Skeeter | |
---|---|
General information | |
Type | Trainer, Scout |
Manufacturer | Saunders-Roe |
Primary users | British Army |
Number built | 78 + 10 prototypes |
History | |
Introduction date | October 1956 |
First flight | 10 October 1948 (as Cierva W.14 Skeeter) |
The Saunders-Roe Skeeter is a two-seat training and scout helicopter that was developed and produced by British manufacturer Saunders-Roe ("Saro") of Cowes and Southampton, in the United Kingdom.
Work on what would become the Skeeter had been commenced by the Cierva Autogiro Company as the Cierva W.14. Following Saunders-Roe's takeover of Cierva's helicopter development contracts, it was decided to continue its projects, including the Skeeter. Despite an initial preference for the rival Fairey Ultra-light Helicopter, which had already been ordered, there was a reversal of fortune with interest from the Bundeswehr in the potential procurement of a large number of Skeeters. This led to the British order for the Ultra-light Helicopter being cancelled and the Skeeter effectively taking its place, which also served to guarantee an export order from Germany.
During the late 1950s, the Skeeter entered service with the British Army Air Corps, the German Navy, and the German Army. It has the distinction of being the first helicopter to be used by the Army Air Corps. While some consideration had been made to developing a version of the Skeeter powered by a turbine engine instead of a piston engine, it was decided to produce the developmental Saro P.531 for this purpose instead of a more direct Skeeter derivative.
In the 21st century, a number of examples are preserved as museum pieces in the UK, Germany, and Poland.
In 1947, the Cierva Autogiro Company commenced work on a new project, which was designated as the W.14 Skeeter. As designed, it was a relatively compact two-seat helicopter, intended to be suitable for use as both a civilian aircraft and for aerial observation duties with military customers. The original engine selected to power the Skeeter was a single 110 hp Jameson FF-1 air-cooled horizontally-opposed piston engine. [1] [2] On 10 October 1948, the first prototype Skeeter performed its maiden flight at Eastleigh airfield. Initial flight trials of the prototype proved the rotorcraft to be underpowered, which was partially as a result of the experimental Jameson engine being prone to overheating. In response, the company decided to develop an improved Mark 2 Skeeter which was to be equipped with the well-established de Havilland Gipsy Major 10, which provided 145 hp (108 kW). [3] The Mark 2 Skeeter was a noticeably larger aircraft and had a different appearance. [4]
On 20 October 1949, the larger Skeeter Mark 2 performed its first flight. [4] Powered tests using the rotorcraft soon made it apparent that the Mark 2 suffered from severe ground resonance problems. Cierva found it difficult to resolve these issues; on 26 June 1950, the Skeeter Mark 2 was destroyed during ground testing. Despite these problems, Cierva had received an order from the British Ministry of Supply for three improved Skeeters, a pair of Mark 3s and a single Mark 4, for evaluation purposes by the Royal Air Force (RAF) and Royal Navy. [5] Prior to the completion of any of these three rotorcraft, rival manufacturer Saunders-Roe completed its take over of Cierva's helicopter development contracts and took control of its facilities and development programmes in January 1951. [note 1] [4]
During March 1953, the Blackburn Bombardier-engined Skeeter Mark 3B was transferred to the Aeroplane and Armament Experimental Establishment (A&AEE). [4] Subsequent testing showed that these aircraft continued to be underpowered and that the previously encountered ground resonance problems had yet to be properly resolved; these failings were cited as the reason for official support for the rotorcraft being suspended. [4] In response to the suspension, Saunders-Roe chose to undertake a lengthy series of company-funded tests, which involved the use of a specially-built rig as well as more theoretical work being performed, for the purpose of identifying both the causes of and solutions to the resonance issue. [5] [7]
During the early 1950s, the British Army became highly interested in the potential use of compact helicopters in the observation and aerial observation roles. [8] In 1953, there was a requirement issued by the British Ministry of Supply which sought for a low-cost two-seat helicopter, which would be suitable for reconnaissance, casualty evacuation and training duties. [9] This specification was considered to be quite demanding, calling for it to be capable of high speeds and quick climb rates even under tropical conditions. The rotorcraft was also required to be transportable on the back of a standard Army three-ton truck, constricting the dimensions of the prospective vehicle considerably. [9] Further requirements for the prospective light helicopter included a flight endurance of one hour along with the potential for carrying light cargos such as fuel and tools as well as stretcher-bound wounded troops. [8] An initial request for a rear-facing observer's seat was present early on, but was discarded in later revisions. At this time, newly developed gas turbines were beginning to appeal both to helicopter designers and to prospective operators, the British Army made the use of such an engine one of its requirements. [8]
A diverse range of entries were submitted in response to the issuing of the requirement; amongst these were Fairey Aviation with its Ultra-light Helicopter which harnessed tip jet propulsion, Saunders-Roe with a smaller version of the Skeeter, the Bristol Aeroplane Company's proposed Type 190, a ducted rotor proposal by Percival Aircraft, Short Brothers proposed the larger Short SB.8, and a ram jet-powered proposal by Austrian-born helicopter pioneer Raoul Hafner. [10] In response to the detailed design submission that Fairey had produced for their proposal, the Ministry decided to award the firm a contract to produce a total of four development aircraft for demonstration and flight testing purposes; the company later decided to construct a further two more rotorcraft as a private venture. [9]
Meanwhile, a solution for the Skeeter's troublesome resonance issue had been developed, which involved the adoption of a redesigned undercarriage and the fitting of revised blade friction dampers on the rotor head. These improvements allowed Saunders-Roe to finally demonstrate that the ground resonance problems had been fixed when the Skeeter Mark 5 underwent testing by the A&AEE in March 1954. [4] The resolution of the issue served to reignite official interest in the rotorcraft, quickly leading to a smaller order being placed for four Skeeter Mark 6s, each equipped with 200 hp (149 kW) Gipsy Major 200 engines (designated as AOP.10 and T.11 by the British armed forces), for evaluation purposes. [11]
It was around this point that the British Army became more focused on the Skeeter and the addressing of its shortcomings, while the Fairey Ultra-light fell out of favour. [12] According to aviation author Derek Wood, the Skeeter had benefitted from a favourable early impression of the type that had been made upon some West German officials; the rotorcraft had attracted the offer of a sizable military order from the German government, however, the placing of the order was on the condition that the Skeeter was in turn adopted by the British armed forces as well. Thus, the decision was taken in Whitehall to concentrate its efforts on the Skeeter, which effectively meant the abandonment of the Ministry requirement that the rival Fairey Ultra-light had been being developed towards fulfilling. [12] In 1956, Saunders-Roe finally received production orders for 64 AOP.12s, each powered by a215 hp (160 kW) engine; production deliveries of the Skeeter commenced in 1958. [11] [13]
Overall 78 Skeeters were produced, in addition to 10 prototypes. [14]
The Saunders-Roe Skeeter is a light all-metal, two-seat single-rotor helicopter, complete with a tail rotor for torque compensation and yaw control. [15] It was intended to perform as an all-purpose rotorcraft, primarily being used for light civil work as well as aerial observation and training missions in military service. The handling characteristics were broadly similar to comparably-sized rotorcraft of the era, while possessing the necessary simplicity, robustness, and reliability that commonly typified trainer aircraft. [15]
The Skeeter possessed a relatively conventional configuration for a helicopter, being powered by a single piston engine which drove a 29-foot (8.84 metre) three-bladed main rotor and a three-bladed anti-torque rotor, which was mounted at the end of a triangular-section tailboom. [15] The main rotor-blades made use of a composite construction, using a steel-tube spar that was bonded to wooden veneers, formers, and ribs, as well as brass balance-weights; these reportedly delivered a cost-effective and relatively simplistic rotor blade that also possessed favourable fatigue properties. Saunders-Roe also developed a replacement metal light alloy rotor blade that possessed superior aerodynamic properties and provided increased performance. [15] A fixed tricycle undercarriage arrangement, complete with interchangeable wheels and brake units, was also present. [1] [2]
The Skeeter's crew of two were housed within an enclosed glazed perspex canopy, complete with removable doors. [16] The design of the cabin had been heavily shaped by the requirement for the Skeeter to be suited to the air observation post (AOP) role that the type had been heavily marketed towards. [15] The nose structure of the Skeeter bore the weight of the rotorcraft's equipment, payload, and crew in addition to the inertial forces present during manoeuvring and landing loads from the nose wheel. The light-alloy structure contained control access panels in the floor and a battery unit within the nose itself. [16]
Directly behind the cockpit and underneath the main rotor was the rotorcraft's engine and its nylon bag-type fuel tank, which was housed within a welded tubular steel framework attached to the cockpit structure and to the tailboom. Power was directed to the tail rotor via a torque shaft contained within the tail cone, which featured gearing so that pilots could readily adjust the speed and direction of tail rotor movement. [15] The engine was provided with cooling air via an intake on the centre of the starboard side of the rotorcraft; for improved ventilation, the cowling around the engine area could be entirely removed. The de Havilland Gipsy Major that was used to power the majority of Skeeters was credited with being a major contributor to the rotorcraft's relatively high fuel efficiency due to its use of fuel injectors (the high aerodynamic efficiency of the airframe itself was another beneficial factor). [17]
With the limited power of the Gipsy Major, means of boosting power were investigated, including a de Havilland developed turbo-supercharger. As an alternative to the turbocharger, a rocket powered rotor boost system was developed by D. Napier & Son, fuelled by High Test Peroxide (HTP) decomposed at blade tip nozzles by contact with a catalyst. The Napier N.R.E. 19 system was fitted to two Skeeter 6 helicopters (G-AMTZ and G-ANMI), re-designated as Skeeter 6 (mod) when modified. [18]
The rocket system consisted of a hemispherical HTP tank on the top of the rotor head and pipes running through the blades to catalyst chambers and rocket nozzles at each blade tip. Total thrust was 22.5 lbf (0.10 kN) thrust for 15 minutes, at a total HTP consumption rate of 1 imp gal/min (1.2 US gal/min; 4.5 L/min), boosting rotor power by 67 shp (50 kW) and increasing vertical climb rate considerably . Total weight of the system was under 30 lb (14 kg). [18] [19]
Flight trials proved the system to work as advertised but it was rejected due to the logistical problems involved with HTP in peace-time and particularly during military action. [18]
The British Army ordered 64 Skeeter 6's, to be designated as the Skeeter AOP.12 (air observation post - artillery direction & control), and the Skeeter finally entered service in October 1956. Several Skeeter AOP.12s were operated by the Central Flying School of the Royal Air Force. With the merger of the helicopter activities of the British Bristol Aeroplane Company, Fairey and Saro with Westland Aircraft in 1960, plans to develop a turbine powered version were abandoned[ citation needed ] – although this knowledge was used in the development of the Westland Scout and Westland Wasp through to the P.531, which had been based on the Skeeter's airframe.
Data fromSaunders and Saro Aircraft since 1917. [40]
General characteristics
Performance
Related lists
The Westland Whirlwind helicopter was a British licence-built version of the U.S. Sikorsky S-55/H-19 Chickasaw. It primarily served with the Royal Navy's Fleet Air Arm in anti-submarine and search and rescue roles. It was also exported to other countries, and the Whirlwind was succeeded by the turbine powered Westland Wessex which was developed from the H-19/Whirlwind. The helicopter was made in many variants using a variety of radial (piston) and turbine engines.
The Sikorsky H-19 Chickasaw is a multi-purpose piston-engined helicopter that was used by the United States Army and United States Air Force. It was also license-built by Westland Aircraft as the Westland Whirlwind in the United Kingdom. United States Navy and United States Coast Guard models were designated HO4S, while those of the U.S. Marine Corps were designated HRS. In 1962, the U.S. Navy, U.S. Coast Guard and U.S. Marine Corps versions were all redesignated as H-19s like their U.S. Army and U.S. Air Force counterparts.
Saunders-Roe Limited, also known as Saro, was a British aerospace and marine-engineering company based at Columbine Works, East Cowes, Isle of Wight.
The Fairey Rotodyne was a 1950s British compound gyroplane designed and built by Fairey Aviation and intended for commercial and military uses. A development of the earlier Fairey Jet Gyrodyne, which had established a world helicopter speed record, the Rotodyne featured a tip-jet-powered rotor that burned a mixture of fuel and compressed air bled from two wing-mounted Napier Eland turboprops. The rotor was driven for vertical takeoffs, landings and hovering, as well as low-speed translational flight, but autorotated during cruise flight with all engine power applied to two propellers.
The Piasecki H-21 Workhorse/Shawnee is an American helicopter, the fourth of a line of tandem rotor helicopters designed and built by Piasecki Helicopter. Commonly called "the flying banana", it was a multi-mission helicopter, capable of being fitted with wheels, skis or floats.
The Hiller YH-32 Hornet is an American ultralight helicopter built by Hiller Aircraft in the early 1950s. It was a small and unique design because it was powered by two Hiller 8RJ2B ramjet engines mounted on the rotor blade tips which weigh 13 lb (5.9 kg) each and deliver an equivalent of 45 hp (34 kW) for a total of 90 hp (67 kW). Versions of the HJ-1 Hornet were built for the United States Army and the United States Navy in the early 1950s.
The Bell 47 is a single-rotor single-engine light helicopter manufactured by Bell Helicopter. It was based on the third Bell 30 prototype, which was the company's first helicopter designed by Arthur M. Young. The 47 became the first helicopter certified for civilian use on 8 March 1946. The first civilian delivery was made on 31 December 1946 to Helicopter Air Transport. More than 5,600 Bell 47s were produced, including those under license by Agusta in Italy, Kawasaki Heavy Industries in Japan, and Westland Aircraft in the United Kingdom. The Bell 47J Ranger is a modified version with a fully enclosed cabin and tail boom.
The Sikorsky HH-52 Seaguard is an early amphibious helicopter designed and produced by American helicopter manufacturer Sikorsky Aircraft. It was the first of the company's amphibious rotorcraft to fly and the United States Coast Guard's first turbine-powered helicopter and first amphibious helicopter.
The Kaman HH-43 Huskie is a helicopter developed and produced by the American rotorcraft manufacturer Kaman Aircraft. It is perhaps most distinctive for its use of twin intermeshing rotors, having been largely designed by the German aeronautical engineer Anton Flettner.
The Cierva C.30 is an autogyro designed by Juan de la Cierva and built under licence from the Cierva Autogiro Company by A V Roe & Co Ltd (Avro), Lioré-et-Olivier and Focke-Wulf.
A tip jet is a jet nozzle at the tip of some helicopter rotor blades, used to spin the rotor, much like a Catherine wheel firework. Tip jets replace the normal shaft drive and have the advantage of placing no torque on the airframe, thus not requiring the presence of a tail rotor. Some simple monocopters are composed of nothing but a single blade with a tip rocket.
The Cierva W.9 was a British 1940s experimental helicopter with a three-blade tilting-hub controlled main rotor, and torque compensation achieved using a jet of air discharged from the rear port side of the fuselage. The design was not further developed into production, and the prototype crashed in 1946.
The Cierva W.11 Air Horse was a helicopter developed by the Cierva Autogiro Company in the United Kingdom during the mid-1940s. The largest helicopter in the world at the time of its debut, the Air Horse was unusual for using three rotors mounted on outriggers, and driven by a single engine mounted inside the fuselage.
The Fairey FB-1 Gyrodyne is an experimental British rotorcraft that used single lifting rotor and a tractor propeller mounted on the tip of the starboard stub wing to provide both propulsion and anti-torque reaction.
The Cierva Autogiro Company was a British firm established in 1926 to develop the autogyro. The company was set up to further the designs of Juan de la Cierva, a Spanish engineer and pilot, with the financial backing of James George Weir, a Scottish industrialist and aviator.
The Gyrodyne RON Rotorcycle was a tiny, single-seat helicopter designed under contract for the United States Navy. in the mid-1950s. It later was redesigned for a U.S. Marine Corps requirement for a small personal helicopter that would fulfill an array of roles, including observation, liaison, small unit tactical maneuvers, and which could be dropped to downed airmen behind enemy lines to facilitate their escape.
The Bell H-13 Sioux is an American single-engine light helicopter built by Bell Helicopter and manufactured by Westland Aircraft under license for the British military as the Sioux AH.1 and HT.2. It was the first helicopter to be certified for civil use.
The Fairey Ultra-light Helicopter was a small British military helicopter intended to be used for reconnaissance and casualty evacuation, designed by the Fairey Aviation Company.
The Saro P.531 is a British all-metal five-seat helicopter designed and built by Saunders-Roe Limited (Saro). The P.531 was a larger development of the two-seat Saro Skeeter to use turbine power and formed the basis of the military Westland Scout and Westland Wasp helicopters.
The Saunders Helicogyre was a 1920s experimental helicopter designed by Vittorio Isacco and built by S.E. Saunders Limited for the British Air Ministry.