SPLASHDOWN (SPACECRAFT LANDING)

'Splashdown' is the method of landing a spacecraft by parachute in a body of water. It was used by American manned spacecraft prior to the Space Shuttle program. It is also possible for the Russian Soyuz spacecraft and Chinese Shenzhou spacecraft to land in water, though this is only a contingency. The only example of the splashdown in Soviet history is Soyuz 23 landing.
As the name suggests, the capsule parachutes into an ocean or other large body of water. The properties of water cushion the spacecraft enough that there is no need for a braking rocket to slow the final descent as was the case with Russian and Chinese manned space capsules, which returned to Earth over land. The American practice came in part because American launch sites are on the coastline and launch primarily over water. Russian and Chinese launch sites are far inland and most early launch aborts are likely to descend on land.
The splashdown method of landing was utilized for Mercury, Gemini and Apollo (including Skylab, which used Apollo capsules). On one occasion the Soviet spacecraft Soyuz 23 punched through the ice of a frozen lake (nearly killing the cosmonauts), but this was unintentional.
On early Mercury flights, a helicopter attached a cable to the capsule, lifted it from the water and delivered it to a nearby ship. This was changed after the sinking of ''Liberty Bell 7''. All later Mercury, Gemini and Apollo capsules had a flotation collar (similar to a rubber life raft) attached to the spacecraft to increase their buoyancy. The spacecraft would then be brought alongside a ship and lifted onto deck by crane.
After the flotation collar is attached, a hatch on the spacecraft is usually opened. At that time, some astronauts decide to be hoisted aboard a helicopter for a ride to the recovery ship and some decided to stay with the spacecraft and be lifted aboard ship via crane. (Because of his overshoot aboard ''Aurora 7,'' and mindful of the fate of ''Liberty Bell 7,'' Scott Carpenter alone egressed through the nose of his capsule instead of through the hatch, waiting for recovery forces in his life raft.) All Gemini and Apollo flights (Apollos ''7'' to ''17'') used the former, while Mercury missions from Mercury 6 to Mercury 9, as well as all Skylab missions and Apollo-Soyuz used the latter, especially the Skylab flights as to preserve all medical data.
The new Crew Exploration Vehicle, which will replace the Space Shuttle (which lands on a modified aircraft-style runway), will be designed to be recovered on land using a combination of parachutes and airbags, although it is also designed to make a contingency splashdown (only for an in-flight abort) if needed. Although not new, NASA and the Air Force originally wanted to place a paraglider recovery system to allow for a controlled, precise landing on land on ski-like skids (a landing system used on X-15 rocket plane), most likely on the dry lakebeds at Edwards Air Force Base in California. This idea was first proposed for the Gemini spacecraft, but was dropped in favor of the traditional parachute system.

Contents

Disadvantages

Locations of splashdowns

Manned spacecraft

Unmanned spacecraft

External links

Gallery

References

Disadvantages

While the water the spacecraft landed on would cushion it to some degree, the impact could still be quite violent for the astronauts.
There are several disadvantages for splashdowns, foremost among them being the danger of the spacecraft flooding and sinking. This happened to Gus Grissom when the hatch of his Mercury-Redstone 4 capsule malfunctioned and blew prematurely. The capsule was lost and Grissom nearly drowned. Space capsules are also not very good boats and many astronauts got seasick.
Another problem associated with splashdown is that if the capsule comes down far from any recovery forces the crew are exposed to greater danger. As an example, Scott Carpenter in Mercury 7 overshot the assigned landing zone by 400 km. This was caused by a retroattitude misalignment caused by the spacecraft automatic guidance system. It took three hours for a recovery helicopter to reach his location. These recovery operation mishaps can be mitigated by placing several vessels on standby in several different locations, but this is quite an expensive option.

Locations of splashdowns

Manned spacecraft

'Spacecraft'	'Landing Date'	'Coordinates'	'Recovery Ship'	'Miss Distance'
Freedom 7	May 5, 1961		USS Lake Champlain CVS 39	5.6 km
Liberty Bell 7	July 21, 1961		USS Randolph CVS-15	9.3 km
Friendship 7	February 20, 1962		USS Noa DD-841 (USS Randolph CVS-15 ★ ★ )	74 km
Aurora 7	May 24, 1962		USS Farragut DLG-6 (USS Intrepid CVS-11 ★ ★ )	400 km
Sigma 7	October 3, 1962		USS Kearsarge CVS-33	7.4 km
Faith 7	May 16, 1963		USS Kearsarge CVS-33	8.1 km
Gemini 3	March 23, 1965		USS Intrepid CVS-11	111 km
Gemini 4	June 7, 1965		USS Wasp CVS-18	81 km
Gemini 5	August 29, 1965		USS Lake Champlain CVS 39	270 km
Gemini 7	December 18, 1965		USS Wasp CVS-18	12 km
Gemini 6A	December 16, 1965		USS Wasp CVS-18	13 km
Gemini 8	March 17, 1966		USS Mason DD-852 (USS Boxer LPH 4 ★ ★ )	2 km
Gemini 9A	June 6, 1966		USS Wasp CVS-18	0.7 km
Gemini 10	July 21, 1966		USS Guadalcanal LPH-7	6 km
Gemini 11	September 15, 1966		USS Guam LPH-9	5 km
Gemini 12	November 15, 1966		USS Wasp CVS-18	5 km
Apollo 1	March 7, 1967	Planned N of Puerto Rico	USS Essex CVS-9 ★ ★	Planned
Apollo 7	October 22, 1968		USS Essex CVS-9	3 km
Apollo 8	December 27, 1968		USS Yorktown CVS-10	2 km
Apollo 9	March 13, 1969		USS Guadalcanal LPH-7	5 km
Apollo 10	May 26, 1969		USS Princeton CVS-37	2.4 km
Apollo 11	July 24, 1969		USS Hornet CVS-12	3.1 km
Apollo 12	November 24, 1969		USS Hornet CVS-12	3.7 km
Apollo 13	April 17, 1970		USS Iwo Jima LPH-2	1.9 km
Apollo 14	February 9, 1971		USS New Orleans LPH-11	1.1 km
Apollo 15	August 7, 1971		USS Okinawa LPH-3	1.9 km
Apollo 16	April 27, 1972		USS Ticonderoga CVS-14	5.6 km
Apollo 17	December 19, 1972		USS Ticonderoga CVS-14	1.9 km
Skylab 2	June 22, 1973		USS Ticonderoga CVS-14	9.6 km
Skylab 3	September 25, 1973		USS New Orleans LPH-11	8 km?
Skylab 4	February 8, 1974		USS New Orleans LPH-11	8 km?
ASTP Apollo	July 24, 1975		USS New Orleans LPH-11	7.3 km
Soyuz 23	October 16, 1976	Lake Tengiz	Helicopter Mi-8	Not intended to land in water

''Planned recovery ship
★
★ ''

Unmanned spacecraft

'Spacecraft'	'Landing Date'	'Coordinates'	'Recovery Ship'	'Miss Distance'
Jupiter AM-18	May 28, 1959	2,735 km SE Cape Canaveral	USS Kiowa ATF-72	? km
Mercury-Big Joe	September 9, 1959	2,407 km SE Cape Canaveral	USS Strong DD-758	925 km
Mercury-Little Joe 2	December 4, 1959	319 km SE Wallops Is, VA	USS Borie DD-704	? km
Mercury-Redstone 1A	December 19, 1960	378.2 km SE Cape Canaveral	USS Valley Forge CV-45	33 km
Mercury-Redstone 2	January 31, 1961	679 km SE Cape Canaveral	USS Donner LSD-20	111 km
Mercury-Atlas 2	February 21, 1961	2,305 km SE Cape Canaveral	USS Donner LSD-20	30? km
Mercury-Atlas 4	September 13, 1961	320 km E of Bermuda	USS Decatur DD 936	63 km
Mercury-Atlas 5	November 29, 1961	472 km SE of Bermuda	USS Stormes DD-780	48 km
Gemini 2	January 19, 1965		USS Lake Champlain CVS 39	38 km
Apollo 201	February 26, 1966		USS Boxer LPH 4	72 km
Apollo 202	August 25, 1966		USS Hornet CVS-12	370 km
Gemini 2-MOL	November 3, 1966	SE KSC near Ascension Is.	USS La Salle LPD-3	13 km
Apollo 4	November 9, 1967		USS Bennington CVS-20	16 km
Apollo 6	April 4, 1968		USS Okinawa LPH-3	80 km
Zond 5	September 21, 1968		Vasiliy Golovin
Zond 8	October 27, 1970	Indian Ocean

External links

Gallery

References

★ NASA Historical Data Book - Volume II - Programs and Projects 1958 - 1968 - NASA SP-4012

★ NASA Historical Data Book - Volume III - Programs and Projects 1969 - 1978 - NASA SP-4012