V-2 rocket

:''V-2 re-directs here; for alternate uses see V2 The V-2 rocket (German: Vergeltungswaffe 2 or "reprisal weapon 2", or A4 a short form of Aggregat 4, the fourth rocket type) was an early ballistic missile used by Germany during the later stages of World War II against mostly British and Belgian targets. German V-2 test launch.

Pre-operational history

[[Peenemünde Museum replica of the first successful V-2 rocket. Like the original, this rocket has the Frau im Mond  logotype at its base.]] As early as 1927 members of the Verein für Raumschiffahrt (VfR) ("Spaceflight Society") had started experimenting with liquid-fuelled rockets. Rockets using a solid propellant had been used as weapons by all sides in WWI, and as a result, the Treaty of Versailles forbade solid fuel rocket research in Germany. By 1932 the Reichswehr started taking notice of their developments for potential long-range artillery use, and a team led by General Walter Dornberger was shown a test vehicle designed and flown by Wernher von Braun. Although the rocket was of limited ability, Dornberger saw von Braun's genius and pushed for him to join the military. Von Braun did so, as eventually did most of the other members of the society. In December 1934 von Braun scored another success with the flight of the A2 (''A'' for Aggregat) rocket, a small model powered by ethanol and liquid oxygen, with work on the design continuing in an attempt to improve reliability. Many different liquid fuels had been developed, but the German military specifically encouraged the use of ethanol as a rocket fuel because Germany had always been hampered by a shortage of crude-oil-based fuels. throughout WWII a wide variety of military rockets were fuelled by ethanol that was primarily derived from potatoes. By 1936 the team had moved on from the A2 and started work on both the A3 and A4. The latter was a full-sized design with a range of about 175 km (110 miles), a top altitude of 80 km and a payload of about a tonne. This increase in capability had come through a complete redesign of the engine by Walter Thiel. It was clear that von Braun's designs were turning into real weapons, and Dornberger moved the team from Kummersdorf (near Berlin) to a small town, Peenemünde, on the island of Usedom on Germany's Baltic coast, in order to provide more room for testing and greater secrecy. The A3 proved to be problematic, and a redesign was started as the A5. This version was completely reliable, and by 1941 the team had fired about 70 A5 rockets. The first A4 flew in March 1942, flying about 1.6 km and crashing into the water. The second launch reached an altitude of 11 km before exploding. The third rocket, launched on October 3 1942, changed things by following its trajectory perfectly. It landed 193 km away, and became the first man-made object to enter space. Production started in 1943 on the wonder weapon Vergeltungswaffe 2 (reprisal weapon 2), or the V-2 as it became better known, at the insistence of Goebbels' propaganda ministry. The Allies were already aware of the weapon. At a test site at Blizna in Poland a fired missile had been recovered by Polish resistance agents from the banks of the Western Bug, and vital technical details had been given to British intelligence. The British launched a massive bombing campaign against Peenemünde which slowed testing and production considerably as well as killing many slave workers. Dornberger had always wanted a mobile launch platform for the missiles, but Hitler pressed for the construction of massive underground blockhouses from which to launch them. V-2s arrived from a number of factories in a continuous stream on several redundant rail lines, and launching was almost continual. Construction of the first such site started at Eperleques in the Pas-de-Calais area in 1943, but the British spotted it almost immediately and started a massive bombing campaign that eventually forced the Germans to abandon it. Another site was then started nearby in a huge quarry and called La Coupole, but it wasn't long before that too was bombed into submission. Eventually they gave up on the area and moved to the south near Cherbourg, but once again the site was discovered and bombed — this time while the concrete was still wet. The plan was changed to build large truck-towed trailers for the missiles. An entire convoy for the missile, men, equipment and fuel required about thirty trucks. The missile was delivered to a staging area on a Vidalwagen and the local crews would fit the warhead. Launch teams would then transfer their missile to their own Meillerwagen and tow it to the launch site. There it was erected onto the launch table, fuelled, and launched. The missile could be launched practically anywhere, roads running though forests being a particular favourite. The system was so mobile and small that not one Meillerwagen was ever caught in action.

Peenemünde test launch list (until July 1943)

For the period after July 1943 only incomplete launch logs of experimental A4-launches at Peenemünde are available. Experimental launches continued in spite of air raids on August 17, 1943 and in July/August 1944 until February 21, 1945. A test rocked launched from Peenemünde on June 13, 1944, crashed in Sweden. Image:Peenemunde August 1943.jpg|Test range in Peenemunde Image:Peenemunde August 1943 2.jpg|Failed test at Peenemunde, August of 1943 Image:V-2 Bug.jpg|V-2 rocket being recovered from the Bug river by the Home Army Image:V-2 Bug parts.jpg|Parts of the V-2 rocket recovered from the Bug river by the Home Army Image:V-2 Leaflet testsitearea.jpg|German WWII leaflet in Polish and German warning the inhabitants of the area of testing site at Blizna of the crashed V-2 rockets Image:Struszynski Marceli profPW analis v-2fuel.jpg|Marceli Struszyński, a professor of the Warsaw University of Technology who successfuly analised the composition of fuel used by the V-2 and then passed the results of his research to the UK Image:MostIII v2 parts.jpg|Members of the Operation Most III, during which the parts of the captured V-2, as well as the analisis and sketches were transferred from occupied Poland to UK Image:Traeger Roman intellAK Peenemundediscov.jpg|Roman Traeger, a Polish scientist and member of the Polish intelligence service who discovered the Peenemunde test site Image:V-2 Holland December 1944.jpg|V-2 ready to use; Holland, December of 1944

Operational history

V-2 mass production was conducted at the Mittelwerk tunnel system under the Kohnstein mountain, part of the Mittelbau-Dora slave labour camp complex, near Nordhausen, Germany. By late 1943 over 10,500 forced laborers were in Kohnstein and many died due to the conditions (cold and humidity, especially) and heavy labour. For example, 2,900 died between October 1943 and March 1944, but others died during transfers and other work. Put another way, fatalities averaged over 100 per day during certain periods. The majority of the slaves were Russian, Polish and French, although there were also prisoners of war, foreign workers and Germans forced to compulsory work. Mittelwerk V-2 production chain. Mittelbau-Dora crematorium. The engine of a V-2 rocket. The first unit to reach operational status was Batterie 444. On September 2 1944 they formed up to launch attacks on Paris, recently liberated, and eventually set up near Houffalize in Belgium. The next day the 485th moved to The Hague for operations against London. Several launch attempts over the next few days failed, but on the 8th both groups fired successfully. This was the tip of the iceberg. Over the next few months the total number of V-2s fired were 3,172, distributed over the various targets as follows: A V-2 test rocket fired on 30th May 1944 crashed near the test facility at Sarnaki nad Bugiem and was recovered and secured by Polish resistance (Home Army). On the night of 25/26 July 1944 it was successfully transported to the UK from occupied Poland by a RAF plane (see Operation III Most). Analysis of the captured equipment proved vital in improving the Allies anti-V-2 defences. On 3 March 1945 the allies attempted to destroy V-2s and launching equipment near The Hague by a large-scale bombardment, but due to navigational errors the Bezuidenhout quarter was destroyed, killing 500 civilians. The V-2 was militarily ineffective. Its guidance systems were too primitive to hit specific targets, and its costs were approximately equivalent to four-engined bombers, which were more accurate (though only in a relative sense—see discussion in strategic bomber), had longer ranges, carried many more warheads, and were reusable. Nevertheless, it had a considerable psychological effect as, unlike bombing planes or the V1 Flying Bomb, which made a characteristic buzzing sound, the V-2 travelled faster than the speed of sound, with no warning before impact and no possibility of defense. The British were able to redirect V-1's and V-2's aimed at London to less populated areas east of the city by sending false impact reports via the German espionage network in Britain, which was actually controlled by the British. See: Double Cross System. A submarine towed launch platform was tested successfully, effectively making it the prototype for submarine launched ballistic missiles. The project codename was Prufstand XII. If deployed, it would have allowed a U-boat to launch V-2 missiles against American cities, though only with considerable effort (and likely limited effect). Twelve V-2 rockets were shipped to the Japanese by U-boat in dismantled condition. These left Bordeaux in August 1944 on transport U-boats U-219 and U-195 reaching Djakarta in December 1944. A civilian V-2 expert was also a VIP passenger on the U-234 bound for Japan in May 1945 when the war ended in Europe. The fate of these V-2 rockets is unknown.

Post-war V-2 usage

US test launch of a Bumper V-2. At the end of the war a race started to retrieve as many V-2 rockets and staff as possible. Under Operation Paperclip three hundred trainloads of V-2s and parts were captured and shipped to the United States, as well as 126 of the principal designers, including both Wernher von Braun and Walter Dornberger. Under British supervision, there were also three V-2 rocket launches to demonstrate the launch of V-2 rockets (operation Backfire) in October 1945. For several years afterward, the United States rocketry program made use of the supply of unused V-2 rockets left from the war. Some of these were equipped with a WAC-rocket as a second stage. These rockets were called Bumper. In 1949 such a rocket reached a then-record altitude of 400 km (250 miles) at its launch from White Sands. The Bumper was also the first rocket launched from Cape Canaveral. Many of these rockets were used for peaceful purposes, including upper-atmosphere research. Von Braun went to work for the US Army's Redstone Arsenal, eventually settling in Huntsville, Alabama in 1950. He quickly became the father of almost all US rocketry, working on the Redstone, Jupiter, Jupiter-C, Pershing, and Saturn rockets. The USSR also captured a number of V-2s and staff, letting them set up in Germany for a time. In 1946 they were moved to a site near Moscow in the USSR where Groettrup headed up a group of just under 250 engineers. The first Soviet missile was the R-1, an exact copy of the V-2 manufactured in the USSR. Starting with the R-1 (soon followed by its evolved version R-2) the Soviets developed a number of new missile designs which would eventually lead to the Scud missile. The designs produced by the German team in Moscow were not put directly into production; instead, local designers would incorporate the better features into their own designs. In this way the Soviet Union built up its own rocket design experience. The German team was eventually repatriated in the 1950s after the local design teams had captured all their knowledge. The British also captured a small number of V-2 missiles, and launched several of them from a site in northern Germany under Operation Backfire. However the engineers involved had already agreed to move to the US when the test firings were complete. The Backfire report however remains the most extensive technical documentation of the rocket, including all support procedures, tailored vehicles and fuel composition.

Technical details

right The V-2 had an operational range of about 300 km (200 statute miles) carrying a 1000 kg (2200 lb) warhead. The V-2 had an accuracy circular error probable (CEP) of 11 miles (17 km). This means at a 200-mile (300 km) range, the V-2 would only have a 50% chance of being within an 11-mile (17 km) circle centred on the target. With that kind of accuracy, it could be aimed to hit a city, but not a factory. Modern missiles, the Minuteman for example, have a CEP of 100 meters at a range of 10,000 km (330 ft at 6,200 mi). The V-2 was propelled by alcohol (ethanol) and water fuel, and the oxidizer was liquid oxygen. The fuel and oxidizer pumps were steam turbines, and the steam was produced by concentrated hydrogen peroxide with calcium permanganate catalyst. The water-alcohol fuel was kept in a tank of aluminium to save weight, which put a high pressure on German war economy, as this metal was rare and valuable. The combustion burner reached a temperature of 2500 to 2700 °C. The alcohol-water fuel was pumped along the double wall of the main combustion burner. This cooled the chamber and heated the fuel. The fuel was then pumped into the main burner chamber through 1224 nozzles, which assured the correct mixture of alcohol and oxygen at all times. Small holes also permitted some alcohol to escape directly into the combustion chamber, forming a boundary layer that further protected the wall of the chamber, especially at the neck where the chamber was narrowest. This boundary layer ignited in contact with the atmosphere, accounting for the long, diffuse exhaust plume of the V-2. (Later, post-V2 engine designs not employing the boundary layer show a translucent plume with shock diamonds.) The V-2 was controlled by four external rudders on the tail fins, and four internal rudders, made of graphite, at the exit of the motor. Some later V-2s used "guide beams" (i.e. radio signals transmitted from the ground), to navigate the missile toward its target, but the first models used a simple analog computer that would adjust the azimuth for the rocket, and the flying distance was controlled by the moment of engine cut-off,''"Brennschluss"'', ground controlled by a Doppler system or by different types of on-board integrating accelerometers. The rocket would stop accelerating and soon reach the top of the (approximately parabolic) flight curve. The painting of the operational V-2s was mostly a camouflage ragged pattern with several variations, but in the end of the war a plain olive green rocket also appeared. During tests, the rocket was painted in a characteristic black/white chessboard pattern which aided in determining if the rocket was spinning around its own longitudinal axis.

Lesser known influences on culture and technology

Model rockets

Model rocket V-2s are available in many sizes. For Germans, the 33-cm and 47-cm NORIS models are the best flying versions, because they can be launched without special permission with model rocket engines available in Germany.

Surviving V-2 examples and components

The short overview below includes only four of the at least 20 V-2s still existing as of 2005. For a presumably complete list, consult V2ROCKET.COM's "Surviving A4/V2 Rockets Around the World". Most, but not all, of the listed examples are available on public display.

United Kingdom

United States

Germany

See also

References

Category:World War II guided missiles of Germany de:A4 (Rakete) es:V2 fr:V2 is:V-2 flugskeyti it:Missile V2 he:V-2 nl:V-2 ja:V2ロケット pl:V2 (rakieta) pt:V-2 sv:V-2 zh:V2火箭

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