World War 2 saw the airplane rise to even greater importance than in the first World War. Air superiority became a crucial component of battlefield operations and air forces were massively expanded during the conflict.The Allied and Axis sides of the war developed enormous war machines, capable of developing and rolling out unprecedented numbers of advanced new military equipment in rapid response to changing conditions on the battlefield, as well keeping up with the technological advances of adversaries.
High altitude bombing raids and night fighting were hallmarks of the War for Europe, whilst aircraft carrier battles pitched the American and Japanese fleets against one another. The technology of the day was pushed to it’s limit with the use of superchargers in aircraft engines, the introduction of radar, and the rapid development of the jet engine by the war’s end.
The period ended as the Nuclear Age and subsequent Cold War were ushered in by the tremendous and tragic blows to Japan’s wearied people.
Nazi Germany (1936)
Shipborne and coastal reconnaissance aircraft – 98~118 Built
In the mid-thirties, the German Ministry of Aviation (Reichsluftfahrtministerium – RLM) tasked the Heinkel company with developing a replacement for the He 60 shipborne and reconnaissance aircraft. While Heinkel fulfilled the request by building the He 114, its overall performance was deemed insufficient for German standards.
History
During the early thirties, the He 60 was adopted for service as the main German shipborne and coastal reconnaissance aircraft. As it was considered outdated, in 1935, the RLM issued to Heinkel a request for a new shipborne and coastal reconnaissance aircraft that was to replace the He 60. The next year, two prototypes were completed. While it was originally planned to test these aircraft with the BMW 132 engine, due to lack of availability, this was not possible. The first prototype (with D-UBAM marking) made its maiden flight in September 1936. It was powered by a Daimler Benz DB-600A which gave out 900 hp. The test results of the first flight were disappointing, as it proved difficult to control on the water but also in the air. The second prototype, V2 (D-UGAT), powered by a 740 hp Jumo 210 E, made its first flight in December 1936. It was used to test the catapult launching capabilities of this aircraft. It had some modifications in comparison to the first prototype, like having a larger tail and redesigned floats. Despite some improvements, the catapult launch testings from the Gneisenau showed that the He 114 was not suited for this role.
Despite not having a promising start, further prototypes were ordered. The V3 (D-IDEG) prototype was powered by an 880 hp BMW 132 K (or D, depending on the source) engine. The floats were once again redesigned and the pilot had a better-glazed shield. This aircraft was tested in April 1937 with similar performance as previous versions.
V4 (D-IHDG) made its maiden test flight in August 1937. It had many modifications in order to improve its performance. The wing’s edges were redesigned, new floats were used and it was also fitted with machine gun armament. V5 (D-IQRS) had new improved floats which enabled it to take-off even from ice. While most sources mention only five prototypes, some note that there were two more. The V6 and V7 prototypes were tested with similar equipment and were armed with two machine guns, one firing through the propeller and the second mounted to the rear. Additional armament tested consisted of two 50 kg (110 lb) bombs.
Technical characteristics
The He 114 was designed as a single-engine, all-metal, twin crew biplane aircraft. It had a monocoque oval-shaped fuselage design. It was powered by one BMW 132K 960 hp nine-cylinder radial engine. The fuel load consisted of 640 l.
Somewhat unusual for biplanes of the era, the lower wings were much smaller than the upper ones. They had a half-elliptical design and were thicker than the upper wings. The upper wing was connected to the fuselage by two ‘N’ shaped struts. There were also two ‘Y’ struts connecting the lower and the upper wings. The upper wing was constructed using three parts with two ailerons. The upper wing could, if needed, be folded to the rear. The landing gear consisted of two floats which could also act as auxiliary fuel storage tanks with 470 l each.
The crew consisted of the pilot and the rear positioned machine gunner/observer. The armament consisted of one MG 15 7.92 mm (0.31 in) machine gun placed to the rear. The ammunition load for this machine gun was 600 rounds. Additionally, there was an option to externally mount two 50 kg (110 lb) bombs.
Further development
Despite being shown to have poor performance, a small production run was made by Heinkel. Some 10 (or 6 depending on the source) aircraft of the A-0 series, together with 33 of the A-1 series would be built. The only difference was the use of a larger rear tail design on the He 114A-1 series. The small number of He 114 built were given to various test units and flight schools, where its performance was often criticized by all. During its introduction to service, the much more promising Ar-196 was under development, but it would need some time until production was possible. As a temporary solution, the Luftwaffe officials decided not to retire the He 60 from service yet. Heinkel was informed that, due to the He 114’s overall poor performance, it would not be accepted for service and that it would be offered for export if anyone was interested. For this reason, Heinkel developed the He 114A-2 series. The He 114A-2 had a reinforced fuselage, floats that could be used as fuel storage tanks, and, additionally, it was modified to have catapult attach points. The He 114A-2, while tested, was not operated by the Luftwaffe, and it was used for the export market.
The following B-series (including B-1 and B-2) were actually just A-2 planes with some slight improvements, meant primarily for export. The history of the C-series is somewhat unclear, as it appears to be specially developed for Romania. It was much better armed, with either two 20 mm (0.78 in ) MG 151 cannons, two 13 mm (0.51 in) MG 131 heavy machine guns, or even two MG 17 7.92 mm (0.31 in) (the sources are not clear) placed inside the lower wings. Some sources also mention that additional machine guns were installed inside the engine compartment and could be fired through the propeller. Additionally, it appears that its fuselage was modified to be able to carry two additional 50 kg (110 lb) bombs. The rear positioned MG 15 was unchanged. This version also had a new Junkers type 3.5 m diameter propeller. The floaters were also slightly redesigned and it received smoke screen trovers. Additionally, to provide better stability while positioned near shore, a small anchor could be realized.
Operational use
Despite not being accepted by the Luftwaffe, due to the Kriegsmarine’s (German war navy) lack of sufficient seaplanes, some He 114 had to be used for this purpose. The distribution of the He 114 began in 1938 when the 1./Küstenfliegergruppe 506 was equipped with this aircraft. In 1939, it was 43equipped with the older He 60, as these proved to be better aircraft. Some German ships, like the Atlantis, Widder, and Pinguin, received these aircraft. During their use, the He 114 floater units proved to be prone to malfunctions. These were reported to be too fragile and could easily be broken down during take-off from the sea during bad weather.
A group of 12 He 114 C-1 aircraft that were to be sold to Romania were temporarily allocated to the 2nd Squadron of the 125th Reconnaissance Group (2/125 Aufkl.Sta.). These units operated in the area of Finland’s shore. When the Bv 138 became available in sufficient numbers, the He 114 C-1 was finally given to Romania.
Foreign use
While the He 114 failed to get any large production orders in Germany, it did see some export success. These included Denmark, Spain, Romania and Sweden. The B-series was sold, which was more or less a copy of the A-2 series.
In Danish service
The Danish use of the He 114 is not clear. Depending on the source, there are two versions. In the first, Denmark managed to buy 4 He 114 aircraft and even ordered more, but the German occupation stopped any further orders. In the second, while Denmark wanted to buy some He 114, nothing came of it, once again due to German occupation.
In Spanish service
During 1942, Spain obtained some 4 He 114s from the Germans. In Spanish service, these were known as HR-4. Despite their obsolescence and lack of spare parts, these would remain in use up to 1953.
In Romanian service
Romania received a group of 12 He 114 in 1939. During the war, the number would be increased to 29 in total. These would be extensively used to patrol the Black Sea. At the end of the war, these were captured by the Soviets, who confiscated them. Some would be returned to Romania in 1947, which would continue to use them up to 1960, when they were scrapped.
In Swedish service
Sweden bought some 12 He 114 in March 1941. In Swedish service, these would be renamed to S-12. Despite being an unimpressive design and prone to malfunction, the Swedish used them extensively during the period of 1941 to 1942, with over 2054 flight missions. They would remain in service up to 1945, with six aircraft being lost in accidents.
Production
Despite its poor performance, Heinkel undertook a small production of the He 114. The number of produced aircraft ranges from 98 to 118 depending on the source.
He 114 Prototypes – Between 5 to 7 prototypes were built
He 114 A – Limited production series
He 114 B – Export version of the A-series
He 114 C – Slightly improved version with stronger armament
Operators
Germany – Small numbers of these aircraft were operated by the Luftwaffe and Kriegsmarine, but their use was limited
Denmark – Possibly operated four He 114 before the German occupation
Spain – Bought four He 114, and operated them up to 1953
Sweden – Bought 12 He 114 in March 1941, which remained in use until 1945
Romania – Operated 29 He 114, with the last aircraft being scrapped in 1960
Surviving aircraft
While there are no complete surviving He 114s various parts and wrecks have been found over the years. Parts of one wreck were found in lake Siutghiol near Mamaia, on the Romanian Black Sea coast, in 2012. There is a possibility that the wreck of another lays in a lake near Alexeni as well.
Conclusion
The He 114 was an unsuccessful design that failed to gain any larger production orders in Germany. It had difficult controls both in the air and on the water. While it would see some limited service with the Luftwaffe, most would be sold abroad, where some were used up to the ’60s.
D. Nešić (2008), Naoružanje Drugog Svetskog Rata Nemačka Beograd
M. Griehl (2012) X-Planes German Luftwaffe Prototypes 1930-1945, Frontline Book.
S. Lonescu and C. Craciunoi, He 114, Editura Modelism
Jean-Denis G.G. Lepage Aircraft Of The Luftwaffe 1935-1945, McFarland and Company.
Ferenc A. and P. Dancey (1998) German Aircraft Industry And Production 1933-1945. Airlife England.
https://www.cugetliber.ro/stiri-eveniment-hidroavion-din-al-doilea-razboi-mondial-descoperit-in-lacul-tasaul-201060
Kingdom of Hungary (1939)
Fighter aircraft – Number used: 70 brought and 185 to 203 built under license
Despite not being adopted by the Italian Air Force, the Re.2000 would see some export success. Hungary bought a production license and 70 new aircraft for its Air Force. These would be supplemented by locally produced planes, both of which would see action during the Second World War. In Hungarian service, the Re.2000 would be known under the ‘Héja’ (Hawk) nickname.
Hungarian-Italian cooperation
During 1939, Hungarian Air Force (Magyar Királyi Honvéd Légierő) military officials were concerned with the need of acquiring more modern aircraft designs. As, during the 1930s, Hungary was a regular customer of Italian aviation equipment and planes (like the Fiat CR.32, for example), it was logical for the Hungarian Air Force military officials to turn to Italy for the acquisition of new aircraft.
By the end of 1939, Hungary sent a military delegation to purchase 70 fighter and 70 bomber planes. The Italians presented a number of different designs to this delegation, which included the Re.2000, Savoia-Marchetti S.M.79, and Ca.135bis. After a demonstration, the Hungarians were satisfied with the Re.2000’s performance. On 27th December 1939, a contract for the purchase of 70 new aircraft of this type was signed. This contract also included weapons, spare parts, onboard equipment, and a small number of airframes. Radios were not bought, as the Hungarians planned to equip them with domestically built R-13 ones. In addition, a license for domestic production was also obtained. The domestic production of the Re.2000 was to be carried out by MAVAG (Magyar Állami Vas, Acél és Gépgyárak/ Hungarian State Iron and Steel Works). The Re.2000s built-in Hungary were to be powered by domestically produced W.M. (Weiss Manfred) K-14 engines. The Italians were to deliver the first specimens by 15th January 1940.
As there were delays with the shipment of the first planes, the Hungarian Air Force sent a new delegation in April 1940 to Italy to determine what the problem was. To their astonishment, only one Re.2000 had been completed by this time. The Reggiane factory could not produce more planes due to a constant lack of raw materials. This single plane was flown to Hungary in May 1940. In Hungarian service, the first Héja received the serial number V-401 or V.401 (the V stands for Vadász/fighter). The remaining Héjas supplied by the Italians received the serial numbers V-402 to 470.
By the end of 1940, only 7 Héjas had been delivered to Hungary. The slow delivery rate was due to the shortage of materials, but also due to the fact that the Italian Air Force confiscated 9 planes for their own use. These would later be replaced by 9 newly built aircraft. The sources are not clear when the last aircraft arrived in Hungary. According to Gianni C., this happened at the end of 1941, but according to George P., this was on 29th May 1943!
The name
As already mentioned, the Re.2000 was known in Hungary under the Héja nickname. The origin of this name can be traced back to the Italian name given to this plane, “Falco”. In some sources, possibly in order to distinguish between the Italian and Hungarian built planes, the first were marked as Héja I and those built-in Hungary as Héja II. This article will use these two designations (when the precise model is noted by sources) but, for the sake of simplicity, the Héja I will be simply called Héja.
In Hungary
As the first Italian built Héja planes began to arrive in Hungary, they were intended to be given to different pilot training schools. Immediately after the arrival of the Héjas, the Hungarians noted a number of technical or structural problems with these planes. A great issue was the poor state and design of the throttles. These faulty throttles caused a number of accidents, with one Héja being lost in a fire during a landing accident. This issue with the throttles, despite efforts from Hungarian engineers, could not be solved until the end of 1941. Other issues with the Héjas were the poor state of the machine guns, which often jammed during firing or were misaligned, the instability of the canopy panels, and the lower quality of the wing skin. All this caused the Hungarians to make many modifications to the Héja in order to put them into service.
The Hungarian Héja II
With the contract to purchase 70 new fighters, the Hungarians also bought a license for production. The production of new planes was to be done by MAVAG. In order to avoid being dependent on Italian engines and to lower the overall price of the Re.2000, the Hungarians decided to upgrade this fighter with a domestically built engine. The initially planned new engine was a radial 14-cylinder air-cooled WMK-14 giving out 950 hp (or 930 hp, depending on the source). This engine was, in fact, a license-built version of the Gnome-Rhône Mistral Major K 14. One WMK-14 engine was sent to Reggiane to be installed in a Re.2000 in order to see if this modification was possible, but also to test its performance. The Italians, on the other hand, were never interested in this idea and preferred to sell the Re.2000 with its original engine. Due to the low interest and slow production rate of the Re.2000, nothing came from the Hungarian proposal. For this reason, the Hungarians decided that MAVAG should make these modifications.
In order to improve the potential flight performance of the plane, the Hungarian Ministry of Defence decided to use the stronger WMK-14B 1085 hp engine. For this reason, the manufacturer, Weiss Manfred, was to produce 329 new WMK-14B engines, of which 247 were to be used on Héja’s and the other 82 as spare engines.
The first plane to be powered with this engine was the Héja (V-401) supplied by the Italians. It was modified by MAVAG and then tested. The tests were successful and the order for 100 Héja II was given. The production was to be divided into two batches, a first one of 25 planes and a second with 75 planes after the first one was completed.
The Italians sent the needed documents for the production of the Re.2000 to Hungary in October 1940, which caused some delays for the Héja II production run. The first operational Héja II was built in June 1941 and was successfully tested the same month. By this time, the Hungarians also obtained a license production for the German Me-109 fighter. This plane was much better than the Héja II, but it was estimated that the production of Me-109s in any larger numbers could not be achieved until 1943. For this reason, it was decided to continue Héja II production as a temporary solution.
The preparations for the production of the first 25 Héja IIs began in November 1941. Despite the extra spare parts and airframes supplied by the Italians, the start of production could take place immediately. The reason for this was the lack of proper machine tools and production capacities of MAVAG, but also due to various testing and modifications. The second Héja (V-402) was reequipped with the stronger engine for testing purposes. It was flight tested at the Experimental Institute near Csepel. After a series of test flights, some modifications were required, like improving throttle controls and modifying the rear tailwheel.
Production of the Héja II began only in July 1942. Immediately at the start of production, problems with the Reggiane fuel tank seal were noted. The Hungarian engineers simply replaced it with 22 smaller 20-25 l fuel tanks. To their surprise, this modification actually improved the Héja II’s stability during flight, as it reduced fuel sloshing in the tank. The production of the first 25 planes (with the modified fuel tanks) was completed by October 1942. Before the start of the second series of 75 aircraft, an order for 100 additional Héja IIs was placed. The last Héja II would be built in early March 1944. Officially, the Héja II was accepted for service in late September 1942 by the Hungarian Air Force.
A Héja II (V-495) from the first batch was tested by test pilot Tibor T. in March of 1943. The production of the later series was slowed down due to difficulties with obtaining necessary parts from abroad (due to the Italian capitulation and the desperate state of the German economy). In addition, the WM factory was bombed in early April 1944. The factory was almost completely destroyed, with the loss of nearly all equipment and spare parts. For this reason, the Hungarians were forced to stop the production of the WMK-14 engine. WM was finally destroyed in another bombing raid in July 1944. For this reason, the production of a group of nearly 30 new Héja IIs could not be completed.
Technical characteristics
The Héja I was a regular Re 2000, the characteristics of which will not be repeated.
The Héja II was a low wing, metal construction, single-seat fighter plane. The fuselage consisted of a round frame covered with metal sheets held in place by using flush-riveting. The Héja II wings had a semi-elliptical design, with five spars covered with stress skin. The original Re.2000 fuel tanks, placed in the central part of the wing, were replaced with 22 smaller 20-25 l fuel tanks. The wings were equipped with fabric-covered Frise type ailerons. The rear tail had a metal construction with the controls covered with fabric.
The landing gear system was unusual. When it retracted backward, it rotated 90° before it fell into the wheel bays. For better landing, the landing gear was provided with hydraulic shock absorbers and pneumatic brakes. The smaller rear wheel was also retractable and could be steered if needed.
The Héja II was powered by one WMK-14B 1085 hp engine. With the stronger engine, the Héja II could achieve a maximum speed of 323 mph (520 km/h). A larger 10.5 ft (3.2 m) Weiss Manfred three-bladed and hydraulically controlled variable pitch propeller were used. Due to the installation of the new engine, the front fuselage design had to be changed and extended by 1.3 ft (40 cm). As the new engine had a somewhat smaller diameter, the pilot front field of view was increased. In addition, the engine cowling design was changed.
The pilot cockpit canopy opened to the rear and gave a good overall view of the surroundings. The Hungarian Héja II was not originally provided with the 0.3 in (8 mm) thick armor plate placed behind the pilot seat. The Hungarians tested domestically built ones, but the results of these tests are not clear. Most interior equipment, except the radio, was provided by the Italians.
The two 0.5 in (12.7 mm) Breda-SAFAT heavy machine guns were replaced with Hungarian Gebauer MGs of the same caliber. The Gebauer gun had a firing rate of 1000 rounds per minute. The ammunition for each machine gun was 300 rounds stored in a box magazine. With the installation of these machine guns, the upper part of the front fuselage had to be redesigned.
During the war
With the German attack on the Soviet Union in June 1941, Hungary, together with other Axis allies, joined this offensive. For the attack on the Soviet Union in early August 1941, the Hungarians dispatched the Independent Fighter Group, which consisted of two fighter squadrons equipped with CR.42 planes. The first Héja fighter squadron with seven (or six, depending on the source) planes was formed on 7th August 1941. It was stationed at Sutyska airfield near Vinnytsia, in Ukraine. A few days later, it was moved to Pervomayks and was put in a fighter escort role for Hungarian bombers. The first operational mission was to escort a group of Ca.135 bombers in attacking Nikolayev on the 11th of August. The first air victories were achieved in late August when three Héja fighters engaged a group of five Soviet I-16 fighters near Dniepropetrovsk. The Hungarian fighters managed to shoot down three I-16s with no losses. By the end of August, the Héja fighters had made in 151 sorties with five achieved victories. The Héja would see action on the Eastern front up to late October 1941, when they were recalled to Hungary. One aircraft was lost during the flight back to Hungary when it crashed somewhere over the Carpathian mountains. During its first year of service, the Héja’s were mostly used in bomber escort and occasional ground attack missions. As most of the Soviet Air Force was destroyed early on, there were few air encounters with enemy planes. In total, three Héja were lost, with one additional being damaged.
In preparation for the new German campaign on the Eastern Front in 1942, the Hungarian Air Force formed the 1st Fighter Group. This Fighter Group had a Squadron equipped with 12 Héja fighter planes commanded by Colonel K Csukas. This Squadron was combat-ready by 5th July 1942. As there were cases of Germans mistaking the Héja for Soviets planes, one Héja and also a CR.42 were sent to several German airfields in order to familiarize German pilots with these planes. Initially, the Germans gave the Hungarian fighters the task of patrolling and escorting reconnaissance and bomber planes near the front. On 13th July, the Héjas were tasked with defending the ground forces concentrating for the attack on Soviet positions.
By the end of July 1942, a second unit equipped with 11 Héja was deployed to the front. Both Héja units were moved to Ilosvoskoye in early August. The first squadron was tasked with a bomber escort mission, while the second with a reconnaissance escort mission. The 1st Fighter Group was in really bad shape due to maintenance problems, with only four Héja being operational by the 8th of August. This forced the Hungarians to ask the Germans for fighter cover for their troops.
In early August 1942, the Héja fighters were hard-pressed to stop the increasing number of Soviet bombing raids into Axis lines. On 7th August, a Soviet IL-2 managed to shoot down a Héja fighter which crashed into the ground. On the same date, Héja fighters intercepted a group of three German He-111 bombers which were accidentally bombing Hungarian lines and managed to shoot down one.
On 20th August, while making a take-off from an airfield near Ilosvoskoye, István Horthy (son of Miklós Horthy) lost his life in an accident. Author Maurizio D. T. notes that the accident was possibly caused due to the installation of a 0.98 in (25 mm) thick armor plate behind the pilot seat. There are also claims that the plane was sabotaged by the Germans due the Miklós Horthy allegedly showing sympathy for the English people, but this is improbable. The Germans were in no position to sacrifice trained fighter pilots or planes. Horthy probably simply crashed due to a pilot error or miscalculation.
By late August, the 1st Fighter Group lost four planes either due to enemy action or accidents and six more were damaged but in a state that could be repaired. By the end of August, Héja pilots managed to shoot down five enemy aircraft, with three more in September. By October 1942, most Héja pilots were recalled to Hungary to begin training on the new Me-109 planes. The remaining 13 Héjas were used on the Eastern Front up to late December, with only six still being operational.
During the Soviet attack on Axis positions around Stalingrad, the Hungarians sent all available planes, including the few working Héja fighters, to stop these attacks. The following days, a pair of Héja fighters sent to escort German bombers were attacked by Soviet fighters but managed to escape. By 15th January, the Héja performed mostly escort missions. The surviving Héjas met their fate when they were destroyed by their crew in order to avoid being captured, as they could not make an escape due to the harsh Russian winter.
No improved Héja IIs were used on the Eastern Front, as these were kept in reserve. As a shipment of more advanced Me-109G arrived in Hungary from Germany in late 1943, the Héja was mostly used for training. But, due to the increase of Allied bombing runs, they were put into action for the defense of Hungary skies.
By March 1944, Germans sent forces to occupy Hungary, as there was information that Hungarian politicians were negotiating with the Soviets for an armistice. During this occupation, the Germans prevented any further work or training on the Héja II. In April, the Allies made major bombing raids against Hungarian factories. This affected the supply of new spare parts, but, despite this, a group of 30 newly built Héja II was tested in April.
During the Allied Bombing raid by the 15th Air Force on Budapest (13th April 1944), the P-38 escort fighters were attacked by a group of Héja II fighters. During this engagement, one Héja II was damaged. Another group of 8 Héja II was sent to support the defense of Budapest. Four of these attacked Allied bombers but, due to heavy defensive fire, the attack had to be aborted. Two Héja II fighters were damaged and one had to make an emergency landing. The second group of four fighters failed to reach the bombers but ran into a group of P-47s. After a short engagement, one Héja II was shot down and one was damaged.
Due to the lack of spare parts, some 30 Héja II fighters could not be completed. The Hungarians tried to salvage any parts from damaged aircraft, but this was insufficient. In December 1944, there were six operational planes with the training unit ‘Puma’ Fighter Wing. The last Héja II was lost in early 1945 in an accident.
Héja wartime improvements and modifications
Based on the front line experience, in order to provide the pilots with better protection, the Hungarians asked the Italians for the design blueprints of the Re.2000 and Re.2001 0.3 in (8 mm) armored plates. The Re.2001 version was preferred, as it was much lighter at 110 lbs (50 kg), while the Re.2000 one was heavier, at 200 lbs (90 kg). The Italians, for some reason, did not agree to give these blueprints, so the Hungarians were forced to develop their own design. Author Maurizio D. T. mentions that a 0.98 in (25 mm) armor plate was added behind the pilot seat, which affected plane performance.
An additional fuel tank with 100 l was added into the fuselage in order to increase the operational range. It was equipped with a self-sealing coating in order to avoid any fuel leaks which could lead to a fire accident.
In the late part of the war, two planes were modified and equipped with dive brakes and bomb racks for 550 lbs (250 kg) or 1100 lbs (500 kg), in order to be tested for use as dive bombers. For further testing, one additional Héja II was modified for this. The tests appear to have been unsuccessful, as no production order followed for this modification.
By the end of 1942, there were plans to form a Night Fighter Squadron equipped with German radio equipment. As the promised equipment never arrived, no such unit was ever formed.
Production
The production of the first Héja II began in July 1942, with the first 25 completed by October 1942. Before the start of the second series of 75 aircraft, an order for 100 additional Héja IIs was placed. The last Héja II would be built in early March 1944. Depending on the sources used, the production numbers are different. The numbers go from 185, 192 to 203 planes. The difference in number may be caused by the fact that some sources include also the last 30 unfinished airframes.
Héja I – 70 planes were purchased from the Italians
Héja II – Hungarian built version
Prototypes
Héja II dive bomber – Three Héja IIs were modified for the role of dive bombers but were not accepted for service
Héja II night fighter – There were plans to use the Héja II as a night fighter but due to the lack of necessary equipment no plane was ever used in this role.
Conclusion
The Héja provided the Hungarians with a much needed modern fighter plane. While it did see service, it was never used in any larger numbers due to problems with the delivery of new planes from Italy. Even when the improved Héja II was produced in Hungary, it was also plagued with slow production and distribution to combat units. By the time the Héja II was built in larger numbers, it was already outdated by late-war standards.
Héja II Specifications
Wingspans
36 ft 1 in / 11 m
Length
26 ft 6 in / 8.4 m
Height
10 ft 4 in / 3.15 m
Wing Area
220 ft² / 20.4 m²
Engine
One WMK-14B 1085 hp engine
Empty Weight
4560 lbs / 2.070 kg
Maximum Takeoff Weight
5550 lbs / 2,520 kg
Fuel Capacity
500 + 100 l
Climb to 6 km (19,700 ft)
6 minutes 10 seconds
Maximum Speed
323 mph / 520 km/h
Cruising speed
255 mph / 410 km/h
Range
560 mile / 900 km
Maximum Service Ceiling
25.700 ft / 8.140 m
Crew
1 pilot
Armament
Two 0.5 in (12.7 mm) heavy machine guns
Gallery
Heja, Illustration by Pavel Alexe
Heja II, Illustration by Pavel Alexe
Source
Nešić, D. (2008). Naoružanje Drugog Svetsko Rata-Italija. Beograd
David M. (2006). The Hamlyn Concise Guide To Axis Aircraft OF World War II, Bounty Books
Maurizio D.T. (2002). Reggiane RE 2000 Falco, Heja, J.20, Instituto Bibliografico Napoleone
G. Punka (1994), Hungarian Air Force, Signal Publications
George P. Reggiane Fighters In Action. Signal Publication
Jonathan T. (1963) Italian Civil And Military Aircraft 1930-1945, Aero Publisher
Gianni C. (1966) The Reggiane Re.2000, Profile Publication Ltd.
John F.B. (1972) Caproni Reggiane Re 2001 Falco II, Re 2002 Ariete and Re 2005 Sagittario, Profile Publications
Kingdom of Italy (1941)
Fighter Aircraft – 32 ~ 48 Built
The Re.2005 was one of the better and more modern Italian WWII fighter designs. It was developed by Reggiane in 1941. Due to the lack of DB.605 engines, the development and production process of the aircraft was too slow and, by the time of the Italian surrender to the Allies, less than 50 had been built.
History
Officine Meccaniche Reggiane SA (hailing from Reggio Emilia in Northern Italy) was a WWI era aircraft manufacturer. However, following the First World War, it was not involved in any large aircraft production or design work. Rather as a company, it focused primarily on the Rail and Agriculture sectors primarily building locomotives and agricultural equipment. Its production efforts only returned to aircraft during the thirties when Reggiane became a subsidiary of the much larger Caproni aircraft manufacturer, which was led by the well-known Engineer Gianni Caproni. Thanks to this, Reggiane was aided by Caproni with a larger and more qualified aircraft design department. Reggiane and Caproni were involved with several experimental pre-war designs, like the Ca.405 Procellaria and P.32bis version, in addition to their license production of the S.M.79.
By 1941, the Italian Air Force was in a very desperate state, as it lacked an effective fighter design that could engage the increasing Allied bombing actions against Italian cities. The only modern design, the Macchi C.202, could not be produced in sufficient numbers to make a difference. For this reason, the Italian Air Force initiated the development of the so-called Serie 5 fighter designs that would eventually lead to the Fiat G.55, Macchi C.205, and the Reggiane Re.2005.
One of the greatest problems that the Italian aircraft designers and manufacturers had was the lack of sufficiently strong engines. In 1938, the development of a 1200 hp Fiat A.38 engine began, but many problems appeared and the engine could not be produced in time nor in any great numbers. For this reason, the license for the production of the German DB.601 was obtained. The problem was that Alfa Romeo’s, the manufacturer of this licensed engine, production output of this engine was only around 50 to 60 per month. Due to the lack of an adequate engine, Italian General Francesco Pricolo proposed creating new designs using the German 1475 hp DB.605 engine, which was to be produced by Fiat from 1942 on. The first planes chosen to be equipped with this engine were the Re.2001 and C.202. On 23rd July 1941, a decision was made to save the entire production of the DB.601 engine for the C.202. In addition, around 1000 new DB.605 engines were ordered to be produced by Fiat. Reggiane officials, seeing a new business opportunity, devoted all their available resources in the development of the new Re.2005 model.
The name
In various sources, this plane is marked by different but similar designations. These include RE 2005, Re 2005, or Re.2005. This article has and will use the Re.2005 designation. In early January 1943, the Re.2005 received its ‘Sagittario’ (name of the Constellation Archer) nickname, which is very well known today.
Re.2005 beginnings
In order to design the future Re.2005, a team was chosen under the leadership of Giuseppe Maraschini. His team decided that, instead of simply improving earlier models, they would design and build a brand new aircraft prototype. Carryovers from previous vehicles included the wings, which were similar to previous models but were made of a single piece. The armament was increased to two 0.5 in (12.7 mm) machine-guns and one 0.78 in (20 mm) cannon firing through the propeller hub, with two additional 0.5 in (12.7 mm) machine guns to be placed in the wings. A new outward retracting landing gear was to be installed. The radiators were placed under the fuselage. The building of the wooden fuselage mock-up was completed by the end of October 1941. The wings were completed by early November 1941. Preparation for the construction of two working prototypes (MM.494 and 495) began soon after.
However, there were delays due to the lack of promised DB.605 engines, that were not ready for license production yet. There was also a possibility that all future produced DB.605 engines would be delivered to Fiat and Macchi designs only. Despite these setbacks, the work on an operational prototype continued and, in February 1942, the factory was visited by the High Technical-Military Inspectorate commission. This commission gave good remarks for the Re.2005 design but asked to move the wing-mounted machine guns into the fuselage. As this would cause many technical problems and delays, nothing was done on this matter and the machine guns remained in the wings. By this time, the required shipments containing the armament (Mauser 0.78 in/20 mm MG 151 cannons), canopies, and windscreens (same as on the MC.205) were yet to arrive, as there were constant delays.
Once completed, the first test flight of the MM.494 prototype was made on 9th (or 7th, depending on the source) May 1942. For the main test, pilot Major Tullio De Pranto was hired by Reggiane, for the payment of 140.000 lire. This flight lasted around 5 minutes and was without problems. The following day, Major De Pranto made another flight with the MM.494 prototype. At first, it was fine but then the landing gear mechanism on the right leg broke down, which forced the pilot to make an emergency landing. The prototype was damaged but repaired and the flight tests continued during June and July 1942. By this time, over 6 hours of flight were achieved. In late July, the plane was transported to the Guidonia test center for further testing. There, during dive testing, a maximum speed of some 560 mph (900 km/h) was achieved. But there were again problems with the landing gear and also with the cockpit design and, for these reasons, it was returned to Reggiane for modifications. During August, modifications on the cockpit were made, mostly on the design of glass surfaces and the length of the windscreen, which was considered to be too long for the pilot. In September, the flight tests continued, but there were some issues with the engine malfunctioning and the MM.494 pilot was forced to make an emergency landing. By late September, many pilots had the opportunity to fly on the Re.2005 prototype.
At the start of October 1942, the second prototype was moved to the Guidonia test center for testing. There, the problem with the landing gear persisted, in addition to problems with fuselage vibrations that were also noted. By the end of October, the Re.2005 was used in a mock fight with the Fiat G.55. During the firing of its 0.78 in (20 mm) cannons, there were ammunition feed problems. For these reasons, in combination with the previous notes, the MM.495 prototype was returned to Reggiane for further modifications. In late December 1942, an Air Force Commission was formed to examine the Re.2005 prototype overall flying performance, armament, production speed, etc. The Re.2005 was noted to be inferior to the MC.205 but better than the Fiat G.55. While the final decision was not clear, the development of the Re.2005 continued on.
The next step in Re.2005 testing was the addition of bomb loads. During these tests, no major problem was recorded, but the take-off run was increased by some 657 ft (200 m) due to the extra weight. While piloted by Captain Enzo Sant’andrea, instead of releasing the 1410 lb (640 kg) bomb, the release harness mechanism failed and the bomb remained stuck to the plane. He was forced to land with the bomb, but luckily it did not explode and the landing was successful. Various tests were carried out with the original German engine and equipment from April to June 1943.
The Re.2005 prototype was used to supplement a mixed unit in the defense of Rome on 27th May 1943. During this flight, the Re.2005 was piloted by Lieutenant Giorgio Berolaso. While no enemy aircraft were detected, he managed to test the main armament. He later wrote, “ … It was a terrific experience! Such was the recoil that I had the impression that the entire aircraft slowed down…”.
Reggiane fights for production orders
In January 1942. Italian Air Force Officials decided to adopt the Macchi C.202, C.205, and the Fiat G.55 for mass production. The fate of the Re.2005 was, for some time, uncertain. Only in August 1942 did Reggiane receive orders to prepare machine tooling for the possible production of the Re.2005. In October, Reggiane petitioned for the production of 16 Series-0 Re.2005 aircraft. This petition was accepted by Italian Air Force officials and an order for 16 Series-0 (MM.092343-092358) planes was placed in November. Engineer Roberto Longhi was tasked with the construction of the first Series-0 aircraft. As numerous modifications were required, he immediately began working to improve the Re.2005’s performance. The fuselage skin was reinforced, along with the wing spar caps, skins, and internal structure.
As Engineer Roberto Longhi was working to improve the Re.2005, a special Air Force committee rejected it for serial production. Instead, the Re.2005’s improved wings were to be applied to the Re.2002 to serve either as an advanced fighter or as a fighter-bomber. It was also proposed to reequip the Re.2005 with the weaker DB.601 due to a lack of DB.605 engines. For some time, there were fierce discussions between Reggiane officials and the Italian Air Force about the Re.2005. The Reggiane officials even managed to involve Benito Mussolini in this discussion. Eventually, Reggiane managed to obtain a production order for 100 Re.2005 in January 1943, with an additional 18 of the Series-0. In late January 1943, it was increased to 600 aircraft with a monthly production of 70. In order to achieve such high production orders, other manufacturers were to be included in Re.2005 production, like Breda, Caproni, and Aerfer. Eventually, an order for 1000 aircraft was sent with Reggiane, but these numbers were never achieved due to a lack of engines and the war ending for the Italians.
When the production began in early March 1943, it was decided that, from the 24th produced plane onward, bomb racks would be added and the planes were to be used solely as fighter-bomber aircraft.
Technical characteristics
The Re.2005 was designed as a single-engined, low wing, all-metal fighter plane. The fuselage was made using a reinforced sheet metal construction covered with an aluminum alloy skin. The fuselage around the cockpit was additionally strengthened in case of a crash landing.
The landing gear had a simpler design than previous Reggiane designs. It consisted of two outward retracting wheels which were operated hydraulically. The rear tail wheel retracted into the fuselage and was enclosed by two small metal doors. The rear tail wheel could also be steered by the pilot if needed.
To speed up and ease production, the wings were made of one semi-elliptical piece. The wings were made using light alloy materials. They consisted of three double ‘T’ shape spars connected with sheet metal ribs. The split flaps made of metal were extended to under the fuselage. The ailerons (Frise type) were made using a combination of fabric and light alloy materials.
The cockpit had a canopy that could be opened to the right side. For better pilot protection, his seat was made using an 8 mm steel plate. The cockpit was provided with standard Italian equipment, like an Allocchio-Bacchini 30 radio, San Giorgio reflector collimator, Patin telecompass, etc.
The engine used was the German Daimler Benz DB.605A-1 1.475 hp that was being produced under license in Italy as the R.A.1050 RC.58 Tifone (Typhoon). A Piaggio P.2001 three-bladed, mechanically controlled metal propeller was used. The engine was placed in a specially designed mount that was connected to the rest of the fuselage. The Re.2005 oil radiators and coolant were placed on the sides.
The total fuel load was 580 l (or 536 l, depending on the source) stored in four fuel tanks placed in the wings. Access to the fuel tanks was done by removing metal plate panels held in place by screws. Three additional external fuel tanks could be added if needed, one larger with 240 l under the fuselage and two 100 l tanks under the wings.
For Italian standards, the Re.2005 was heavily armed with German supplied cannons. Its armament consisted of one 0.78 in (20 mm) MG 151 cannon firing through the propeller center and two 0.45 in (12.7 mm) Breda SAFAT machine-guns were placed in the front fuselage. Depending on the availability, two 0.45 in or two 0.78 in cannons could be placed in the wings. The total ammunition load was 550-600 (for all three) rounds for the cannon and 700 rounds for the two machine guns. Different bomb load combinations were tested, with a maximum load under the fuselage of 1410 lb (640 kg) and 350 lb (160 kg) under each wing.
In Operational service
Due to the small number built, the Re.2005 saw only a limited number of actions with the Italian Air Force. All surviving Re.2005 were captured by the Germans, who put them to use. The last operator was the Aeronautica Nazionale Repubblicana, which had only a few Re.2005, but if any were ever used operationally is not known. There were attempts to sell the Re.2005 to Sweden, but nothing came from this.
In Italian Service
The delivery of the Re.2005 to operational units was slow, maximally up to four planes per month. The first unit to be supplied with this aircraft was the 362° Squadriglia which was part of the XXII Gruppo Caccia commanded by Captain Germano La Ferla. The first prototype, MM.494, was given to this unit in early 1943. At the start of April 1943, a group of 20 Italian fighters attacked an Allied B-24 bomber formation and managed to shoot down two bombers. One kill was credited to Re.2005. On 10th April, another attack on an Allied bomber formation was made and the Re.2005 again managed to shoot down one bomber. The next day, two more B-24 were shot down at the cost of one Re.2005. The pilot managed to survive using a parachute. On 28th April, another attack was made by a group of four Re.2005, eleven Macchi C.202 and one French captured D.520. In this action, the Re.2005 pilots shot down two more bombers. By this time, it was apparent to the pilots that the Re.2005 was far superior to the C.200 and C.202. The greatest strength of the Re.2005 was its strong firepower of up to three 0.78 in (20 mm) cannons. From May to June, there were several more flights but without any success.
The 362° Squadriglia was moved to Latina in June 1943. By this time, the 362° Squadriglia had only 8 Re.2005 with 7 operational. On 25th June, this position was attacked by Allied aircraft and four fighters were damaged.
In early July 1943, the 362° Squadriglia, with around 8 Re.2005, was relocated to Sicily in an attempt to stop the Allied advance. In the following days, the Re.2005 managed to shoot down several British Spitfires with the loss of a few aircraft. With the inevitable Axis defeat in Sicily, the Re.2005 crews were moved to Italy. The last two operational Re.2005 were lost in an air raid on the positions of the 371° Squadriglia to which they were temporarily attached.
In mid-July, the 362° Squadriglia was operated from Naples with newly supplied Re.2005. By 20th July, this unit had only six Re.2005 but, in the following days two, were lost during bad landings, including the second prototype. Other units were also supplied with the Re.2005 but, in most cases, they were supplied in very limited numbers, for example to 369° Squadriglia. Through August, there were several unsuccessful flight attempts against Allied aircraft. A number of Re.2005 were lost either to Allied action or to other circumstances. By early September, due to the Italian surrender, all available Re.2005 stationed in Naples were destroyed by their crews.
The maximum number of Re.2005 ever operated by 363° Squadriglia was around 9 operational planes. By the time of the Italian surrender, in total, 19 Re.2005 were supplied for operational use to front line pilots. During the period in which XXII Gruppo Caccia was equipped with the Re.2005, it claimed to have shot down some 24 enemy aircraft, with 17 more labeled as possible. In addition, 8 to 13 aircraft were reported to be damaged by this unit. The total losses of Re.2005 amounted to 12 planes, with the deaths of 3 pilots and 4 wounded. While in service, the Re.2005 landing gear proved to be problematic and thus the ground repair crews made several field modifications in order to solve this problem.
In German hands
After the Italian defeat, the Germans rushed to capture any available military equipment and factories they could find. This included the Reggiane factory, along with all surviving Re.2005 in September 1943. Once in German hands, 8 Re.2005 that were under construction were completed. The Germans seemed to be satisfied with its performance and allocated them to the Luftwaffe Luftdienst Kommando Italien in October 1943. At the start of 1944, two additional Re.2005 were completed and given to the Luftwaffe.
The use of the Re.2005 by Germans is somewhat confusing, as some authors suggest that they were used in defense of Berlin up to the war’s end ( like D. Mondey). Author M. Di Terlizzi mentions that the MM.495 prototype along with MM.096105 were sent to Germany for evaluation, but what their fate was is not known. Author G. Punka even writes that the second prototype was used in defense of Bucharest. Both cases seem highly unlikely if we take into account the cost of transport, lack of spare parts which would force it to operate close to the Reggiane factory, and the small numbers of captured planes. Even if the Re.2005 were repositioned to defend Berlin, they would have made no difference due to the small number built.
In an Allied bombing raid in March 1944, three Re.2005 were lost. From March to June 1944, three more were damaged, mostly due to accidents, and were returned to Reggiane for repair. By the end of July, five Re.2005 were still operational and used by the Fliger Ziel Staffel 20. This unit was active from June to December 1944. The final fate of the German-operated Re.2005 is not clear but, by the end of 1944, all were probably lost.
Aeronautica Nazionale Repubblicana
The Aeronautica Nazionale Repubblicana had two operational Re.2005 captured at Castiglione del Lago in October 1943. It is highly unlikely that they ever saw any operational service.
Offer to Sweden
In 1942, the Chief of the Caproni commercial company (Compagnia Commerciale) made an attempt to sell the license and 50 incomplete airframes to Sweden. His offer was based on the fact that Italy had sold older Re.2000 and that Sweden had obtained a license for the production of the German DB.605 engine. By the time the Air Ministry and Mussolini allowed this arrangement, in June 1943, it was too late and the whole deal was never achieved.
Proposals and modifications
During the Re.2005’s development process, there were few attempts to overcome the problem of the lack of an adequate engine. Other different modifications were also tested, but with little to no success.
Re.2005 SF/R
In late November 1942, there were proposals to mount an additional jet engine on the Re.2005 which could help it reach a speed up to 466 mph (750 km/h), at least in theory. Due to the extra weight of some 1000 lb (310 kg) and complications with the installation, no Re.2005 was ever fitted with this engine. This proposal is often marked by Re.2005 SF, after the names of the main proponents of this project, Marcello Sarracino and Antonio Ferri. It is also marked simply as Re.2005 R, Reazione (Reaction), by some sources.
Re.2005 wooden version
Luigi Nardi made a proposal to build the Re.2005 aircraft using mostly wood. This would make the production of Re.2005 cheaper. Nardi was involved in building the first wooden wings in March, following with a fuselage in June 1943. Reggiane officials hired Nardi in late 1942 ( officially in early 1943) and gave him a team of 39 men to complete a wooden model. Little to no progress was made by 1943 and, in the end, it appears that no working prototype was ever built.
Twin fuselage Re.2005 version
There was a paper proposal in late 1942 to build a twin-fuselage heavy fighter version of the Re.2005. It was to be powered by two DB.605 engines and the pilot was to be positioned in the left fuselage. This project remains on paper only and no mock-up or working model was ever built. In 1943, Nardi proposed a similar all-wood project, but nothing came of this. If these two projects were related, it is not known. It is unknown if this version received any official designation.
Re.2005 aircraft carrier version
Due to Reggiane’s experience with shipboard aircraft designs, the Re.2005 was chosen to be used for the Aquila aircraft carrier. No progress was ever made for this version and, in the end, nothing came from it.
Re.2004
Due to the lack of DB.605 engines and the priority given to the G.55 and C.205 aircraft, Italian Air Force officials proposed in late 1941 that Reggiane adopt another solution. This included the use of the new Isotta Fraschini Zeta 1.250 hp engine still in development. This new aircraft project was named Re.2004. The development process of the Re.2004 was slow and, by late June 1943, only two prototypes were ordered to be built. The main engine was never successfully completed nor used due to huge problems with the cooling system. It is likely that only wooden mock-ups were ever built of the Re.2004. Some authors, like John F.B, note that the Re.2004 was actually based on the Reggiane Re.2001 fighter design.
Re.2006
In March 1943, the Italians managed to obtain a number of German 1750 hp DB.603 engines. Immediately, there were plans to equip the existing fighter designs with this engine, including the Re.2005. In May 1943, the Italian Air Force ordered Reggiane to construct two new prototypes (MM.540-541) using this engine. By the time of the Italian surrender, only one incomplete (or complete, depending on the source) prototype was built. After the Germans captured the Reggiane factory, they continued work on the Re.2006 by using some components taken from the Re.2005 (the fuselage). The work on it was never finished by the Germans. It was captured by the Allies, who showed no interest in it, and the incomplete Re.2006 was scrapped in April 1946.
Production
Despite promising performance and an official production order for more than 740 aircraft, only small numbers were actually ever built. The number of production aircraft depends on the sources: According to author Christ C. 37 were built, while D. Mondey and Nešić, D claim 48 being built.
Author John F.B. gives information that 2 prototypes, 16 Series-0 and 18 pre-production aircraft were built, in total 36. Author Gregory A. notes that, by September 1943, 32 Re.2005 were built. These include 2 prototypes, 29 Series-0 and a single Series-I aircraft. He also notes that an additional one was under construction but never finished.
Re.2005 Prototype – two prototypes (MM.494 and 495) built
Re.2005 Series-0 – 16 to 29 were built and used for testing and in combat.
Re.2005 Series-I – 1 to 18 built with some structural modifications.
Proposals and modifications
Re.2005 SF – Proposed version equipped with an extra jet engine, none built.
Re.2005 wooden version – Proposed version to be built using wood, only limited progress made.
Twin fuselage Re.2005 – Paper project only.
Re.2005 carrier version – Proposed version to be used on the Aquila aircraft carrier, no prototype was ever built.
Re.2004 – Experimental fighter project equipped with the Isotta Fraschini Zeta 1.250 hp engine, possibly only a mock-up built.
Re.2006 – Proposed fighter plane powered with Daimler Benz DB 603 and to be built using Re.2005 components, only one incomplete model built.
Operators Italian Regia Aeronautica – Operated less than 22 aircraft during the war. Aeronautica Nazionale Repubblicana – Operated two Re.2005. Germany – Rebuild 10 Re.2005 which were used by the Luftwaffe. Sweden – There were proposals to negotiate a deal with Sweden for license production. Nothing came from this.
Surviving Re.2005
One Re.2005 captured in Sicily was allegedly put on display in the American National Aircraft Show in November 1946. There is little to no evidence that proves that this ever happened. Today, only a part of a Re.2005 is the rear fuselage and tail of MM.092352362-2, restored by GAVS Milan. It can be seen at the Gianni Caproni Museum of Aeronautics near Milan.
Conclusion
While the Re.2005 had the potential to be a good fighter design, its development process was plagued by the lack of engines, problems with vibrations, and the indifference of the Italian Air Force officials. While it was used in combat, it was built in small numbers and too late to have any influence on the war.
Re.2005 Specifications
Wingspans
36 ft 1 in / 11 m
Length
28 ft 7 in / 8,7 m
Height
10 ft 4 in / 3.15 m
Wing Area
220 ft² / 20.4 m²
Engine
One Fiat R.A.1050 RC.58 12-cylinder 1475 hp engine
Empty Weight
5732 lbs / 2.600 kg
Maximum Takeoff Weight
7.960 lbs / 3.610 kg
Fuel Capacity
580 + 440 l
Climb to 8 km (19,700 ft)
7 minutes 50 seconds
Maximum Speed
390 mph / 630 km/h
Cruising speed
319 mph / 515 km/h
Range
776 mile / 1.250 km
Maximum Service Ceiling
39.370 ft / 12,000 m
Crew
1 pilot
Armament
Three 0.78 in (20 mm) cannons and two 0.5 in (12.7 mm) heavy machine guns
One 1,410 lb (630 kg) bomb, and two 252 lb (160 kg)
Gallery
Re. 2005, Illustration by Pavel Alexe
Source:
D. Nešić. (2008). Naoružanje Drugog Svetsko Rata-Italija. Beograd.
D. Mondey (2006). The Hamlyn Concise Guide To Axis Aircraft OF World War II, Bounty Books.
G. Punka, Reggiane Fighters In Action. Signal Publication.
J. W. Thomson (1963) Italian Civil And Military Aircraft 1930-1945, Aero Publisher
G. Alegi. (2001) Reggiane RE 2005, SATE Zingonia.
M. Di Terlizzi (2001) Reggiane RE 2005 Sagittario, IBN Editore
John F.B. (1972) Caproni Reggiane Re 2001 Falco II, Re 2002 Ariete and Re 2005
Sagittario, Profile Publications
N. Sgarlato (1979) Italian Aircraft OF World War II, Squadron Signal Publication.
C. Dunning (1998) Courage Alone The Italian Air Force 1940-1943, Hikoki Publication
Nazi Germany (1939)
Experimental jet-engine powered aircraft – 2 prototypes and 1 mockup
The He 178 has the honor to be the first aircraft that made it to the sky solely powered by a jet engine. It was mainly designed and built to test the new jet engine technology. Two would be built, of which the first prototype made its maiden flight in late October 1939, just weeks after the start of the Second World War.
Early German jet engine development
The leading German scientist in jet engine development was Hans Joachim Pabst von Ohain. He began working on jet engine designs during the thirties, and by 1935 managed to patent his first jet engine while working at the University of Göttingen. The following year, the director of this University, seeing the potential of the Hans Joachim jet engine, wrote a letter to Ernst Heinkel (the owner of the Heinkel aircraft manufacturer). Ernst Heikel was very interested in the development of jet-powered aircraft, seeing they had the potential of achieving great speed and range. After a meeting with Hans Joachim (17th March 1936), Ernst immediately employed him and his team (led by a colleague named Max Hahn) to work for his company.
In 1936, Hans Joachim and his team began building the first working prototype jet engine, using hydrogen gas as the main fuel, the HeS 1 (Heinkel-Strahltriebwerk 1). The HeS 1 was not intended as an operational engine, but for testing and demonstration purposes only. It was built and tested in early 1937, and was considered successful, so the research continued. The HeS 2 was the second test jet engine that initially used hydrogen gas fuel, but this would be changed to gasoline fuel. While this engine had some issues, it helped Hans Joachim and his team in gaining important experience in this new technology.
In September 1937, a series of modifications were made in order to improve its performance. By March 1938, the third HeS 3 jet engine was able to achieve 450 kg (1,000 lbs) of thrust during testing, much lower than the estimated 800 kg (1,760 lbs). Further modifications of the HeS 3 jet engine would lead to an increase of only 45 kg (100 lbs) of thrust.
Experimenting with the HeS 3 engine mounted on the He 118
In May (or July depending on the source) of 1939, testing of the improved HeS 3A engine began. At the same time, field testing done by attaching this engine to a piston-powered aircraft was being planned. For this reason, an He 118 was equipped with this auxiliary test jet engine. The He 118 was Heinkel’s attempt to build a dive bomber, but the Junkers Ju 87 was chosen instead. Having a longer undercarriage, the He 118 was able to mount the jet engine without any major problem. In order to keep the whole flight testing a secret, the tests were scheduled to start early in the morning.
The pilot chosen for this test flight was Erich Warsitz. When the He 118 reached the designated height using the piston engine, the pilot would then activate the auxiliary jet engine. During this flight, the He 118 powered by the HeS 3A jet engine managed to achieve 380 kg (840 lb) of thrust. More test flights were carried out with the modified He 118 until it was destroyed in a fire accident during landing. Despite this accident, the final version of the HeS 3B jet engine was intended to be mounted in the Heinkel designed He 178 aircraft. While this engine was far from perfect and did not manage to achieve the designer’s expected thrust, Ernst Heinkel urged its installation in the He 178 as soon as possible.
The He 178 history
Interestingly, the whole He 178 development began as a private venture. It was also under the veil of secrecy and the RLM (Reichsluftfahrtministerium), the German Aviation Ministry, was never informed of its beginning. Ernst Heinkel gathered the designers and technical directors to reveal to them ’…We want to build a special aircraft with a jet drive! The RLM is not to know anything about the 178. I take full responsibility!..’
Heinkel was possibly motivated by a desire to get an early advantage over the other German aircraft manufacturers. The main competitor was the Junkers Flugzeugwerke, which would also show interest and invest resources in developing this new technology.
While Hans Joachim was in charge of developing the proper jet engine, work on the He 178 airframe was led by the team of Hans Regner as main designer and Heinrich Hertel, Heinrich Helmbold, and Siegfried Günter as aircraft engineers. The first He 178 mockup was ready by the end of August 1938. Ernst Heinkel was, in general, satisfied with the design, but asked for some modifications of the cockpit and requested adding an emergency escape hatch door for the pilot on the starboard side. The following year, both the He 178 airframe and the HeS 3B jet engine were ready, so the completion of the first working prototype was possible.
Technical characteristics
The He 178 was designed as a shoulder wing, mixed construction, jet engine-powered aircraft. As it was to be built in a short period of time and to serve as an experimental aircraft, Ernst Heinkel insisted that its overall construction should be as simple as possible. It had a monocoque fuselage which was covered with duralumin alloy. The wings were built using wood and were sloping slightly upwards. The wing design was conventional and consisted of inboard trailing edge flaps and ailerons. The rear tail was also made of wood. The pilot cockpit was placed well forward of the wing’s leading edge.
The jet engine used initially was the HeS 3B, but this was later replaced with a stronger HeS 6 jet engine. The He 178 jet engine was supplied with air through a front nose Pitot-type intake, then through a curved shaped duct which occupied the lower part of the fuselage, leading directly to the engine. The exhaust gasses would then go through a long pipe all the way to the end of the fuselage. At the developing stage, there were proposals to use side intakes but, probably for simplicity’s sake, the nose-mounted intake was chosen instead. The He 178 fuel tank was placed behind the cockpit.
The He 178 was to be equipped with a retractable landing gear with two larger wheels in the front and a small one at the rear. All three landing gear legs retracted into the aircraft fuselage. For unknown reasons, this was not adopted early on and many test flights were carried out with landing gear in the down position. One possible explanation was that the Heinkel engineers may have left it on purpose. They probably wanted to have the landing gear down in order to be able to land quickly if the engine failed.
First test flights
The first He 178 V1 prototype was completed by June 1939, when it was transported to the Erprobungsstelle Rechlin (test center). Once there, it was presented to Adolf Hitler and Hermann Göring. Interestingly, prior to the flight testing He 178 V1, another Heinkel innovative rocket-powered aircraft, the He 176 was demonstrated. On 23rd June 1939, the He 178 pilot Erich Warsitz performed a few ground test runs. During this presentation, the He 178 was not taken to the sky, mostly due to the poor performance of the HeS 3A jet engine.
Following this presentation, He 178 V1 was transported back to the Heinkel factory in order to prepare it for its first operational test flight. The first He 178 test flight was achieved on 27th August 1939 at the Heinkel Marienehe Airfield near Rostock. At this stage, the pilot, Erich Warsitz, was instructed by the Heinkel engineers not to fly this aircraft at high speeds, mostly due to the fixed undercarriage. In addition, the HeS 3B could only provide enough thrust for only six minutes of effective flight. During this flight, there was a problem with the fuel pump but, despite this, the pilot managed to land with some difficulty but nevertheless successfully.
The flight is best described by the pilot’s own words. ‘…As the aircraft began to roll I was initially rather disappointed at the thrust, for she did not shoot forward as the 176 had done, but moved off slowly. By the 300-meter mark, she was moving very fast. The 176 was much more spectacular, more agile, faster, and more dangerous. The 178, on the other hand, was more like a utility aircraft and resembled a conventional aircraft …In this machine, I felt completely safe and had no worries that my fuel tanks would be dry within a minute. She was wonderfully easy to hold straight, and then she lifted off. Despite several attempts, I could not retract the undercarriage. It was not important, all that mattered was that she flew. The rudder and all flaps worked almost normally, the turbine howled. It was glorious to fly, the morning was windless, the sun low on the horizon. My airspeed indicator registered 600 km/h, and that was the maximum Schwärzler had warned me. Therefore, I throttled back, since I habitually accepted the advice of experienced aeronautical engineers. The tanks were not full and, contrary to custom, I did not want to gain altitude for a parachute jump should things go awry. It was supposed to be a short flight. At 300 to 400 meters altitude I banked cautiously left – rudder effect not quite normal, the machine hung to the left a little, but I held her easily with the control stick, she turned a little more and everything looked good.
After flying a wide circuit my orders were to land at once, this had been hammered into me, but now I felt the urge to go round again. I increased speed and thought, ‘Ach! I will!’ Below I could see the team waving at me. On the second circuit – I had been in the air six minutes – I told myself ‘Finish off!’ and began the landing. The turbine obeyed my movement of the throttle even though a fuel pump had failed, as I knew from my instruments and later during the visual checks. Because the airfield was so small for such flights I was a little worried about the landing because we did not know for certain the safe landing speed: we knew the right approach, gliding and landing speeds in theory, but not in practice, and they did not always coincide. I swept down on the heading for the runway. I was too far forward and did not have the fuel for another circuit. Now I would have to take my chances with the landing, losing altitude by side-slipping. I was flying an unfamiliar, new type of aircraft at high speed near the ground and I was not keen on side-slipping. It was certainly a little risky, but the alternative was overshooting into the River Warnow. Such an ending, soaking wet at four on a Sunday morning, appealed less. The onlookers were horror-struck at the maneuver. They were sure I was going to spread the aircraft over the airfield. But the well-built kite was very forgiving. I restored her to the correct attitude just before touching down, made a wonderful landing, and pulled up just short of the Warnow. The first jet flight in history had succeeded! …’’ Source: L. Warsitz (2008) The First Jet Pilot The Story of German Test Pilot Erich Warsitz.
An interesting fact is that pilot Erich Warsitz managed to be the first man that flew on both a rocket-powered (He 176) and a jet-powered (He 178) aircraft in history.
Heinkel’s attempt to gain the support of the Luftwaffe
During the following months, Hans Joachim tried to improve the HeS 3B jet engine, which would lead to the development of the HeS 6. This jet engine managed to achieve a thrust of 1,300 lb (590 kg), but due to the increase in weight, it did not increase the He 178’s overall flight performance.
As the He 178 was built as a private venture, Heinkel’s next step was to try obtaining state funding for further research from the RLM. For this reason, a flight presentation was held at Marienehe with many RLM high officials, like Generaloberst Ernst and General Erhard Milch. During the He 178 V1’s first attempt to take off, the pilot aborted the flight due to a problem with the fuel pumps. During his return to the starting point, a tire burst out. The pilot, Erich Warsitz, lied to the gathered RLM officials that this was the reason why he aborted the takeoff.
After a brief repair, Erich Warsitz managed to perform several high-speed circuits flights. During the presentation flight, Erich Warsitz estimated that he had reached a speed of 700 km/h (435 mph), which was incorrect, as later turned out… Interestingly, even at this stage, the He 178 was still not provided with the retractable landing gear. The RLM officials were not really impressed with the He 178’s performance, and for now, no official response came from them.
This was for a few reasons. The Luftwaffe had achieved great success during the war with Poland, which proved that the piston-powered engines were sufficient for the job. In addition, Hans Mauch, who was in charge of the RLM’s Technical Department, as opposed to the development of jet engines. He was against the development of jet engines by any ordinary aircraft manufacturer. Another problem was the He 178’s overall performance. During the test flights, the maximum speed achieved was only 595 km/h (370 mph). Hans Joachim calculated that the maximum possible speed with the HeS 6 was 700 km/h (435 mph). The speed was probably affected by the landing gear, which was still deployed and not retracted.
While the RLM did not show any interest in the He 178, Heinkel would continue experimenting with it. While the He 178 did perform many more flight tests, these were unfortunately not well documented. What is known is that, in 1941, the He 178 (with fully operational landing gear) managed to achieve a maximum speed of 700 km/h (435 mph) with the HeS 6 jet engine.
The He 178’s final fate
By this time, Heinkel was more interested in the development of the more advanced He 280. In addition, the use of the HeS 3B jet engine was completely rejected, being seen as underpowered. The interest in the development of the He 178 was lost and it was abandoned. The second prototype, which was similar in appearance, but somewhat larger in dimensions, was never fitted with an operational jet engine. It was possibly tested as a glider. There was also a third mockup prototype built that had a longer canopy.
The He 178 V1 was eventually given to the Berlin Aviation Museum to be put on display. There, it was lost in 1943 during an Allied bombing raid. The fate of the second prototype is unknown but it was probably scrapped during the war. While no He 178 prototypes survived the war, today we can see a full-size replica at the Rostock-Laage Airport in Germany.
Conclusion
Today, it is often mentioned that the He 178 was Germany’s lost chance to get an edge in jet-powered aircraft development. What many probably do not know is that the He 178 was not designed to be put into production, but to serve as a test aircraft for the new technology. We also must take into consideration that the jet engine technology was new and needed many years of research to be properly used. While Germany would, later on, operate a number of jet aircraft, they were plagued with many mechanical problems that could never be solved in time. Regardless, the He 178 was an important step in the future of aviation development, being the first aircraft solely powered by a jet engine
Heinkel He 178 (HeS 6 jet engine) Specifications
Wingspan
23 ft 7 in / 7.2 m
Length
24 ft 6 in / 7.5 m
Wing Area
98 ft² / 9.1 m²
Launch Weight
4.405 lbs / 2.000 kg
Engine
One HeS 6 jet engine with 590 kg (1,300 lb) of thrust
Maximum speed
435 mph / 700 km/h
Cruising speed (when towed)
360 mph / 580 km/h
Crew
Pilot
Armament
None
Gallery
Illustration’s by Ed Jackson
He-178 V1
He 178 V2
Sources
C.Chant (2007), Pocket Guide Aircraft Of The WWII, Grange Books
D. Nešić (2008), Naoružanje Drugog Svetskog Rata Nemačka Beograds
Jean-Denis G.G. Lepage (2009), Aircraft Of The Luftwaffe 1935-1945, McFarland & Company Inc
M. Griehl (2012) X-Planes German Luftwaffe Prototypes 1930-1945, Frontline Book
T. Buttler (2019) X-Planes 11 Jet Prototypes of World War II, Osprey Publishing
L. Warsitz (2008) The First Jet Pilot The Story of German Test Pilot Erich Warsitz Pen and Sword Aviation
By the middle of the Second World War, the Germans were losing control of the skies over the occupied territories. Even the Allied air attacks on Germany itself were increasing. In an attempt to stop these raids, the Blohm und Voss company presented the Luftwaffe with a new project which involved using cheap gliders in the role of fighters. While a small series would be tested nothing came from this project.
History
By 1943, the German Luftwaffe (air force) was stretched to limits in an attempt to stop the ever-increasing number of Allied air attacks. The Allied Bombing campaign particularly targeted German war industry. During this time, there were a number of proposals on how to effectively respond to this ever-increasing threat. Proposals like the use of a large number of relatively inexpensive fighter aircraft, that were to be launched from larger aircraft, were considered with great interest. One proposal went even further by suggesting the use of an inexpensively modified glider for this role. This idea came from Dr. Ing Richard Vogt who was the chief designer at Blohm und Voss.
In mid-August 1943, Dr. Ing Richard Vogt handed over the plans of a cheap and easy to build (without the use of strategic materials which were in short supply) glider that could be built by a non-qualified workforce to the German Ministry of Aviation (Reichsluftfahrtministerium – RLM). The pilots intended to fly this glider were to be trained in basic flying skills only. The initial name of this Gleitjäger (glider fighter) was P186 which would later be changed to Bv 40. After receiving the initial plans the RLM responded at the end of October 1943 with a request for six prototypes to be built. The number of prototypes would be increased to 12 December 1943 and again to 20 in February 1944. If the project was successful, a production order of some 200 per month was planned.
Design
The Bv 40 was designed as a partly armored and armed, mixed construction, fighter glider. Its 0.7 m (2ft 3 in) wide fuselage was mostly constructed using wooden materials, while the cockpit was provided with armored protection. The front armor of the cockpit was 20 mm (0.78 in) thick, the sides were 8 mm (0.31 in), and the bottom 5 mm (0.19 in) thick. Additionally, the cockpit received a 120 mm thick armored windshield.
The wings and the tail unit were also built mostly using wooden materials. The rear tail had a span of 1.75 m (5ft 9in). For towing operation, the Bv 40 was provided with a jettisonable trolley that was discarded once the Bv 40 was in the air. Once it was back to the airbase it was to land using a skid.
What is interesting is that in order to have as small a size as possible, the cockpit was designed so that the pilot had to be in a prone position. While a pilot prone positioned design offered advantages like being a smaller target and having an excellent view at the front, it also caused some issues like a bad rearview. While this design was tested in Germany (like the Akaflieg Berlin B9 for example), it was never implemented. Inside the cockpit, there were only basic instruments that were essential for the flight. In addition, due to the high altitude that it was supposed to operate, the pilot was to be provided with an oxygen supply system and a parachute. The side windows had sliding armored screens with integral visor slots that could offer extra protection.
The armament of this glider consisted of two 3 cm (1.18 in) MK 108 cannons. These were placed in the wing roots with one on each side. This was serious firepower which could cause a huge amount of damage to the target it hit. Due to its small size, the ammunition loadout was restricted to 35 rounds per cannon. The ammunition feed system was quite simple; it consisted of a rectangular ammunition feed hatch placed in the middle of each wing. Inside the wings, an ammunition conveyor chute was placed to guide the rounds directly to the cannons. There was also a secondary option which included the use of one cannon together with the ‘Gerät-Schlinge’ 30 kg (66 lb) towed guided bomb. This bomb was to be guided by the Bv 40 toward the enemy bombers and was then detonated at a safe distance. In practice, during testing, this proved to be almost impossible to achieve success.
Other weapon systems were also proposed. For example the use of R4M rockets placed under the wings. There was also a proposal to use the Bv 40 in the anti-shipping role by arming it with four BT 700 type torpedoes or even using 250 kg (550 lbs) time-fused bombs. Due to the extreme weight increase, this was never possible to achieve.
How should it be used?
In essence, the glider was to be towed by a Me-109G to a height of around 6 km before being released. Once released, it was to engage incoming enemy bombers with its two 3 cm (1.18 in) cannons. If circumstances allowed, a second attack run was to be launched. After the attack, the pilot simply guided the glider to the nearby airbase. It was hoped that the small size and armored cockpit would be the pilot’s best defense.
Testing of the Prototypes
Once the first prototype (marked PN+UA) was completed in early 1944, the first test flight made at Hamburg-Finkenwerder was unsuccessful as it was not able to take-off from the ground. A second more successful attempt was made on the 6th (or 20th depending on the source) May 1944 at Wenzendorf. Despite being intended to have an armored cockpit, the first prototype was tested without it. It appears also that during the maiden flight it was towed by another unusual Blohm und Voss design: the asymmetrical Bv 141. But according to most sources, the Me-110 was to be used, which seems more plausible. After the first flight, some modifications to the jettisonable undercarriage were made. On the 2nd June 1944, the first prototype was lost during a crash landing.
A few days later the second prototype (PN+UB) made its first test flight. During a dive, it managed to reach a speed of 600 km/h (370 mph). Its final fate is unknown but it was probably scrapped. The third prototype never took off from the ground as it was used for static structural tests. The fourth prototype (PN+DU) was lost during its first test flight but the precise date is unknown. The fifth prototype (PN+UE) made its first test flight on 6th July 1944, but its fate is also unknown. The last prototype (PN+UF) was tested with a new fin section and made its maiden flight on the 27th of July 1944.
During these test flights, the Bv 40 was able to achieve a flight speed of up to 650 km/h (404 mph). During dive testing, the following speeds at different altitudes were achieved: 850 km/h (528 mph) at 4,000 m (13,120 ft), 700 km/h (435 mph) and an astonishing 900 km/h (560 mph) at 5,000 (16,400 ft). Nevertheless, the results of the test flight appear to have been disappointing due to Bv 40’s poor overall flight performance.
Rejection of the Project
Once the project was properly revised by the RLM officials, the obvious shortcomings of the Bv 40 became apparent. The Bv 40 was simply deemed too helpless against the Allied fighter cover. In addition, when the report of the first few prototypes was studied, it became clear even to the RLM that the Bv 40 was simply a flawed concept and so it decided to cancel it in mid-August 1944. The next month the Allies bombers destroyed the remaining 14 Bv 40 which were in various states of production.
Not wanting to let their project fail, the Dr. Ing Richard Vogt and the Blohm und Voss designers proposed to mount either two Argus As 014 pulsejets or two HWK 109-509B rocket engines under its wings. Nothing came from this as the Me-328 and Me-163 proved to be more promising (these ironically also ended in failure). There was even a proposal to modify the BV 40 to be used as a Rammjäger (ram fighter) which was never implemented.
Production
Despite initial requests for the production of 200 such gliders only a small prototype series would be built by Blohm und Voss during 1944.
Bv V1 – Lost during its second test flight.
Bv V2 – Fate unknown.
Bv V3 – Used for static testing.
Bv V4 – Lost during it’s first flight.
Bv V5 – Flight tested but final fate unknown.
Bv V6 – Tested with modified fin section.
Bv V7-V20 – Lost during one of many Allied bombing raids on Germany.
Operators
Germany – While testing was conducted on a small prototype series no production order was given.
Conclusion
The Bv 40 on paper had a number of positive characteristics; it was easy to make, could be available in large numbers, was cheap, well-armed and it did not need skilled pilots. But in reality, the poor performance, lack of a power plant, low ammunition count, and its vulnerability to Allied escort fighters showed that this was a flawed concept. This was obvious even to RLM officials who put a stop to this project during 1944.
Gallery
Illustration by Ed Jackson
Blohm und Voss Bv 40
Blohm und Voss Bv 40 Specifications
Wingspan
25 ft 11 in / 7.9 m
Length
18 ft 8 in / 5.7 m
Height
5 ft 4 in / 1.63 m
Wing Area
93.64 ft² / 8.7 m²
Empty Weight
1.844 lbs / 830 kg
Launch Weight
2.097 lbs / 950 kg
Climb rate to 7 km
In 12 minutes
Maximum diving speed
560 mph / 900 km/h
Cruising speed (when towed)
344 mph / 550 km/h
Maximum Service Ceiling
23,000 ft / 7,000 m
Crew
Pilot
Armament
Two 3 cm (1.18 in) MK 108 cannons
Or one 3 cm (1.18 in) MK 108 cannon and a glider bomb
Sources
J. Miranda and P. Mercado (2004) Secret Wonder Weapons of the Third Reich: German Missiles 1934-1945, Schiffer Publishing.
R. Ford (2000) Germany Secret Weapons in World War II, MBI Publishing Company.
Jean-Denis G.G. Lepage Aircraft Of The Luftwaffe 1935-1945, McFarland and Company.
M. Griehl (2012) X-Planes German Luftwaffe Prototypes 1930-1945, Frontline Book.
D. Herwig and H. Rode (2002) Luftwaffe Secret Projects, Ground Attack and Special Purpose Aircraft, Midland.
Nazi Germany (1938)
Transport plane – 13 built with 4 uncompleted aircraft
The Blohm und Voss Bv 222 was the largest World War Two flying boat that ever reached operational service. Even though it started as a civilian project, due to wartime demand, it was quickly put into service with the Luftwaffe during the Second World War.
The History of Blohm & Voss
The Blohm & Voss Schiffswerft und Maschinenfabrik (shipbuilding and engineering works) company was founded in 1877 by Hermann Blohm and Ernst Voss. After World War I, Blohm & Voss continued production of ships, but also reoriented to the production of aircraft (especially flying boats). In the following years, the company managed to cooperate with Lufthansa (the German Passenger Airline) and later even with the Luftwaffe.
Early on in the development and production of their first aircraft, they received the ‘Ha’ designation (standing for Hamburger Flugzeugbau, the factory’s station at Hamburg). This would be later replaced by ‘Bv’ (also sometimes marked as ‘BV’), which represented the owner’s initials. Blohm & Voss would build a number of flying boat designs like the Ha 138, Ha 139, Bv 222 and BV 238. During the war, the company was also engaged in developing a number of glide bombs like the Bv 143 and Bv 246 Hagelkorn.
The Lufthansa Request
In 1937, Lufthansa opened a tender for long-range passenger transport flying boats. The requirements for this tender included that the aircraft had to be able to travel from Berlin to New York in 20 hours. A few well known German aircraft manufacturers responded to this tender, including Heinkel, Blohm & Voss and Dornier. Whilst both Heinkel and Dornier had enough experience in designing seaplanes, Blohm & Voss was relatively new to this. One of the first Blohm & Voss seaplane designs was the Ha 139. While only a few were built, the company gained valuable experience in building such aircraft. The man responsible for designing the flying boat was Dr. Ing. Richard Vogt (chief designer at the Blohm & Voss) and his assistant R. Schubert.
All three aircraft manufacturers presented their models. Heinkel submitted the He 120 (renamed later to He 220), Dornier came up with the Do 20 and Blohm & Voss proposed the Ha 222 (later renamed to Bv 222). The Lufthansa officials, after detailed considerations, decided that the best aircraft was the Bv 222. An official contract between Lufthansa and Blohm & Voss was signed on 19th August 1937 for three aircraft to be built.
By the end of 1937, the Lufthansa officials requested improvements to the Bv 222. One of these regarded the number of passengers. It now had to accommodate at least 24 passengers on shorter trips and 16 during long voyages across the Atlantic.
Change into a Military Project
The design work on the new aircraft began in January of 1938 and lasted almost a year. This was mainly due to the huge task and the inexperience of Blohm & Voss in designing such large aircraft. Nevertheless, the construction of the first Bv 222 V1 prototype began in September 1938, followed a few weeks later by the V2 and V3 prototypes. Work on the Bv 222 was slow and it dragged on into 1939 and 1940. By this time, due to the outbreak of war, a shortage of skilled labour and the decision to concentrate on the Bv 138, the Bv 222 had low priority.
In July 1940, Blohm & Voss presented a mockup of the Bv 222 exterior and interior to Lufthansa officials. They were generally satisfied but demanded some changes. In early August, despite receiving Lufthansa approval, the Bv 222 project was actually slowly being taken over by the Luftwaffe for its own use.
By the end of August 1940, the Bv 222 V1 prototype was completed, and many taxi and loading tests were carried out. The first test flight was piloted by Captain Helmut Wasa Rodig on 7th September 1940. While the general flight performance was deemed satisfactory, there were some issues, such as instability during horizontal flights and staggering from one side to another when floating on water. While still under development and testing for civilian use, the Bv 222 V1 received the registration D-ANTE.
Technical Characteristics
The Bv 222 was designed as a six-engined, high wing, flying transport plane. Unfortunately, the sources do not provide us with more precise information about its construction. This is mostly due to the small number of aircraft built.
While the sources do not mention if it was built using only metal or mixed construction, the Bv 222’s fuselage was covered with 3-5 mm thick anticorrosive metal framework. Its large size made it possible to build two floors. The upper floor was designed for the crew of the plane. The lower floor was initially designed to accommodate civilian seats, but as the Bv 222 was put into military service, this area was used to store equipment or soldiers. A large door was provided to access the lower floor.
The wings were constructed using a huge tubular main spar. These were used to provide additional room for spare fuel and oil tanks. The fuel was stored in six fuel tanks with a total capacity of 3,450 litres. Four outboard stabilising floats (two on each side) were carried on the wings. These would split into two halves and retract into the wing. The purpose of these stabilising floats was to stabilise the plane during landings on water.
The crew number varied between each aircraft. It usually consisted of two pilots, two mechanics, a radio operator and, depending on the number of guns installed, additional machine gun operators.
The Bv 222 was initially powered by six Bramo 323 Fafnir 1000 hp strong radial engines. Other engines, for example Jumo 207C, were used later during the production run.
The defensive armament varied between each plane and usually consisted of several different machine guns or cannons. The following different types of weapons are known to have been used: 7.92 mm (0.31 in) MG 81, 13 mm (0.51 in) MG 131 and 20 mm (0.78 in) MG 151.
The Bv 222 (V4, V5, V6 and V8) were equipped with the most advanced electronic equipment that the Germans had, such as the FuG 200 surface search radar, FuG 101 A radio altimeter, FuG 25 A friend or foe identification system and the FuG 16 command guided target approach system. The radio equipment used on these four were the Lorenz VP 257 and the Lorenz VP 245 transoceanic relay sets.
First Military Transport Flight Operations
By the end of 1940, Bv 222 V1 was mostly used for testing and correcting any issues. By December of 1940, due to the winter and bad weather, further tests were not possible. As Bv 222 V1 was fully operational and enough fuel was stored, it was deemed a waste of resources to simply wait for the arrival of spring. For this reason, Luftwaffe officials proposed for the Bv 222 V1 to be used in a military transport operation between Hamburg and Kirkenes (Norway). For this operation, the Bv 222 V1 was modified by adding a large side hatch door. During this operation, Bv 222 V1 received a military camouflage paint scheme and received the registration number CC+EQ. By mid August 1941, the Bv 222 V1 achieved a total of 120 hours flight, with some 65 tonnes of cargo and 221 wounded soldiers transported. This mission was a success and the Bv 222 V1 proved to be an effective transport plane.
After a period of needed general overhaul and repair, Bv 222 V1 was set for a new transport mission, this time to support the DAK-Deutsches Afrikakorps (German Africa Corps). The main bases of operation were from Athens to Derna in Africa. The mission was carried out from 16th October to 6th November 1941. In total, seventeen flights were carried out, with 30 tonnes of supplies and 515 wounded soldiers and personnel transported. As Bv 222 V1, at this time, was not equipped with any defensive armament, two Me 110s were provided for its escort. While it was a prototype plane, no defensive armament was installed. But, after several encounters with the British Air Force in the Mediterranean, the need for defensive armament became apparent. At this stage, the Bv 222 was lucky, as it managed to emerge from these engagements in one piece. It even managed to survive the attack of three British Beaufighters on a flight from Taranto to Tripoli.
During these transport flights, the improved Bramo 323 engines (which replaced the earlier BMW 132) achieved a solid but satisfactory overall flight performance. But the Bramo 323 engines were deemed prone to malfunctions.
Future Service within the Luftwaffe
During the winter of 1941/1942, Bv 222 V1 was again returned to Blohm & Voss for more repairs but also for fitting its first defensive armament. The armament consisted of several 7.92 mm (0.31 in) and 13 mm (0.51 in ) machine guns. Note that the information about armament in this article is taken from H. J. Nowarra’s book “Blohm and Voss Bv 222”, but other authors state that different armament was used. One MG 81 was placed in the nose, four more MG 81s were placed in the fuselage and two additional DL 131 turrets with MG 131s were placed in the upper fuselage. At the same time, Bv 222 V1 received a new registration code, X4+AH. It was attached to Luft-Transport-Staffel 222 (short LTS 222) which mainly operated in the Mediterranean. The LTS 222 official squadron marking was a Viking longship and it is probably for this reason that the Bv 222 were nicknamed ‘Wikings’.
During 1942, LTS 222 was reinforced with four newly built Bv 222s of the A-series. V4 (reg. num. X4+DH) was received in mid April, V5 (reg. num. X4+EH) on 7th July, V6 (reg. num. X4+FH) on 21st August and V8 (reg. num. X4+HH) in late September. These four were provided with defensive armament consisting of two DL 151 turrets, each armed with an MG 151 in the upper fuselage, one MG 131 in the nose position and two MG 81 on the fuselage sides.
After many extensive and dangerous transport missions, Bv 222 V1 finally ran out of luck, and was lost in a tragic accident in early 1943. While on a flight to Athens, due to Allied air raids, the pilot tried to land on water. Because of the total darkness, the pilot was unable to see a half sunken wreckage, which damaged the plane so much that it sank in only a few minutes. Luckily, the crew was safely evacuated.
Bv 222 V2 made its first test flight on the 7th August 1941. It was initially used by the Erprobungsstelle Travemünde for testing and improvements. It had its bottom fuselage redesigned to provide better stability when floating in water. In addition, two reserve thrust propellers were attached to each middle engine on both sides, which improved flight performance. It was not used by LTS 222 but was instead given to the Fliegerführer Atlantik unit. As this unit name suggests, Bv 222 V2 (which later included other Bv 222s) was used to patrol the Atlantic. Its main base of operations was the city of Biscarrosse in occupied France. Bv 222 V2 would remain in use up to the war’s end, when it was captured by the Allied forces in May 1945.
The Bv 222 V3 prototype had a much shorter operational service life. It made its first test flight on the 28th November 1941. It was lost on the 30th June 1943 while on a patrol mission across the Atlantic.
Bv 222 V4 was initially used in a transport mission above the Mediterranean. On 10th December 1942, it was damaged by Allied raids. After the necessary repairs, it would be used for the remainder of the war on patrol missions across the Atlantic. In October 1943, it, together with Bv 222 V2, managed to shoot down a British Avro Lancaster bomber over the ocean. The circumstances of this event are not clear even to this day. Bv 222 V4 was sunk by its crew in May 1945 at Kiel.
V5 was used for transport of materiel and men above the Mediterranean, until the loss of Bv 222 V1. After that, it was recalled to Germany to be structurally strengthened and equipped with stronger defensive armament. From April 1943, it was used in Atlantic patrol missions, until it was shot down by the Allies in June the same year.
V6 was shot down by the British shortly after it was attached to LTS 222. Bv 222 V8 also had a short operational life, as it was lost in action to Allied fighters on 10th December 1942.
It is interesting to point out that, during the Bv 222’s service in the Mediterranean, the British would attack these aircraft only when they were transporting ammunition and supplies to Africa, but they would not attack them on their way back to Europe as they would be transporting wounded soldiers.
After construction of the first three prototypes, the next four aircraft were reclassified as the A-series (V4, V5, V6 and V8). Interestingly, these would also retain their prototype ‘V’ designation, which can lead to some confusion.
Future Improvements and Modifications
Even as the first series of Bv 222 were under construction, there was a proposal for a new improved civilian version named Bv 222 B, which was to be powered by Jumo 208 engines. Due to the war, this was never implemented and remained a paper project.
As the first series of Bv 222 had some issues with the engines, there were attempts to equip them with better models. For this reason, Bv 222 V7 (reg. TB+QL ) was instead powered by Jumo 207 C 680 hp diesel engines. The idea behind using diesel engines was that the Bv 222 could be refueled at sea by using U-boats. The Jumo 207C engines also proved to have some issues, but it was nevertheless decided to use the Bv 222 V7 as the basis for the C-series. Bv 222 V7 was flight tested in April 1943, and it would remain in service up to the war’s end, when it was destroyed by its crew to avoid capture by Allied forces in May 1945.
Due to the bad wartime situation for the Germans and the lack of materials, only a limited number of C-series aircraft were ever built. Of the nine that were under construction, only about five (beside V7) were ever completed. Two of the C-series aircraft were to be used for a new D-series powered by the Jumo 207 D engines. Due to problems with this engine, production was never implemented.
The first aircraft of the C-series (Bv 222 C-9) was allocated to Fliegerführer Atlantik on the west in late July 1943. After the Allied landings in France, the Germans lost their air bases in this area. For this reason, the long-range patrol missions were carried out from occupied Norway. C-9 was lost in early 1945 (or 1944, depending on the source), when it was shot down by a British Hawker Typhoon. C-10 was lost in a crash in February 1944. C-11 was fully equipped but was never used operationally for unknown reasons. C-12 was tested with rocket assisted engines to help during takeoff. The use of the C-13 aircraft is unfortunately unclear. While the C-14 to C-17 were under construction, they were never completed due to a lack of resources.
While the Bv 222 was primarily designed as a flying boat, there were plans to modify it to be used as a standard transport plane. This was to be achieved by adding landing gear wheels to it. The projects received the P.187 designation. Possibly due to a low priority, this project was under development up to the war’s end and was never implemented.
Flight to Japan
During the war, the Germans had plans to establish a flight line connection with Japan. Original flight plans stated that the starting point for the Germans was Kirkenes and then to Tokyo via the Sakhalin Island. The Bv 222 was in the competition for this mission, but was rejected due to the small number built and because it was not designed for this role. Other aircraft considered were the Ju 290 and the He 177. The aircraft ultimately chosen was the Ju 290, but this planned flight was never attempted and the whole project was dropped.
Arctic Rescue Mission
During the war, the Germans managed to set up a secret meteorological station in the Arctic. In the spring of 1944, the crew of this station were sick because they had eaten raw meat. A supply mission was conducted using a Fw 200 for transporting a doctor to this base. The pilot tried to land but, during the landing, one wheel of the landing gear broke down. The base sent back a distress call for further aid. For this mission, one of the Bv 222s was chosen and was loaded with a spare wheel and spare parts. Once it was above the base, the parts were successfully dropped by a parachute. The station crew were eventually rescued once the Fw 200 was repaired.
In Allied Hands
By the end of the war, the Americans managed to capture two Bv 222 aircraft, C-11 and C-13. C-11 would be flown to America and was used for evaluation. While it would eventually be scrapped, it gave the Americans valuable information about designing and building such huge flying bots. C-13 was also flown to America, where it would later be scrapped.
The British also managed to capture Bv 222 C-12 in Norway. During the flight to the UK, one of the engines stopped working, but the pilot managed to reach the UK. The British also captured the Bv 222 V2 prototype which was also relocated to the UK. These would serve the British in gaining valuable information about the aircraft’s construction.
Production
The only producer of these aircraft was Blohm & Voss at Hamburg. Due to many factors, such as long development and testing time, the substantial resources needed to build them and the pressing need for fighter aircraft, there was only a limited production run. In total, only 13 Bv 222 were ever made. These included three prototypes, four of the A-series and six C-series aircraft. While there were a few more under construction, these were never completed.
Versions
Bv 222 V1-V3 – Several prototypes built with different armament and engines tested
Bv 222 A – Four aircraft built
Bv 222 B – Proposed improved civilian version
Bv 222 C – Version powered by the Jumo 207 engine, few built
Bv 222 D – Proposed improved C-series to be powered by Jumo 207 D engine, none built
P.187 – Proposed land-based version, none built
Operators
Lufthansa – Although the original purchaser of this aircraft, only V1 saw limited evaluation and testing service in Lufthansa service
Nazi Germany – Operated a small number of these aircraft
USA – Captured two aircraft of the C-series which were used for testing
UK – Captured two aircraft.
Surviving aircraft
Unfortunately, due to wartime attrition and sabotage by their own crews, not a single BV 222 is known to have survived to this day. There are possibly several wrecks underwater, like the one in Greece, that could maybe one day be salvaged or even restored.
Conclusion
The Bv 222 was the largest operational aircraft built during the war. While it was never used in its original role, it would see extensive service with the Luftwaffe, despite being available only in small numbers. Due to its large transport capabilities, it was vital to the Germans, as they lacked transport planes throughout the war. But, due to the bad military situation in the second half of the war and the need for a large number of fighter planes, the Bv 222 would only be built in limited numbers.
Nazi Germany (1938)
Multi-role Fighter – 12 ~ 18 Built
The Ar 240 was designed as a possible replacement of the Me 110. While initially it seemed to have great potential, problems with handling and mechanical breakdowns proved to be too much for this aircraft. As it would not be accepted for service, only a small number were actually built. While a few were used by the Luftwaffe, their operational usage was limited.
History of Arado
Werft Warnemünde, later known as Arado, was an aircraft manufacturer that was founded during the Great War, in 1917, as a subsidiary of Flugzeugbau Friedrichshafen. In 1921, this company was purchased by an engineer, Heinrich Lübbe, who was more interested in designing and building ships. In 1924, it was once again engaged in development of aircraft designs, mainly intended for foreign markets. For the position of chief designer, Walter Rethel, who previously had worked for Fokker was chosen.
Werft Warnemünde would be renamed in 1925 to Arado Handelsgesellschaft and renamed again in March 1933 to Arado Flugzeugwerke GmbH. At this time, Walter Blume was appointed as the new chief designer. During his supervision, several projects that were later used by the Luftwaffe were built, including the Ar 66 trainer and the Ar 65 and Ar 68 fighter aircraft.
At the start of the Second World War, Arado was mostly engaged in licenced aircraft production for the Luftwaffe. But work on its own aircraft designs was not discarded. The most important of these upcoming designs were the Ar 96 trainer, Ar 196 reconnaissance plane and the Ar 234, which would become the first operational jet bomber in the world. While these proved a huge contribution to the German war efforts, the Ar 240 design proved to be a failure.
Development of the Ar 240
During 1938, the German Ministry of Aviation (Reichsluftfahrtministerium, RLM) was interested in the development of a new multi-purpose twin engine aircraft that would replace the Me 110. Besides Messerschmitt, which began development of the Me-210, the Arado company would also be involved. In early April 1939 or 1938, depending on the source, the Arado company received a contract for the construction of three prototypes of the new multi-purpose plane initially called E-240. The development of this new aircraft was carried out by an Arado team of designers and engineers led by Walther Blume and by Dipl.-Ing. Wilhelm van Nes.
Interestly, possibly for reasons such as good connections with the Nazi Party or Arado’s good reputation as an aircraft manufacturer, even before the completion of the first prototype, an order for 10 additional prototypes was given by the RLM. While these would be built, a number of problems were identified which would prove to be the downfall of the aircraft.
Technical Characteristics
The Arado 240 was designed as a two seater, twin-engined, mid wing monoplane. The fuselage had a monocoque design and stressed-skin. The fuselage was oval-shaped, with the rear part being more round shaped. The rear tail of the Ar 240 consisted of two fins and rudders, but also had dive brakes installed.
The central parts of the wings were rectangular, while the outer part was trapezoidal in shape. The wings were constructed using a two-part spar structure. The Ar 240 used Fowler type flaps, which covered the entire trailing edge. What is interesting is that the Ar 240 flaps were integrated with the ailerons and that this configuration was previously tested on the Ar 198. Another innovation was the use of automatic leading edge slats, but this system was used only on the first few prototypes and abandoned later on. The wings also housed four fuel tanks on each side, which had a total fuel load of 2,300 liters (600 US gallons). The fuel tanks were built using a new self-sealing system that used thinner tank liners, which enabled the aircraft to have a much increased fuel load.
The cockpit was initially positioned directly over the place where the wing root. After the third prototype, the cockpit was moved forward. The cockpit used a back to back seat configuration, with the pilot positioned on the front seat and the radio operator, who was also acting as the rear gunner, being positioned in the rear seat. The Ar 240 cockpit was completely pressurized. The cockpit was directly connected to the fuselage, but was provided with a jettisonable canopy in case of emergency. The well designed glazed canopy provided the pilot and crewman with an excellent all-around view.
The Ar 240 used a conventional retractable landing gear which consisted of two front wheels and one smaller tail wheel. The two front wheels retracted outward into the engine nacelles, while the third wheel retracted into the rear tail fuselage section.
The Ar 240 was tested with a number of different engine types, as the designer had problems in finding an adequate one. The prototype series was powered by Daimler Benz DB 601A and DB 603 A. The later built A series would also be tested with a number of different engines, including the DB 601 A-1 and DB 603, BMW 801 TJ etc..
Different armaments were proposed for the AR 240, including a pair of remotely controlled defence turrets. The control of these turrets was hydraulic and they were equipped with periscope aiming sights. The bomb load would consist of around 1 to 1.8 tons, placed under the fuselage.
Development and Usage of the Ar 240 Prototype Series
Note: Due to differing information depending on the author, the following information was mostly taken from G. Lang. (1996), Arado Ar 240, A Schiffer Military History Book.
The first operational Ar 240 V1 prototype (markings DD+QL), powered by two 1,157 hp DB 601 engines, was completed in early 1940 and was flight tested on the 10th of May the same year. The next flight tests were made on 25th June and 17th July 1940. In May 1941, the engines were replaced with two DB 603 E. More tests were carried out until October 1941, when the prototype was removed from service for unknown reasons. According to M. Griehl, it was destroyed on the 18th April 1941. The test results of the Ar 240 V1 showed that this aircraft had huge problems with the controls and was difficult to fly, a trend which will be inherited on all Ar 240 planes.
The second prototype, V2, is somewhat shrouded in mystery, as the date of its first operational test flight is unknown. A possible date for the first test flight is 15th September 1940. While it is not clear, the V2 prototype probably received the DD+CE markings. Arado test pilots made several flight trials during September 1940. By the end of February 1941, the Ar 240 V2 prototype was relocated to Rechlin for future tests. By May 1941, the V2 prototype received new DB 603 engines. At the same time, it was also fitted with two 7.92 mm (0.311 in) MG 17 and two 20 mm (0.78 in) MG 151/20 cannons. In November 1941, this plane was modified to be used in dive bombing trials. An additional change was the installation of two DB 601 E engines. The final fate of the V2 prototype is not known precisely, but it was probably scrapped.
The Ar 240 V3 (KK+CD) prototype was first flight tested on 9th May 1941. In comparison to the earlier two prototypes, this model had the cockpit moved forward. The rear tail-positioned dive brakes were replaced with a cone and ventral fins. Numerous engines were tested on this aircraft, including two Jumo 203 and DB 601 E. In early 1942, a number of pressure cabin tests were conducted on the V3 prototype. This aircraft also served as a test bed for the new FA-9 remote controlled system developed in cooperation between Arado and the DVL (aviation research institute), but proved to be problematic. V3 would be used operationally as a reconnaissance aircraft over England. It was piloted by Oberst Siegfried Knemeyer, and while his plane was unarmed, thanks to its high speed, he managed to avoid any confrontation with British planes. The fate of this aircraft is not known, as (depending on the sources) it could have been lost in either April 1944 or May 1942.
The V4 prototype was to be tested as a dive-bomber variant. The first test flight was made on 19th June 1941. It was powered by two 1,750 hp DB 603 A engines. It was modified with added dive brakes and was capable of carrying up to eight 50 kg (110 lb) bombs under the fuselage. Its fuselage was also elongated to 13.05 m (42 ft 9 ¾ inches). Many detailed tests with the V4 were carried out in France and in the Mediterranean. The V4 prototype was lost in August 1941 in an air accident.
The V5 (GL+QA or T5+MH) prototype made its maiden flight test in September 1941. What is interesting is that it was not built by Arado but by AGO Flugzeugwerken from Oschersleben. It was powered by two 1,175 hp DB 601 E engines and was provided with a tail cone. It was armed with two wing root MG 17 machine guns and two same caliber MG 81 machine guns placed into two (one above and under the fuselage) FA-13 type remotely controlled turrets. In late March 1942, this aircraft was given to the Aufklärungsgruppe Oberbefehlshaber der Luftwaffe (reconnaissance unit/group belonging to the Commander in Chief of the Luftwaffe). It was then, possibly in late 1942, allocated to Versuchsstelle für Höhenflüge VfH (research station for high-altitude flight).
The V6 (GL+QA or T5+KH) prototype was also built by AGO, and while most parts were ready during November 1941, the aircraft was only completed in early 1942. It was flight tested in January 1942, but if this was its first test flight is not clear. It was given to the Luftwaffe in early March 1942 and moved to Oranienburg for future tests. It was similar in appearance and equipment with the previous V5 aircraft. While it was used mostly for testing, it saw front line service during the winter of 1942/43 around the Kharkov area. The plane is listed as destroyed but under which circumstances is not known.
The V7 (DM+ZU) prototype made its first test flight in October or December 1942. It was designed to be used as the basis for the Ar 240 B high-altitude reconnaissance aircraft. It was to be provided with a pressurized cockpit and a heating system. V7 was powered by two 1,475 hp DB 605 A engines, which were specially designed to use a methanol-water injection in order to increase the engine overall performance and output. Armament consisted of two wing mounted MG 17s and a rear mounted remotely-controlled turret armed with the MG 151/20, and two 50 kg (110 lb) bombs. Operational range was 1,900 km (1,180 mi) and it a was capable of climbing to 6 km (19,685 ft) in 10 minutes and 6 seconds.
The V8 prototype was a direct copy of the V7 and possibly made its first test flight in December 1942 or March 1943 depending on the sources. The final fate of this and the previous aircraft is not known.
The V9 (BO+RC) prototype was designed as a Zerstörer (heavy fighter) aircraft. It was to be used as a test base for the planned Ar 240 C version. The V9 had redesigned longer wings and fuselage. It was powered by two DB 603 A engines which were also equipped with a methanol-water injection system. The main armament consisted of four forward and two rear MG 151/20. While this version had a great priority and was even considered for acceptance for production. This was never achieved, mostly due to a lack of necessary equipment and parts. The final fate of this aircraft is not clear, as it was possibly never even fully completed, but some sources also mention that it was lost in a landing accident.
The V10 prototype was designed as a night fighter aircraft, powered by two Jumo 213 engines. The first test flight was made in September of 1943, while more tests would be carried out up to late 1944. Arado reused this aircraft for the new improved version called Ar 440.
The V11 prototype was tested as a heavy fighter-bomber and was to be used as the base of the Ar 240 F aircraft. Due to many delays, it was actually never fully completed. It had the heaviest armament, which included a mix of MG 151 and 30 mm (1.18 inch) MK 103 cannons forward mounted, rear mounted MG 151 and 13 mm (0.5 inch) MG 131 and a bomb load of 1,800 kg (3,970 lbs). V12 was a direct copy of V11 and, as these two aircraft were never completed, both were scrapped. V13 was to be used as a test base of the Ar 240 D equipped with two 2,020 hp DB 614 engines, but none were built.
V14 was probably never fully constructed. It was to be used as a base for the Ar 240 E project and powered by two DB 627 engines. V15 was to be used in a reconnaissance role and equipped with the FuG 202 Lichtenstein radar. The V15 prototype was probably never built.
There are two more Ar 240 aircraft only known by their serial numbers (240009 and 2400010). While the usage and fate of the first aircraft is generally unknown, the second was used by the Luftwaffe operationally in the Soviet Union during 1943. It was damaged during a landing in August the same year. Its final fate is unknown.
Development of the ‘A’ Version
After a series of prototypes were built, work on the first Ar 240 A version was also undertaken by Arado. Initially, the Ar 240 A aircraft were to be powered by two 1.750 hp DB 603 A-1 engines equipped with four blade metal propellers. Armament chosen for this version consisted of two MG 151/20 (with 300 rounds of ammunition for each gun) placed in the fuselage floor and two more MG 151/20 (with same ammunition load) placed in the wings roots. There was an option for increasing the fire power by adding two more MG 151/20. For rear defence, two defense turrets equipped with MG 131 machine guns could be placed under and above the fuselage. The bomb load could have different configurations, like: One 1,000 kg (2,220 lbs) or 1,800 kg (3,930 lbs) bomb, two 500 kg (1,100 lbs) bombs, eight 50 kg (110 lbs) bombs or even 288 smaller 2.5 kg (5 lbs) incendiary and fragmentation bombs. As the Ar 240 was never accepted for service, only few of the A version aircraft were ever built.
Ar 240 A-01 (GL+QA possible marking) made its first test flight on 28th June 1942. The test flights were carried out until September 1942, when this aircraft was to be given to the Luftwaffe. After a series of further flight and weapon tests conducted at Rechlin and Tarnewitz, the Ar 240 A-01 was to be allocated to the front. It was used around Kharkov in late 1942. On 16th February 1943, Ar 240 A-01 was lost during a flight due to mechanical failure. Both crew members lost their lives during the fall.
The second Ar 240, A-02 (GL+QB), was completed by September 1942. On 13th September, the first test flight was made. The aircraft was damaged in a landing accident in late January 1943. The final fate of this aircraft is not known.
Ar 240 A-03 (DI+CY) was initially powered by two DB 601 engines, but these were replaced with BMW 801 TJ. This aircraft had a change in the cockpit configuration, with the radio operator/observer facing forward. This aircraft was stationed at Rechlin, where it was tested from May to June 1943. During testing, Ar 240 A-03 showed to have better stability and handling during flight in contrast to previous built aircrafts. From June to late July, it was tested at Brandenburg. After these tests were completed, the aircraft was allocated for operational front use. It was given to the Aufklärungsgruppe 122, a reconnaissance unit stationed in Italy at that time. This aircraft had the same fate as most previous Ar 240, as it was heavily damaged in a crash. As the damage was extensive, it was never repaired.
Ar 240 A-04 (DI+CG) was initially equipped with two DB 601 E engines, but these would be later replaced with DB 603. It made its first flight test in late September 1942. Ar 240 A-04 was allocated to the Aufklärungsgruppe 122 as a replacement for the previous aircraft. Ironically, it suffered the same fate, but it was repaired and sent back to Arado.
Ar 240 A-05 was powered by two 1880 hp BMW 801 TJ engines equipped with a Rateau type turbo supercharger. It was possibly allocated to Aufklärungsgruppe 10 stationed in the Soviet Union.
Proposed Versions
During the Ar 240’s development, the Arado officials proposed several different variants of this aircraft, but as the whole project was not going well beside a few experimental attempts, nothing came from most of them.
Ar 240 B
This was a high-altitude reconnaissance aircraft version that was to be equipped with a pressurized cockpit and a heating system. Nothing came from this project.
Ar 240 C
On 10th March 1942, Arado officials proposed that the Ar 240 should be modified for the bomber role. For this reason, the wings were modified and its size increased. The tail design was also changed, with added tail dive brakes. As the attempt to increase the size of the internal fuel tanks proved a failure, external tanks were to be used instead. The armament consisted of two MG 151/20 and two rear mounted MG 81. It is not clear, but it is possible that at least one aircraft was built.
Ar 240 D
A proposed paper project version powered by two DB 614 engines.
Ar 240 E
A proposed version with reinforced fuselage, added bomb rack for two 500 kg (1,100 lbs) bombs and increased fuel load. Different engines were also proposed for this version, including DB 603 G, DB 627 or BMW 801 J.
Ar 240 F
A proposed heavy fighter/bomber version to be powered by two DB 603 G engines.
Ar 240 mit 7.5 cm Bordwaffen
During the war, Arado and Rheinmetall discussed the installation of a 7.5 cm gun in the Ar 240. In September 1944, it appears that one plane was actually equipped with this weapon, but was probably never operationally flight tested.
Ar 240 TL
In 1942, Dr. Ing. Walther Blume proposed a heavy fighter and night-fighter version of the Ar 240. This version was designated as Ar 240 TL, which stands for Turbinen-Luftstrahltriebwerk (turbojet). This plane was to be powered by two jet engines placed in the fuselage. It remained only a paper project.
Ar 440
With the cancellation of the Ar 240 project, Arado tried to improve the Ar 240’s overall performance by building a new version, named Ar 440. The Ar 240 V10 prototype served as a base for this modification. Beside this prototype, three more were built using already existing Ar 240 components. After some time in testing, the Ar 440 was officially rejected in October 1943 by the RLM.
Overall Performance and Cancellation of the Ar 240 Project
The Ar 240 possessed several advanced characteristics like a pressurized cockpit, remote-controlled defensive turrets, traveling flaps which provided this aircraft with good low-speed overall lift performance and fuel tanks with a new self-sealing system that used thinner tank liners. But, almost from the start of first flight testing, things turned from bad to worse for this aircraft. Almost from the start, the Ar 240 was plagued with extremely bad handling on all three axes. There were also huge problems with the controls during landing, with most aircraft being lost due to this. As the aircraft proved to be dangerous to fly, it was never adopted and the initial orders for production of 40 aircraft were never materialized.
Allied Examination After the War
Strangely, despite being a rare aircraft, the Allies managed to capture at least one Ar 240 during their advance in the West in 1944/45. This aircraft was tested by Allied pilot Captain Eric Brown. He was Chief test pilot of the Royal Aircraft Establishment at Farnborough. He was involved in a British project of taking over of German war research installations and interrogating technical personnel after the war. After the war, he managed to find the single surviving Ar 240 and, after a flight on it, made a report on its performance. The source for this account is Wings Of The Luftwaffe Flying The Captured German Aircraft of World War II by Eric Brown. This aircraft would be given by the Allies to the French and its fate is unknown.
In his report, he stated. “When the Ar 240 was wheeled out of the hangar, I was struck by its angular appearance. The wings, fuselage, and tail unit all seemed to be straight-edged, with very few curves to be seen. The engines looked very large, the airscrew spinners being level with the nose of the cockpit and well ahead of the wing leading edge, while the nacelles protruded well aft of the trailing edge. I had the feeling that, if this aeroplane was as fast as it was reputed to be, then brute engine force must be the answer … The cockpit layout was neat and the instruments were quite logically arranged, while the view was good all around except downwards on either side, where the engines interfered. Take-off was quite long, even with using 20 degrees of flap, and the initial climb rate was just over 600 m/min (2,000 ft/min). Longitudinal stability was poor, lateral stability neutral, and directional stability positive. The rate of climb fell off very little as I climbed to 6,096 m (20,000 ft), where I levelled out and settled into the cruise at what I calculated was a true airspeed of 580 km/h (360 mph). In the cruise, the aeroplane could not be flown hands-off because it diverged quickly both longitudinally and laterally, and would be tiring to fly for a long time. An autopilot was fitted, although not serviceable in my case, but I believe it would have been essential for instrument flying in bad weather. On opening up to full power, I estimated that after three minutes I was hitting an impressive true airspeed of 628 km/h (390 mph), but it was obvious that the Ar 240 was a poor weapons platform. The harmony of control was terrible, with heavy ailerons, light elevators. and moderately light rudders. ….
My assessment of the Arado Ar 240 is that it was an aircraft of outstanding performance for its class and era, but it could not capitalise on this because of inferior, and indeed dangerous, handling characteristics. According to German information, it had a service ceiling of 10,500 m (34,450 ft) and a maximum range of 1,186 miles, so it had great potential as a reconnaissance intruder, and indeed it is claimed that it made such sorties over Great Britain in 1941 and 1944. Be that as it may, there can be little doubt that the Ar 240 was a failure ..”
Production Numbers
While the Ar 240 production was initially to begin in 1941, due to many problems and delays, this was not possible. While there were attempts to start production, by the end of 1942, the RLM officially terminated the program.
How many aircraft were built depends on the source. According to author G. Lang, the problem with identification of the production numbers is complicated by the fact that some prototype aircraft were allegedly modified and used for the few A-series aircraft built. Another issue, according to Lang, is that the highest known serial number production was 240018 (starting from 240000), which suggests that at least 18 were built, but it is not completely clear. Authors Ferenc A. and P. Dancey mention that at least 15 were built by 1944. Eric Brown claims that 12 prototypes were built.
Main Production and Prototypes
Ar 240 V1-V14 – Prototypes series used to test different equipment, armament and engines.
Ar 240 A – Was to be main production version, but only few aircraft were actually built
Ar 240 B – High-altitude reconnaissance version, possibly few built.
Ar 240 C – A bomber version, unknown if any were built.
Ar 240 D – Proposed version powered by two DB 614 engines.
Ar 240 E – Proposed modified Ar 240 version.
Ar 240 F – Proposed heavy fighter/bomber version to be powered by two DB 603 G engines.
Ar 440 – An improved version of the Ar 240. Only a few were built. The project was cancelled in 1943.
Ar 240 mit 7.5 cm Bordwaffen – A proposed version armed with a 7.5 cm gun, possibly one built, but its fate is unknown.
Ar 240TL – A jet-powered paper project.
Operators
Germany – Operated small numbers of these aircraft, mostly for testing and reconnaissance operations.
France – Captured one, but the fate is not known.
Conclusion
While the Ar 240 was, on paper, an excellent design with many innovations and advanced technology, in reality it did not live up to expectations. The plane proved to be dangerous during flight and many were damaged during landing, with fatal outcomes. Because the Ar 240 proved to be difficult to control, the RLM simply decided to stop the project, as it was probably unwilling to waste more time and resources on it.
Arado Ar 240 A-0 Specifications
Wingspan
14.3 m (47 ft)
Length
12.8 m (42 ft)
Height
3.95 m (13 ft)
Wing Area
31 m² (333 ft²)
Engine
Two liquid cooled twelve-cylinder 1,750 hp DB 603 A-1
Empty Weight
6,350 kg (14.000 lbs)
Maximum Takeoff Weight
10,500 kg (23,150 lbs)
Fuel Capacity
2,300 liters (607.6 US gallons)
Maximum Speed at 6 km
670 km/h (415 mph)
Cruising Speed
600 km/h (370 mph)
Range
2,200 km (1,370 mi)
Maximum Service Ceiling
11,500 m (37,730 ft)
Climb speed
Climb to 6,000 m in 9.7 minutes
Crew
Two pilot and the rear radio operator/gunner
Armament
Four 2 0mm (0.78 inch) MG 151/20
Two 13 mm (0.5 inch) MG 131
One 1,000 kg (2,220 lbs) or one 1,800 kg (3,930 lbs) bomb
Or two 500 kg (1,000 lbs) bombs,
Or eight 50 kg (110 lbs) bombs,
Or 288 2.5 kg (5 lbs) incendiary and fragmentation bombs
Kingdom of Italy (1937)
Fighter Aircraft – 158 ~ 170 Built
The Re.2000 was one of many Italian pre-war fighter aircraft developments. Despite having overall decent flying performance, it was never adopted for Italian service. It did see export success, to Sweden and Hungary.
History
Officine Meccaniche Reggiane SA (Reggio Emilia in Northern Italy) was a WWI-era aircraft manufacturer. However, after the war, the Reggiane was not involved in any aircraft production or design work. Things started moving only during the thirties, when Reggiane became a subsidiary of the much larger Società de Agostini e Caproni and Società Caproni e Comitti aircraft manufacturer, which was led by well-known Engineer Gianni Caproni. Thanks to him, Reggiane was provided by Caproni with a larger and well qualified aircraft design department. Reggiane and Caproni were involved in several experimental pre-war designs, like the Ca.405 Procellaria and P.32bis, in addition to the licence production of the S.M.79 bomber.
In 1938, the development of the Re.2000 began at the request of the Italian Aviation Ministry (Ministero dell Aeronautica) under the codename “Programme R”, which aimed to upgrade the Italian Air Force (Regia Aeronautica) with new and modern designs. Special care was given to the development of new single wing fighter designs. At that time, several different fighter designs were in various states of development (like the Fiat G.50, Caproni-Vizzola F.5, Macchi C.200 etc.). The Reggiane officials wanted to participate in this, and ordered the design team to begin developing a fighter plane.
A team was formed, led by the Technical Director Antonio Alessio and Engineer Roberto Longhi, who immediately began work on the new design. Due to a lack of time to properly design the new fighter, a solution was proposed to simply buy a licence from the Americans, but this was rejected by chief Ing. Caproni. The new design was, surprisingly, soon finished. This was achieved by utilizing some elements of design of an American Seversky P-35 aircraft. The main reason why the Re.2000 was influenced by the American design was Roberto Longhi. He had spent some time working in the aviation industry in America before returning to Italy in 1936. While the two planes look very similar, there were some differences, like the cockpit, landing gear etc.
Technical Characteristics
The Re.2000 was designed as a low wing, mixed construction (mostly metal), single seat fighter plane. The fuselage consisted of a round frame covered with metal sheet held in place by using flush-riveting. The Re.2000 wings had a semi-elliptical design, with five spars covered with stressed skin. The central part of the wing held two integral fuel tanks. The front position had a capacity of 455 l (120 US gallons), while the smaller rear one could hold around 240 l (63 US gallons). The wings were equipped with fabric covered Frise type ailerons. The rear tail had a metal construction with the controls covered with fabric.
The landing gear system was unusual. When it retracted, it rotated 90° (a copy from the Curtiss model) before it entered the wheel bays. For better landing handling, the landing gear was provided with hydraulic shock absorbers and pneumatic brakes. The smaller rear wheel was also retractable and could be steered if needed.
The Re.2000 engine was the Piaggio P.XI R.C.40 14-cylinder air cooled radial engine, a licensed derivative of the French Gnome-Rhône Mistral Major 14K, providing 985 hp (840 hp depending on the source), equipped with a three blade variable pitch propeller made by Piaggio.
The cockpit canopy opened to the rear and the pilot had a good overall view of the surroundings. For pilot protection, a rear 8 mm (0.3 in) thick armor plate was placed behind the seat. The pilot was provided with an oxygen tank and a type B.30 radio. The Re.2000 had an option for installing wing gun-cameras, but this was rarely done.
The Re.2000 possessed weak offensive capabilities, as it was armed with only two Breda-Safat 12.7 mm (0.5 in) heavy machine guns. The machine guns were placed above the front fuselage and fired through the propeller arc. For each machine gun, 300 ammunition rounds were provided. The machine guns could, depending on the combat situation (lack of ammunition, for example), be fired together or individually. There were plans to add two more machine guns (unknown caliber) to the wings but nothing came of this.
The Re.2000 also had two small bomb bays placed in each central wing section. Each bomb bay had a payload of twenty two 2 kg (4.4 lb) anti-personnel or incendiary bombs. The bombs were electrically released individually or in larger groups.
Tense Start
The first operational Re.2000 prototype (serial number MM.408) was completed in early 1939. It made its first test flight on 24th March (or May, depending on the source) that year, piloted by Caproni test pilot Mario De Bernardi. During this flight, the Re.2000 was shown to have good flying speed and manoeuvrability. There were some modifications requested, like changes in the design of the exhaust and carburettor air intakes. The cockpit design was also requested to be changed from a round windshield to a framed model. These flight tests were followed by armament tests, which also were without any major problems. During this time, the Re.2000 was tested in mock dog-fights against the Italian Macchi C.200 and even a German Me-109E. In these mock fights, the Re.2000 proved to have better handling and maneuverability than its counterparts.
In August 1939, the prototype was moved to the Air Force Guidonia test site near Rome for further testing. The Re.2000 was flight tested by two pilots, Colonels Aldo Quarantotti and Angelo Tondi, who both gave positive remarks on its performance. Maximum speed achieved during these test flights was 515 km/h (320 mph).
Further tests done by the Aeronautical Construction of the Air Ministry, on the other hand, stressed the important structural problems that this plane had. The main issue was the position of the fuel tanks in the wings, which was dangerous for a fighter plane. There was another huge issue with fuel tank leaks due to loosening of the rivets. The low quality of the welding and a number of internal structural defects were also noted. Despite still being in a prototype stage, meaning that these defects could possibly have been addressed, the Re.2000 program was abandoned.
Despite the proposal of the Re.2000 main designers Alessio and Longhi to redesign the fuel tanks and improve the structure of their prototype, the decision for the cancellation of the project was not changed. The small serial production of 12 planes was rejected and the preparation of the tooling equipment for the production of the originally planned 188 aircraft was abandoned.
Strangely, for some unknown reason ,the Aviation Ministry gave permission for the construction of a second prototype (MM.454). Later, this prototype would serve as a base of the Re.2002 aircraft design.
Success Abroad
Despite not being adopted for service, the Aviation Ministry did actually include the Re.2000 for the export market, where it did see some success. Even though the Reggiane lost the order for the Re.2000 serial production, their management decided to go on with production as a private venture. The idea was that, if its own Air Force did not want to adopt it, maybe another country would. Many Nations in Europe would show interest in this design, which included Hungary, Yugoslavia, Spain, Switzerland, UK, Finland and Sweden. In the end, due to the war’s outbreak, only Hungary and Sweden would receive the Re.2000.
Negotiations with the UK
In late 1939, the UK sent a delegation led by Lord Hardwick and Wing Commander H. Thornton to Caproni. The British were interested in buying a number of aircraft designs (Ca.313 and Ca.311), including 300 Re.2000. The order was confirmed in January 1940. What is interesting is that, initially, the Germans did not try to prevent these negotiations. Later, in March, the Germans tried to enforce an embargo on the Italian sale of weapons to the UK. Caproni and Lord Wardwick tried to bypass this embargo by making a deal through a Caproni Portugese subsidiary. But, as Italy attacked the French in June 1940, the negotiations between Italy and the UK were stopped.
In Swedish Service, the “J 20”
Sweden negotiated with Reggiane to buy a group of 60 Re.2000 aircraft. After some initial negotiations, the deal was made on the 28th November 1940. The price of these 60 aircraft was 18.7 million Swedish Krona, but was instead paid in much needed chrome-nickel metal (of the same value) instead. The 60 Re.2000 were broken into parts and sent by train through Germany and then again re-assembled at Malmen. In Swedish service, the Re.2000 was known as the J 20. While it proved to have good flying performance, due to the harsh weather conditions, it was difficult to maintain properly. During the war, the J 20 were mostly used to patrol the Swedish skies and occasionally intercept German or Allied aircraft. Only one was lost, when it was shot down by a German Do 24 in April 1945. Due to a lack of spare parts, all were removed from service in 1946. One surviving J 20 can be seen in the Swedish Air Force Museum in Linköping.
In Hungarian service, the “Héja”
For some time, Hungary acquired aircraft and aviation equipment from Italy (like the CR.32 and CR.42, for example). By the end of 1939, Hungary asked for 70 new Re.2000 in addition to the licence rights for domestic production. Once the deal was completed, the production of the Re.2000 was given to well known manufacturer MAVAG, but the start of the production process was slow. On the other hand, the 70 Italian-produced Re.2000 arrived by the end of 1941. The first Hungarian-produced Héja (Hawk, as the Re.2000 was known in Hungary) was only built and tested in 1942. By the time production stopped, in 1944 around 185-203 aircraft of this type were built.
During their Hungarian service, the Héja’s engine was deemed insufficient, and so a new, 14-cylinder WMK-14B 1085 hp engine was used. The heavy machine guns were also replaced with Hungarian Gebauer ones of the same caliber.
The Héja were used on the Easter front with some success, managing to achieve a number of air victories. As a shipment of more advanced Me-109G arrived in Hungary from Germany in late 1943, the Héja was mostly relegated to training. But, due to the rapid Soviet advance in 1944, many were put back into frontline service in the vain hope of stopping the enemy.
Negotiation with Yugoslavia
In early 1940, the Kingdom of Yugoslavia sent an Air Force delegation led by Colonel Pavlović to negotiate an order for 50 Re.2000 aircraft. After a brief demonstration, the delegation was impressed with its performance. In March, a new delegation led by Colonel Rubčića, with two test pilots, was sent to personally test the Re.2000’s performance. In July, Yugoslavia requested a delivery of six Re.2000 aircraft without armament. Due to the outbreak of the war, none were ever delivered to Yugoslavia.
A New Chance in Italian service
The Re.2000 would see some limited service in the Italian Air Force and Navy. Due to an urgent need for modern aircraft, the Italians simply reused 28 aircraft (the numbers are different depending on the source used) which were originally intended for Hungary (20) and Sweden (8). An additional 28 aircraft were built to replace the ones requisitioned, and supplied to the respective buyers.
Shipboard Version
When Italy declared War on the Western Allies, their navy had only a small number of 44 Ro.43 and few Ro.44 floatplanes available. Thus, the Italian Navy finally showed interest in the Re.2000 as a replacement for the older models. For this reason, a Re.2000 was to be modified with catapult mounting points, so that it could be launched by ship catapults. These were piloted not by navy pilots, but instead by the Air Force. Two Re.2000 that were modified for this purpose and were lost in accidents. The first (MM.471), piloted by Cap. Giovanni Fabbri, was lost during the flight to Taranto and the second (MM.485) was damaged during transport.
The first catapult tests were carried out in late 1941 near Perugia, by Giulio Reiner. More intensive tests were carried out in early 1942 on the Italian battleships Roma and Vittorio Veneto. These tests were considered a great success and an order was placed for 10 Re.2000 to be modified for this role.
These Re.2000 saw some modifications, like the removal of the covering behind the sliding canopy in hope of improving rear visibility, a modified windshield was added, new radio and modifications to the fuselage so that it could be launched from ship catapults.
When the testing was completed, the Re.2000 were given to the 1° Squadriglia FF.NN (Forze Navali – Naval force). Two each were given to the battleships Roma, Vittorio Veneto and Littorio. Due to the rapid development of the War in the Medeterain, the Italian navy was no longer able to effectively battle the Allied navy. These Re.2000 were never used operationally on any Italian ships in its intended role. By the time of the Italian surrender (September 1943), these battleships tried to escape to the Allied side but were attacked by the German bombers, and only one Re.2000 (from the Vittorio Veneto) survived the engagement.
Depending on the source, this version was powered by a stronger 1025 hp P.XIbis engine. The Re.2000 design for the shipboard is marked as Series II. In addition, some authors (like Maurizio D.T.) name this version as Re.2000Bis.
The Re.2000 G.A. Long Range Version
The flow of supplies to the Italian colony of Ethiopia with much needed modern weapons and equipment was constantly harassed by the British navy and aviation. One of the problems for the Italians was the lack of proper fighter cover. They attempted to send S.M.82 transport planes carrying parts for CR.42 biplanes. While these attempts did see some success, a proper solution was needed. The best Italian fighter at that time was the Macchi C.200, but it lacked the needed operational range to reach this front. Someone in the Italian Air Force proposed to modify some already produced models with increased fuel load. The Italian Navy (Regia Marina) also showed interest in this project, as they were desperate to replace the aging Ro.43 and Ro.44 aircraft (carried by larger shipps for various missions). For this proposal, the Re.2000 was chosen, despite not being adopted for service.
The prototype of the Re.2000 design for longer operational range was named “G.A” (Grande Autonomia, long range). The Re.2000 G.A had an increased fuel load to 1490 l, which increased the operational range from 840 km (520 miles) to 1.300 km (807 miles). This aircraft was tested by the famous Italian Ace Col. Adriano Mantelli. The flight proved to be successful and without any problems. Despite these results, the loss of Ethiopia to the Allies in May 1941 stopped the long range fighter project.
The modified Re.2000 aircraft were allocated to the 23° Gruppo Autonomo (independent group) in the spring of 1941. The 23° Gruppo Autonomo consisted of the 70° ,74° and 75° Squadriglia. This unit was stationed at Sicily under the leadership of Major Tito Falconi. As this unit had only a small number of Re.2000, it was reinforced with older CR.42.
To better test the Re.2000 G.A. version’s performance, a special experimental section (Sezione Sperimentale), a part of the 23° Gruppo Autonomo, was formed. This Section was led by Capt. Pietro Calistri. For some time, this unit had a nonoperational status, as the Re.2000 had engine problems and could not be used. As the engine problems were solved, the Re.2000 were mainly used for patrolling the Italian coast, but in a few cases even for bombing British military installations on Malta. The Re.2000 were moved to support the 377° Squadriglia in July (or August depending on the source). At that time, the 377° Squadriglia had around 13 (or up to 17) Re.2000. This unit was stationed at the Trapani Milo airfield in Sicily. From that point, this unit was mostly used for patrol and escort missions in the Mediterranean sea.
The 23° Gruppo Autonomo was, for a very short time, even used in North Africa, but without any Re.2000. In early 1942, the unit was engaged in naval escort and reconnaissance operations, but no enemy fighters were encountered. From March 1942, this unit, under the command of Capt. Marcolini, operated from Palermo in Sicily. Its objective was to protect Palermo from any possible enemy bombing attacks and to scout for enemy ships and aircraft. During one such mission, one British Blenheim bomber was shot down, which may be the only Re.2000 air victory in Italian service.
The 377° Squadriglia was engaged in supporting the Italian attacks on British convoy ships near Malta in June 1942. During this action, no victory was achieved and no losses were recorded. After more than 320 operational missions, the Re.2000 were replaced with Macchi C.200 aircraft in September 1942. The remaining Re.2000s were in such poor repair condition that it was decided to return them to the Reggiane factory. After some were repaired, they were then moved to Treviso to be used as training aircraft, but no flights were ever made. After the Italian surrender, the Germans took over these aircraft, but they were likely scrapped, as there is no record of their use by the Germans.
Future Developments
During the war, the Re.2000 would see some improvement attempts by using a new engine and improving the overall design. There were several such projects, including the Re.2001, Re.2002, Re.2003, Re.2004 and Re.2005.
Re.2001
In the hope of improving the Re.2000’s overall flight performance, in 1939 and 1940, one plane was equipped with a German Daimler Benz DB 601 engine. While it improved the performance, Alfa Romeo was unable to produce large numbers of this engine and, for this reason, only 252 were built. They were used in different roles: fighter, ground attack, shipboard and torpedo attack plane.
Re.2002
The Re.2002 was a fighter-bomber version which incorporated design elements from the Re.2000 and Re.2001. It received two additional light machine guns, bomb racks under the fuselage and under the wings. It was powered by a 1175 hp Piaggio P.XIX R.C.45 engine. Small numbers were produced for the Italians by 1943. The German captured the Reggiane factory and produced additional aircraft.
Re.2003
One Re.2000 was used as a base for the experimental two-seat Re.2003 version. After some testing and an initial order for 200 planes, it was not adopted for service.
Production
Despite being canceled for mass production, Reggiane decided on its own initiative to produce a series of 158 to 170 (depending on the source) aircraft for export sales. Most of these would be sold to Hungary and Sweden. Small numbers (less than 30, including the prototypes) did eventually enter limited service with the Italian navy.
Re.2000 Prototype – two prototypes built
I Series – Main production version
II Series- Shipborne fighter/scout version
III Series – Long range version
Prototypes and modifications
Re.2001 – Improved version powered with German Daimler Benz DB 601 engine, 252 were built.
Re.2002 – Powered with 1175 hp Piaggio P.XIX R.C.45 engine, 225 were built.
Re.2003 – Experimental two-seater, one prototype built.
Operators
Italy – Operated less than 40 aircraft
Hungary – Bought 70 aircraft and a licence production for the Re.2000 under the ‘Héja’ name. Total domestic production was 185-192 aircraft
Sweden – Bought 60 aircraft in 1940.
UK – Negotiated buying 300 aircraft, but the war prevented this from happening.
Other countries like Yugoslavia, Finland, Spain and Switzerland showed interest in buying a number Re.2000, but nothing came from this.
Surviving Re.2000
Two Re.2000 wrecks were recovered from the bottom of Mediterranean. One shipboard Re.2000 (MM.8287) wreckage was found by the Italian company Micoperi. It was lost in a reconnaissance flight during April 1943. What is interesting is that this plane was modified as an experimental two seater according to author Maurizio D. T. The wreckage was, after a proper desalination process, transported to the Museum of the Italian Air Force at Vigna Di Valle. This plane is currently under restoration. Another Re.2000 (MM.8281) was also recovered in late April 2012.
Conclusion
The Re.2000 had good flying performance but it did have a number of issues. The greatest one was the engine, which demanded a lot of maintenance. There were many problems with the engine overheating. While the larger forward mounted engine did provide the pilot with additional protection from enemy fire, it also affected the pilot’s front view, which was limited. The two heavy machine guns proved to be insufficient and problematic. The biggest issue was the poor quality of the fuel tanks, a problem that was never solved successfully, which was the main reason why it was never adopted for service.
Re.2000 Specifications
Wingspans
36 ft 1 in / 11 m
Length
26 ft 5 in / 8 m
Height
10 ft 4 in / 3.15 m
Wing Area
220 ft² / 20.4 m²
Engine
One Piaggio P.XI RC.40 985 hp
Empty Weight
5424 lbs / 2.460 kg
Maximum Takeoff Weight
7143 lbs / 3.240 kg
Fuel Capacity
675 l (180 US gallons)
Climb to 6 km (19,700 ft)
6 minutes 10 seconds
Maximum Speed
320 mph / 515 km/h
Cruising speed
280 mph / 450 km/h
Range
522 mile / 840 km
Maximum Service Ceiling
34.450 ft / 11,500 m
Crew
1 pilot
Armament
Two 0.5 in (12.7 mm) heavy machine guns
Bomb bay with twenty two 4.4 lb (2 kg) bombs.
Gallery
Illustrations by Pavel
Credits
Nešić, D. (2008). Naoružanje Drugog Svetsko Rata-Italija. Beograd.
Nazi Germany (1942)
Transport Floatplane – 1 Built
With the success of the previous Blohm & Voss Bv 222 flying boat, Dr. Ing. Richard Vogt, chief designer at Blohm & Voss, began working on an even larger improved design in the form of the Blohm & Voss Bv 238. As the Bv 238 development began in the late stages of the war, only one aircraft was ever completed and used only briefly.
Dr. Ing. Richard Vogt’s Work
In 1937, Lufthansa opened a tender for a long-range passenger flying boat transport that would be able to reach New York in 20 hours. Blohm & Voss eventually would go on to win this tender. The chosen aircraft was the Blohm & Voss Bv 222, designed by Dr. Ing. Richard Vogt.
During 1941, Dr. Ing. Richard Vogt began working on a new aircraft larger even than the already huge Blohm & Voss Bv 222. In July the same year, he presented to the RLM, the German ministry of aviation (Reichsluftfahrtministerium), the plans for the new Blohm & Voss Bv 238. This aircraft was, in essence, a modified and enlarged version of the Bv 222 powered by six Daimler-Benz DB 603 engines. Three aircraft powered with this engine were to be built, belonging to the A-series. Six more aircraft were to be powered by six BMW 801 engines and these would be designated as B-series.
To speed up the development and avoid wasting resources if the project proved to be unsuccessful, the RLM officials asked for a smaller scale flying model to be built first instead of a working prototype. This scale model plane was named FG 227 (or FGP 227, depending on the source) and was to be built and tested at Flugtechnische Fertigungsgemeinschaft GmbH located in Prague.
The FG 227 scale flying model
The construction of this scale model was undertaken by a group of Czech students under the direction of well-known glider pilot Dipl.Ing. Ludwig Karch. It was to be powered by six ILO Fl 2/400 engines pushing 21 hp each. As it was meant to be tested on the ground and not in water, the FG 227 was provided with landing gear which consisted of two wheels in the nose and two more wheels placed on each side of the fuselage.
When the FG 227 was completed, it was to be flight tested. From the start, there were issues with it, as it was unable to takeoff under its own power. After the unsuccessful start, it was disassembled and transported to Travemünde for future testing. During transport, French prisoners of war deliberately damaged one of the wings. Once the damage was repaired, it was flight tested. But during the flight, made in September 1944, all six engines stopped working, which caused an accident where the FG 227 was damaged. After yet another major repair, a few more flights were carried out. The FG 227’s overall performance was disappointing and it didn’t play any major role in the Bv 238 development.
The Bv 238
Construction of the first Bv 238 parts began in early 1942. The final assembly was not possible until January 1944. Due to a shortage of materials and the increasing assaults by the Allied Air Forces, the Bv 238 V1 first prototype could not be completed until March of 1945. The first flight test we conducted immediately after its completion. However, sources do not agree on the exact year when this happened. This is the timeline of development and construction according to author H. J. Nowarra.
Author M. Griehl states that the first flight test was made on the 11th of March 1944. Author C. R. G. Bain states, according to post war testimonies of Dr. Ing. Richard Vogt, that the first test flight was actually made in 1943. According to D. Nešić, the first flight was made in April 1944. The results of this test flight showed that the Bv 238 prototype had surprisingly excellent flying performance. For this reason, it was immediately put into operational service.
Throughout the Bv 238 development phase, it was often discussed precisely which role it could fulfill. While it was primarily designed as a transport plane, a new idea was proposed to act as a U-boat support aircraft. This would include carrying supplies, fuel, torpedos and men to the U-boats operating in the Atlantic. Of course, by the time the first prototype was near completion, the war was almost over, so this proposal was realistically not possible. Plans to use it as a long range bomber, carrying six 2,400 kg bombs, also never materialized.
Bv 238 V1 was meant to operate from Shaalsee, and for its service with the Luftwaffe, it received the RO+EZ designation. As the Allied bombing raids effectively destroyed the Blohm & Voss factory in Hamburg, orders came down to hide the Bv 238 from the Allied Air Force. The question was how to hide such a huge aircraft. The Germans did try to do so but the aircraft was eventually found by the Allies who managed to sink it. The circumstances are not clear to this day, as both Americans and the British pilots claimed the kill. According to the most well-known story, it was destroyed by a group of American P-51 Mustangs belonging to the 131st Fighter Group. The kill was made by the leading P-51 piloted by Lt. Urban Drew. According to the testimony of the Blohm & Voss workers, the British, in their advance discovered the hidden craft. Once spotted, the British sent attack aircraft to sink it. Its remains would finally be blown up during 1947 or 1948 to make the scrapping process easier. All the remaining Bv 238 that were under construction were also scrapped after the war.
Technical Characteristics
The Bv 238 was designed as a six-engined, high wing, flying transport floatplane. The Bv 238 fuselage was divided into two decks. On the upper deck, the crew and the inboard equipment were housed. The lower floor was designed as a storage area during transport flights. In theory, there was enough room for around 150 soldiers in the Bv 238. A huge front hatch door was provided for easy access to the fuselage interior.
The wings were constructed using large tubular main spars. The wings were used to provide additional room for spare fuel and oil tanks. The wings were provided with flaps running along the trailing edge. The large size of the wing construction allowed passageways for the crew to be installed, in order to have easy access to the engines. Unlike the Bv 222, which had a pair of outboard stabilizing floats mounted on each side, the Bv 238 had only two. The Bv 238 was powered by six Daimler DB 603G engines.
For self defense, the Bv 238 was to be provided with two HD 151 twin-gun turrets with 20 mm (0.78 in) MG 151 cannons, two HL 131 V turrets with four 13 mm (0.51 in) MG 131 machine-guns and two additional MG 131s mounted in the fuselage sides. Despite the plans to arm the V1 prototype, this was never done.
The crew number is mentioned as 11 or 12 depending on the source. The sources do not specify the role they performed. It can be assumed, based on what is known from Bv 222, that there were at least two pilots, two mechanics, a radio operator and machine gun operator.
Production
The production of the Bv 238 was carried out by Blohm & Voss factory at Hamburg. Only one completed prototype would be built during the war. There were also at least two to six more prototypes under construction (depending on the source), but due to the war ending, none were completed.
The small number under construction may be explained by the fact that, in the late stages of the war, the Luftwaffe was more in need of fighter planes than transports planes. In addition, there is a possibility that the Bv 238 project was actually canceled by the RLM officials.
Versions
Bv 238 A – Powered by Daimler-Benz DB 603 engines, only one built
Bv 238 B – Powered by six MW 801 engines, none built
Bv 250 – Land based version, none built
FG 227 – Scale test model of the Bv 238, used for testing
Land Based Version
There were plans to adapt the Bv 238 for land based operations by adding landing gear wheels. The project was designated Bv 250 but none were ever built. It was planned to provide this version with heavy defence armament consisting of twelve 20 mm (0.78 in) MG 151 cannons. The engine chosen for this model was the six Jumo 222. As this engine was never built in any large numbers, the DB 603 was meant to be used instead.
Escape Aircraft
There are some rumors that the Bv 238 was actually developed as an escape aircraft for high ranking Nazi officials. It was rumored that Martin Bormann had plans to use it to escape Germany in early 1945. Of course, due to Allied Air Force supremacy and the Bv 238’s large size, this may have not been a viable plan if ever attempted.
Conclusion
If it was put into production, the Bv 238 would have had the honor of being the largest flying boat that saw service during the war. While it only performed test flights and was never used operationally, it was nevertheless an astonishing engineering achievement.
The Fi 167 was developed out of a need for a dedicated torpedo-bomber to be operated on the first German aircraft carrier. While its overall performance proved to be satisfactory, due to the cancellation of the aircraft carrier project, only a small number were ever built. Unfortunately, information about the Fi 167 is not available or precise enough, with many disagreements between different authors.
Fieseler Flugzeugbau
In the early 1930’s, World War I fighter veteran Gerhard Fieseler (1896–1987) bought the Segelflugzeugbau Kassel Company, which mostly produced gliders, and renamed it to Fieseler Flugzeugbau. Gerhard Fieseler had gained experience in aircraft design while working as a flight instructor for the Raab-Katzenstein Aircraft Company in Kassel. In 1926, he managed to design his first aircraft, named Fieseler F1, which would be built by the Raab-Katzenstein company. By the end of twenties, Gerhard Fieseler designed another aircraft, the Raab-Katzenstein RK-26 Tigerschwalbe, of which 25 were built and sold to Swedish Air Force.
With his own company, he changed to focus on sports aircraft. In 1935, Gerhard Fieseler managed to obtain a licence for the production of military aircraft. While his best known design was the Fi 156 ‘Storch,’ he also designed the less known Fi 167 torpedo-bomber. The Fi 167 was built in small numbers and never managed to reach the fame of the Storch.
History of the Fi 167
As the German Navy began construction of its first aircraft carrier, the ‘Graf Zeppelin,’ in 1937, there was a need for a completely new torpedo bomber. For this reason, the German Ministry of Aviation (Reichsluftfahrtministerium) opened a tender for all German aircraft manufacturers who wished to participate to present their designs for such aircraft. The new aircraft was requested to have folding biplane wings, the best possible STOL (short take-off and landing) capabilities, and that the whole construction should have sufficient strength to successfully endure offensive combat operations at high speeds.
Only two manufacturers, Fieseler and Arado, presented their designs. For Fieseler it was the Fi 167 and for Arado the design was the Ar 195. In the summer of 1938, after a series of flight tests, the Fieseler Fi 167 was declared the better design. For this reason, another prototype was to be built for further testing.
The first prototype built, Fi 167 V1 (serial no. 2501), was powered by a DB 601 A/B engine. It was used mainly for testing and evaluation purposes. The second prototype (serial no. 2502) had some changes to the design, such as a modified undercarriage and was powered by the DB 601B. This engine would be used on later production versions. While most sources state that only two prototypes were built, some authors, like M. Griehl (X-Planes German Luftwaffe Prototypes 1930-1945), mention a third prototype being built. This third prototype, Fi 167 V3 (serial no. 2503), according to Griehl, was used to test the equipment used on this plane. While the sources do not give precise details about the fate of the Fi 167 prototypes, after May 1940, they were not present in the Luftwaffe inventory anymore. This may indicate that all three were scraped. After a number of tests with the Fi 167 were completed, series production of 80 aircraft was ordered.
Short lived operational service life
Despite having promising overall performance, the Fi 167 was directly connected with the Graf Zeppelin project. While the production of a small series was underway, the construction of the Graf Zeppelin aircraft carrier was stopped in 1940, so the same fate befell the Fi 167, as there was no longer a need for a carrier capable fighter. In 1942, there was a brief revival of the aircraft carrier concept, but by that time the Ju 87C was deemed better suited for this role. This decision was not without merit, as the Ju 87 was already in production and it would be much easier, quicker, and cheaper to simply modify it for the role of aircraft carrier torpedo bomber than to put the Fi 167 back into production.
As a small number of 12 Fi 167 A-0 were built, they were sent to Holland for evaluation and testing purposes in order not to waste the resources invested in them. These were used to form Erprobungstaffel 167 which operated in Holland from 1940 to 1942. In 1943, the Fi 167 were returned to Germany and Erprobungstaffel 167 was disbanded. Their use by the Germans from 1943 onward is not completely clear in the sources. While the majority were given to Germany’s allies in late 1944, the final fate of the remaining aircraft is not known, but they were probably either lost or scrapped.
Technical characteristics
The Fi 167 was an all-metal, single engine biplane designed as a torpedo bomber. The Fi 167’s fuselage was constructed by using thin but with high-strength steel tubes that were welded together and then covered with duralumin sheet metal.
In the glazed cockpit there was room for two crew members, the pilot and the observer/rear gunner. The cockpit was covered with plexiglass but was open to the rear in order to provide the rear gunner with a good arc of fire. The Fi 167 was powered by the Daimler-Benz DB 601B 12-cylinder inverted-V engine putting out 1,100 horsepower. The total fuel load was 1,300 liters.
The Fieseler Fi 167 had a biplane layout. The upper and lower wings were the same in size and had a rectangular shape with rounded edges. The wings were divided into three parts in order to make any necessary maintenance or disassembly easier. Being designed to be used on an aircraft carrier, the Fi 167’s wings could also be folded. In order to be adequately structurally stable, the upper and the lower wings were interconnected by ‘N’ shaped metal rods. There were four of these ‘N’ shaped metal rods in total. These were then held in place with steel cables. For better control during flight, both wings were provided with flaps.
The landing gear consisted of two independent fixed landing wheels which were provided with shock absorbers to ease the landing. The forward landing gear units were covered with duralumin coating to help reduce the aerodynamic drag. To the rear there was a smaller fixed landing wheel. The Fi 167 landing gear was designed to be easily discarded in the case of a forced landing on water. The idea was that it would enable the Fi 167 to float on the water surface and thus provide more time for the crew to successfully evacuate the aircraft.
The armament consisted of two machine guns, one forward mounted 7.92 mm MG 17 with 500 rounds of ammunition and a second MG 15 of the same caliber mounted in a rear, flexible mount with 600 rounds of ammunition. The Fi 167 could be additionally armed with up to 2,200 lbs (1,000 kg) of bombs or one torpedo. In some sources, it is mentioned that there were actually two forward mounted machine guns.
Production
The Fi 167 production run was quite limited, mostly due to cancellation of the Graf Zeppelin aircraft carrier. Besides the two or three prototypes, only a small series of Fi 167 (A-0) pre-production aircraft were made. How many were built varies depending on the source. Authors C. Chant (Pocket Guide: Aircraft Of The WWII) and D. Nešić (Naoružanje Drugog Svetskog Rata Nemačka) mention that, besides two prototypes, 12 pre-production aircraft were built. Authors F. A. Vajda and P. Dancey (German Aircraft Industry And Production 1933-1945) give a number of 15 aircraft produced. They also mention that a serial production of 80 Fi 176 was to be completed by June 1941 but, due to the cancelation of the project, this was never achieved. On different internet websites, the total number of Fi 167 built varies between 14 and 29.
Fi 167 V1 – Powered by the DB 601 A/B engine.
Fi 167 V2 – Had modified undercarriage and was powered by the DB 601B engine.
Fi 167 V3 – Possibly-built third prototype, but sources are not in agreement about its existence.
Fi 167A-0 – 12 aircraft built.
In Romanian hands?
It is commonly stated in many sources that the Fi 167 were sold to Romania in 1943. These were allegedly used to patrol the Black Sea. This is likely incorrect, as another German ally, the Independent State of Croatia ‘NDH,’ received nearly all Fi 167 produced. There is a possibility that the Fi 167 were given to Romanians and then returned back to Germany. But due to the lack of any valid documentation, this is only speculation at best.
In NDH service
A group of 11 (or 10 depending on the source) Fi 167 (serial no. 4801-4812) arrived in NDH during September 1944. These aircraft were given to the 1st Squadron stationed in Zagreb for the necessary pilot training. While during its service in the NDH, the Fi 167 was used in bombing combat operations, but was mostly used as a transport plane for food and ammunition. Due to having no problem carrying significant loads and its ability to take off or to land on short airfields, they were ideal for supplying many NDH garrisons besieged by Yugoslav Partisans.
Due to the overall difficult situation of the Axis forces on all fronts, the NDH Army and Air Force were plagued with frequent desertions, including a number of pilots. On 25th September 1944, while flying a Fi 167 (serial no. 4808), pilot Romeo Adum escaped to the Yugoslav Partisan held airfield at Topusko.
There is an interesting story about one Fi 167 piloted by Mate Jurković, as it is claimed he managed to avoid being shot down by five American P-51 Mustangs. This engagement happened on 10th October 1944 during a Fi 167 ammunition supply mission to Bosanska Gradiška. During this flight, the Fi 167 was attacked by a group of five Mustangs. Outgunned and outnumbered, the pilot could only hope to escape by using the Fi 167’s excellent maneuverability at lower altitudes. He eventually managed to escape his pursuers without taking any damage.
Due to a lack of spare parts, Allied air supremacy and Partisan advance, by April 1945 there were only four Fi 167 still present in the NDH Air Force. The condition of these planes is not known. Of these, at least three would be used after the war by the new JNA (Yugoslav People’s Army) army. During its operational use by the NDH Air Force, the Fi 167 was known as ‘The Great Fiesler’.
In Partisan hands
As mentioned earlier, the Partisans managed to acquire one Fi 167. It would be redeployed to the island of Vis and included in the group of NDH aircraft that had defected earlier (one FP 2, two Saiman 200s, one Bü 131, and one Fiat G. 50).
On the 17th of October 1944, while on a liaison mission from Vis to the village of Vrdovo, after delivering orders to the command of the Partisan 20th Division stationed there, the Fi 167 piloted by M. Lipovšćak and with General Ćetković as a passenger began taking to the sky. Unfortunately for them, a group of four P-51 Mustangs attacked the lone aircraft. The Fi 167 was hit in the engine and the tail and the wounded pilot was forced to land on a nearby open plateau. While the pilot was only wounded, General Ćetković was dead, being directly hit by machine gun fire. Circumstances of this accident are not clear even to this day. The P-51 pilots later claimed that, due to bad weather, they could not see the Partisan markings. By the later account of the Fi 167 pilot, he claimed that the visibility was such that the Partisan markings could have been easily seen.
In JNA service
At least three Fi 167 were put into use by the JNA (Yugoslav People’s Army) after the war. Due to the lack of spare parts, their use was probably limited. They would remain in use up to 1948, but unfortunately they were probably all scrapped, as none survive to this day.
Conclusion
Despite being considered an overall good design, the Fi 167 was never put into mass production. The main reason for this was the cancellation of the Graf Zeppelin aircraft carrier. Nevertheless, the Fi 167 did see some limited service within the Luftwaffe, mainly for testing, but also with the Croatia NDH, where its performance was deemed sufficient.
Operators
Nazi Germany – Used the small number of Fi 167, mostly for various experimental purposes.
Romania – Allegedly supplied with Fi 167 in 1943, but this is not confirmed.
Independent State of Croatia NDH – Operated 10 to 11 aircraft between September 1944 and April 1945.
SFR Yugoslavia – Operated a small number of Fi 167 during the war and up to 1949.
Specification: Fi 167
Wingspan
44 ft 3 in / 13.5 m
Length
37 ft 5 in / 11.4 m
Height
15 ft 9 in / 4.8 m
Wing Area
490 ft² / 45.5 m²
Engine
One 1100 hp (820 kW) Daimler-Benz DB 601B
Fuel load
1,300 l
Empty Weight
6170 lb / 2,800 kg
Maximum Takeoff Weight
10,690 lb / 4,860 kg
Maximum Speed
200 mph / 325 km/h
Cruising Speed
168 mph / 270 km/h
Range
800 mi / 1,300 km
Maximum Service Ceiling
26,900 ft / 8,200 m
Crew
One pilot and one observer/rear gunner
Armament
One 7.92 mm MG 17 forward-firing machine gun
One 7.92 mm MG 15 rear mounted machine gun
Bomb load of 1.000 kg (2.200 lbs)or 750 kg (1650 lbs) torpedo