Sprite/Super Sprite | |
---|---|
de Havilland Super Sprite on display at the de Havilland Aircraft Museum | |
Type | Rocket engine |
National origin | United Kingdom |
Manufacturer | de Havilland Engine Company |
First run | May 1951 (first flight) |
The de Havilland Sprite is a British rocket engine that was built by de Havilland in the early-1950s for use in RATO (Rocket-assisted take off) applications. A developed engine with slightly less thrust but a longer burn time was known as the Super Sprite, production ceased in October 1960.
For RATO use only a short burn time is required, with simplicity and light weight as major virtues. The intended market was for assisting take-off of de Havilland Comet 1 airliners (as hot and high operations in the British Empire were considered important) and also for V bombers carrying heavy nuclear weapons. [1] [2] [3] 30 successful test flights were carried out by Comets, from May 1951, but gas turbine performance improved rapidly, and so RATO was not required in service.
A hydrogen peroxide monopropellant was used, decomposed into oxygen and steam over a metallic calcium catalyst. The maximum thrust was 5,000 lbf (22 kN), varying over the 16 second burn time for a total impulse of 55,000 seconds. [4]
A technology update then took place with the proving of silver-plated nickel gauze packs as catalysts with the establishment of optimum loadings and flows. This practice was replicated in all future applications with the catalyst no longer consumed.
In April 1952 the DSpr.2 proved this modification impressively in Comet demonstrations with clean exhaust. The next stage was pursued with the Super Sprite (DSpr.4) following the ATO development precedent with 'hot' operation but now enhanced in simplicity by ability to inject kerosene fuel once chamber pressure was established by the catalysed peroxide flow. The units, flight approved in August 1953, reverted to the practice of being parachuted after firing for routine re-use in service operations with the Vickers Valiant V bomber. [5]
The Super Sprite was a re-development of the Sprite application, using a significantly different 'hot' propellant technology, that of hydrogen peroxide / kerosene. [6] [7] Although the peak thrust was actually reduced, burn time was 2.5 times longer, with a proportionate increase in total impulse.
For simplicity, there were no fuel pumps and the tanks were pressurised by nitrogen from nine cylinders wrapped around the combustion chamber. [4] The Super Sprite was packaged as a self-contained engine in its own nacelle, jettisoned after take-off and retrieved by parachute. Inflatable air bags cushioned its impact with the ground. To obtain a clean separation from the carrier aircraft, the production engines fitted to the Vickers Valiant had a small canard vane at the nose, pitching the nacelle downwards on separation.
De Havilland regarded the 166 Super Sprite units manufactured as a standard production item, supported by their service department alongside piston and turbojet engines. It was the first rocket engine to gain formal type approval. [8]
The Super Sprite project was cancelled in October 1960, at a reported total cost of £850,000. [9]
Related development
Comparable engines
Related lists
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JATO is a type of assisted take-off for helping overloaded aircraft into the air by providing additional thrust in the form of small rockets. The term JATO is used interchangeably with the term RATO, for rocket-assisted take-off.
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A hypergolic propellant combination used in a rocket engine is one whose components spontaneously ignite when they come into contact with each other.
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