Fenestron

A Fenestron (sometimes alternatively referred to as a fantail or a "fan-in-fin" arrangementLeishman 2006, p. 321.) is an enclosed helicopter tail rotor that operates like a ducted fan. The term ''Fenestron'' is a trademark of multinational helicopter manufacturing consortium Airbus Helicopters (formerly known as Eurocopter). The word itself comes from the Occitan term for a ''small window'', and is ultimately derived from the Latin word '' fenestra'' for ''window''.Prouty, Ray. ''Helicopter Aerodynamics'', Helobooks, 1985, 2004. p. 266.

The Fenestron differs from a conventional open tail rotor by being integrally housed within the tail boom, and like the conventional tail rotor it replaces, functions to counteract the torque generated by the main rotor. While conventional tail rotors typically have two or four blades, Fenestrons have between seven and eighteen blades; these may have variable angular spacing so that the noise is distributed over different frequencies. By placing the fan within a duct, several distinct advantages over a conventional tail rotor are obtained, such as a reduction in tip vortex losses, the potential for substantial noise reduction, while also shielding both the tail rotor itself from collision damage and ground personnel from the hazard posed by a traditional spinning rotor.Leishman 2006, p. 324.

It was first developed for use on an operational rotorcraft by the French company Sud Aviation (now part of Airbus Helicopters), being first adopted upon the Aérospatiale Gazelle. Since then, the company (and its successors) have installed Fenestrons upon many of their helicopters. Other manufacturers have also made limited use of the Fenestron on some of their own products, including the American aerospace corporations Bell Textron and Boeing, the Russian rotorcraft manufacturer Kamov, the Chinese Harbin Aircraft Industry Group, and the Japanese conglomerate Kawasaki Heavy Industries.

History

The concept of the Fenestron was first patented in Great Britain by the Glaswegian engineering company G. & J. Weir Ltd. It was designed by British aeronautical engineer C. G. Pullin as an improvement to helicopters in British patent number 572417, and is registered as having been filed during May 1943. At that time, Weir had been participated in development work for the Cierva Autogiro Company, who was the holding company for the patent. In concept, the invention was to function as a viable replacement for the conventional tail rotor arrangement, aiming to produce improvements in both safety and performance upon such equipped rotorcraft.Prouty 2009, p. 266. However, this early work in Britain would not directly lead to any released product by Cierva making use of this innovation. Instead, the Fenestron would only be further developed during the 1960s by an unrelated company.

The Fenestron was first practically applied by the French aircraft manufacturer Sud Aviation, who had decided to introduce it upon the second experimental model of their in-development SA 340 (the first prototype had been furnished with a conventional anti-torque tail rotor).Leishman 2006, p. 43. The SA 340's fenestron was designed by French aerodynamicist Paul Fabre; unusually, this unit had its advancing blade set at the top in defiance of conventional practice, but this was reasoned to pose little impact upon this particular helicopter.Prouty 2009, p. 267. Fitted accordingly, on 12 April 1968, the SA 340 became the first rotorcraft to fly using a Fenestron tail unit.Huber, Mike
"The Fenestron Turns 50."
''AIN Online'', 12 April 2018. Having been determined to have been satisfactory, this tail unit was retained and was put into production on a refined model of the rotorcraft, which was designated Aérospatiale SA 341 Gazelle.

Over time, the design and performance of the Fenestron has been improved by Sud Aviation and its successor companies, as well as by other companies. During the late 1970s, Aérospatiale (which Sud Aviation had merged into) launched a second generation all-composite unit; it primarily featured a reversal of the blade's direction of rotation as well as adopting a 20 per cent larger diameter duct for greater efficiency. This unit was fitted onto the Aérospatiale SA 360 Dauphin, along with its more successful AS365 Dauphin model and its derivatives. While further flight experiments were conducted using an even larger Fenestron upon an SA 330 Puma medium lift helicopter around the same time frame, it was concluded that there were practical limits to how large a helicopter such a configuration would be suited to, and production examples of the Puma retained a conventional tail rotor instead.

During the 1990s, a third generation Fenestron was produced by Eurocopter (Aérospatiale's multinational successor), equipped with unevenly-spaced blades in order to optimize its noise levels; this unit was first fitted onto the company's EC135 helicopter, and was later incorporated into the designs of the EC130 and the EC145, the latter of which having original been produced for over a decade with a conventional tail rotor. During the 2010s, multinational helicopter manufacturer Airbus Helicopters (a rebranded version of the Eurocopter entity) developed the Fenestron further for their new H160, a medium-twin sized rotorcraft; in this revision, the fan duct was intentionally sloped by 12 degrees to achieve improved performance and greater stability when being operated with higher payloads and flown at lower speeds.

A Fenestron is normally paired with a larger vertical stabiliser unit that also performs the role of compensating for torque; this configuration has the effect of reducing wear on the Fenestron blades and transmission system, which in turn leads to maintenance savings. Furthermore, the adoption of larger diameter units, while posing some engineering challenges, normally increases their efficiency and decreases their power requirements. Advanced implementations of the Fenestron are provisioned with stators and adjustable weights in order to optimise the blades for a reduction in power required and pitch control loads imposed. During the 2010s, Airbus Helicopters stated that it expected the design of the Fenestron to continue to be refined, in order to suit rotorcraft of increasing tonnages and to enable additional innovations to be made in the field.

Through multiple mergers from Sud Aviation to Airbus Helicopters, a considerable number of light, intermediate, and medium weight helicopters have used the Fenestron as an anti-torque tail rotor. Such implementations can be found on many of Eurocopter's helicopter range, such as the Eurocopter EC120 Colibri, EC130 ECO Star, EC135 (and '' EC635'', the military version of the EC135), EC145, the AS365 N/N3 Dauphin (also built as the HH-65 Dolphin, a dedicated variant used by the United States Coast Guard, and the license-built Harbin Z-9), and the enlarged EC155 (a wider, heavier and more advanced version of the AS365 N/N3 series).Prouty 2009, pp. 266–267.

Other than Airbus Helicopters and its predecessors, other companies have also made use of Fenestron anti-torque arrangements. One such rotorcraft was the American Boeing/Sikorsky RAH-66 Comanche, a stealthy aerial reconnaissance helicopter which was canceled in 2004. Another example is the Sikorsky S-67 Blackhawk, which, in 1974, had a Fenestron for testing purposes used for 29 flight hours.Apostolo 1984, p. 89. It was removed in August the same year. Ducted fan tail rotors have also been used in the Russian Kamov Ka-60 medium-lift helicopter,Leishman 2006, p. 46. and also on the Japanese military's Kawasaki OH-1 Ninja reconnaissance rotorcraft. French light helicopter manufacturer Hélicoptères_Guimbal has also used a Fenestron for their Guimbal Cabri G2, a compact reciprocating engine-powered rotorcraft."Cabri G2 Fenestron."
''collegeaviationdegree.com'', Retrieved: 16 April 2018. Chinese Harbin Aircraft Industry Group use Fenestron in Z-19 reconnaissance/attack helicopter. American Bell Textron in Bell 360 Invictus proposed helicopter design intended to meet the United States Army requirement for a Future Attack Reconnaissance Aircraft.

Advantages

* Increased safety for people on the ground because the enclosure provides peripheral protection.
* Greatly reduced noise and vibration due to the enclosure of the blade tips and greater number of blades.Gey 2004, p. 180.
* A decrease in power requirements during the cruise phase of flight.
* Typically lighter and smaller than conventional counterparts.
* A lower susceptibility to foreign object damage because the enclosure makes it less likely to suck in loose objects such as small rocks.
* Enhanced anti-torque control efficiency and reduction in pilot workload.
* Reduced chance for the tail rotor to cause accidents, because it cannot strike the environment.

Disadvantages

The Fenestron's disadvantages are those common to all ducted fans when compared to propellers. They include:
* Greater weight, power requirement,Johnson 2013, p. 282. and air resistance brought by the enclosure;
* Higher construction and purchasing cost.Newman 2005,
* Increase in power required during the hover phase of flight.

See also

* NOTAR

References

Notes

Citations

Bibliography

* Corda, Stephen. ''Introduction to Aerospace Engineering with a Flight Test Perspective.'' John Wiley & Sons, 2017. .
* Gay, Daniel. ''Composite Materials: Design and Applications.'' CRC Press, 2014. .
* Johnson, Wayne. "Rotorcraft Aeromechanics." Cambridge University Press, 2013. .
* Leishman, Gordon L. "Principles of Helicopter Aerodynamics." Cambridge University Press, 2006. .
* Newman, Ron. ''The Technical, Aerodynamic & Performance Aspects of a Helicopter.'' BookBaby, 2015. .
* Prouty, Ray. ''Helicopter Aerodynamics Volume I.'' Lulu.com, 2009. .

External links

{{Commons category, Fenestron

Dave's All the World Fenestrons

Helicopter components
Ventilation fans