Aircraft catapult

F-14 Tomcat preparing to connect to a catapult on the USS Saratoga (CV-60)

An aircraft catapult is a device used to launch aircraft from ships, most commonly used on aircraft carriers, as a form of assisted take off. It consists of a track built into the flight deck, below which is a large piston or shuttle that is attached through the track to the nose gear of the aircraft, or in some cases a wire rope, called a catapult bridle, is attached to the aircraft and the catapult shuttle. Different means have been used to propel the catapult, such as weight and derrick, gunpowder, flywheel, air pressure, hydraulic, and steam power. The U.S. Navy is developing the use of electromagnets with the construction of the Gerald R.Ford class aircraft carrier.


History

First recorded flight using a catapult

Samuel Pierpont Langley's catapult, houseboat and unsuccessful man-carrying Aerodrome (1903)

Aviation pioneer and Smithsonian Secretary Samuel Langley used a spring-operated catapult to launch his successful flying models and his failed aerodrome of 1903.[1] Likewise the Wright Brothers beginning in 1904 used a weight and derrick styled catapult to assist their early "aircraft" with a takeoff in a limited distance.[2]

On 31 July 1912, Theodore Gordon Ellyson became the first person to be launched from the experimental catapult system. The U.S. Navy had been perfecting a compressed-air catapult system and mounted it on the Santee Dock in Annapolis, Maryland. The first attempt nearly killed Lt. Ellyson when the plane left the ramp with its nose pointing upward and it caught a crosswind, pushing the plane into the water. Ellyson was able to escape from the wreckage unhurt. On 12 November 1912, Lt. Ellyson made history as the Navy's first successful catapult launch, from a stationary coal barge. On 5 November 1915, LCDR Henry C. Mustin made the first catapult launch from a ship underway.[3]

Interwar and World War II

A Supermarine Walrus being launched from the catapult of HMS Bermuda (1943)

The US Navy experimented with other power sources and models, including catapults that utilized gunpowder and flywheel variations. On 14 December 1924, a Martin MO-1 observation plane flown by Lt. L. C. Hayden was launched from USS Langley using a catapult powered by gunpowder. Following this launch, this method was used aboard both cruisers and battleships.[4]

Up to and during World War II, most catapults were hydraulic. Some carriers were completed before and during World War II with catapults on the hangar deck that fired athwartships, but they were unpopular because of their short run, low clearance of the hangar decks, inability to add the ship's forward speed to the aircraft's airspeed for takeoff, and lower clearance from the water (conditions which afforded pilots far less margin for error in the first moments of flight). They were mostly used for experimental purposes, and their use was entirely discontinued during the latter half of the war.[4]

Test launch of a Hurricane using the rocket-catapult of a CAM ship, Greenock, Scotland, 31 May 1941

Many naval vessels apart from aircraft carriers carried float planes, seaplanes or amphibians for reconnaissance and spotting. They were catapult-launched and landed on the sea alongside for recovery by crane. There were submarine aircraft carriers, and some Japanese submarines used them for offensive operations also. The first launch off a Royal Navy battlecruiser was from HMAS Australia on 8 March 1918. Subsequently many RN ships carried a catapult and from one to four aircraft; battleships or battlecruisers like the HMS Prince of Wales carried four aircraft and HMS Rodney carried two, while smaller warships like the cruiser HMNZS Leander carried one. The aircraft carried were the Fairey Seafox or Supermarine Walrus. Some like HMS Nelson did not use a catapult, and the aircraft was lowered onto the sea for takeoff. Some had their aircraft and catapult removed during WWII e.g. HMS Duke of York, or before (HMS Ramillies).

During World War II a number of ships were fitted with rocket-driven catapults, first the Fighter catapult ships of the Royal Navy, then armed merchantmen known as CAM ships from "catapult armed merchantmen." These were used for convoy escort duties to drive off enemy reconnaissance bombers. CAM ships carried a Hawker Sea Hurricane, dubbed a "Hurricat" or "Catafighter", and the pilot bailed out unless he could fly to land.[5]

While imprisoned in Colditz Castle during the war, British prisoners of war planned an escape attempt using a falling bathtub full of heavy rocks and stones as the motive power for a catapult to be used for launching the Colditz Cock glider from the roof of the castle.

Ground-launched V-1s were typically propelled up an inclined launch ramp by an apparatus known as a Dampferzeuger ("steam generator").[6][7]

Steam catapult

Elements of the catapult of Charles de Gaulle, disassembled during her refit in 2008
Final checks on an aircraft catapult prior to flight operations aboard the USS John C. Stennis (CVN 74)

Following World War II, the Royal Navy was developing a new catapult system for their fleet of carriers. Commander Colin C. Mitchell, RNV, recommended a steam-based system as an effective and efficient means to launch the next generation of naval aircraft. Trials on HMS Perseus, flown by pilots such as Eric "Winkle" Brown, from 1950 showed its effectiveness. Navies introduced steam catapults, capable of launching the heavier jet fighters, in the mid-1950s. Powder-driven catapults were also contemplated, and would have been powerful enough, but would also have introduced far greater stresses on the airframes and might have been unsuitable for long use.[4]

The way the steam catapult works is at launch, a release bar holds the aircraft in place as steam pressure builds up, then breaks (or "releases"; older models used a pin that sheared), freeing the piston to pull the aircraft along the deck at high speed. Within about two to four seconds, aircraft velocity by the action of the catapult plus apparent wind speed (ship's speed plus or minus "natural" wind) is sufficient to allow an aircraft to fly away, even after losing one engine.[8]

Nations that have retained large aircraft carriers and high performance CATOBAR (Catapult Assisted Take Off But Arrested Recovery,) which the United States Navy, Brazilian Navy, and French Navy, are still using catapults for their superior power and flexibility. The Royal Navy operates STOVL aircraft, such as the imminent F-35B on the HMS Queen Elizabeth Class Carriers and US Carrier/Expeditionary Strike Groups, others employ the Sea Harrier or AV-8B Harrier II, which do not require catapult assistance and take off vertically from STOVL configuration carriers which are less expensive[9] and generally smaller in size compared to CATOBAR carriers. The Russian Su-33 "Flanker-D" can take off from aircraft carriers without a catapult, albeit at a reduced fuel and armament load. U.S. Navy tactical aircraft use catapults to launch with a heavier warload than would otherwise be possible. Larger planes, such as the E-2 Hawkeye and S-3 Viking, require a catapult shot, since their thrust-to-weight ratio is too low for a conventional rolling takeoff on a carrier deck.[4]

Steam catapults types

Presently or at one time operated by the U.S. Navy include:[10][11][12][8][13][14]

Type Overall length Stroke Capacity Carriers
C-11 and C-11-1 225 feet (69 m) 211 feet (64 m) 39,000 pounds (18,000 kg) @ 136 knots; 70,000 pounds (32,000 kg) @ 108 knots SCB-27C Essex class conversions, USS Coral Sea, bow installations on USS Midway and USS Franklin D. Roosevelt, waist installations on USS Forrestal and USS Saratoga
C-11-2 203 feet (62 m) 150 feet (46 m) Waist catapults on USS Midway and USS Franklin Roosevelt
C-7 276 feet (84 m) 253 feet (77 m) 40,000 pounds (18,000 kg) @ 148.5 knots; 70,000 pounds (32,000 kg) @ 116 knots USS Ranger, USS Independence, bow installations on USS Forrestal and USS Saratoga
C-13 265 feet (81 m) 250 feet (76 m) 78,000 pounds (35,000 kg) @ 139 knots Kitty Hawk class, USS Midway after SCB-101.66 modernization, USS Enterprise
C-13-1 325 feet (99 m) 310 feet (94 m) 80,000 pounds (36,000 kg) @ 140 knots One installation on USS America and USS John F. Kennedy, All on USS Nimitz, USS Dwight D. Eisenhower, USS Carl Vinson, and USS Theodore Roosevelt
C-13-2 325 feet (99 m) 306 feet (93 m) USS Abraham Lincoln, USS George Washington, USS John C. Stennis, USS Harry S. Truman

Bridle catchers

USS Saratoga (CV-60) underway on 15 September 1985. The bridle catchers are the extensions at the end of the forward catapults

The ramps at the catapult ends on some aircraft carriers are used to catch the bridles (ropes) so they can be reused; bridles have not been used on U.S. aircraft since the end of the Cold War, and all U.S. Navy carriers commissioned since then have not had the ramps. The last U.S. carrier commissioned with a bridle catcher was USS Carl Vinson; starting with USS Theodore Roosevelt the ramps were deleted. During Refueling and Complex Overhaul refits in the late 1990s–early 2000s, the bridle catchers were removed from the first three Nimitz-class aircraft carriers. USS Enterprise was the last U.S. Navy operational carrier with the ramps still attached before her inactivation in 2012.

Like her American counterparts today, the French aircraft carrier Charles De Gaulle is not equipped with bridles catchers because the modern aircraft operated on board use the same launch systems as in US Navy.[15]

Because of this mutual interoperability, American aircraft are also capable of being catapulted from and landing on the Charles De Gaulle, and conversely, French naval aircraft can use the US Navy carriers' catapults.

At the time when the Super Étendard was operated on board of the Charles de Gaulle, its bridles were used only once, as they were never recovered by bridles catchers.

The carriers Clemenceau and Foch were also equipped with bridles catchers, not for the Super Étendard's ones but only to catch and recover the Vought F-8 Crusader's bridles.

Electromagnetic Aircraft Launch System

A computer-generated model of the linear induction motor used in the EMALS.

The size and manpower requirements of steam catapults place limits on their capabilities. A newer approach is the Electromagnetic Aircraft Launch System (EMALS). Electromagnetic catapults place less stress on the aircraft and offer more control during the launch by allowing gradual and continual acceleration. Electromagnetic catapults are also anticipated to require significantly less maintenance through the use of solid state components.[16]

Linear induction motors have been experimented with before, such as Westinghouse's Electropult system in 1945.[17] However, at the beginning of the 21st century, navies again started experimenting with catapults powered by linear induction motors and electromagnets. EMALs would be more energy efficient on nuclear-powered aircraft carriers and would alleviate some of the dangers posed by using pressurized steam. On gas-turbine powered ships, an electromagnetic catapult would eliminate the need for a separate steam boiler for generating catapult steam. The U.S. Navy's upcoming Gerald R. Ford class carrier includes electromagnetic catapults in its design.[18]

Civilian use

From 1929, the German Norddeutscher Lloyd-liners SS Bremen and Europa were fitted with catapults to launch mail-planes. These ships served the route between Germany and the United States. The aircraft, carrying mail–bags, would be launched while the ship was still many hundreds of miles from its destination, thus speeding mail delivery by about a day. Initially, Heinkel He 12 aircraft were used before they were replaced by Junkers Ju 46, which were in turn replaced by the Vought V-85G. The catapults were powered by compressed air.[19]

After World War II, Supermarine Walrus amphibian aircraft were briefly operated by a British whaling company, United Whalers. Operating in the Antarctic, they were launched from the factory ship FF Balaena, which had been equipped with an ex-navy aircraft catapult.[20]

See also

Wikimedia Commons has media related to Catapults (ship).

References

Citations
  1. McFarland, Stephen L. (1997). A Concise History of the U.S. Air Force. Ft. Belvoir: Defense Technical Information Center. p. 2. ISBN 0-16-049208-4.
  2. Stephen J. Chant, Douglas E. Campbell (2013). Patent Log: Innovative Patents that Advanced the United States Navy. Syneca Research group, inc. p. 289. ISBN 978-1-105-62562-6.
  3. "Our Navy Has the Best Seaplane Catapult; New Invention of Captain Washington I. Chambers Makes It Possible to Launch Aircraft from a Warship's Deck at Sea". query.nytimes.com. Retrieved 2015-11-24.
  4. 1 2 3 4 "Launch and Recovery: From Flywheels to Magnets". navalaviationnews.navylive.dodlive.mil. Retrieved 2015-11-24.  This article incorporates text from this source, which is in the public domain.
  5. "HMS Ariguani aircraft carrier profile. Aircraft Carrier Database of the Fleet Air Arm Archive 1939-1945". www.fleetairarmarchive.net. Retrieved 2016-02-15.
  6. Werrell 1985.
  7. https://www.youtube.com/watch?v=Bl580XVFWqw
  8. 1 2 Friedman, Norman (1983). U.S. Aircraft Carriers: An Illustrated Design History. Naval Institute Press. ISBN 978-0-87021-739-5.
  9. "Why I Joined the Dark Side".
  10. "Installations on the Flight Deck". navysite.de. Retrieved 2015-11-24.
  11. Power, Hugh Irvin (1996). Carrier Lexington. College Station, TX: Texas A&M University Press. p. 72. ISBN 978-0-89096-681-5.
  12. "Chapter 4 STEAM CATAPULTS". navyaviation.tpub.com. Retrieved 2015-11-24.
  13. http://www.hnsa.org/wp-content/uploads/2014/08/cv41.pdf
  14. http://www.hnsa.org/wp-content/uploads/2014/08/cv60.pdf
  15. Safran Messier-Dowrty
  16. "History, Travel, Arts, Science, People, Places - Air & Space Magazine". airspacemag.com.
  17. Linear Electric Machines- A Personal View ERIC R. LAITHWAITE PROCEEDINGS OF THE IEEE, VOL. 63, NO. 2, FEBRUARY 1975
  18. "Gerald R Ford Class (CVN 78/79) – US Navy CVN 21 Future Carrier Programme - Naval Technology". naval-technology.com.
  19. Cook, John (March 2002). "Shot from Ships: Air Mail Service on Bremen and Europa". Air Classics. Retrieved February 27, 2013.
  20. London 2003, p. 213.
Bibliography

External links

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