SM-65A Atlas

Last updated
Atlas A (SM-65A)
Atlas missile launch.jpg
Launch of Atlas 11A from LC-12 at CCAS
FunctionPrototype ICBM
Manufacturer Convair
Country of originUnited States
Launch history
StatusRetired
Launch sites LC-12 & LC-14, CCAFS
Total launches8
Success(es)4
Failure(s)4
First flight11 June 1957
Last flight3 June 1958
Boosters
No. boosters1
Powered by2 XLR-89-1
Total thrust341,128 lbf (1,517.41 kN)
Specific impulse 282 s
Burn time133 s
Propellant RP-1/LOX

The Convair SM-65A Atlas, or Atlas A, was the first full-scale prototype of the Atlas missile, which first flew on 11 June 1957. Unlike later versions of the Atlas missile, the Atlas A did not feature the stage and a half design. Instead, the booster engines were fixed in place, and the sustainer engine was omitted. The propulsion system used on the initial Atlas As was an early version of the Rocketdyne MA-1 engines with conical thrust chambers that produced a mere 135,000 pounds of thrust, compared with the 360,000 pounds of the fully operational Atlas D. Several pieces of hardware found on the operational Atlas were either missing on the A-series or only partially implemented. Powered flight on the A-series would last about two minutes and compared to later Atlases, long pad hold-down times, with up to 11 seconds between engine start and launcher release.

Contents

The first three Atlases built were used merely for static firing tests with Missile 4A being the first flight article. It was delivered to Cape Canaveral in December 1956 and erected on LC-14 in March 1957, where it sat until the following summer.

Test history

The last Atlas A (vehicle 16A) is launched at Cape Canaveral on 3 June Launch of Atlas A.JPG
The last Atlas A (vehicle 16A) is launched at Cape Canaveral on 3 June

On June 11, 1957, the Atlas made its maiden voyage. Engine start proceeded normally and the launcher release system also functioned properly. All went well until T+26 seconds when the B-2 engine lost thrust, followed two seconds later by the B-1 engine. The Atlas reached a peak altitude of 9,800 feet (3,000 meters) and tumbled end-over-end through its own exhaust trail until T+50 seconds when the range safety officer sent the destruct command.

During 4A's launch, thousands of spectators lined the beaches around Cape Canaveral to watch, although the Air Force did not confirm that the new missile was in fact an Atlas. The sensational press reports of the missile cartwheeling and exploding in mid-air belied the fact that program officials did not really consider the test a failure, and that all things considered, the Atlas had performed far better than expected.

Analysis of telemetry data confirmed that the Atlas had malfunctioned due to hot exhaust gases being recirculated into the thrust section, which apparently caused failure of propellant ducting and engine shutdown due to LOX starvation. The pneumatic system also malfunctioned as tank pressure never properly transitioned to in-flight levels and along with propellant flow and pressure steadily decreased during ascent. The flight was considered a partial success because the missile had otherwise performed well. In particular, the Atlas's inflated balloon structure, which engineers doubted would even fly at all, had held together as the missile tumbled. The flight control system also worked well as it tried in vain to correct the missile's flight path.

Convair engineers decided that the Atlas needed a heat shield in the thrust section more substantial than the thin fiberglass one included on the missile. They proposed a modified heat sink made from steel and fiberglass, but the Air Force rejected that idea as the shield would be extremely heavy and also complicate booster section staging on operational Atlases. As one small modification, the pneumatic system was modified to vent inert helium gas down into the thrust section to reduce the risk of fire.

On September 25, Missile 6A was launched. Aside from more instrumentation in the thrust section and the above-mentioned helium vent modification, it was identical to 4A and predictably met the same fate as once again, the thrust section overheated. Thrust levels in both engines dropped to only 35% at T+32 seconds and two seconds later, the propulsion system completely shut down. The Range Safety destruct command was sent at T+63 seconds. This time, overheating and high vibration levels had caused a LOX regulator to fail, resulting in gas generator flameout. After this debacle, the Air Force relented and accepted the need for an improved heat shield. Other modifications were made as well, including removal of the long skirt covering the boattail and engine nozzles. The gas generator vent pipe was changed to point outward and away from the missile instead of directly underneath it. The engine nozzles were covered with fiberglass insulation boots and aluminum plumbing in the Atlas changed to steel plumbing which had a greater heat tolerance. The autopilot received additional filters to dampen vibration levels.

The overheating problems had not shown up on the static firing tests of Missiles 1A-3A, but it was later revealed that the engineering crews at the Sycamore test stand had had the plumbing changed to steel because it reduced the risk of overheating compared with the aluminum plumbing on flight article missiles. The PFRF (Pre Flight Readiness Firing) tests conducted on 4A and 6A also would have caused exhaust gases to go up into the boattail, and thus they probably already had internal damage at launch.

On December 17, Missile 12A lifted from LC-14. The modified boattail worked; the Atlas performed well on its first successful launch, an event that raised morale after the devastating blow of two Soviet space launches and the failure of Vanguard a week earlier. This was the first Atlas with a functional guidance system (although open loopthe guidance system was included merely for evaluation purposes and not actually added to the flight program until the B-series tests), as Missiles 4A and 6A merely had a dummy guidance receiver that test patterns were transmitted to. At T+75 seconds, the guidance system tracking beacon shorted, which caused a momentary large drain on the batteries but did not otherwise affect missile performance. The missile's flight trajectory in the yaw axis by the time of Booster Engine Cutoff (BECO) deviated by about 10,000 feet (3,000 meters) from the planned program, studies of trajectory data showed this anomaly to be nearly constant during powered flight. It was concluded that there had been an incorrect offset in the yaw axis, either from a misaligned engine, yaw gyro, or some combination of both. After the success of the launch, the Air Force acknowledged for the first time that the missile was in fact an Atlas.

Atlas A launch from Cape Canaveral in 1958 Atlas Missile launch- Cape Canaveral, Florida (8594154699).jpg
Atlas A launch from Cape Canaveral in 1958

The fourth Atlas test involved Missile 10A, which was erected on LC-12 in September and would have been the third Atlas launched, but there were considerable difficulties getting it ready for flight. After the postflight findings from 6A, it was taken down for modifications and a PFRF firing on December 10 resulted in the B-1 thrust chamber rupturing from rough combustion. The thrust chamber was replaced, and a launch attempt was made on December 16, but had to be aborted following a leak in the B-1 main fuel valve. A second launch attempt on January 7, 1958, failed due to another fuel valve leak, and finally on January 10, the missile was launched. 10A performed an almost perfect flight, with no abnormalities of note occurring. This was also the first Atlas with functioning vernier engines, although they were not attached to the autopilot loop.

On February 7, Missile 13A was launched from LC-14. The engines switched to an improved variant of the MA-1 system with bell-shaped thrust chambers and 150,000 pounds of thrust, also the verniers were added to the autopilot loop for the first time. The APS (Auxiliary Power System) ceased operating at liftoff due to improper disconnect of a pad umbilical. At T+108 seconds, the engines started oscillating in all three axes and the propulsion system quickly shut down due to propellant starvation caused by missile tumbling. The Atlas broke up at T+163 seconds. The failure was attributed to a short in the vernier engine feedback transducer which caused the unexpected engine oscillation. Flight data also confirmed that the B-2 turbopump had disintegrated due to loss of lubricant oil pressure. The lube oil manifold pressure had dropped rapidly at T+16 seconds and remained steady at 460 psi until a pressure surge and then dropoff at T+106 seconds. The turbopump broke apart at T+116 seconds due to a bearing failure, but the propulsion system already shut down due to missile tumbling so it ultimately had no effect on the outcome of the flight.

Missile 11A was launched from LC-12 on February 20. This was the first flight where a roll program was added to the autopilot. Once again, the vernier feedback transducer shorted, leading to complete loss of control at T+103 seconds. The booster engines shut down due to missile tumbling and breakup of the Atlas occurred at T+126 seconds. The V-2 vernier shut down at T+109 seconds due to an apparent LOX duct rupture, while the V-1 vernier operated until final missile destruction.

Missile 15A was launched on April 5, following two aborted launch attempts on March 28 and April 1, the latter being called off when the V-2 vernier exploded at ignition. Because aerodynamic heating was believed to have caused the electrical malfunctions on 13A and 11A, more insulation and resistors were added around the vernier wiring and the fairing around the engine nozzles extended. The flight was uneventful until T+96 seconds when a momentary drop in B-1 thrust occurred. Total engine shutdown occurred at T+105 seconds and the Atlas fell into the Atlantic Ocean, remaining structurally intact until impact. Postflight analysis concluded that a bearing in the LOX turbopump gearbox had come loose, resulting in shutdown of the pump and loss of thrust.

The Atlas A program concluded with the flight of 16A on June 3, which mostly completed its mission objectives, although several hardware malfunctions occurred. An improperly adjusted LOX regulator resulted in slightly below normal booster engine thrust. The pneumatic system experienced difficulties and helium bottle pressure was nearly down to zero at BECO. This was thought to be caused by a valve sticking open that allowed helium to enter the LOX tank uncontrollably, although the boil-off valve operated correctly and opened to vent the tank and prevent excessive pressure buildup. The V-1 vernier failed to start due to a leak resulting in loss of the start tank fuel supply. Telemetry data for the propellant utilization system was erratic or nonexistent for most of the flight, and the guidance tracking beacon failed at T+69 seconds; it was thought to have been torn off the missile. The pressure level in the turbopump gearbox was also modified slightly to prevent a recurrence of the malfunctions on 13A and 15A. [1]

The Atlas A conducted eight test flights, of which four were successful. All launches were conducted from Cape Canaveral Air Force Station, at either Launch Complex 12 or Launch Complex 14.

Launch history

DateTime (GMT)PadSerial Apogee OutcomeRemarks
1957-06-1119:37 LC-14 4A2 km (1.2 mi)FailureFirst launch attempt of an Atlas vehicle. Performance was normal until T+30 seconds when the missile lost thrust due to exhaust gases being sucked back into the boattail and burning through wiring. Range Safety issued the destruct command at T+50 seconds. The flight was declared a "partial success" because the Atlas's balloon skin had maintained its structural integrity until vehicle destruction.
1957-09-2519:57LC-146A3 km (1.9 mi)FailureLoss of thrust followed by vehicle tumbling and RSO destruct at T+74 seconds due to overheating that led to gas generator failure.
1957-12-1717:39LC-1412A120 km (75 mi)SuccessFirst successful flight of an Atlas missile.
1958-01-1015:48 LC-12 10A120 km (75 mi)Success
1958-02-0719:37LC-1413A120 km (75 mi)Failure[ citation needed ]Short circuit in the guidance system caused engine shutdown and vehicle breakup at T+167 seconds.
1958-02-2017:46LC-1211A90 km (56 mi)FailureShort circuit in the guidance system caused engine shutdown and vehicle breakup at T+126 seconds.
1958-04-0517:01LC-1415A100 km (62 mi)FailureTurbopump failure caused loss of thrust at T+105 seconds. Vehicle remained structurally intact until impacting the Atlantic Ocean 200 miles downrange.
1958-06-0321:28LC-1216A120 km (75 mi)Success

See also

Related Research Articles

The SM-65 Atlas was the first operational intercontinental ballistic missile (ICBM) developed by the United States and the first member of the Atlas rocket family. It was built for the U.S. Air Force by the Convair Division of General Dynamics at an assembly plant located in Kearny Mesa, San Diego.

<span class="mw-page-title-main">Soyuz (rocket family)</span> Russian and Soviet rocket family

Soyuz is a family of expendable Russian and Soviet carrier rockets developed by OKB-1 and manufactured by Progress Rocket Space Centre in Samara, Russia. With over 2,000 flights since its debut in 1966, the Soyuz is the rocket with the most launches in the history of spaceflight.

<span class="mw-page-title-main">HGM-25A Titan I</span> Early American intercontinental ballistic missile

The Martin Marietta SM-68A/HGM-25A Titan I was the United States' first multistage intercontinental ballistic missile (ICBM), in use from 1959 until 1962. Though the SM-68A was operational for only three years, it spawned numerous follow-on models that were a part of the U.S. arsenal and space launch capability. The Titan I was unique among the Titan models in that it used liquid oxygen and RP-1 as propellants; all subsequent versions used storable propellants instead.

<span class="mw-page-title-main">PGM-17 Thor</span> Intermediate-range ballistic missile

The PGM-17A Thor was the first operative ballistic missile of the United States Air Force (USAF). It was named after the Norse god of thunder. It was deployed in the United Kingdom between 1959 and September 1963 as an intermediate-range ballistic missile (IRBM) with thermonuclear warheads. Thor was 65 feet (20 m) in height and 8 feet (2.4 m) in diameter.

<span class="mw-page-title-main">Rocketdyne J-2</span> Rocket engine

The J-2, commonly known as Rocketdyne J-2, was a liquid-fuel cryogenic rocket engine used on NASA's Saturn IB and Saturn V launch vehicles. Built in the United States by Rocketdyne, the J-2 burned cryogenic liquid hydrogen (LH2) and liquid oxygen (LOX) propellants, with each engine producing 1,033.1 kN (232,250 lbf) of thrust in vacuum. The engine's preliminary design dates back to recommendations of the 1959 Silverstein Committee. Rocketdyne won approval to develop the J-2 in June 1960 and the first flight, AS-201, occurred on 26 February 1966. The J-2 underwent several minor upgrades over its operational history to improve the engine's performance, with two major upgrade programs, the de Laval nozzle-type J-2S and aerospike-type J-2T, which were cancelled after the conclusion of the Apollo program.

<span class="mw-page-title-main">Big Joe 1</span> Uncrewed boilerplate Mercury program capsule

Big Joe 1 (Atlas-10D) launched an uncrewed boilerplate Mercury capsule from Cape Canaveral, Florida on 9 September 1959. The purposes of the Big Joe 1 were to test the Mercury spacecraft ablative heat shield, afterbody heating, reentry dynamics attitude control and recovery capability. It was also the first launch of a spacecraft in Project Mercury.

<span class="mw-page-title-main">LGM-25C Titan II</span> US ICBM, in service from 1962 to 1987

The Titan II was an intercontinental ballistic missile (ICBM) developed by the Glenn L. Martin Company from the earlier Titan I missile. Titan II was originally designed and used as an ICBM, but was later adapted as a medium-lift space launch vehicle to carry payloads to Earth orbit for the United States Air Force (USAF), National Aeronautics and Space Administration (NASA) and National Oceanic and Atmospheric Administration (NOAA). Those payloads included the USAF Defense Meteorological Satellite Program (DMSP), NOAA weather satellites, and NASA's Gemini crewed space capsules. The modified Titan II SLVs were launched from Vandenberg Air Force Base, California, up until 2003.

<span class="mw-page-title-main">Staged combustion cycle</span> Rocket engine operation method

The staged combustion cycle is a power cycle of a bipropellant rocket engine. In the staged combustion cycle, propellant flows through multiple combustion chambers, and is thus combusted in stages. The main advantage relative to other rocket engine power cycles is high fuel efficiency, measured through specific impulse, while its main disadvantage is engineering complexity.

<span class="mw-page-title-main">Atlas-Centaur</span> Family of space launch vehicles

The Atlas-Centaur was a United States expendable launch vehicle derived from the SM-65 Atlas D missile. The vehicle featured a Centaur upper stage, the first such stage to use high-performance liquid hydrogen as fuel. Launches were conducted from Launch Complex 36 at the Cape Canaveral Air Force Station (CCAFS) in Florida. After a strenuous flight test program, Atlas-Centaur went on to launch several crucial spaceflight missions for the United States, including Surveyor 1, Mariner 4, and Pioneer 10/11. The vehicle would be continuously developed and improved into the 1990s, with the last direct descendant being the highly successful Atlas II.

<span class="mw-page-title-main">Missile Defense Alarm System</span> Satellite early warning system

The Missile Defense Alarm System, or MIDAS, was a United States Air Force Air Defense Command system of 12 early-warning satellites that provided limited notice of Soviet intercontinental ballistic missile launches between 1960 and 1966. Originally intended to serve as a complete early-warning system working in conjunction with the Ballistic Missile Early Warning System, cost and reliability concerns limited the project to a research and development role. Three of the system's 12 launches ended in failure, and the remaining nine satellites provided crude infrared early-warning coverage of the Soviet Union until the project was replaced by the Defense Support Program. MiDAS represented one element of the United States's first generation of reconnaissance satellites that also included the Corona and SAMOS series. Though MIDAS failed in its primary role as a system of infrared early-warning satellites, it pioneered the technologies needed in successor systems.

<span class="mw-page-title-main">SM-65B Atlas</span> Prototype of the Atlas missile

The Convair SM-65B Atlas, or Atlas B, also designated X-12 was a prototype of the Atlas missile. First flown on 19 July 1958, the Atlas B was the first version of the Atlas rocket to use the stage and a half design with an operational sustainer engine and jettisonable booster engine section. Unlike later Atlas models, the Atlas B used explosive bolts to jettison the booster section.

<span class="mw-page-title-main">SM-65C Atlas</span> Missile

The SM-65C Atlas, or Atlas C was a prototype of the Atlas missile. First flown on 24 December 1958, the Atlas C was the final development version of the Atlas rocket, prior to the operational Atlas D. It was originally planned to be used as the first stage of the Atlas-Able rocket, but following an explosion during a static test on 24 September 1959, this was abandoned in favor of the Atlas D. Atlas C was similar to Atlas B, but had a larger LOX tank and smaller RP-1 tank due to technical changes to the Rocketdyne engines. Improvements in materials and manufacturing processes also resulted in lighter-weight components than the Atlas A and B. Booster burn time was much longer than the A/B series, up to 151 seconds. All launches took place from LC-12 at CCAS.

<span class="mw-page-title-main">SM-65D Atlas</span> First operational version of the U.S. Atlas missile

The SM-65D Atlas, or Atlas D, was the first operational version of the U.S. Atlas missile. Atlas D was first used as an intercontinental ballistic missile (ICBM) to deliver a nuclear weapon payload on a suborbital trajectory. It was later developed as a launch vehicle to carry a payload to low Earth orbit on its own, and later to geosynchronous orbit, to the Moon, Venus, or Mars with the Agena or Centaur upper stage.

<span class="mw-page-title-main">SM-65E Atlas</span>

The SM-65E Atlas, or Atlas-E, was an operational variant of the Atlas missile. It first flew on October 11, 1960, and was deployed as an operational ICBM from September 1961 until April 1966. Following retirement as an ICBM, the Atlas-E, along with the Atlas-F, was refurbished for orbital launches as the Atlas E/F. The last Atlas E/F launch was conducted on March 24, 1995, using a rocket which had originally been built as an Atlas E.

<span class="mw-page-title-main">SM-65F Atlas</span> Missile

The SM-65F Atlas, or Atlas-F, was the final operational variant of the Atlas missile, only differing from the Atlas E in the launch facility and guidance package used. It first flew on 8 August 1961, and was deployed as an operational ICBM between 1961 and 1966. Following retirement as an ICBM, the Atlas-F, along with the Atlas-E, was refurbished for orbital launches as the Atlas E/F.

<span class="mw-page-title-main">Atlas G</span> Expendable launch vehicle

The Atlas G, also known as Atlas G Centaur-D1AR was an American expendable launch system derived from the Atlas-Centaur. It was a member of the Atlas family of rockets and was used to launch seven communication satellites during the mid to late 1980s. Atlas G consisted of an improved Atlas core with modernized avionics and stretched propellant tanks. The Centaur stage also had several updated components and other technical improvements. Atlas G flew 7 times, with all missions aiming to go to a geostationary transfer orbit. It was replaced by the near-identical Atlas I, which had an improved guidance system and offered a larger payload fairing.

The Mercury-Redstone Launch Vehicle, designed for NASA's Project Mercury, was the first American crewed space booster. It was used for six sub-orbital Mercury flights from 1960–1961; culminating with the launch of the first, and 11 weeks later, the second American in space. The four subsequent Mercury human spaceflights used the more powerful Atlas booster to enter low Earth orbit.

<span class="mw-page-title-main">Titan II GLV</span> Expendable launch system

The Titan II GLV or Gemini-Titan II was an American expendable launch system derived from the Titan II missile, which was used to launch twelve Gemini missions for NASA between 1964 and 1966. Two uncrewed launches followed by ten crewed ones were conducted from Launch Complex 19 at the Cape Canaveral Air Force Station, starting with Gemini 1 on April 8, 1964.

<span class="mw-page-title-main">Atlas LV-3B</span> American space launch vehicle

The Atlas LV-3B, Atlas D Mercury Launch Vehicle or Mercury-Atlas Launch Vehicle, was a human-rated expendable launch system used as part of the United States Project Mercury to send astronauts into low Earth orbit. Manufactured by Convair, it was derived from the SM-65D Atlas missile, and was a member of the Atlas family of rockets. With the Atlas having been originally designed as a weapon system, testing and design changes were made to the missile to make it a safe and reliable launch vehicle. After the changes were made and approved, the US launched the LV-3B nine times, four of which had crewed Mercury spacecraft.

<span class="mw-page-title-main">Rocketdyne LR-101</span> Vernier thruster developed by Rocketdyne

The LR-101 is a fixed thrust, single start vernier thruster developed by Rocketdyne in the mid-to-late fifties and used in the Atlas, Thor and Delta launch vehicles until 1990.

References

  1. "The First Atlas Test Flights". 11 June 2015.