F-1 (rocket engine)
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The F-1 is a rocket engine developed by Rocketdyne and used in the Saturn V. Five F-1 engines were used in the S-IC first stage of each Saturn V, which served as the main launch vehicle in the Apollo program.
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[edit] History
The F-1 was originally developed by Rocketdyne to meet a 1955 US Air Force requirement for a very large rocket engine. The eventual result of that requirement was two different engines, the E-1 and the much larger F-1. The E-1, although successfully tested in static firing, was quickly seen as a technological dead-end and was abandoned for the larger, more powerful F-1. The USAF eventually halted development of the F-1 because of a perceived lack of requirement for such a large engine. However, the recently created NASA appreciated the usefulness of an engine with so much power and contracted Rocketdyne to complete its development. Test firings of F-1 components had been performed as early as 1957. The first static firing of a full stage developmental F-1 was performed in March 1959.
For seven years of development F-1 tests revealed serious combustion instability problems which would sometimes cause catastrophic failure.[1] Progress on this problem was initially slow, as the problem onset was intermittent and unpredictable. Eventually engineers developed a technique of detonating small explosive charges (which they called "bombs") inside the combustion chamber while the engine was firing, which allowed them to determine exactly how the running chamber responded to variations in pressure. The designers could then quickly experiment with different fuel-injector designs to obtain the one most resistant to instability. These problems were addressed from 1959 through 1961. Eventually the engine's combustion was so stable it would self-damp artificially induced instability within about 1/10th of a second.
[edit] Design
The Rocketdyne-developed F-1 engine was the most powerful single-nozzle liquid fueled rocket engine ever developed. The F-1 was a liquid-fuelled rocket motor, burning RP-1 (kerosene) as fuel, and using liquid oxygen (LOX) as the oxidizer. It operated on the gas-generator cycle; it burned a small part of its fuel and oxidizer in a separate combustion chamber (gas generator) to power a turbopump, which in turn pumped the remainder of the fuel and oxidizer into the main combustion chamber.
The heart of the engine was the thrust chamber, which mixed and burned the fuel and oxidizer to produce thrust. A domed chamber at the top of the engine served as a manifold supplying liquid oxygen to the injectors, and also served as a mount for the gimbal bearing which tansmitted the thrust to the body of the rocket. Below this dome were the injectors, which directed fuel and oxidizer into the thrust chamber in a way designed to promote mixing and combustion. Fuel was supplied to the injectors from a separate manifold; some of the fuel first travelled in 178 tubes down the length of the thrust chamber — which formed approximately the upper half of the exhaust nozzle — and back in order to cool it.
Fuel and liquid oxygen were pumped at high pressure into the thrust chamber assembly by separate pumps, both driven from a common turbine. The turbine was driven by gas from the gas generator; it spun at 5,500 RPM, and produced 55,000 brake horsepower (41 MW) of power. This was used to drive the fuel pump, pumping 15,471 gallons (58,564 litres) of RP-1 per minute; and the oxidizer pump, which delivered 24,811 gal (93,920 l) of liquid oxygen per minute. The turbopump was required to cope with severely differing temperatures: it was driven by gas at 1,500 °F (816 °C), and handled liquid oxygen at -300 °F (-184 °C). Some of the kerosene fuel was used as a lubricant and coolant for the turbopump bearings.
Below the thrust chamber was the nozzle extension, roughly half the length of the engine. This extension increased the expansion ratio of the engine from 10:1 to 16:1. The exhaust from the turbopump was fed into the nozzle extension by a large, tapered manifold; this relatively cool gas formed a film which protected the nozzle extension from the hot (5,800 °F, 3,200 °C) exhaust gas.[2]
The F-1 burned two short tons (1.8 t) of liquid oxygen and one ton (0.9 t) of RP-1 each second, generating over 1.5 million pounds-force (6.7 meganewtons) of thrust. During their two and a half minutes of operation, the five F-1s propelled the Saturn V vehicle to a height of 68 km (42 miles) and a speed of 9,921 km/h (6,164 mph). The combined propellant flow rate of the five F-1s in the Saturn V was 3580 U.S. gallons (13552 liters) per second. The flow rate could empty a 30,000 U.S. gallon (113,562 liter) swimming pool in 8.5 seconds. Each F-1 engine has more thrust than all three space shuttle main engines combined.
[edit] Specifications
| Apollo 4, 6, and 8 | Apollo 9 on | |
|---|---|---|
| Thrust (sea level): | 1,500,000 lbf (6.67 MN) | 1,522,000 lbf (6.77 MN) |
| Burn time: | 150 s | 165s |
| Specific impulse: | 260 s (2.55 kN·s/kg) | 263 s (2.58 kN·s/kg) |
| Engine weight dry: | 18,416 lb (8,353 kg) | 18,500 lb (8,391 kg) |
| Engine weight burnout: | 20,096 lb (9,115 kg) | 20,180 lb (9,153 kg) |
| Height: | 19 ft (5.79 m) | |
| Diameter: | 12.3 ft (3.76 m) | |
| Exit to throat ratio: | 16 to 1 | |
| Propellants: | LOX & RP-1 | |
| Mixture ratio: | 2.27:1 oxidizer to fuel | |
| Contractor: | NAA/Rocketdyne | |
| Vehicle application: | Saturn V / S-IC 1st stage - 5-engines | |
[edit] F-1 improvements during the Apollo program
F-1 thrust and efficiency were improved between Apollo 8 (SA-503) and Apollo 17 (SA-512). This was necessary for Saturn V payload capacity to meet the increasing demands of the later Apollo missions. There were small performance variations between engines on a given mission, and variations in average thrust between missions. For Apollo 15, F-1 performance was:
- Thrust (average, per engine, sea level liftoff): 1,553,200 lbf (6.909 MN)
- Burn time: 159 s
- Specific impulse: 264.72 s
- Mixture ratio: 2.2674
- S-IC total sea level liftoff thrust: 7,766,000 lbf (34.55 MN)
Measuring and making comparisons of rocket engine thrust is more complicated than first appears. Based on actual measurement the liftoff thrust of Apollo 15 was 7.823 million lbf (34.8 MN), which equates to an average F-1 thrust of 1.565 million lbf (6.962 MN), which is significantly more than the specified value. For more information, see S-IC thrust comparisons
[edit] The F-1 after Apollo
There was an uprating redevelopment of the F-1 undertaken by Rocketdyne during the 1960s which resulted in a new engine specification known as the F-1A. While outwardly very similar to the F-1, the F-1A was actually lighter yet significantly more powerful (9.1 MN compared to F-1's 6.7 MN) and would have been used on future Saturn V vehicles in the post-Apollo era. However, the Saturn V production line was closed prior to the end of Project Apollo and no F-1A engine ever flew on a launch vehicle.
There were proposals to use eight F-1 engines on the first stage of the Nova rocket. Numerous proposals have been made from the 1970s on to the present day to develop new expendable boosters based around the F-1 engine design, but none have proceeded beyond the initial study phase.
The F-1 remained the most powerful liquid-fuel rocket engine at 6.7 MN of thrust at sea level until overshadowed by RD-170 from the Soviet Union. The RD-170 is actually a cluster of four separate combustion chambers and nozzles driven by a single turbopump. It visually appears to be and is considered by some a cluster of four engines, not a single engine. Viewed as a single engine it is the most powerful liquid-fuel rocket engine ever developed. The F-1 still holds the crown of largest single-chamber, single-nozzle liquid fuel engine ever flown. However among solid-fuel engines, more powerful engines exist, such as the Space Shuttle Solid Rocket Booster, with a sea-level liftoff thrust of 12.45 MN.
[edit] References
- Apollo 15 Press Kit
- Saturn V Launch Vehicle, Flight Evaluation Report, AS-510, MSFC-MPR-SAT-FE-71-2, October 28, 1971
- Saturn V News Reference F-1 Engine Fact Sheet, December 1968
Designer of the pump for the E-1/F-1 for Rocketdyne was Ernest A. Lamont. His hand written original calculations are part of the family archives and available for display. He stated that the design of the rocket engine was hinged on the question of whether the pump design was viable.
[edit] Notes
- ^ Ellison, Renea & Moser, Marlow, Combustion Instability Analysis and the Effects of Drop Size on Acoustic Driving Rocket Flow, Huntsville, Alabama: Propulsion Research Center, University of Alabama in Huntsville, <http://reap.uah.edu/publications/Ellison.pdf>
- ^ a b Saturn V News Reference: F-1 Engine Fact Sheet, National Aeronautics and Space Administration, December 1968, pp. 3-3,3-4, <http://history.msfc.nasa.gov/saturn_apollo/documents/F-1_Engine.pdf>. Retrieved on 1 June 2008
- ^ F-1 Engine (chart), NASA Marshall Space Flight Center, MSFC-9801771, <http://ntrs.nasa.gov/search.jsp?R=345547&id=1&qs=Ntt%3DMSFC-9801771%26Ntk%3Dall%26Ntx%3Dmode%2520matchall%26N%3D0%26Ns%3DHarvestDate%257c1>. Retrieved on 1 June 2008
[edit] External links
- E-1 at the Encyclopedia Astronautica
- F-1 at the Encyclopedia Astronautica
- F-1A at the Encyclopedia Astronautica
- NASA SP-4206 Stages to Saturn - the official NASA history of the Saturn launch vehicle
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| Main Article: F-1 | |||
| Technologies: Bipropellant | Gas-generator cycle | LOX | RP-1 | |||
| Historic Spacecraft: Saturn V (S-IC) | |||
| Other LOX & RP-1 Engines: LR-87 | LR-91 | H-1 | |||
