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{{Short description|Explosive device utilizing a tube of long welded metal cylinders}}
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[[File:CRWarheadTest.jpg|thumb|300px|Arena firing of continuous-rod warhead, 1972 at [[Naval Air Weapons Station China Lake]].]]
A '''continuous-rod warhead''' is a specialized munition
== Early anti-aircraft munitions ==
[[Rifle]] and [[machine-gun]] [[bullet]]s were used against early military aircraft during [[World War I]]. [[Artillery]] was used when aircraft flew above the range of rifle and machine-gun cartridges. Since the probability of actually striking the aircraft was small, artillery shells were designed to explode at the approximate altitude of the aircraft to throw a shower of [[fragmentation (weaponry)|fragments]] in the vicinity of the explosion. Similar anti-aircraft weaponry with larger calibers, higher rates of fire, and improved [[fuze]]s continued to be used through [[World War II]]. These bullets and small fragments often made small holes in the airframe. Unless a bullet or fragment struck the pilot, or some critical part of the airframe, (such as a fuel line, part of the engine coolant system, a critical wire or hydraulic line actuating control surfaces), the aircraft remained operational.▼
▲[[Rifle]] and [[machine-gun]] [[bullet]]s were used against early military aircraft during [[World War I]]. [[Artillery]] was used when aircraft flew above the range of rifle and machine-gun cartridges.
Some anti-aircraft artillery projectiles were designed to fragment into long, thin pieces in an attempt to inflict damage on the airframe. Holes made by such fragments were more likely to cause destructive disruption of airflow around high-speed aircraft, but the hit probability was lowered for the smaller number of fragments from a warhead of equal size. The problem became more significant as anti-aircraft missiles were developed to replace guns after World War II. A smaller number of missiles would require an improved warhead to match the aircraft destruction probability of the larger number of artillery projectiles potentially carried by a weapon of the same size and cost. The concept of a folded continuous rod warhead was suggested in 1952. The Applied Physics Laboratory of Johns Hopkins University invented the Continuous Expanding Rod Warhead as part of its Navy-contracted development of the U. S. Navy's anti-air missile defense program. The details of the warhead were Top Secret until its use was no longer needed.<ref name="talos">{{cite web|url=http://www.okieboat.com/Warhead%20history.html|title=Talos Missile Warhead History|accessdate=2011-01-27}}</ref>▼
The problem became more significant as anti-aircraft missiles were developed to replace guns after World War II: A smaller number of missiles would require an improved warhead to match the aircraft destruction probability of the larger number of artillery projectiles potentially carried by a weapon of the same size and cost.
▲
==Construction==
An [[even number]] of individual [[steel]] rods are arranged in parallel to form a cylinder. The ends of the rods are welded together—the first rod and the second rod are welded together at the top, the second and third at the bottom, and so on all the way around the form.
<gallery>
Image:CRUnweld.png|Rods arranged on [[mandrel]] prior to welding (single layer shown)
Image:CRWeld.png|Alternating welds completed and ready to receive explosives
Image:CRExpanding.png|Representation of rod expansion due to detonation of explosives
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==Operation==
[[File:Defe15-2399-figures-3-5-6-7.jpg|thumb|right|upright|Before-and-after detonation of a K11A1
When detonated, the high explosive imparts momentum to the rods, thrusting them outward in an expanding circle. The pressure wave from the explosive needs to act evenly on the rods over their length, so some sort of tamper is used to shape the shock wave similar to an [[explosive lens]]. The rods are sufficiently soft ([[ductility|ductile]]) to allow the expansion without breaking the rods or the welded joints, and the detonation velocity is limited to under 1,150 m/s,<ref name="FAS">{{cite web|url=http://www.fas.org/man/dod-101/navy/docs/fun/part13.htm|title=Fundamentals of Naval Weapons Systems|accessdate=2011-05-15}}</ref> allowing the rods to bend at these locations instead. At some intermediate point the ring will have a zig-zag (alternating direction) appearance within a cylindrical envelope. Upon ultimate expansion the ring is circular and contained within a plane. The ring will then break and ultimately tend to form one or more straight rods. Since the net [[momentum]] of the rod relative to the missile is roughly zero, its effectiveness will rapidly diminish as the broken ring expands.<ref>{{Cite book | publisher = Naval Institute Press | isbn = 978-1-59114-658-2 | last = Payne | first = Craig M. | title = Principles of Naval Weapon Systems | page = 352 | date = 2006-12-08 }}</ref>
This rapidly expanding ring, when hitting the aircraft, can be more effective than an equivalent [[Fragmentation (weaponry)|fragmentation warhead]]: the ring of rods
When designing the ill-fated [[Surface-to-air missile|SAM
==References==
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