Supercavitation

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File:Superkavitation schema.svg
An object (black) encounters a liquid (blue) at high speed. The fluid pressure behind the object is lowered below the vapor pressure of the liquid, forming a bubble of vapor (a cavity) that encompasses the object.

Supercavitation is the use of cavitation effects to create a bubble of gas inside a liquid large enough to encompass an object traveling through the liquid, greatly reducing the skin friction drag on the object and enabling achievement of very high speeds. Current applications are mainly limited to projectiles or very fast torpedoes, but in principle the technique could be extended to include vehicles.

Physical Principle

In water, cavitation occurs when water pressure is lowered below the water's vapor pressure, forming bubbles of vapor. That can happen when water is accelerated to high speeds as when turning a sharp corner around a moving piece of metal such as a ship's propeller or a pump's impeller. The greater the water depth (or pressure for a water pipe) at which the fluid acceleration occurs, the less the tendency for cavitation because of the greater difference between local pressure and vapor pressure. Once the flow slows down again, the water vapor will generally be reabsorbed into the liquid water. That can be a problem for ship propellers if cavitation bubbles implode on the surface of the propeller, each applying a small force that is concentrated in both location and time, causing damage.

A common occurrence of water vapor bubbles is observed in a pan of boiling water. In that case the water pressure is not reduced, but rather, the vapor pressure of the water is increased by means of heating. If the heat source is sufficient, the bubbles will detach from the bottom of the pan and rise to the surface as steam. Otherwise if the pan is removed from the heat the bubbles will be reabsorbed into the water as it cools, possibly causing pitting on the bottom of the pan as the bubbles implode.

A supercavitating object uses cavitation in a larger and more sustained manner than with the (typical) ship's propeller (hence the name supercavitation). A supercavitating object's main features are a specially shaped nose, usually flat with sharp edges, and a streamlined, hydrodynamic and aerodynamic shape[citation needed]. When the object is traveling through water at high speeds, the flat nose deflects the water radially outward at speeds such that there is a tremendous drop in pressure aft of where the water passes over the sharp edge of the periphery of the nose, causing a cavitation bubble that will generally close in behind the object[citation needed]. The bubble will persist, traveling with the object, forming at the nose and closing in behind[citation needed]. If the resulting cavity is not large enough, it may be extended by internally generating additional gas to inject into the cavity[citation needed]. The result is that the only portion of the object in direct contact with the water is the nose, and skin friction drag is substantially reduced.[citation needed]

The great speed required for supercavitation to work can be achieved temporarily by a projectile fired under water or by an airborne projectile impacting the water[citation needed]. For sustained operation, rocket propulsion can be used, which by its nature adds gas at high pressure to the cavitation bubble[citation needed]. An example of rocket propulsion is the Russian Shkval supercavitating torpedo.[1][2] Maneuvering may be achieved by various methods, such as drag fins that project through the bubble into the surrounding liquid[3] (p.22), by tilting the flat surface on the nose of the object, by injecting gas asymmetrically near the nose of the object in order to distort the geometry of the cavity, or by vectoring rocket thrust by gimballing or differentiating nozzle thrusts.

Applications

In 1960, the USSR started developing a project under the codename "Шквал" (Squall) run by NII-24 (Kiev) to develop a high-speed torpedo, an underwater rocket, four to five times faster than traditional torpedoes capable of combating enemy submarines. Several models of the device were made, the most successful – M-5 – was created by 1972. In 1972 to 1977, over 300 test launches were made (95% of them on Issyk Kul lake), by 29 November 1972 VA-111 Shkval was put into service with mass production started in 1978.

In 2004, German weapons manufacturer Diehl BGT Defence announced their own supercavitating torpedo, Barracuda, now officially named "Superkavitierender Unterwasserlaufkörper" or "supercavitating underwater running body" (English translation). According to Diehl, it reaches more than 400 kilometres per hour (250 mph).[4]

In 1994, the US Navy began developing a sea mine clearance system invented by C Tech Defense Corporation, known as RAMICS (Rapid Airborne Mine Clearance System), based on a supercavitating projectile stable in both air and water. These have been produced in 12.7 millimeters (0.50 in), 20 millimeters (0.79 in), and 30 millimeters (1.2 in) diameters.[5] The terminal ballistic design of the projectile allowed it to cause explosive destruction of sea mines as deep as 45 meters (148 ft) underwater with a single round.[6] In 2000, these projectiles were used to successfully destroy a range of live underwater mines when fired from a hovering Sea Cobra gunship at Aberdeen Proving Grounds. RAMICS is currently[when?] undergoing development by Northrop Grumman for introduction into the fleet. The darts of German (Heckler & Koch P11) and Russian underwater firearms,[7] and other similar weapons are also supercavitating.

In 2005, DARPA announced the 'Underwater Express program', a research and evaluation bid to establish the potential of supercavitation. The program's ultimate goal is a new class of underwater craft for littoral missions that can transport small groups of Navy personnel or specialized military cargo at speeds up to 100 knots. The contracts were awarded to Northrop Grumman and General Dynamics Electric Boat in late 2006.[citation needed] In 2009, DARPA announced progress via a new class of submarine.
The submarine's designer, Electric Boat, is working on a one-quarter scale model for sea trials off the coast of Rhode Island. If the trials are successful, Electric Boat will begin production on a full scale 100-foot submarine. Currently, the Navy's fastest submarine can only travel at 25 to 30 knots while submerged. But if everything goes according to plan, the Underwater Express will speed along at 100 knots, allowing the delivery of men and material faster than ever."[8]

Iran claimed to have successfully tested its first supercavitation torpedo on 2 April and 3 April 2006. Some sources have speculated it is based on the Russian VA-111 Shkval supercavitation torpedo, which travels at the same speed.[9] Russian Foreign Minister Sergei Lavrov denied supplying Iran with the technology.[10] Iran called this weapon the Hoot (Whale).

Alleged applications

The Kursk submarine accident is rumored to have been due to a faulty Shkval torpedo.[11]

See also

References

  1. http://www.articlesextra.com/supercavitation-torpedoes.htm
  2. http://www.periscope.ucg.com/mdb-smpl/weapons/minetorp/torpedo/w0004768.shtml#pictures
  3. http://www.aem.umn.edu/research/supercavitation/documents/thesis_eric.pdf
  4. Diehl BGT Defence: Unterwasserlaufkörper
  5. RAMICS
  6. C Tech
  7. [1]
  8. http://www.popsci.com/military-aviation-amp-space/article/2009-07/darpa-readies-ultra-fast-mini-sub
  9. [2] [3] [4]
  10. [5]
  11. Gertz, Bill (August 23, 2001). "Russian book sheds light on missile". Washington Times: p. A.4.
  • Office of Naval Research (2004, June 14). Mechanics and energy conversion: high-speed (supercavitating) undersea weaponry (D&I). Retrieved April 12, 2006, from http://www.onr.navy.mil/
  • Savchenko Y. N. (n.d.). CAV 2001 - Forth Annual Symposium on Cavitation - California Institute of Technology Retrieved April 9, 2006, from http://cav2001.library.caltech.edu/159/00/Savchenko.pdf
  • Hargrove, J. (2003). Supercavitation and aerospace technology in the development of high-speed underwater vehicles. In 42nd AIAA Aerospace Sciences Meeting and Exhibit. Texas A&M University.
  • Kirschner et al. (2001, October) Supercavitation research and development. Undersea Defense Technologies
  • Ashley, S. (2001, May). Warp drive underwater. Scientific American
  • Miller, D. (1995). Supercavitation: going to war in a bubble. Jane's Intelligence Review. Retrieved Apr 14, 2006, from http://www.janes.com/
  • Graham-Rowe, & Duncan. (2000). Faster than a speeding bullet. NewScientist, 167(2248), 26-30.
  • Tulin, M. P. (1963). Supercavitating flows - small perturbation theory. Laurel, Md, Hydronautics Inc.

External links

de:Superkavitation es:Supercavitación fr:Supercavitation it:Supercavitazione ja:スーパーキャビテーション pl:Superkawitacja pt:Supercavitação fi:Superkavitaatio uk:Суперкавітація zh:超空蝕效應


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