Category Helicopters

• All-weather transport helicopter • Gulf and Bosnia veteran

Building on its experience with the earlier, larger Super Frelon, Sud Aviation (later Aerospatiale) answered the French army’s call for an all-weather medium transport holicopter with the Puma. France and later Britain ordered sizeable fleets. Civil operators, too. found uses for what was to be the first all-weather helicopter in the West. Military and civil exports have flourished and the Puma is still in production almost 30 years later.

• Heavylift • Anti-submarine warfare • Assault transport

urope’s largest production helicopter, the Super Frelon was built with the assistance of Sikorsky. Used for assault transport, anti-submarine warfare and dolivory to ships, the SA 321 was also converted to fire Exocet missiles for Iraq in the war against Iran. More than 35 years after its first flight, the Super Frelon is still in service with the forces of China, France, Israel and Libya, mainly as a utility and assault transport aircraft.

▲ Although the market in heavy helicopters was dominated by Amencan and Soviet designs, the SA 321 achieved notablo oxport success. The aircraft went to war with Israeli forces m 1973 in the assault transport role, and has also been used to rescue French navy pilots.

Aerospatiale SA 321 Super Frelon

A Pick up

The Super Frelon was used by the Aeronavale for air-sea rescue duties from carriers.

Pacific deployment ^

A small number of Super Frelons worn deployed to France’s Pacific island nuclear test centres.

FACTS AND

► Iraq used Super Frelons. equipped with Omora radar and AM39 Exocot missilos, in anti-shipping strikes against Iran.

FIGURES

>■ In French naval service the Frelon equips three units: 33F and 20S at St Mandrier and 32F based at Lanveoc.

>• Production of tho Frelon continues in China, where the type is called the Z-8.

>• Israel re-enginod eight of its Super Frelons and sold them to Argentina.

>• The prototype troop-carrying Super Frelon first new on 7 December 1962.

► French Aeronavalo Sa 321s aro used to refuel naval vessels from the air.

Bravely entering a competitive market Uominated In Soviet ami Amencm design*, the Super Frelon was a derivative ul the original Frelon (Hornet). This large three-engined aireralt was designed to a French military rcquia-ment for a multi-role, inediiiin-si/ed helicopter with tile assistance r»l Sikorsky in the United States. Fiat in Italy were responsible for producing the main gearbox and transmission. The First pnMotypcs flew m

1962 and 1963. with the Aetonavale receiving the first Su(kt Freloas. equipped with a podded Sylph surveillance raiLir. in 1966. Some were later modified with nose-mounted radar and Hxotcl missiles for anti-ship attack, and the SA 321G.1 was delivered for utility transport duties. The 20 surviving Aerotlavale Super Fielons earn’ out search-and – rescue, vertical replenishment and transport duties, having largely relinquished tlicir

Above: There is little externally, except for camouflage, to distinguish the transport Super Frelons from their maritime counterparts.

anti-submarine warfare role The Super Frelon was exported to Iraq. Israel. Libya and South Africa. A 27-se-.it civil heli liner variant, the SA 321.1 was also produced but not widely used

Below: A total of 99 French-built Super Frelons were produced.

The type also flew as a fire-fighter and hell-liner.

MAXIMUM SPEED

SA 321 Super Frelon

Power is prortJoo by tfvee frabomeco Tixmo IttC engnes. Fuel ts stored n texbie tanks irx3e« the floor ol the centre tusetoge. these helps to tower the centre of gravity.

The rotor в а мх Uadud, My-arhcttoiod uni. Tlw Aral tow rotor ixxte were groi/xl tested in the Urn! or I Slates The Wades are of al-metai

G«nm ji>y. the bggesi rwucopter* лги aho the Ltsiew Th* Super Fiaron n a powarful machine well a Uronrrtned fuselage shape and a high top speed ГПс SA 32t» purchased by brnrl had new engines fitted. greno mproved performance

The Super Frelon remains in limited use In the AOronavale, although it has now given up its former roles of anti-submarine and anti-ship warfare.

SA 321 SUPER FREID* 275 IjMi (171 m. p.».)

»-3M

W km* (U6 «.M l

The Supe Fnftm fiaa а поев’ mcHnted radar tor r*Wr slip work

MM4 НАЛ – no ka.1i (t«3 m. p k. l

ШШ sa 32i swu. nan tot-jfandraiull іВ7вкт|Ш h-icootprs requre tone r. v<gt in t» «ftocltm They can ouppiomert the/ patiol endurance By carrying CM hovonno r**uo*» irom Oev.«r, tr% wh<n. ve loo amal lo actuary lend on and can i вяз ortim cany •*»» infernal ‘ и tuM tor Inrry fights The naval M*-t4 а їлиійу thor*-baaed

I COS ka (124 nl»’ Я

The tal rotor Is a flve-ttaded unit ot ormitt construction to the mam rotor, rotating at 990 revokitcns per rrWxtte The rotor в driven by gearing Irom me shaft inking the rear and pen toward engines.

The man cabn houses up to 28 troops n the assault transport rote. Exocet speaM the fusotogo wdcs The і rwi have tho stabdsmg floats which ore fitted to tho SA 32IG

ARMAMENT

Мов na. nl h»acopccri carry a two torpedo or two-meala amamenl. The Russians are unusual n rarely railing trier hdcoptars. tm a becauae they rdy on long-ranged antl-auCmame manioc SS-N-14, when are f*ed Irom «arshpt

Я MIL Ml-8 ‘HAZE’: The most numerous hencopter ever buUL the Mi-8 (and the newer, more powerful Mi-17) remain in service with navies, armies and in crvAan roles around the world.

SA *21 SU«A FRUON SM-3M МИ4 НАЛ’ 4 taryaden 2 lorpedm 2 teryedoei or 2 Eiacets or 2 Emcth

Aerospatiale (Westland)

• Alpine search and rescue • Unrivalled high-altitude performance

igh in the Alps, the Alouette is a guardian angel – risking fierce winds, snow, ice and treacherous terrain to rescue those in trouble on Europe’s high mountains. The highly successful Alouette is found in dozens of nations performing hundreds of jobs. None have become better known than its dramatic mercy missions, which it carries out at great risk to the crew to save those in peril.

◄ Vintage gunship A

Using AS-11 rockets and heavy cannon, the Alouette was a pioneer in the development ol helicopter gunships. The Alouette served in the war in Algeria with French forces, and also in the Rhodesian civil war.

FACTS AND

^ In Juno 1960 an Alouolto III proved that it could operate at 4810 m (15,780 ft.) on Mont Blanc, Europe’s highest mountain.

The first flight of the Alouette III took place on 28 February 1959.

^ On 21 June 1972, an SA 315B Lama (Alouetto II airframe and III engine) set a height record of 12442 m (40,820 ft).

FIGURES

Alouettes also servo as light transports, agncultural, liaison, observation and photo-mapping aircraft.

The Alouette III has an oxternal sling for loads up to 750 kg (t,650 lb.) or a rescue hoist which can lift 175 kg (400 lb.).

^ Indian Alouettes regularly operate in the Himalayas, the world’s highest mountains.

Aerospatiale Alouette III
Alouette III Type: general-purpose helicopter Powerplanl: on* 870-kW <870»hp.) Turbomoca Artouste HIB hjrboshatt derated to 425 kW/550 shp. (SA-316BI. ono &49-kW/870-shp TurbomOca Astazou XIV turboshaft derated to 448 kV/600 shp. (SA-319C) Maximum speed: 210 km/h <137 m p h i at sea level Hovering ceiling in ground effect: 2880 m (8.400 ft I Hovering ceiling out ol ground effect: 1520 m (5.000 ft I Range: 480 km (375 mi.) Weights: empty 1143 kg (2.440 ip ): lo. ldod 2200 kg <4.960 to.) Dimensions: rotor diameter 11.02 m (36 ft. 2 m.) length (btodra foldedi 10.03 m (33 ft.)
III has reached operators in numlxrrs exceeding 1,500 In every climate, the Alouette is a versatile aircraft and military operators have used tlte Alouette 111 lor light-attack and anti submarine duties However, it has become famous for living life-saving missions in mountain ranges the world over
French Alouettes have performed a variety of jobs. As a military light utility transport they havo boon replaced by the Gazelle and Puma, but the Gendarmerie continues to approciato its superb high-altitude performance in the mountains.
The Atouoito »v»s о traditional twigoc! rotor head wth throe rotor binder Draper; it* CW design tho Atouoito s и nmiblo maebno and m wrti liked by ptotj.
bought wing area	3.00 m |9 ft. 10 in) 95 38 m-(1,027 ft I
Tt/bomecak Astarou газ proved lo be a refcabto and powodii engine. Tho Astarcuk *ght wwgfit and hqh powv output grw the Atouotto much at 4s tomous porlamanco at altitude
The roomy catwi & a uselir feature kv search and гекие Six разаэтд»» can be caned, or two soetenrrs and two seated passengers n the casualty BVOCUAtW. IOW
tat rotors are a vulnerable areo of arty hobcopter. and even with this 4 largo guaro beTOw il Iho p«to1 r, aways corncmed aboul the tail Tho successors to too Ateuotto havo on enclosed tail rotor m a fonrasren’ fin mounting, for protection and mproved pnrtormanc*.
ACTION DATA
Tt« бік passenger seats in the siandanf Alouetie ink roomy caton can гулску be removed The hetcopfer then becomes a »ghi cargo transport, abto to Ift payloads of cp to 750 kg (1,660 lb.}.	The fins on the tatooom gr. o added stabdty m terwaro hgtit. and ofeo hofp the prot k«© a steady hover wnen pertormng doscato rescue manoeuvres in tvgn wind conditions.
SERVICE CEILING
I Any Alouettes have worries and spothghts fitted tor tght transport. I he maxmum 750-kg 11.650-ID.) pa/oed can 350 tie earned etternaty on a sing
Th*>ny lone МоиеПе Шbgrvaetudo рчПотцпж а от ни о» fhtfirtomer-
ardru
w/r*
юмі lor люилимі песий h« Qwoto nho 4100 ■ 0 MOO П.|
Alouettes in the mountains ■ UNDERCARRIAGE: The ski-cguipped undcrcantoge of an AJouotlo in a high mountain valley shows that it operate* her© all year round. The w;irm summer weather in this picture makes the helicopter’s performance lower than usual, as the a. r density « reduced even more.
■ RESCUE VETERAN: Thousands ot pooplo owe the* lives to the Alouette for saving them in daring winch rescues. This mission needs careful work between all three crew – the pilot, winch operator and the winchmon Long periods in the hover also demand the good performance given by the Alouette.
■ SNOW OPERATIONS: The Alooette’s етап s»ze. light weight, lorgrving Hying characteristics and ski undercarriage are essential whon operating on snow. Heavy hoilcoptcrr. with normal wheels would probably get stuck in these conations, as wen as finding it hard to fly in the thin alpine air.

Aerospatiale

• High altitude • Air ambulance • Excellent handling

Sud-Est, one of the forerunners of

Aerospatiale, combined Turbomeca’s new Artouste turbine with a gearbox adapted from the Sikorsky S-55 to produce power for the Alouette. It flew for the first time in March 1955, and within three months the machine had set a new helicopter altitude record of 8209 m (26,925 ft). Two years later an Alouette raised the record to 10984 m (36,028 ft.). This altitude performance made the aircraft a natural candidate for mountain rescuos.

Airborne ambulance ►

Once retrieved from the mountain, survivors are flown to hospital m special fuselage stretchers.

A The search is on

Pilots often look for the survivors themselves, exploiting the excellent visibility from the Alouotto’s cockpit.

Star performer ►

Demonstrating the capabilities of the helicopter is this example, lifting a large balloon as part of a publicity stunt. Crews find the helicopter a delight to fly.

FACTS AND

Tho Alouette II first flow on 12 March 1955: French certification on 2 Мзу 1956 cleared the way for production.

Germany has used the helicopter for more than 25 years without any crashes.

Because of the shape of the fuselago tho helicopter is known as ‘bug-eye.*

FIGURES

Options available for the helicopter include skid landing gear, floats or a wheelod undorcarriage.

In the rescuo role the Alouette has a 120-kg (264-lb.) capable hoist.

^ Many civilian oxamplos operating today are ex-military machines.

Even Ivfore flight testing h;u! Ічч-п completed, the Alouette II was showing its abilities as a mountain rescue aircT. ill The second prototype Alouette II was in the Alps lot performance tests in July 1956 when the test team learned that a clinilier was dying after liaving a heart attack in the Valid Mountain refuge, one of die highest in Enrol*’ at )56J ill (1 1.^07 ft.)

Tlic liisj attempt at a rescue was unsuccessful, I ни the second worked, within five minutes of landing the helicopter had

Help from above

transported the ilnnlier to hospual in Clumonix. thereby saving his life.

At the Ixrginning of 1957 two Alouette* t arried c Hit a similar rescue, retrieving six mountain guides, and two pilots of an rescue helicopter which had crashed, from the same refuge

Since tlien the Alouette II and its high altitude version, the lama, have carried out mail) mountain rescues, retrieving stranded climlH-Ts from places that would not have Інч*п reachable by any other means

Aerospatiale

s long ago as the fourth century

iu., children in China were playing with a little toy whose principle would lx* used hundreds of years later to bring a new dimension to the science of flight It was a simple round stick with feathers mounted on top. each feather twisted slightly so that it struck the air at an angle when the stick was spun.

creating enough lift to enable the device to fly up into the air. Two hundred yeans later. Archimedes of Syracuse* – the Greek physicist and inventor who was responsible for many scientific discoveries that laid the foundations of modern science – hit u|KMi exactly the same principle lor use in a different medium.

I le perfected a rotating screw which.

when fined inside a cylinder, made an excellent water-pump Rotated continuously inside the cylinder, the screw puslied against the water and moved it along, and this in turn gave rise to a reaction: the water resisted In pushing hack. Two thousand years were to elapse before the principle that governed the operation of Archimedes’ screw in w ater

Above: The European-manufactured EH. 101 Merlin is one of the now generation of large multi-role helicopters.

Right: The CH-53E is currently the West’s most powerful helicopter.

Far right: The tandem-seat AH-64 Apache is one of the leading battlofiold helicopters in the world, and packs a powerful punch.

was applied to another fluid – air – to produce a lifting force.

On 13 Xovcmlxx 1907. a Frenchman named Paul Cornu made the world’s first free, untethered, manned helicopter flight at Coquainvilliers. near Lisieux. His primitive machine – known as the flying bicycle’ – hovered 50 cm (I ft) clear of the ground for 30 seconds. It would l>e

nuiny years before ibe dream ol vertical flight became.1 practical reality, but it was a beginning.

The early pioneers of rotary-wing flight faced a formidable challenge, because to make a helicopter (die name means, literally, flying screw > fly successfully, several different principles must lx* brought together. The first of these is lift.

The cross-section of a helicopter blade is of aerofoil shape, just like the wing section of a conventional aircraft. The top surface of this aerofoil section is more curved, or canilx*red. than the under surface, so that when a stream of air Hows over it the speed of the air increases and its pressure decreases. Under the wing the opposite happens; since the wing is

Introduction

usually inclined at ;i small angle to the airflow, the air passing underneath it is slowed down by Ix’ing obstructed and the pressure increases. Hie high pressure area IK’l<>\ the wing tries to move towards the low pressure area above the wing, and a lifting force is created.

Л conventional aircraft has to move forward through the air to reach the speed
where enough lift is obtained to take it off the ground, but with a helicopter, the wings – or rotor blades – are gien motion through the air by rotation, even when the aircraft is not moving.

The amount of lift produced by a helicopter’s rotor blades depends on three things: the shape and size of the blades, the speed at which they rotate, and their

angle of attack – the angle at whic h they bile into the air One or more of these factors must Ik* increased if* the lift is to lie increased. The first two iwesibilities are both ruled out; there is nothing the pilot can do to alter the size of the blades, nor has he the reserves of engine power at his dis|X>sa! vers – quickly when he needs extra lift.

He can. however, alter the angle of

attack, for the main rotor blades of a helicopter can lie automatically ‘feathered – in other words, made to twist in the rotor hub. If the angle ol attack of all the blades is increased at the same time, there is a sudden increase in total lift, and when the lift Ivcomes greater than the weight, the helicopter rises off the ground. Once airborne, the pilot can

UNITED NATIONS

Loft: The Eurocopter Panther is one of a number of highly successful multi-role helicopters built by Aerospatiale and then Eurocoptcr.

Above: Mil Mi-26s have been used on United Nations humanitarian relief operations in recent years.

Right: Igor Sikorsky pictured piloting his first successful helicopter, the VS300. in 1939.

Far right: A Wallis autogyro in the colours of the Royal Air Force.

make the aircraft hover by slightly reducing tlie angle of attack of the blades so the total lift of the rotor now balances the weight of the helicopter. ‘Го alter the angle of attack of all blades at the same moment the pilot uses a lever known as the collective pitch control.

The helicopter is now off the ground and hovering, but to make it move
forward through the air some 1‘onn of horizontal thrust is needed. A conventional aircraft achieves this by means of its propeller or jet exhaust; in a helicopter, the lift force is tilled slightly to produce a horizontal thrust component. Tills can lx* achieved by lilting the whole rotor assembly slightly forward, but in practice it was found more effective to

h*nge each blade to the rotor huh so that it сап Пар’ up and down. When the helicopter is motionless on the ground, its rotor blades have a noticeable ‘droop* because of this hinge arrangement; a slop is fitted lx*Um each blade to prevent it drooping too far When the main rotor starts t« * revolve at inc reasing speed, centripetal force (the force that is exerted

Above: The Piasecki/Voriol H-21 was flown in Sabcna colours at the 1958 World’s Fair.

Right: The Flcttncr FL 282 Kolibri appeared towards the end of World War II and was one of the world’s first successful military helicopters.

when you swing a weight around on a piece of string) tends to lilt the blades back to a horizontal position.

As each blade is feathered its angle of attack increased to produce more lift it rises slightly on its hinge. II the angle of attack is reduced slightly as it approaches the forward position on its way around the rotor disc, the lift is

Introduction

slightly reduced loo; and if the angle of attack is inc reased again as the blade retreats’ rearwards so the lift is increased – with the result that each blade flaps downwards as it revolves through the forward position under the influence of centripetal force and rises under the influence of lift as it passes around the rear of the disc.

The whole effect is of the rotor disc tilting forward to produce forward thrust, with each blade changing its pitch as it moves round. This change of pitch is automatic and is governed by the cyclic pitch control.

If the helicopter consisted only of a set of main rotor blades mounted on the fuselage, the reaction to the rotor as it

revolved would lurn the fuselage in I III* opposite direction. Tliis is known as torque effect. and is nornially overcome by a small vertically-revolving rotor mounted at tile tail to prevent the fuselage from swinging round.

To operate all the helicopter’s mechanical devices, the pilot has four main controls: the collective pitch control, the throttle, the cyclic pitch control and the tail rotor control.

In the 1920s. while designers struggled to overcome the problems of helicopter design, a young Spanish aircraft designer named Juan de la Сп іл а (Jordonia came up with an alternative, which he named the autogiro In this machine, lift was provided by a frecly-windinilling rotor, and forward propulsion by a conventional aero-engine. Although the autogiro could never jHTlorm all the functions of a helicopter, it had practical applications in

both civilian and military fields, and was widely used in the years lx*tween the two world wars.

It was left to the inventive Germans to produce the world s first truly successful helicopter, the twin-rotor Focke-Wull Fw 61. Designed by Professor Heinrich Focke. it first flew in 19.56 and went on to establish a numlx-r of world records. For the next few years, the Germans enjoyed an undisputed lead in helicopter
development, I ho I wo companies. it the forefront Ix’ing I«кkc Schgelis and Hetiner. ‘lliese firms pioneered the operational use of the helicopter In World War II. both as an air observation platform anil a transport vehicle. On the Allied side, one name quickly came to the forefront of helicopter design: that ol Igor Sikorsky. It is a name that still stands at the forefront of medium and heavy helicopter design unlay Another American

Far left: Tho huge twin-rotor Mil V-12 shattered every record for hclicoptor payload.

Lett Pescara’s No.3 helicopter, the first to incorporate collective and cyclic controls.

Right: The giant Mil Mi-6 pioneered the use of supplementary wings for extra lift.

Far nght: The Sikorsky S-61 is one of the most common search and rescue helicopters.

firm, Bell Helicopters, dominated the post­war market Гог lighter machines, ranging from utility to Гам attack helicopters In tin Soviet Union, Igor Sikorsky’s opposite numlx-r was Aitem I Mil. whose design bureau was responsible Гог a range of massive heavy-lilt helicopters. By the beginning of the 21st century, more than 30.0Ш Mil helicopters had been Іміііі, with manv of tlx-.se rugged machines remaining in service worldwide.

.. -«nc? economics

". Western toi |o 1|U|

eventuallv conip1 l, c

specialised in lielicopicr prixluafon to join forces. liuuxopier is now I 111- official manufacturer of all МНИ and Aerospatiale helicopters, and Britain’s Westland now operates under the name GKN Westland.

In common with other types of aircraft. Ix>th civil and military, helicopters arc – now the subject of joint design and production on 14*11 sides of the Atlantic.

Introduction

Today, helicopters are applied to so many diflfcrcni tasks that it is difficult to list them all. They are the most versatile flying machines in existence, and they enable the pilot to operate in three dinK*nsions in a way that no fixed-wing aircraft can – except, ot course, VSTOL machines like the Harrier, which are intended for a specific role and which are by no means as prolific.

The helicopter, for all that it is expensive to operate, has become an
indispensable tool of modern aviation. New technology, in particular the use of advanced composite materials of far greater strength and lightness than anything previously available, has given designers the means to enter a new phase of development that combines greater speeds with lower operating costs. It is in the commercial world of tomorrow that the helicopter will make its greatest impact.

Aerospatiale

• Middle Eastern favourite • Combat proven • Assault transport

A tactical transport helicopter based on the anti-submarine Sea King, the Commando dispenses with the naval equipment to make room for troops, cargo or casualties. Operated in various versions as troop and VIP transport, electronic warfare platform and anti-ship helicopter by several overseas air arms, as well as the Royal Navy, it has seen service in the Falkland Islands, the Persian Gulf and Bosnia.

Westland Commando

▼ Commando production

Wearing a ‘class B’ registration, this Commando is undergoing pre-delivery test flying. The aircraft has been produced in some numbers for export.

▲ Sponsons gone

Neither the Commando Mk 2 nor the Sea King HC. Mk 4 have the distinctive undercarriage sponsons of the Sea King.

Egyptian assault ►

Having used the early Commando Mk 1, Egypt later purchased the Mk 2. The aircraft are often flown without sand filters.

Qatari ship killers ►

Qatar may have added upgraded Commando Mk 2As to its fleet of Mk 3s. Tho latter aircraft represent a powerful maritime strike effort.

◄ VIPs on the Mk 2B

Egypt’s Mk 2Bs have air-conditioning and a thoroughly soundproofed cabin.

FACTS AND FIGURES

► The Commando Mk 1 is also known as the Sea King Mk 70 and is basically a stripped-out Sea King HAS. Mk 1.

> No customer has ever specified tho Mk 2’s optional underwing hardpoints.

>■ Westland flew the first commando Mk 2 on 16 January 1975.

► An idea to fit the Commando Mk 2 with 26 inflatable cabin seats was abandoned at an early stage.

>■ Commando Mk 2Bs have extra seats for two flight attendants.

>■ Qatar’s Mk 3s have Sea King-like undercarriage sponsons.

Commando Mk 2 Type: tactical notary helicopter Powerplant: two 1238-kW (1.680-ftp.) Rolls – Royce Gnome H.1400-1T turboshafts Maximum cruising speed: 204 km/h 026 m. p.h.) nt sea level Range: 396 Km (245 m) with maximum payload: 1482 Km (920 mi I with standard fuel Hover ceiling: 1980 m (6 500 It) m ground enact Weights: empty operating 5620 kg (12.364 m > maximum take-off 9752 kg (21.455 lb) Accommodation: two crew plus up to 28 troops Dimensions: main rotor diameter 18.9 m (62 ft.) fuselage length 17.02 m (55 ft. 10 m.) height 4.7? m (15 ft. 6 m.) man rotor tfcsc area 280.47 m'(3.018 sq ft
Вам-d on llic Sea King MK »l, ilit – original Commando MK I was developed by Woiland in the hope that it might he ordered to replace the Koyal Navy’s Wessex Commando helicopters In the event, no initial British interest was expressed and the Egyptian air hiree placed the first oixki Tile MK I hail minim. il modifications, Ін» the MK 2 has a fixed undeu arrrage. an Лі I va need Sea King tail unit and composite rot<ir blades. HgV|* acquired I’ standard Mk Js. plus two Mk 2H VII’ transport versions and four NIK 21. electronic warfare variants. A) upcrulors of tho Commando trooientry игл чи» overall m harm, sandy onwrorxnonts. Sand «Попі tor tho ongno mljKua ore ІГлгиІию a uaetii optorv
Wesilnnd kngftionod tho cabn of ltd Commando, although exlom. il dnrwKrons die urtertomd. Іо лг. пж-лі tie. Ihn rn. r IxAhexvi was moved alt by 1.7 motne (5 ft, 7 m l
AJhough it nftsncU the boat-shaped hut c* Ihe Sea K/g the Commando dtspensed w. tn V» ftttroclaofe mam wtxMrls and ihe spensons wth the* associated notation txjmpmoni TTxj smrpto stub wmg-moemtea undercamogt мда wwgre and «кгсэдвз левЬопз-сапупд ab*ty, anc may be fiireo with mmovobto emergency flotation pucks.
SKYHAWK ATTACK: Aftor dobverng a cargo ot tQ6-mm art dory shells to a forward location. ZA298. a Sea King HC. Mk 4 of No 846 Naval An Squadron, was attacked by an Л-4В Sky hawk. The main rotor was hit by 20-mm cannon fire, despite tho pilot’s evasion tactics, but a replacement tilado was flown in and the helioootor was repaired in the brio
Royal Navy Commandos in the Falklands
TAKING THE NARWAL: Following a Sea Hamer attack on the Argentine spy trawler Naiwal. two Sea King HC MK 4s and an HAS Mk 5 took the crew prisoner
whan convomd to tho older Wnssex and itw RMCPvrei •ICMk I.

riginating m the Anglo – French Ik’llinpler agreement of 1967. the Westland Lynx is one of rite most advanced medium shiplxirnc helicopters in ІІК* vvoi Id The Royal Navy and French Athnnavulc wen* die ftnq users of the type. Init it lus since Iven ordered liy «tight oilier navies.

Alii* nigh with a crew of two or three its maximum weight is only 1600 kg і 10.120 Hi >. the Lynx can perfonn a wide variety of naval tasks Its primaiy function is anti submarine

Tlw nose con tare the odionoed Seaspray radar for surface search British Lynxes use я to gude tlw Sea Skua jntiVxp mcssAs.

The Lynx has been the most successful small shipboard helicopter of the post-war period. It combines small size and high performance with excellent handling at sea, advanced – technology sonar and weapons, and unmatched multi-role capability.

The Lynx crew consists о* a plot and observer (tactical systems operator) litting sido by ado m the cockpl. Some users also ііяглі n crewman m tlw mar cabn, lor sonor- oporabng or roacuo woik

Lynx HAS. Mk 2 (FN)

Type: shipboard anti-submanmc ant.-ship, and rvscuo heftcoptor

Powerplant: two 836-kW (i. 120-hp) Rolls – Royce Gem 41-1 turboshaft engines

Max speed: 322 km/h (200 m p hj

Max cruising speed: 232 km/h (140 m p. h.)

Range: uyp«caO 590 km (365 m*)

Weights: empty 3030 kg (6.670 0> I. max loaded 4763 kg (10.479 lb.)

Armament: iwin Mk 44. Mk 46 or Sting Ray ASW torpedoes or Mk II depth charges plus anti submarine sensor systems, or (our Sea Skua or similar anti-ship missiles: provision tor 1361-kg (2.995-lb ) siung cargo

Dimensions:

main rotor diameter 12.8 m (42 ft)

tongth 11.93 m (39 ft.)

height 3.6 m (12 (1.)

COMBAT DATA

MAXIMUM CRUISING SPEED

737 toll ІНОт р » I

ARMAMENT

Lynx Sea Skua attack
■ SOLID FUEL; The Sea Skua is powered by a sokt rocket, and can be handled and stored like ammunition		■ SEA SKIMMER: To avoid oeieciion on onemy radar, the 1000-knvh (600- m p. h,) Sea Skua is programmed to (ly lust above the surfaco of the water	■ TARGET DESTROYED: A Waxing Iraqi patrol boot proves tlw devastating erect or the Sea Skua’s ?0-kg (44-lb.) armour-piercing warhead
SM-jsusmit tax Prnpie типе» и la* li|M»*leai Uiprtui

Westland

• Anti-submarine helicopter • Missile-armed anti-ship strike

Naval helicopters have added a new

dimension to naval warfare. Blooded in the Falkland» and used to deadly effect in the Gulf, the Westland Lynx, flown by the Royal Navy and other maritime services, is one of the most capable and versatile of the breed.

In addition to hunting for submarines and attacking with torpedoes, depth charges or mines, it can track down even the fastest of surface vessels with onboard radar, striking with highly accurate air-to-surface missiles.

Westland Lynx (Navy)

Super Lynx>

The very Most Lynx variants have a 360 radar capability. passtvo infra-red sensors and medial and satcAte navigation systems.

▲ War veteran

Britain’s Fleet Air Arm has used the Lynx to devastating effect in modern mantime confrontations. It made its name launching Sea Skua missiles against Argentine craft.

A Marine! lieger

The German Mannefheger operates its Sea Lynx helicopters from ‘Bromcn’-class frigates in the anti-submarine role. Unlike British Lynxes, the Marincthcger versions have a dipping sonar fitted. Tho unit. MFG 3. is basod at NordhoU when it is not deployed at sea.

While it was not specifically built for rescue missions, all Lynxes are capable of this, and most end up doing a rescue at some stage. Dutch navy Lynxes aro also equipped with dunking sonar.

FACTS AND FIGURES

>■ The first Lynx prototypo made its initial flight on 21 March 1971.

>■ The naval Lynx made its maiden flight on 10 February 1976.

Most export Lynxes, like the nine used by tho Brazilian navy, are based on Britain’s HAS. Mk 2.

► Britain’s first naval Lynx unit was No. 702 Squadron, Royal Navy, at Yeovilton, formed in December 1977.

>■ The Norwegian air forco uses tho naval Lynx for unarmed rescue missions.

► A modified Lynx holds tho holicoptor world speed record.

• Anti-tank • Tactical transport • Gulf War veteran

Westland and Aerospatiale

produced the Lynx, together with the Puma and Gazelle, under the Anglo-French helicopter agreement of 1967. The first of 13 prototypes flew in March 1971, and subsequent production includes both army and navy versions. Unlike its naval counterpart, the Army Lynx has not attracted export orders, but it has beon developed into the British Army’s main battlefield helicopter.

A Humanitarian Lynx

Britain’s army, hko many European forces, has dedicated a number of aircraft to United Nations’ support missions.

▼ Looking tor exports

Lynx 3 was a bold attempt by Westland to wm export orders and was marketed soveral times.

A TOW attack

Using natural cover as its only defence, a Lynx AH. Mk t unleashes a TOW missile at an unsuspecting tank. The missile’s guide wires can lust bo soon at the mouth of the launch tube

FACTS AND FIGURES

> Westland planned to build 16 WG.13 prototypes because It considered the programme so technically demanding.

> Modified Scout holicoptors were used to test the Lynx’s main rotor system.

> An Army Lynx was rolled out publicly for the first time at Farnborough In 1972.

► During 1977 the Army Air Corps recoivod its first production Lynx; the aircraft bccamo operational in 1978.

► Lynx AH. Mk 1s wore converted to AH. Mk 7 standard by the Royal Navy.

► Soveral fcaturos of the Lynx 3 were incorporated into tho AH. Mk 9.

Designated ЛІІ. Мк I, tlur first Anny Lynxes wva* delivered in l‘>7~ lliey и mid carry nine trou|>>. глеч 1350 kg і. З.ООО lb.) of external cargo or eight TOW fTtilx– bundled. Optically-tracked. W’in– guidtxl) missiles, aimed using.1 sight on tlie і. d tin tool More powerful Oem il engines weir introduced in the ЛІІ. Мк in jddiiHin 10 impronxl avionics. iikI a nx»e power! ul tail rotor. This enabled tlx? helicopter to remain m the hover when

carrying tile heavy loads involved in anttaimicNir operations.

Hie final Army Ліг Corps version was die – ARM к 9, which has w heels instead of skids and <UIfusers to reduce 1 Ik* mfr. i-пчі signature of tlie exltaust. Ii serves with tin – two sqtiadnMVs formed to мі{цх»п the rapid intervention 2nit Armoured Brigade*.

< )ne-o4l experimental anti trials versions of the Army l. vnx include a lly-lty wire conversion Of an ЛІІ. Мк 7 and a single ЛН. Мк 5X wnli (iem il engines

Above: Currently, the Lynx AH. Mk 9 has no TOW compatibility. II funding permits this could bo added later, but the capability seems irrelevant following tho recent purchase of the AAC Apache.

A few other Al l Mk 5s were built, and although most were completed as All Mk “s. one of the tk*vclo|>ment aircraft was useil for mglil-llying trials using a helmet-mounted display*.

ACTION DATA
Up to nne sorters court be свгтіЕгі n the mart r-.tr, m of Р» AH Mk і. or ax with fK combat equprnent A common transport rrtsson lor the Lynx « the forward movement and швелоп of Men-anred anti tank teams	Westland rttrpduced a sernmgirl mam rotor noad on the Lyrw lbs system vwb tar less nuky and cornpiex than pie-nous systems. arvl it improved pe-frymance and handing ugnifcancy
British Aerospace, under bconco from Hughes, bud the Lynx tool’thou-rite! it. Лм-я ігшчбкі mnyrmolnp to
The i’ll Mk 1 featured a counter-clockwise-rourng lid rotor On Iho u|>;y, tiled AH. Mk 7 it has been replaced by a more powerful ckxkwr&e >otiitng unit medo from compoetn malntia». when gives hotter control n the hover
Л *j«i ir«x«a»nagn nlows the hotcoptor to operate from a variety ot r. xtacen without ttvp •tsk of smtang «to soft ground
Hughes manutacturod tho tOWnussics wficfi am »k! lynx’s рппорої ant – tank armomryil OpJcrvi woopona mckidu air to-л» ттаел a’kt gun nr rocket pods
В GAZELLE: Co-produced with Aerospatiale, tho Gazelle took over the battletield observation rolo from tho Scout
В SCOUT: Also built as the ruval Wasp, the Scout was the AAC’s primary observation and attack helicopter before the Lynx and Gazelle

Westland