemble the circumlunar spacecraft was abandoned in favor of a single launch using a four-stage Proton rocket.^[9]

1.2.5 Salyut 1 (1970-1971)

The Original Soyuz survived the Moon program to become the ancestor of all subsequent Soyuz and Soyuz-derived craft. Spacecraft designer Konstantin Feoktistov stated that the Original Soyuz missions in 1966-1970 provided engineering data for its conversion into a space station transport. Plans for the conversion were drawn up in the first half of 1970.^[14]

Soyuz 10 and Soyuz 11 carried docking systems permitting internal crew transfer. In this work these vehicles are called the Salyut 1-type Soyuz. Apart from their docking systems, they differed only slightly from the Original Soyuz. The three Soyuz 10 cosmonauts became the first people to dock with a space station, but were unable to enter Salyut 1. This was blamed on a “weak” docking unit.^[15] The Soyuz 11 crew occupied Salyut 1 in June 1971. Because Soyuz cosmonauts wore pressure suits only for EVAs, the Soyuz 11 crew perished during reentry when pyro shock jarred open a 1-mm pressure equalization valve, allowing the Soyuz 11 descent module to vent its atmosphere into space.^[16]

1.2.6 Early Soyuz Ferry (1973-1977)

The Soyuz spacecraft underwent further redesign in the aftermath of the Soyuz 11 accident. Putting the cosmonauts in pressure suits during “dynamic operations” (such as liftoff, docking, reentry, and landing) forced Soviet engineers to pull one crew couch. The solar arrays were replaced by chemical batteries to save weight, restricting Soyuz to 2 days of autonomous flight. Removing the arrays also improved the spacecraft’s maneuverability. In addition, the Soviets modified the Soyuz orbital module to improve its ability to carry cargo to Salyut stations. These modifications produced the Soyuz Ferry.^[17]

1.2.7 Apollo-Soyuz Test Project (1973-1976)

The Apollo-Soyuz Test Project (ASTP) sprang directly from letters exchanged between NASA Administrator Thomas O. Paine and Soviet Academy of Sciences President Mstislav Keldysh in 1969 and 1970. (Of course, U.S.-Soviet space cooperation dates from nearly the beginning of spaceflight—see Portree, David S. F., “Thirty Years Together: A Chronology of U.S.- Soviet Cooperation”, NASA Contractor Report 185707, February 1993.) Several proposals for a joint manned mission were floated. For a time, an Apollo CSM docking with a Salyut space station held center stage. In April 1972, the sides met in Moscow to finalize the agreement for an Apollo-Salyut docking. The Soviets surprised the Americans by announcing that modifying a Salyut to include a second docking port for Apollo was neither technically nor economically feasible. They offered a Soyuz docking with Apollo instead.^[18]

The Soyuz Ferry needed substantial modifications to fulfill its new role as international ambassador. These included restoration of solar arrays to permit a 5-day stay in orbit, deletion of the Igla (“needle”) approach system boom and transponders, addition of Apollo-compatible ranging and communications gear, and substitution of the Soyuz Ferry probe and drogue docking system with the APAS-75 (androgynous peripheral assembly system) (see figure 1-22). The Soviet Union built five ASTP Soyuz. Three flew as precursors (two unmanned and one manned), and one backed up the prime ASTP Soyuz, Soyuz 19. In the event, Soyuz 19 performed well. Its backup flew as Soyuz 22 on an Earth observation mission (1976). It was the last manned Soyuz flown without the intention of docking with a space station.

1.2.8 Progress and Soyuz (1977-Present)

Since 1977, Soyuz and its derivatives linked with the manned space program have had one function—to support manned space stations. Since the launch of Salyut 6 in 1977, the Soviet/Russian station programs have had the following attributes with implications for Soyuz evolution:

• Multiple docking ports
• Design lifetimes of more than 1 year, with the option to remain in orbit for several years through onorbit repairs, upgrades, and refurbishment
• Extended-duration stays by teams of two or three cosmonauts

Extended-duration stays called for resupply, which in turn called for a specialized resupply spacecraft. This drove development of the Progress freighter, design of which began in 1973—the same year work began on

Progress freighters not only resupply the stations—they also deliver repair parts and new apparatus, permitting the stations’ useful lives to be extended well beyond their original design lifetimes. Along with Soyuz, Progress stood in for the malfunctioning orbit maintenance engines on the Salyuts, preventing premature reentry. (Kvant docked at the Mir base block rear port in 1987, blocking the base block’s orbit maintenance engines. Since then, Mir has relied exclusively for orbit maintenance on Progress and Soyuz craft.)

The Soyuz Ferry had a limited endurance docked to a station— about 60 to 90 days. Two alternatives were available if long-duration crews were to remain aboard for longer periods:

• The Soyuz Ferry could be upgraded to increase its endurance. This drove development of the Soyuz-T, which had an endurance of about 120 days, and the Soyuz-TM, which can stay with a station for at least 180 days.
• As a resident crew’s Soyuz neared the end of its rated endurance, a visiting crew could be sent to dock at the second port in a fresh Soyuz. They would return to Earth in the aging spacecraft, leaving the fresh one for the resident crew. A variation on this

theme had an unmanned Soyuz being sent to the station to replace the resident crew’s aging spacecraft. This was done only once, when Soyuz 34 replacedSoyuz 32.

Soyuz-T development appears to have been influenced by ASTP Soyuz development. Soyuz-T development in turn affected development of the Progress upgraded for Mir (first flown to Salyut 7 as Cosmos 1669 in 1985). Soyuz-T begat Soyuz-TM: the primary difference between the two craft was that Soyuz-T used the old Igla (“needle”) approach system, while Soyuz-TM used the Kurs (“course”) system. Many Soyuz-TM modifications were in turn applied to Progress-M, the most recent new Soyuz derivative.

Soyuz-derived craft might have played yet another role in the Soviet/Russian manned space program. By 1980, work commenced to convert Progress craft into specialized space station modules for the first truly multimodular station—what became Mir. But these were replaced by space station modules derived from an entirely different type of vehicle (see part 3, “Space Station Modules”). The Gamma astrophysics satellite would have been the first Progress-derived module, but it was redesigned to fly as an independent satellite.^[19]

1.2.9 Soyuz Generations

The manned Soyuz spacecraft can be assigned to design generations. Soyuz 1 through 11 (1967-1971) were first-generation vehicles. The first generation encompassed the Original Soyuz and Salyut 1 Soyuz. The second generation, the Soyuz Ferry, comprised Soyuz 12 through 40 (1973-1981). ASTP Soyuz served as a technological bridge to the thirdgeneration Soyuz-T spacecraft (1976-1986). Soyuz-TM is fourthgeneration. These generation designations provide a useful shorthand method for referring to the vehicles. They also parallel similar designations applied to Soviet/Russian space stations and other spacecraft.^[20]

1.2.10 Crew Code Names

Code names used as call signs in radio communications are a traditional fixture of the Soviet/Russian space program. They date from the first manned spaceflight (Vostok 1 on April 12, 1961) and reflect the evolution of Soviet spacecraft and procedures. When they were first adopted, one code name was adequate—Vostok was a singleseater. With the modification of Vostok into the multiseater Voskhod and the development of the multiseater Soyuz, code name conventions changed.

The crew code names listed with the names of cosmonauts in the “Mission Description” subsections whichfollow are in actuality the code names of each mission’s commander. For example, the Soyuz-TM 12 flight crew was called Ozon (“Ozone”) because that was commander Anatoli Artsebarski’s code name. Following tradition, his flight engineer, Sergei Krikalev, was called Ozon Dva (“Ozone-2”). Helen Sharman, a cosmonaut-researcher, sat in Soyuz-TM 12’s third seat. Cosmonautresearcher is a designation roughly equivalent to the designation Payload Specialist in the U.S. Shuttle program. As cosmonaut-researcher, Sharman was called Ozon Tri (“Ozone-3”).

Spacecraft swaps and partial crew exchanges in the space station era also changed code name conventions. Crew code names travel with the commander, and crew members take on the code name of the commander with whom they travel. For example, Helen Sharman returned to Earth in Soyuz-TM 11 with commander Viktor Afanasyev (code name Derbent) and flight engineer Musa Manorov (Derbent Dva). She thus became Derbent Tri for her return to Earth. Sergei Krikalev became Donbass Dva after

Alexandr Volkov (code name Donbass) replaced Artsebarski as his commander aboard Mir.

In this work, crewmembers are listed commander first, flight engineer second, and cosmonaut-researcher last. Missions in which this convention does not hold true are noted.

1.3 The Original Soyuz (1966-1970)

The three-seater Original Soyuz(figure 1-6) was the first ancestor of the Soyuz-derived vehicles in use today. The Original Soyuz played much the same role in the Soviet manned lunar program as Gemini did in the U.S. manned lunar program. That is, it provided experience in essential techniques and technologies for lunar flight.

1.3.2 Original Soyuz Notable Features

• Launched on a Soyuz rocket (figure 1-7). All Soyuz variants except the L1 and L2 have launched on this rocket.
• Except during EVA, its crew did not wear space suits.

• Made no provision for internal crew transfer after docking. Crew transfer involved EVA between two docked craft.
• Used a simple probe and drogue docking system (figure 1-8).
• Had handrails on the outside of its orbital module to facilitate external crew transfer after docking.

• Orbital module served as an airlock for external crew transfer; it also served as a laboratory, a storage compartment, and living space for the crew.
• Carried a toroidal tank in its aft skirt. This was an electronics compartment or propellant tank (it was never flown carrying propellants).

Soyuz spacecraft. The Soyuz orbital module and descent module were dragged to safety by the launch escape system.^[23]

First manned Soyuz spacecraft, meant to play the active role in a docking with a second spacecraft which would have been called Soyuz 2. Soyuz 2 would have carried three cosmonauts, two of whom would have transferred by EVA to Soyuz 1. The mission was scheduled to coincide with the anniversary of Lenin’s birth. Upon reaching orbit, one of the craft’s two solar arrays failed to deploy. Exhaust residue from the attitude control jets fouled the craft’s ion orientation sensors, making control difficult. The second Soyuz launch was cancelled. Komarov carried out a manual reentry on orbit 18, after a failed attempt at an automated reentry on orbit 17. During descent, a “pressure design flaw” prevented the parachute from deploying properly. The Soyuz 1 descent module crashed and cosmonaut Komarov was killed.^[25]

Soyuz 3 was the active craft for the docking with the unmanned Soyuz 2 craft. The craft were unable to dock, though automatic systems brought the ships to within 200 m, and Beregovoi brought Soyuz 3 still closer to Soyuz 2 under manual control.^[28][29] Before launch the flight was called a prelude to manned space stations.^[30]

Landing crew—Vladimir Shatalov, Yevgeni Khrunov, Alexei Yeliseyev
Crew code name—Amur

Crew code name—Baykal

Landing crew—Boris Volynov
Crew code name—Baykal

Soyuz 4 and Soyuz 5 carried out the first docking between manned Soviet spacecraft. Soyuz 4 played the active role in the docking. After docking, Soyuz 4 and Soyuz 5 were described as comprising the first multimodular space station.^[31] More importantly, however, this was a test of rendezvous and docking and EVA procedures, with implications for the manned lunar program.^[32] Yeliseyev and Khrunov transferred by EVA from Soyuz 5 to Soyuz 4. The two craft remained docked for 4 hr, 35 min. Afanaseyev states that, after Soyuz 4 and Soyuz 5, two additional Soyuz craft were to have rendezvoused and docked to prepare for manned lunar landing missions. However, the remaining Original Soyuz craft were “re-assigned for the performance of engineering experiments in a group flight . . . and in a longduration flight.”^[33] These were the Soyuz 6, 7, and 8 and Soyuz 9 missions, respectively.

Remained aloft for 17 days, 17 hr, beating the U.S. space endurance record set by the Gemini 7 astronauts in 1965. The mission gathered biomedical data in support of future space station missions.

1.4 L1 (Zond): Circumlunar Spacecraft (1967-1969)

The L1 (Zond) (figure 1-9) was meant to carry one or two cosmonauts on a circumlunar flight. It never flew manned, but did complete several unmanned circumlunar missions.

Figure 1-9. L1 (Zond) circumlunar spacecraft.

1.4.1 L1 Specifications

Figure 1-10. Proton configured for L1 (Zond). Note the modified Soyuz shroud (top).

Launch weight (Zond 4 through 6) ............ 5140 kg
Launch weight (Zond 7, 8) ....................... 5390 kg
Launch vehicle ....................................... Proton (four-stage); N-1
Length at launch .................................... 5.0 m
Length after support cone ejection ........... 4.5 m
Span across solar arrays ........................ 9 m
Diameter of habitable module .................. 2.2 m
Maximum diameter ................................ 2.72 m
Habitable volume ................................... 3.5 m3
Number of crew ..................................... 1-2*

*Never carried a crew.

1.4.2 L1 Notable Features

• Typically launched atop a fourstage Proton rocket (figure 1-10). The first three stages burn N2O4 and UDMH propellants. The Block D fourth stage, with its restartable motor, was originally intended for use with the N-1 rocket as part of the manned lunar landing program. It burns kerosene and liquid oxygen. It would have inserted the L2 and L3 into lunar orbit and provided most of the DV for powered descent of the L3 to the lunar surface. The L1 used it for translunar injection.
• Launched under a modified Soyuz launch shroud.
• Launch escape system’s solid rocket motors smaller than those on the Soyuz shroud, in keeping with the lower mass it was designed to drag to safety.
• Had an inverted cone-shaped support structure around the hatch at the top of the descent module

escape system. This was ejected in Earth parking orbit or after translunar injection.

• Lacked an orbital module.
• Lacked docking systems.
• Lacked the toroidal instrument container located in aft skirt of Original Soyuz.
• Lacked intermodule umbilical linking the service module to the orbital module.
• Had no backup main engine in the version flown. The sole engine was based on the Soyuz KDU-35 system. Propellant mass was only

400 kg.

• Had shorter solar arrays than Soyuz.
• Had an ablative heat shield thicker than that on the Original Soyuz to withstand atmospheric friction heating at lunar reentry velocities.
• Carried an umbrella-like highgain antenna on its descent module.

had to be destroyed. The launch escape system functioned as designed.

Union.

1.5 L2 (Lunar Orbit Module): Lunar Mission Command Ship (1971-1974)

No L2 (figure 1-11) ever reached orbit. The spacecraft was meant to play the equivalent role of the U.S. manned lunar program’s Apollo CSM. An L2 is on display at the Moscow Aviation Institute. For an L2/CSM comparison, see figure 4-3. Figure 1-12 depicts the Soviet manned lunar landing profile.

Figure 1-11. L2 (Lunar Orbit Module). At the front of the spacecraft (left) is the Aktiv
unit of the lunar mission Kontakt docking system.

1.5.1 L2 Specifications

Figure 1-13. N-1 rocket configured for lunar flight. The basic rocket consisted of the Block A first stage, the Block B second stage, and the Block V third stage. All stages burned liquid oxygen and kerosene. For lunar missions the LRS was added. The N-1 would have delivered about 100,000 kg to low-Earth orbit. (For a comparison with the U.S. Saturn V rocket, see figure 4-1).

Launch weight .......................................... 14,500 kg (estimated)
Launch vehicle .......................................... N-1
Length ..................................................... 12 m (estimated)
Diameter of living module ........................... 2.3 m
Diameter of descent module ...................... 2.2 m
Diameter of service module ........................ 2.2 m
Maximum diameter

(across aft frustum) ............................. 3.5 m (estimated)

Habitable volume ....................................... 9 m³ (estimated)
Number of crew ......................................... 2

1.5.2 L2 Notable Features

• Flight-test version, dubbed T1K, was to have been launched on a Proton rocket. However, the T1K flight-test program was cancelled in favor of all-up testing on the N-1 rocket (figure 1-13).^[40][41] Similarly, in 1965, the Apollo program opted for unmanned allup testing.
• Launched atop an N-1 rocket with a L3 lunar lander and the Block G and Block D rocket stages. Together they formed the lunar rocket system (LRS) (figure 1-14).
• Long service module contained a large spherical propellant tank divided by a membrane into oxidizer and fuel sections. It provided propellant for a main propulsion system different from the Original Soyuz design. The L2 main engines were not used until after the L3 and D unit separated from the L2 in lunar orbit. The propulsion system provided DV for trans-Earth insertion and course corrections during return to Earth.
• Had enlarged conical skirt at service module aft.
• Carried a spring-loaded probe docking system, called Aktiv (“active”), which was designed to penetrate and grip a “honeycomb” drogue docking fixture on the L3. Together they were called

Figure 1-14. Lunar rocket system. Consisted of (bottom to top) the Block G and Block D rocket stages, the L3 lander, and the L2 command ship.

Kontakt (figure 1-15). The docking system was to be used only once during the mission, after the L3 had completed its lunar landing mission and returned to orbit. Little docking accuracy was required to link the spacecraft firmly enough to let the moonwalking cosmonaut return to the L2 by EVA.

• Made no provision for internal crew transfer after docking.
• Orbital module had an EVA hatch larger than the one on the Original Soyuz.
• Electronics more complex than those on the Original Soyuz, in keeping with its more demanding mission.

• Oxygen/hydrogen fuel cells and batteries replaced the solar arrays of the Original Soyuz.
• Descent module had a heat shield thicker than that of the Original Soyuz, permitting it to withstand reentry at lunar return speeds.

1.6 L3: Lunar Lander (1970-1974)

The L3 (figure 1-16) was successfully tested in simplified form in Earth orbit, but the failure of the N1 rocket program prevented it from reaching the Moon. It was designed to deliver a single cosmonaut to the lunar surface. L3 landers and associated hardware are on display in several locations in Russia: the Moscow Aviation Institute, Mozhalsk Military Institute in St. Petersburg, NPO Energia in Moscow, Kaliningrad Technical Institute, and NPO Yuzhnoye in Dnyepetrovsk. For a comparison of the L3 with the Apollo LM, see figure 4-2.

Figure 1-16. L3 lunar lander. The flat, downward-facing face (left) of the ovoid
pressure cabin holds the round viewport (not visible). The Kontakt system passive
unit is at cabin top, and two landing radar booms extend at left and right. Nozzles
of two solid-fueled hold-down rockets are visible at the tops of the legs, near the
bases of the radar booms.

1.6.2 L3 Notable Features

• Not a Soyuz derivative per se, though it was developed as part of the same program which produced the Soyuz-derived L1 and L2 vehicles. L3 was to have been used with the L2 vehicle.
• Flight-test version of the L3 was called T2K. It was launched for Earth-orbital tests on a modified Soyuz rocket with an enlarged (“large caliber”) launch shroud.^[42] T2K had its landing legs replaced by two units for returning systems telemetry to Earth.
• For lunar landing missions, was to be launched on a three-stage N-1 rocket, within a shroud, as part of the LRS. The LRS consisted of Block D and Block G rocket stages, the L3 lunar lander, and the L2 command ship.
• The Block D stage carried out midcourse corrections en route to the Moon and braked the L2 and L3 into lunar orbit. After lunar orbit insertion, a single cosmonaut exited the L2 through the hatch in its living module, traversed the length of the L2 with the aid of a mechanical arm, and entered the L3 through a port in the shroud enclosing it. The shroud then fell away as the Block D and L3 separated from the L2.
• Restartable rocket motor on the Block D provided most of the DV for powered descent to the lunar surface. The Block D was to be depleted and discarded about 1 to 3 km above the surface. After it was discarded, the Block D crashed on the lunar surface a short distance from the L3 touchdown point.
• ?Had one single-nozzle main engine on its longitudinal axis, one two-nozzle backup engine, and four verniers. The lozenge-shaped propulsion unit was dubbed the Ye unit. Loaded with

N₂O₄ and UDMH propellants, the Ye unit weighed approximately 2250 kg (half the weight of the L3). N₂O₄ was stored in a toroidal tank surrounding the engine units. This fuel load gave the L3 about 1 min of flight time before it began to cut into its ascent reserves.

• Control system was the first in the Soviet program based on an onboard computer. Inputs were derived from a three-axis gyrostabilized platform, landing radar, and a collimating sight. The cosmonaut would use the sight to spot the selected landing site, then input the coordinates to the computer. Computer commands were verified using Sun and planet sensors.
• Two 40-kg thrusters gave pitch control; two more gave yaw

control; and four 10-kg thrusters gave roll control. The system was exactly duplicated on a separate control circuit to provide redundancy.^[43]

• Lone cosmonaut stood before a large, round, downward-angled window; controlled flight manually using a control panel located to the right of the window and control sticks. A smaller window faced upward to provide visibility during docking.
• Cabin atmosphere was oxygen/nitrogen at 560 mm/Hg, with slightly less nitrogen than the terrestrial mix normally used in Soviet spacecraft.^[44]
• Relied on five chemical batteries for its electricity. Two were located on the ascent portion of

the spacecraft and three were left behind on the Moon.

• Four solid rocket hold-down motors, with upward-pointing nozzles, were fired at touchdown to help ensure that the L3 would not tumble on contact with the irregular lunar surface.^[45]
• Landing gear designed to contend with a lateral velocity of 1 m/sec at touchdown on hard soil with a 20° slope.
• Cg adjustments possible by redistribution of water in the tanks of the evaporator cooling system.^[46]
• Had an oval hatch designed to accomodate the cosmonaut’s

special Krechet lunar space suit.^[47][48]

• Left only its landing legs, landing radar, and a few other components behind on the Moon. Unlike the Apollo LM, which used separate descent and ascent propulsion systems, the L3 used the same main propulsion system for final descent and ascent. At liftoff from the lunar surface both the main and backup propulsion systems were activated. If both systems were found to be operating normally, the backup system was then shut down (figure 1-17).^[49]
• L3 drogue docking unit extremely simple and tolerant of misalign

-ment. It was a 100-cm aluminum plate, containing 108 recessed hexagons, each 6 cm in diameter. In the nominal mission it would be used only after the L3 ascended from the lunar surface. The L2’s docking probe (Aktiv unit) had only to enter one of the hexagons to create a connection firm enough to allow the L3 cosmonaut to complete a space walk back to the L2 spacecraft. A flat aluminum apron protected the top of the L3 from damage in the event of gross misalignment by the L2. The combined L2/L3 docking system was called Kontakt.^[50][51]

1.7 Salyut 1-Type Soyuz (1971)

The Salyut 1-type Soyuz (figure 1-18) was the Original Soyuz with a new docking system. Its second manned flight (Soyuz 11, 1971) ended in disaster, forcing a redesign.

Figure 1-18. Salyut 1-type Soyuz. This was the Original Soyuz upgraded for Salyut space stations. The probe and drogue docking system (left) permitted internal transfer of cosmonauts from the Soyuz to the station.

1.7.2 Salyut 1-Type Soyuz Notable Features

• Carried three crew, who did not wear space suits during flight.
• Equipped with a probe and drogue docking system permitting internal crew transfer (figure 1-19).

• Carried solar arrays which could be tied into the Salyut 1 power system, increasing the amount of energy available to space station systems.
• Lacked the toroidal tank or pressurized instrument compartment in the aft skirt of the Original Soyuz spacecraft.

• Orbital module was shortened to 2.65 m in length (from about 4 m) by deletion of the external crew transfer docking system probe and frustum, and a docking system for internal crew transfer was added.

Carried three crew to Salyut 1, the first space station, in April 1971. A fault in the docking unit prevented them from entering the station.

Docked successfully with Salyut 1 on June 7, 1971. On June 27 the threeperson Soyuz 11 crew reactivated Soyuz 11 and began packing experiment results for return to Earth. At 1828 UT, June 29, they undocked. They wore hooded flight suits which protected them against the descent module's chill, but not against depressurization. The Yantars fired their Soyuz main engine to deorbit. Explosive bolts for separating the orbital and service modules from the descent module then fired simultaneously, rather than sequentially as planned. The abnormally violent separation jarred loose a 1-mm pressure equalization seal in the descent module which was normally pyrotechnically released at lower altitude. The atmosphere in the descent module vented into space within 30 sec. The crew rapidly lost consciousness and died. The descent module landed automatically in Kazakhstan without additional incident at 2317 UT.^[54]

1.8 Soyuz Ferry (1973-1981)

The Soyuz Ferry (figure 1-20) replaced the Salyut 1-type Soyuz. It transported crews of two cosmonauts to Salyut 3, Salyut 4, Salyut 5, and Salyut 6.

Figure 1-20. Soyuz Ferry.

1.8.2 Soyuz Ferry Notable Features

• Space and weight devoted to a third crewman on the Original Soyuz was devoted to life support equipment designed to supply two crewmen in space suits.
• Deletion of solar arrays.
• Addition of batteries. These were lighter than solar arrays, permitting more cargo to be carried. The batteries restricted the Soyuz Ferry to only 2 days of autonomous flight.
• Igla (“needle”) automatic rendezvous and docking system.
• Whip antennas were relocated from the leading edges of the solar arrays to the sides of the service module.

1.8.3 Soyuz Ferry Detailed Description

Soyuz designer Konstantin Feoktistov provided a detailed description of the Soyuz Ferry near the end of its career in a brochure published in Moscow in 1980.^[55] Many of the Soyuz Ferry attributes he described, listed below, apply equally to other versions of Soyuz.

Descent capsule L/D ratio of 0.2-0.3 permitted a landing site to be targeted within several kilometers. Nominal descent deceleration load was 3-4 g’s. The descent capsule had three windows. The central window was fitted with a “viewer and orientation device” for “triaxial orientation using the horizon and features on Earth over which the spacecraft passed.” The device also

served as a periscope during rendezvous and docking operations, permitting the crew to see around the forward orbital module. Most of the cargo carried by a Soyuz Ferry to an orbiting Salyut space station was carried in the orbital module. A small amount was carried in the descent module.

The service module consisted of the transfer frame and the instrumentservice section. The transfer frame, which joined the service module to the descent module, was unpressurized and held several docking and orientation engines (attitude control engines) and fuel tanks, purging tanks (for providing pressurant to drive propellant from the propellant tanks to the engines), the small exterior radiator for the thermal control system, and the command radio link apparatus, including a

ring-shaped exterior antenna structure surrounding the forward end of the service module. The instrument-service section had electronic equipment in a lozengeshaped pressurized container, the main propulsion system (“rendezvous-correction power plant. . . with two engines [main and backup]”), docking and orientation engines, the large hull-mounted thermal control system radiator, batteries, and orientation system sensors and antennas.

The Soyuz Ferry radio system transmitted and received voice, telemetry, television, and control command communications. Communications were relayed through ground stations and shipborne tracking stations for periods ranging from minutes to tens of minutes. If continuous telemetry were required, onboard recorders could store data for playback when the spacecraft was in range of a surface station. The Soviets also used shortwave frequencies to transmit telemetry data when out of range of a surface tracking facility.

Propulsion, orientation, radio, life support, thermal control, electrical power supply, and descent systems were automated (through programtiming devices) and could be controlled from the Flight Control Center (Russian acronym TsUP) by radio. Onboard manual controls were also available. Automatic, TsUP-operated, and onboard manual controls were all part of the onboard complex control system, which included “logical devices, commutators, the electrical automation (for connecting the electrical power supply of the instruments and systems), the control panel, and the command signal devices.” While it was attached to the station, the condition of the dormant Soyuz Ferry was periodically checked by the TsUP and by the onboard crew.

The “orientation and motion control system” (Russian acronym SOUD) included “the infrared plotter of the local vertical” and ion sensors, “gyroscopic angle gauges and angular velocity gauges,” the rendezvous radio system providing relative motion data during rendezvous, optical and television visual orientation instruments, “calculating and commutation instruments,” and manual control and display systems. The most complex SOUD operations involved rendezvous and docking. Feoktistov described the procedure in some detail. At Soyuz Ferry launch, the target Salyut orbited about 350 km high, in an orbit the plane of which passed through Baikonur Cosmodrome, the Soyuz Ferry launch site. Launch occurred as the station passed over the launch site. The ferry was inserted into a 190-200 km by 250-270 km orbit approximately 10,000 km behind the station. The ferry in its lower orbit caught up with the station. Up to four orbital correction burns using the main engine were made to match altitude and speed near the station. When the Soyuz closed to within 25 km of the Salyut, the automatic rendezvous phase of operations commenced. The two vehicles sensed each other and the automatic rendezvous radio equipment (the Igla system) switched on. The spacecraft maneuvered to keep their Igla antennas in line-of-sight so the Soyuz unit could obtain data on range, speed of approach, and orientation. The control computer on the Soyuz Ferry operated the main and docking and orientation engines based on the input data. The automatic rendezvous phase terminated when the distance between the Soyuz Ferry and the Salyut station dropped to 200 to 300 m. At that point the docking phase began. Automatic control could continue up to “mechanical contact of the docking units” of the two craft, or the crew could take manual control

of the Soyuz and dock (Feoktistov asserted that crews were trained for manual dockings, though events seemed to indicate this was not always the case).

The main propulsion system propellant tanks used organic film (plastic?) membranes (bladders) to prevent pressurant from mixing with propellant. The system consisted of two engines (main and backup) with 400 kg of thrust each. The backup engine could fire only once, at full power. The attitude control system consisted of 14 10-kg thrust docking and orientation engines and 8 orientation engines with 1 kg of thrust each. The main propulsion system and the attitude control system did not share the same propellant supply on the Soyuz Ferry.

The launch control system controlled the descent capsule during return to Earth. Descent attitude control was provided by six engines with 15 kg of thrust each. At 12 km altitude the descent module speed was reduced to 240 m/sec. Parachutes were stored in two separate covered containers. The launch control system controlled the main and backup parachute systems and the landing solid rocket motors.

The electrical power supply was based on chemical batteries during autonomous operations. This replaced the solar arrays of earlier Soyuz versions. After docking with the Salyut, Soyuz Ferry systems operated on electricity provided by the station’s solar arrays. The station also recharged the Soyuz Ferry’s batteries while it was docked. Electrical connections between Salyut and Soyuz were maintained through plugs in their docking collars.

The thermal control system had two main loops and one auxiliary loop. The two main loops were connected

through a liquid-liquid heat exchanger. Heat was radiated into space through radiator tubes on the outside of the instrument-service module. These gave it its characteristic ribbed appearance. The auxiliary loop connected with the Salyut thermal control system. It maintained temperature in the Soyuz Ferry crew compartment while it was docked to the station and powered down. Spacecraft surfaces

not occupied by sensors, antennas, and engines (including those surfaces under the radiator panels on the service module) were covered with “packets of vacuum shielded thermal insulation.”

The life support system provided life support for only a few days. It was modified from the earlier Soyuz to support space suits. Emergency supplies carried in the event that the

descent module landed in an unpopulated area were also part of the life support system. While the Soyuz Ferry was docked to a Salyut, the life support system was turned off. An air duct (a rubberized fabric sleeve) was run from the Salyut through the open hatch into the Soyuz to keep its air from becoming stale.

First manned Soyuz Ferry flight. Its purpose was to thoroughly test the redesigned Soyuz. It was not meant to dock with a space station.^[57]

This was a unique mission using a Soyuz spacecraft with solar arrays. There is some question as to whether this mission should be grouped with the Soyuz Ferries. Soyuz 13 was not intended to dock with a station—no Soviet stations were available at the time of its launch, and it carried no docking apparatus.^[58] Scientific instruments like those used on Soviet space stations filled its orbital module (Oazis-2 plant growth unit) and replaced its docking mechanism (Orion-2 telescope suite). Like the U.S. astronauts aboard Skylab, the Kavkaz crew observed Comet Kohoutek.^[59]

First successful Soviet mission to a space station. It docked with Salyut 3 on July 4 and spent 16 days in space.

Failed to dock with Salyut 3 after its Igla system malfunctioned and the cosmonauts were unable to guide the spacecraft to a manual docking. Gyroscope problems nearly prevented orientation of the spacecraft for the deorbit burn. Reentry had to occur within 2 days of launch, lest Soyuz 15 exhaust its batteries. Landing occurred at night, in a lightning storm. Neither Sarafanov nor Demin flew again. This was taken to imply that they were punished for poor performance which contributed to mission failure. However, a recent Russian report vindicates the crew.^[60]

First to visit Salyut 4. Landed in a fierce blizzard.

Dubbed Soyuz 18a in the West. During ascent, an electrical malfunction in the Soyuz booster prematurely fired two of the four explosive latches holding the core of the first stage and the second stage together. This severed electrical connections necessary for firing the remaining latches. The launch escape system and shroud covering the Soyuz were discarded as normal. When the core first stage burned out it could not be cast off. Second stage ignition occurred as normal, but the booster was rapidly dragged off course by the weight of the spent core first stage. When the course deviation reach 10°, the automatic safety system came into operation. It shut down the booster and separated the Soyuz. At separation the Soyuz was 180 km high and moving at 5.5 km per second. The Soyuz turned around and fired its main engine against the direction of flight to slow down, then discarded its orbital and service modules. Reentry was brutal, with the cosmonauts experiencing up to 12-18 g’s. They landed unhurt, however, in the eastern U.S.S.R. The flight lasted only 21 min, but 24 hr passed before the crew could be recovered. This was the only suborbital flight of the Soviet manned space program. More importantly, it was the only downrange abort in manned spaceflight history.^[61][62]

Docked with Salyut 5 on July 7, 1976. The crew returned home after 49 days in space.

Suffered an automatic docking system malfunction during final approach to Salyut 5. The cosmonauts were ordered to return to Earth. They had less than 2 days of battery power left and had already missed the landing opportunity for that day, so they powered down systems to conserve power. A blizzard with squall force winds broke out in the landing zone, but the Soyuz capsule was designed to land in any weather. Reentry over North Africa was normal. The Soyuz 23 descent module lowered in the dark on its single red and white parachute, rocking as it encountered the high winds driving snow across the landing area. The descent module splashed down in freezing water, surrounded by ice floes, 8 km offshore in Lake Tengiz. All recovery efforts were thwarted. The cosmonauts bobbed in the capsule with systems shut off to save power. The capsule floated, and the pressure equalization valve above the waterline provided air. They ate from their supply of emergency food and donned emergency water survival suits. The next day a helicopter towed the capsule to shore with the cosmonauts still inside. They were unharmed by their ordeal.^[63]

The Tereks spent only 17 days docked to Salyut 5, which had nearly depleted its propellant supply.

Docked with Salyut 6 on October 10, 1977, but its crew was unable to complete hard dock. It was able to insert its probe into the drogue assembly, but could not secure the latches in the docking ring to create an airtight seal. After four docking attempts, Soyuz 25 backed away from the station. Three orbits later, it again failed to hard dock. Mission rules specified immediate preparations for return to Earth because of the limited lifetime of its batteries. Insufficient propellant remained for docking at the Salyut 6 aft port. Suspicion fell on the Soyuz 25 probe docking unit as the cause of the failure. Because the orbital module was discarded at reentry, it was impossible to inspect the unit to confirm that it caused the trouble.

Landing crew—Vladimir Dzhanibekov, Oleg Makarov Crew code name—Pamir Docked at the aft port. Its crew inspected the front port drogue unit and found no abnormalities, increasing suspicions that the Soyuz 25 docking apparatus caused its docking failure. The Soyuz 26 crew remained aboard Salyut 6 for 96 days, surpassing the spaceflight endurance record set by the third manned Skylab mission. Their spacecraft returned to Earth before that, replaced by Soyuz 27 after about 60 days docked to Salyut 6.

Landing crew—Yuri Romanenko, Georgi Grechko
Crew code name—Tamyr

Docked with the Salyut 6 front port, confirming that the port functioned normally. This marked the first time two Soyuz craft were docked to a station at the same time. The two guest cosmonauts transferred their custom-molded couch liners from Soyuz 27 to Soyuz 26. They returned to Earth in the older craft, leaving the long-duration crew a fresh spacecraft. This was the first of many times the Soviets swapped spacecraft in orbit.

Carried the first non-U.S./non-Soviet space traveler, Remek, who was also the first cosmonaut-researcher to fly as part of the international Intercosmos program.

Landing crew—Valeri Bykovski, Sigmund Jähn/E. Germany
Crew code name –Yastreb

Foton crew spent 140 days on Salyut 6. The Yastrebs launched to Salyut 6 in Soyuz 31 and returned to Earth in Soyuz 29.

Intercosmos flight to Salyut 6.

Landing crew—Vladimir Kovalyonok, Alexandr Ivanchenkov
Crew code name—Foton

Carried first German space traveler, paired with veteran cosmonaut Bykovski (he flew solo in Vostok 5, June 1963). After the Yastrebs departed from Salyut 6 in Soyuz 29 on September 3, the Fotons transferred Soyuz 31 to the Salyut 6 front port. Moving a replacement Soyuz to the front port became standard procedure; it freed the aft port for Progress supply ships.

Landing crew—none

Its long-duration crew spent 175 days on Salyut 6. Less than 2 months into their stay, Soyuz 33 failed to dock because of a main engine malfunction. Soyuz 32 returned to Earth unmanned with a cargo of experiment results and equipment no longer in use after Soyuz 34 had docked unmanned with Salyut 6 to replace it.

Failed to dock with Salyut 6. Fired its main engine while closing to within 4 km of the station. The burn, the sixth of the flight, was to have lasted 6 sec, but the engine shut down after 3 sec. The Igla docking system also closed down. The Proton crew aboard Salyut 6 reported flames shooting sideways from the main engine, toward the backup engine, at the time of the shutdown. The docking was called off and the Saturns made ready to return to Earth. The backup engine fired, but did not shut off at the end of the planned 188-sec burn. Rukavishnikov, uncertain if the engine operated at the proper thrust, determined to let it burn an additional 25 sec before shutting it down manually. As a result, Soyuz 33 made a steep ballistic reentry with gravity loads up to 10 g’s. Because the service module was discarded after deorbit burn, examination of the failed engine was impossible. The Soyuz 33 crew was to have traded its spacecraft for Soyuz 32.^[64]

Landing crew—Vladimir Lyakhov, Valeri Ryumin
Crew code name—Proton

Launched unmanned to replace Soyuz 32 following the Soyuz 33 failure. Soyuz 34 included main engine modifications made to prevent a recurrence of the Soyuz 33 failure.^[65]

Crew code name—Orion

Returned to Earth carrying the crew launched on Soyuz 36.

Landing crew—Viktor Gorbatko, Pham Tuan/Vietnam
Crew code name—Terek

Hungarian Intercosmos mission. Postponed from June 1979 after the Soyuz 33 main engine failure. Kubasov and Farkas traded their spacecraft for Soyuz 35. Soyuz 36 was later traded for Soyuz 37.

Crew code name—Terek

Landing crew—Leonid Popov, Valeri Ryumin
Crew code name—Dneiper

Intercosmos mission to Salyut 6. Returned the Dneiper long-duration crew launched in Soyuz 35 to Earth.

Intercosmos mission to visit the Dneipers on Salyut 6.

Intercosmos mission to Salyut 6. The Soyuz 39 crew visited Vladimir Kovalyonok and Viktor Savinykh, who were delivered by the Soyuz-T 4 spacecraft.

Last Soyuz Ferry flight; ended the first phase of the Intercosmos program, which concentrated on placing citizens of Soviet bloc states into space. In all, nine Intercosmos missions were launched between 1978 and 1981.^[66]

1.9 ASTP Soyuz (1974-1976)

ASTP Soyuz (figure 1-21) was the Soyuz Ferry modified to carry out the specialized mission of docking with a U.S. Apollo spacecraft in Earth orbit.

Figure 1-21. Apollo-Soyuz Test Project (ASTP) Soyuz. The APAS-75 docking unit is located at left.

1.9.2 ASTP Soyuz Notable Features

Soyuz 22, the backup to the Soyuz 19 ASTP Soyuz which docked with Apollo, did not incorporate all these notable features. Some may also have been absent from the Cosmos 638 and Cosmos 672 ASTP Soyuz spacecraft; nonetheless, the ASTP Soyuz was generally associated with the following notable features:

• Advanced solar arrays.
• Modified life support systems capable of supporting four crew. This was necessary for Apollo crew visits to Soyuz, and also in

the event that Soyuz had to pull away from Apollo with two Americans aboard.

• APAS-75 androgynous docking unit (figure 1-22) compatible with the unit on the docking module.

U. S. and Soviet engineers jointly developed the system for ASTP. APAS is the acronym for the English translation, “androgynous peripheral assembly system,” and the number is the year of its first use in space.

• Modified coloration for compatibility with Apollo rendezvous sensors.
• Improved control systems.

• Docking tone ranging system and light beacons compatible with Apollo.
• Antennas and UHF air-to-air radio equipment compatible with Apollo. Also radio equipment permitting relay through the U.S. ATS-6 satellite.
• Standard Soyuz launch shroud modified to protect the outwardfacing guides of the APAS-75 docking unit.

Figure 1-22. APAS-75 docking unit. Unlike previous docking systems, both units could
assume the active or passive roles as required. For docking, the spade-shaped guides
of the extended active unit (right) and the retracted passive unit (left) interacted
for gross alignment. The ring holding the guides shifted to align the active unit
latches with the passive unit catches. After these caught, shock absorbers dissipated
residual impact energy in the American unit; mechanical attenuators served the same
function on the the Soviet side. The active unit then retracted to bring the docking
collars together. Guides and sockets in the docking collars completed alignment.
Four spring push rods drove the spacecraft apart at undocking. The passive craft could
play a modified active role in undocking if the active craft could not complete the
standard undocking procedure. Pyrotechnic bolts provided backup.

Crew code name—Buran

Manned test of the ASTP Soyuz. Carried the APAS-75 androgynous docking system.

Crew code name—Soyuz

Docked with Apollo through the intermediary of a docking module using the APAS-75 unit on July 17, 1975 (figure 1-23). Soyuz 19 was officially referred to as Soyuz, just as the Apollo craft used was simply called Apollo (while some sources refer to the craft as Apollo 18, this was not the official designation). The craft undocked on July 19, redocked for 3 hours, then separated to conduct independent operations. Apollo landed after Soyuz, on July 24, 1975.

Crew code name –Yastreb

Flight of the backup ASTP Soyuz. In place of the APAS-75 androgynous docking system or other docking apparatus, it carried an East German MKF-6 camera. It operated in a 64.75° orbit to improve its abilities as an Earth observation platform.

1.10 Progress (1975-1990)

Progress (figure 1-24) was an unmanned version of the Soyuz Ferry designed to perform logistics resupply of the Salyut 6, Salyut 7, and Mir space stations. Progress missions 1 through 12 carried supplies to Salyut 6. Missions 13 through 24 visited Salyut 7, as did the unusual Progress-related Cosmos 1669 mission. Progress missions 25 through 42 served the Mir station. The first 17 Progress missions to Mir delivered 40 tons of supplies, about double the station’s launch weight. Most Progress spacecraft functioned routinely, as expected of a logistics spacecraft. No docking anomalies occurred in the 43 flights of Progress (Progress 1 through 42 plus Cosmos 1669).

Figure 1-24. Progress logistics resupply spacecraft. It consists of the dry cargo module (left); the tanker compartment (center); and a stretched service module (right).

1.10.2 Progress Notable Features

• Launched on a Soyuz rocket under the same type of shroud as the Soyuz Ferry, but with no escape systems.
• Always docked with the aft port of its station target.
• Soyuz descent module replaced by tanker compartment, an assemblage of tanks in an unpressurized conical housing. The pressurized orbital module carried dry cargo. The crew could enter the orbital module to unload dry cargo, but had no access to the tanker compartment.

• No part of Progress was designed to be recovered. At the conclusion of its space station resupply mission, a Progress freighter was intentionally deorbited over the Pacific Ocean, where any pieces which survived incineration could fall harmlessly.

1.10.3 Progress Detailed Description

Spacecraft designer Konstantin Feoktistov published a brochure in 1980 in Moscow in which he described Progress in some detail.^[67] A summary is given below.

Feoktistov stated that Progress constituted an alternative to building reusable (“multiple use”) logistics vehicles. A reusable vehicle, he asserted, would be 1.5 to 2 times heavier empty than the equivalent expendable logistics craft. This would call for a booster nearly as large as the three-stage Proton rocket used to launch Salyut. “If we are talking about an economically effective earth-orbit-earth transport system,” Feoktistov continued, “then it appears expedient to build a fully multiple use complex, not only the spaceship, but also the booster rocket.” This would take too much time; therefore, “when designing the Progress spacecraft the decision was made to make it single-use and to

utilize the . . . Soyuz rocket to insert it [into orbit].”

The Progress orbital module (“cargo bay”) was two hemispheres welded together through the intermediary of a short cylindrical section (very similar to the Soyuz orbital module). The forward hemisphere contained the docking unit and the port connecting the orbital module to the space station. Unlike Soyuz, Progress had no hatch in the aft hemisphere. The orbital module contained a supporting framework to which large equipment (such as air regenerators) was attached. Small items were packed in bins.

The probe and drogue docking unit used on Progress resembled the Soyuz unit. The chief difference was provision of two ducted mating connectors (one each for UDMH fuel and N₂O₄ oxidizer) in the Progress

docking collar for propellant transfer to corresponding connectors in the station collar. Three television cameras were carried near the docking unit.

The tanker compartment carried two tanks each of UDMH and N₂O₄. Feoktistov stressed that these propellants were “chemically aggressive and poisonous to man.” To avoid spillage into the pressurized volumes of the station or the supply ship, fuel lines from the unpressurized tanker compartment ran along the exterior of the Progress orbital module, through the ducts in the docking collar, then into the unpressurized section containing the main propulsion system, which was located around the intermediate compartment at the aft end of the space station. The tanker compartment also carried tanks filled with nitrogen to serve as pressurant for

the fuel system and to purge it of residual propellants. This prevented propellants from spilling on the docking apparatus and being accidentally introduced into the station.

Control equipment normally located in the Soyuz orbital and descent modules was placed in the service module of the Progress spacecraft. The service module also carried equipment for controlling propellant transfer. Progress had mounted to its service module two infrared local vertical sensors (horizon sensors) and two ion sensors for its guidance system. Soyuz, by contrast, had one ion sensor and one infrared horizon sensor. Redundancy was provided because Progress was a wholly automated craft. The Progress service module was longer than the Soyuz module because of the extra equipment it carried.

deployment.

24.

1.11 Progress-M (1989-Present)

Progress-M (figure 1-26) is the Progress logistics resupply spacecraft upgraded by incorporating Soyuz-TM technology and other improvements.

Figure 1-26. Progress-M logistics resupply spacecraft.

1.11.1 Progress-M Specifications^[79]

Figure 1-27. Ballistic return capsule (Raduga) during final descent to Earth.

Launch weight .......................................... 7130 kg
Weight of cargo (maximum) ....................... 2600 kg (maximum)
Weight of dry cargo (maximum) ................. 1500 kg (maximum)
Weight of liquid and gaseous
cargo (maximum) ..................................... 1540 kg* (maximum)
Length ..................................................... 7.23 m
Span across solar arrays .......................... 10.6 m
Volume of dry cargo compartment .............. 7.6 m³
Diameter of cargo modules ........................ 2.2 m
Maximum diameter ................................... 2.72 m

*Includes 200 kg of propellant transferred to Mir from Progress-M propulsion system.

1.11.2 Progress-M Notable Features

• Independent flight time of up to 30 days (10 times longer than the Progress 1 through 42 spacecraft).
• Increased cargo load delivered to Mir (on average, about 100 kg greater than carried by Progress 25 through 42).
• Return payload capability when equipped with Raduga (“rainbow”) ballistic return capsule (figure 1-27). The Russians use this capsule to return small, valuable payloads from Mir. It was named Raduga largely for

cargo compartment. At the beginning of Raduga’s return to Earth, the Progress-M completes its deorbit burn. At an altitude of about 120 km, the capsule separates. The Progress-M undergoes destructive reentry, while the capsule makes an intact reentry, with landing and recovery in central Asia. Raduga is used to return up to 150 kg of payloads to Earth two or three times each year. Each Raduga capsule is about 1.5 m long, is 60 cm in diameter, and weighs about 350 kg empty. Use of the Raduga

ballistic return capsule lowers Progress-M cargo capacity by about 100 kg, to a maximum of about 2400 kg. Progress-M 5 carried the first Raduga capsule.

• Ability to dock and transfer propellant at the Mir front port.

• Ability to transfer excess propellant (up to 200 kg) in Progress-M service module to Mir, or transfer propellant from Mir to Progress-M service module.
• Kurs rendezvous and docking system (same as Soyuz-TM).

Solar arrays like those on Soyuz-TM. While docked, its solar arrays augment Mir’s electrical supply.

1.12 Soyuz-T (1976-1986)

Soyuz-T (figure 1-28) replaced Soyuz Ferry. The “T” stands for transport. Soyuz-T gave the Soviets the ability to launch three cosmonauts in a single spacecraft for the first time since Soyuz 11 in 1971. It was used with the Salyut 6, Salyut 7, and Mir stations.

Figure 1-28. Soyuz-T spacecraft.

1.12.2 Soyuz-T Notable Features

• Ability to carry three crew in pressure suits, or two crew in pressure suits and 100 kg of additional cargo weight.
• Solar arrays (similar to those on the ASTP Soyuz) replaced batteries as the primary source of electrical power. These were smaller and more efficient than those used on the Original Soyuz and Salyut 1-type Soyuz.^[80]
• “Unified” (integrated, or combined) propulsion system: attitude control rockets and main engines drew on the same

supplies of N₂O₄ and UDMH propellants.

• Orbital module was discarded prior to deorbit burn to reduce the mass of the Soyuz-T, resulting in a 10% propellant savings. Occasionally the Soyuz-T descent and service modules detached from the orbital module while it was still attached to the Salyut. Typically the orbital module was then detached from the Salyut within a few hours.
• Igla approach system.
• Chayka flight control system featuring BTSVK digital computer. The computer, also called Argon, had 16 kilobytes of RAM. Under nominal conditions, the

computer replaced the groundbased computers and ground measurement stations which had guided earlier Soyuz craft. Previous Soyuz spacecraft had relied on hard copy technical documentation carried in the descent module and data transmitted in verbal form from the TsUP analysis group. Argon prepared data which it simultaneously displayed on screens in the descent module and in the TsUP. In addition, control systems were upgraded to include integrated circuit chips, saving volume and weight.^[81]

• New main engine similar to that used on Progress. Elimination of

backup engine (with KDU system, attitude thrusters can draw on main propellant supply and thereby deorbit Soyuz-T, removing the need for a separate backup main engine).

• Jettisonable covers for portholes which permitted crew to look out of the spacecraft after reentry. On earlier flights a black coating

formed on the portholes during reentry and prevented crews from looking outside during descent and on the surface.

• A lighter launch escape system.
• Improved telemetry capabilities.
• More powerful land landing system solid rocket motors. This made for a gentler touchdown,

important for the health and safety of the cosmonauts after a long-duration flight.

• Sufficiently different from the Soyuz Ferry that crews required more than a year of special training to be able to fly it. This accounted in part for the gradual introduction of Soyuz-T, while Soyuz Ferries continued to fly.^[82]

First manned Soyuz-T mission. Its crew of two took over from the Argon computer system during final approach to the station, after it committed a guidance control error.

First Soyuz since 1971 to carry three cosmonauts. It constituted a Salyut 6 refurbishment mission.

Docking with Salyut 6 delayed after the onboard Argon computer determined it would occur outside of radio range with the TsUP. In mid-May, Kovalyonok and Savinykh replaced the Soyuz-T 4 probe with a Salyut drogue. This may have been an experiment to see if a Soyuz-T docked to a space station could act as a rescue vehicle in the event that an approaching Soyuz-T equipped with a probe experienced docking difficulties and could not return to Earth.

Landing crew—Leonid Popov, Alexandr Serebrov, Svetlana Savitskaya
Crew code name—Dneiper

First Soyuz to dock with Salyut 7.

Suffered Argon computer failure 900 m from Salyut 7. Commander Vladimir Dzhanibekov took manual control and docked with the station 14 minutes ahead of schedule. The skill he displayed contributed to his being tapped for the Soyuz-T 13 mission to rescue Salyut 7 in 1985. Chretien’s launch marked the start of a new phase in the manned Intercosmos flights.

Landing crew—Anatoli Berezevoi, Valentin Lebedev
Crew code name—Elbrus

Svetlana Savitskaya was the first woman in space since Valentina Tereshkova (who flew in 1963 on Vostok 6).

First failure to dock at a space station since Soyuz 33 in 1979. When the launch shroud separated from the booster, it took with it the rendezvous antenna boom. The crew believed the boom remained attached to the spacecraft’s orbital module, and that it had not locked into place. Accordingly, they shook the spacecraft using its attitude thrusters in an effort to rock it forward so it could lock. The abortive docking attempts consumed much propellant. To ensure that enough would remain to permit deorbit, the cosmonauts shut down the attitude control system and put Soyuz-T 8 into a spinstabilized mode of the type used by Soyuz Ferries in the early 1970s. Landing occurred as normal.

Its mission was heavily impacted by the Soyuz-T and Soyuz booster failures which bracketed it.

Refer to figure 1-29. Shortly before liftoff fuel spilled around the base of the Soyuz launch vehicle and caught fire. Launch control activated the escape system, but the control cables had already burned. The crew could not activate or control the escape system, but 20 sec later ground control was able to activate the escape system by radio command. By this time the booster was engulfed in flames. Explosive bolts fired to separate the descent module from the service module and the upper launch shroud from the lower. Then the escape system motor fired, dragging the orbital module and descent module, encased within the upper shroud, free of the booster at 14 to 17 g’s of acceleration. Acceleration lasted 5 sec. Seconds after the escape system activated, the booster exploded, destroying the launch complex (which was, incidentally, the one used to launch Sputnik 1 and Vostok 1). Four paddle-shaped stabilizers on the outside of the shroud opened. The descent module separated from the orbital module at an altitude of 650 m, and dropped free of the shroud. It discarded its heat shield, exposing the solid-fueled land landing rockets, and deployed a fast-opening emergency parachute. Landing occurred about 4 km from the launch pad. The aborted mission is often called Soyuz-T 10a in the West. This was the last failed attempt to date to reach a space station to date.^[83]

Landing crew—Vladimir Dzhanibekov, Svetlana Savitskaya, Igor Volk
Crew code name—Pamir

Called Soyuz-T 10b in the West.

Landing crew—Leonid Kizim, Vladimir Solovyov, Oleg Atkov
Crew code name—Mayak

Carried the first Indian cosmonaut to the Salyut 7 station.

Volk was a glimpse of things which might have been: he was a Buran shuttle program pilot being flown in space to prove he would be able to pilot Buran back to Earth after an extended stay in space.

Landing crew—Vladimir Dzhanibekov, Georgi Grechko
Crew code name—Pamir

Vladimir Dzhanibekov could have had no notion that he would so soon visit Salyut 7 after his Soyuz-T 12 flight. Soyuz-T 13 was the first Soyuz to dock manually with an inert Salyut. For the purpose it was slightly modified to include control levers in the descent module for proximity operations. Viktor Savinykh and Vladimir Dzhanibekov salvaged the Salyut 7 station, which had been crippled by a solar array problem (see section 2.8.3.4). Savinykh remained aloft for 169 days, returning to Earth in Soyuz-T 14; Dzhanibekov returned to Earth in Soyuz-T 13 with Grechko after spending 110 days on Salyut 7. Before deorbiting, Soyuz-T 13 spent about 30 hr conducting rendezvous and docking tests.

Landing crew—Vladimir Vasyutin, Viktor Savinykh, Alexandr Volkov
Crew code name—Cheget

Demonstrated the wisdom of maintaining a Soyuz at Salyut 7 as an emergency medical evacuation vehicle. Vasyutin, the mission commander, fell ill, forcing early termination of the planned 6-mo mission.

Carried the first two cosmonauts to the Mir station. May 5-6 they transferred to Salyut 7, where they conducted two EVAs and collected experiment results, experimental apparatus, and samples of materials. They returned to Mir on June 25-26.

1.13 Soyuz-TM (1986-Present)

Soyuz-TM (figure 1-30) is an upgraded version of Soyuz-T used with the Mir space station. The “TM” in Soyuz-TM is usually translated as “transport modified,” meaning that it is a further improvement of the Soyuz-T.

Figure 1-30. Soyuz-TM spacecraft. Compare the antennae on the orbital module to those on Soyuz-T. Differences reflect the change from the Igla rendezvous system used on Soyuz-T to the Kurs rendezvous system used on Soyuz-TM.

1.13.2 Soyuz-TM Notable Features

• The Kurs rendezvous system, which permitted automatic dockings with an unresponsive space station, replaced the Igla system. Kurs could operate at greater distances from a station than Igla, and could lock on even if its antennas were not aligned with those on the target station; that is, the antennas were omnidi-

rectional and did not have to be in line of sight.

• 10-kg launch and reentry pressure suits, which in an emergency can protect the wearer in open space.
• Lighter parachutes, which take up less room in the descent module and save up to 140 kg of weight.
• Launch payload increased by 200-250 kg to 51.6° orbit; return payload increased by 70-90 kg.
• Improved propellant tanks—these featured metal membranes for

dividing the oxidizer from the fuel. Past Soyuz propellant systems used organic (plastic?) membranes which could leak, degrading engine performance.

• Improved communications gear—separate voice channels for each cosmonaut and improved reception quality.
• Improved landing radar altimeter.
• Lighter escape system motors.
• Triple redundant electrical systems, and redundant hydraulic systems.

Landing crew—Alexandr Viktorenko, Alexandr Laveikin, Mohammed al Faris/Syria
Crew code name—Vityaz

Laveikin developed heart irregularities which made necessary his early return to Earth.

Landing crew—Yuri Romaneko, Alexandr Alexandrov, Anatoli Levchenko
Crew code name—Tamyr

Faris was the first Syrian in space. Alexandrov was Laveikin’s replacement aboard Mir, becoming Romanenko’s new partner.

Landing crew—Anatoli Solovyov, Viktor Savinykh, Alexandr Alexandrov/Bulgaria
Crew code name—Rodnik

Manarov and Titov spelled Romanenko and Alexandrov. Anatoli Levchenko was a cosmonaut in the Buran shuttle program. Levchenko returned with Romanenko and Alexandrov in Soyuz-TM 3.

Landing crew—Alexandr Lyakhov, Abdul Ahad Mohmand/Afghanistan Crew code name—Proton

Arrived at Mir carrying the second Bulgarian in space, Alexandrov (not to be confused with the Soviet cosmonaut of the same name). He became the first Bulgarian to reach a Soviet space station (Georgi Ivanov failed to reach Salyut 6 on Soyuz 33 in 1979—Alexandrov was his backup). Their launch had been advanced by 2 weeks late in the planning stages to improve lighting conditions for the Rozhen astronomical experiment. On September 5 cosmonauts Alexandr Lyakhov and Abdul Ahad Mohmand undocked from Mir. They jettisoned the orbital module and made ready for deorbit burn to return to Earth. However, unbeknownst to the cosmonauts or TsUP, the guidance computer was using the docking software of the Bulgarian Mir mission in June. The deorbit burn did not occur at the appointed time because the infrared horizon sensor could not confirm proper attitude. Seven minutes after the scheduled time, the sensor determined that the correct attitude had been achieved. The main engine fired, but Lyakhov shut it down after 3 sec. A second firing 3 hr later lasted only 6 sec. Lyakhov immediately attempted to manually deorbit the craft, but the computer shut down the engine after 60 sec. The cosmonauts were forced to remain in orbit a further day. Even if the main engine had permitted them to do so, they would not have been able to redock with Mir because they had discarded the docking system along with the orbital module. The cosmonauts were left for a day in the cramped quarters of the descent module with minimal food and water and no sanitary facilities. Reentry occurred as normal on September 7. After this the Soviets retained the orbital module until after deorbit burn, as they had done on the Soyuz Ferry flights.

Landing crew—Vladimir Titov, Musa Manarov, Jean-Loup Chretien/France
Crew code name—Okean

Dr. Valeri Polyakov remained behind on Mir with cosmonauts Musa Manarov and Vladimir Titov when Mohmand and Lyakhov returned to Earth in Soyuz-TM 5.

Landing crew—Alexandr Volkov, Sergei Krikalev, Valeri Polyakov
Crew code name—Donbass

Original launch date of November 21 was moved back to permit French president Francois Mitterand to attend the launch. Arrived at the Mir station carrying a three-man crew, including French cosmonaut Chretien on his second flight into space. Titov, Manarov, and Chretien returned to Earth in Soyuz TM-6. Alexander Volkov, Sergei Krikalev, and Valeri Polyakov remained aboard Mir. On April 28, 1989, they left Mir in mothballs and returned to Earth in Soyuz-TM 7. The Soyuz-TM land landing system is effective at reducing velocity in the vertical direction. However, according to cosmonaut Sergei Krikalev, winds at the landing site often impart considerable horizontal velocity. As a result, about 80% of all Soyuz descent modules come to rest on their sides. During the rough landing, Krikalev suffered a minor injury to his knee.^[84]

Launch vehicle was painted with advertisements. During final approach to Mir (4 m distance), the Kurs system malfunctioned, so Viktorenko took over manual control and withdrew to 20 m. He then docked manually. Spent 166 days attached to Mir.

During docking, cosmonauts aboard Mir noticed that three of the eight thermal blankets (layers of foil vacuum-shield insulation) on the descent module of the approaching Soyuz-TM 9 spacecraft had come loose from their attachments near the heat shield, yet remained attached at their top ends. The main concern was that the capsule might cool down, permitting condensation to form inside and short out its electrical systems. There was also fear that the blankets might block the infrared vertical sensor, which oriented the module for reentry. Three other areas of concern emerged: that the explosive bolts binding the service module to the descent module might fail to work after direct exposure to space, that the heat shield might be compromised by direct space exposure, and that an EVA to repair the blankets might cause additional damage. Consideration was given to flying Soyuz-TM 10 with one cosmonaut aboard as a rescue mission. During an EVA, the cosmonauts folded back two of the three blankets and left the third alone. During reentry, the cosmonauts ejected both the orbital module and the service module simultaneously in an effort to minimize the chances that a blanket could snag. Normally the orbital module went first. The descent module suffered no damage as a result of its prolonged exposure to space conditions. Reentry occurred as normal.

Landing crew—Gennadi Manakov, Gennadi Strekalov, Toyohiro Akiyama/Japan
Crew code name—Elbrus

Spent 131 days attached to Mir. A camera was installed in the descent module as part of the agreement with Akiyama’s network to film the reactions of the returning cosmonauts.

Landing crew—Viktor Afanasyev, Musa Manarov, Helen Sharman/Britain
Crew code name—Derbent
Spent 175 days docked to Mir. Its launch shroud and Soyuz booster were painted with the Japanese flag and advertisements. A camera inside the descent module filmed the cosmonauts during ascent for Akiyama’s network.

Landing crew—Anatoli Artsebarski, Toktar Aubakirov/Kazakhstan, Viehboeck/Austria
Crew code name—Ozon

Spent 144 days docked to Mir. While it was in orbit, the failed coup d’etat against Mikhail Gorbachev rocked the Soviet Union, setting in motion events which led to the end of the Soviet Union on January 1, 1992.

Landing crew—Alexandr Volkov, Sergei Krikalev, Klaus-Dietrich Flade/Germany
Crew code name—Donbass

Spent 175 days docked to Mir. Krikalev launched from the Kazakh Soviet Socialist Republic of the Soviet Union, and landed in independent Kazakhstan.

Landing crew—Alexandr Viktorenko, Alexandr Kaleri, Michel Tognini/France
Crew code name—Vityaz

Suffered a landing system malfunction, causing its descent module to turn over. It came to rest upside down, trapping its occupants inside until it could be righted.

Landing crew—Sergei Avdeyev, Anatoli Solovyov
Crew code name—Rodnik

Tognini spent 3 weeks in space as part of ongoing space cooperation between Russia and France.

Landing crew—Gennadi Manakov, Alexandr Poleschuk, Jean-Pierre Hagniere/France
Crew code name—Elbrus

First Soyuz without a probe and drogue docking system since 1976. It carried an APAS-89 androgynous docking unit (see figure 3-13) different from the APAS-75 unit (see figure 1-22) used for ASTP in 1975, yet similar in general principles. Soyuz-TM 16 used it to dock with an androgynous docking port on the Kristall module. This was a test of the docking system in preparation for dockings by space shuttles with Mir.

Landing crew—Vasili Tsibliyev, Alexandr Serebrov
Crew code name—Sirius

At 7:37:11 a.m. Moscow time (MT), on January 14, Soyuz-TM 17 separated from the forward port of the Mir station. At 7:43:59 a.m., the TsUP ordered Tsibliyev to steer Soyuz-TM 17 to within 15 m of the Kristall module to begin photography of the APAS-89 docking system. At 7:46:20 a.m., Tsibliyev complained that Soyuz-TM 17 was handling sluggishly. Serebrov, standing by for photography in the orbital module, then asked Tsibliyev to move the spacecraft out of the station plane because it was coming close to one of the solar arrays. In Mir, Viktor Afanasyev ordered Valeri Polyakov and Yuri Usachyov to evacuate to the Soyuz-TM 18 spacecraft. At 7:47:30 a.m., controllers in the TsUP saw the image from Soyuz-TM 17’s external camera shake violently, and Serebrov reported that Soyuz-TM 17 had hit Mir. The TsUP then lost communications with Mir and Soyuz-TM 17. Intermittent communications were restored with Soyuz-TM 17 at 7:52 a.m. Voice communications with Mir were not restored until 8:02 a.m. Inspection of Soyuz-TM 17 indicated no serious damage. In this connection, the Russians revealed that they had studied contingency reentries by depressurized spacecraft in the wake of the Soyuz 11 accident. The Mir cosmonauts did not feel the impact, though the station’s guidance system registered angular velocity and switched to free flying mode. Later analysis indicated that the right side of the orbital module had struck Mir two glancing blows 2 sec apart. The impact point was on Kristall, near its connection to the Mir base block. The cause of the impact was traced to a switch error: the hand controller in the orbital module which governed braking and acceleration was switched on, disabling the equivalent hand controller (the left motion control lever) in the descent module. Tsibliyev was able to use the right lever to steer Soyuz past Mir’s solar arrays, antennas, and docking ports after it became clear impact was inevitable.^[85][86]

Landing crew—Viktor Afanasyev, Yuri Usachyov
Crew code name—Derbent

Afanseyev and Usachyov spent 179 days on Mir. Dr. Polyakov is slated to return to Earth on Soyuz-TM 20 in March 1995, after more than 420 days on Mir.

Commander Malenchenko and Flight Engineer Musabayev, spaceflight rookies, were to have been launched with veteran cosmonaut Gennadi Strekalov, who would have returned to Earth with Viktor Afanaseyev and Yuri Usachyov in Soyuz-TM 18 after a few days on Mir. However, cancellation of one of two Progress-M cargo ships scheduled to resupply Mir during the Agat crew’s stay meant Strekalov’s couch had to carry supplies. The result was an unusual all-rookie flight. Docking occurred without incident on July 3. On November 3, Musabayev, Malenchenko, and Merbold undocked in Soyuz-TM 19 and backed 190 m from Mir. They then activated the Kurs automatic approach system, which successfully redocked the spacecraft. The cosmonauts then transferred back to Mir. The test was related to the difficulties Soyuz-TM 20 and Progress-M 24 experienced during their automatic approaches. Final undocking and reentry the following day occurred without incident.

Landing crew–
Crew code name–Vityaz

Carried 10 kg of equipment for use by Merbold in ESA’s month-long Euromir 94 experiment program. During automatic approach to Mir’s front port, the spacecraft yawed unexpectedly. Viktorenko completed a manual docking without additional incident.